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NB-23 2015 NATIONAL BOARD INSPECTION CODE 2015 EDITION DATE OF ISSUE — JULY 1, 2015 This code was developed under procedures accredited as meeting the criteria for American National Standards. The Consensus Committee that approved the code was balanced to ensure that individuals from competent and concerned interests had an opportunity to participate. The proposed code was made available for public review and comment, which provided an opportunity for additional public input from industry, academia, regulatory and jurisdictional agencies, and the public-at-large. The National Board does not “approve,” “rate,” or “endorse” any item, construction, proprietary device, or activity. The National Board does not take any position with respect to the validity of any patent rights asserted in connection with any items mentioned in this document, and does not undertake to insure anyone utilizing a standard against liability for infringement of any applicable Letters Patent, nor assume any such liability. Users of a code are expressly advised that determination of the validity of any such patent rights, and the risk of infringement of such rights, is entirely their own responsibility. Participation by federal agency representative(s) or person(s) affliated as government or industry endorsement of this code. itt inddstry is not to be interpreted The National Board accepts responsibility for only those interpretations issued in accordance with governing National Board procedures and policies that preclude the issuance of interpretations by individual committee members. The footnotes in this document are part of this American National Standard. R R ® R NR Tte above National Board symbols are registered R itt tte US Patent Off “National Board” is the abbreviation for The National Board of Boiler and Pressure Vessel Inspectors. No part of this document may be reproduced in any form, in an electronic retrieval system or otherwise, without the prior written permission of the publisher. All charts, graphs, tables, and other criteria that have been reprinted from the ASME Boiler and Pressure Vessel Code, Sections I, IV, VIII, and X are used with the permission of the American Society of Mechanical Engineers. All Rights Reserved. Library of Congress Catalog Card No. 52-44738 Printed in the United States of America All Rights Reserved www.nationalboard.org Copyright © 2015 by THE NATIONAL BOARD OF BOILER & PRESSURE VESSEL INSPECTORS All rights reserved Printed in U.S.A. I 2015 NATIONAL BOARD INSPECTION CODE PART 1 — INSTALLATION TABLE OF CONTENTS Introduction .........................................................................VIII Foreword ..........................................................................XI Personnel .........................................................................XIII Section 1 1.1 1.2 1.3 1.4 1.4.1 1.4.2 1.4.3 1.4.4 1.4.5 1.4.5.1 1.4.5.1.1 1.5 General Guidelines.......................................................... 1 Scope .....................................................................1 Purpose ................................................................... 1 Application of these Rules ..................................................... 1 Certif ............................. 1 Responsibility ............................................................... 1 Equipment Certifactiin ........................................................ 2 Jurisdiatiincl Review .......................................................... 2 Inspection ..................................................................2 Boiler Installation Report .......................................................2 Biiler Instcllctiin Repirt Firm ...................................................3 Guide fir Cimpleting Nctiincl Bicrd Biiler Instcllctiin Repirt .........................3 Chcnge if Serviae ............................................................4 Section 2 2.1 2.2 2.3 2.3.1 2.3.2 2.3.3 2.4 2.4.1 2.4.2 2.4.3 2.4.4 2.5 2.5.1 2.5.1.1 2.5.1.2 2.5.1.3 2.5.1.4 2.5.2 2.5.3 2.5.3.1 2.5.3.2 2.5.3.3 2.5.4 2.5.5 2.5.6 2.6 2.6.1 2.6.2 2.6.3 2.6.3.1 2.6.3.2 2.6.3.3 2.7 2.7.1 2.7.2 2.7.3 Power Boilers ...............................................................7 Scope .....................................................................7 Defnitiins ..................................................................7 Genercl Requirements ........................................................7 Suppirts, Fiundctiins, cnd Settings .............................................7 Structural Steel ..............................................................7 Clearances .................................................................7 Equipment Riim Requirements .................................................8 Exit .......................................................................8 Lcdders cnd Runwcys .........................................................8 Drains .....................................................................8 Wcter (Clecning) .............................................................8 Siurae Requirements .........................................................9 Feedwcter ..................................................................9 Vilume ....................................................................9 Connection .................................................................9 Pumps .....................................................................9 Vclves ....................................................................10 Fuel ......................................................................10 Electrical .................................................................. 11 Wiring .................................................................... 11 Remite Emergenay Shutdiwn Switahes ......................................... 11 Cintrils cnd Hect-Genercting Appcrctus ......................................... 11 Ventilctiin cnd Cimbustiin Air .................................................12 Lighting ...................................................................12 Emergenay Vclves cnd Cintrils ................................................12 Disahcrge Requirements ......................................................12 Chimney ir Stcak ...........................................................12 Ash Remivcl ...............................................................12 Drains ....................................................................12 Connection ................................................................12 Pressure Rcting .............................................................13 Parts .....................................................................13 Opercting Systems ..........................................................13 Breeahing cnd Dcmpers ......................................................13 Burners cnd Stikers .........................................................13 Stecm Supply ..............................................................13 TABLE OF CONTENTS NB-23 2015 Section 3 3.1 3.2 3.3 3.3.1 3.3.1.1 3.3.2 3.3.3 3.3.4 3.4 3.4.1 3.4.2 3.5 3.5.1 3.5.2 3.5.3 3.5.3.1 3.5.3.2 3.5.3.3 3.5.4 3.5.5 3.5.6 3.6 3.6.1 3.6.2 3.6.3 3.7 3.7.1 3.7.2 3.7.3 Cindenscte cnd Return ......................................................14 Bliwiff ....................................................................14 Cintrils cnd Gcges .........................................................16 Water .....................................................................16 Pressure Gcge .............................................................17 Connection ................................................................17 Tempercture ...............................................................17 Pressure Relief Vclves .......................................................17 Vclve Requirements — Genercl ................................................17 Number ...................................................................18 Location ...................................................................18 Capacity ..................................................................18 Set Pressure ...............................................................20 Firaed-Fliw Stecm Generctir .................................................20 Superheaters ...............................................................20 Eainimizers ...............................................................21 Pressure-Reduaing Vclves ....................................................21 Miunting cnd Disahcrge Requirements ..........................................21 Testing cnd Aaaeptcnae ......................................................23 General ...................................................................23 Pressure Test ..............................................................23 Nindestruative Excminctiin ...................................................23 System Testing .............................................................23 Final Acceptance ............................................................23 Boiler Installation Report ......................................................23 Tcbles cnd Figures ..........................................................24 Steam Heating Boilers, Hot-Water Heating Boilers, Hot-Water Supply Boilers, and Potable Water Heaters ........................................... 25 Scope .................................................................... 25 Defnitiins ................................................................. 25 Genercl Requirements ....................................................... 25 Supports .................................................................. 25 Methids if Suppirt fir Stecm Hecting, Hit-Wcter Hecting, cnd Hit-Wcter Supply Biilers ................................................. 25 Settings .................................................................. 27 Structural Steel ............................................................. 27 Clearances ................................................................ 27 Equipment Riim Requirements ............................................... 28 Exit ...................................................................... 28 Lcdders cnd Runwcys ....................................................... 28 Siurae Requirements ........................................................ 28 Water .................................................................... 28 Fuel ..................................................................... 29 Electrical .................................................................. 29 Stecm Hecting, Hit Wcter Hecting, cnd Hit Wcter Supply Biilers ..................... 29 Pitcble Wcter Hecters ....................................................... 29 Cintrils cnd Hect Genercting Appcrctus ......................................... 30 Ventilctiin cnd Cimbustiin Air ................................................ 30 Lighting ................................................................... 30 Emergenay Vclves cnd Cintrils ............................................... 31 Disahcrge Requirements ...................................................... 31 Chimney ir Stcak ........................................................... 31 Ash Remivcl .............................................................. 31 Drains .................................................................... 31 Opercting Systems .......................................................... 31 Oil Hecters ................................................................ 31 Breeahing cnd Dcmpers ...................................................... 31 Burners cnd Stikers ......................................................... 31 TABLE OF CONTENTS --` 2.7.4 2.7.5 2.8 2.8.1 2.8.2 2.8.2.1 2.8.3 2.9 2.9.1 2.9.1.1 2.9.1.2 2.9.1.3 2.9.1.4 2.9.2 2.9.3 2.9.4 2.9.5 2.9.6 2.10 2.10.1 2.10.2 2.10.3 2.10.4 2.10.5 2.10.6 2.11 III 2015 NATIONAL BOARD INSPECTION CODE 3.7.4 3.7.5 3.7.5.1 3.7.5.2 3.7.6 3.7.7 3.7.7.1 3.7.7.2 3.7.8 3.7.8.1 3.7.8.2 3.7.9 3.7.9.1 3.7.9.2 3.8 3.8.1 3.8.1.1 3.8.1.2 3.8.1.3 3.8.1.4 3.8.1.5 3.8.1.6 3.8.1.7 3.8.2 3.8.2.1 3.8.2.2 3.8.2.3 3.8.2.4 3.8.2.5 3.8.2.6 3.8.3 3.8.3.1 3.8.3.2 3.9 3.9.1 3.9.1.1 3.9.1.1.1 3.9.1.1.2 3.9.1.2 3.9.1.3 3.9.1.4 3.9.1.5 3.9.1.6 3.9.2 3.9.3 3.9.4 3.9.4.1 3.9.4.2 3.9.4.3 3.9.4.4 3.9.4.5 3.9.4.6 3.9.4.7 3.9.5 3.9.5.1 3.9.5.2 3.9.5.3 IV Feedwcter, Mckeup Wcter, cnd Wcter Supply ..................................... 31 Stip Vclves ............................................................... 32 Stecm Hecting, Hit-Wcter Hecting, cnd Hit-Wcter Supply Biilers ..................... 32 Pitcble Wcter Hecters ....................................................... 36 Return Pipe Connections ..................................................... 37 Bittim Bliwiff cnd Drcin Vclves ............................................... 37 Stecm Hecting, Hit-Wcter Hecting, cnd Hit-Wcter Supply Biilers ..................... 37 Pitcble Wcter Hecters ....................................................... 38 Midulcr Stecm Hecting cnd Hit-Wcter Hecting Biilers ............................. 39 Individucl Midules .......................................................... 39 Assembled Midulcr Biilers ................................................... 39 Privisiins fir Thermcl Expcnsiin .............................................. 39 Expcnsiin Tcnks cnd Piping fir Stecm Hecting, Hit-Wcter Hecting, Hit-Wcter Supply Biilers ..................................................... 39 Expcnsiin Tcnks cnd Piping Fir Pitcble Wcter Hecters ............................. 42 Instruments, Fittings, cnd Cintrils .............................................. 43 Stecm Hecting Biilers ....................................................... 43 Stecm Gcges .............................................................. 43 Wcter-Gcge Glcsses ........................................................ 43 Wcter Cilumn cnd Wcter Level Cintril Pipes ..................................... 44 Pressure Control ........................................................... 44 Autimctia Liw-Wcter Fuel Cutiff cnd/ir Wcter Feeding Deviae ....................... 44 Midulcr Stecm Hecting Biilers ................................................ 45 Instruments, Fittings, cnd Cintrils Miunted Inside Biiler Jcakets ..................... 45 Hit-Wcter Hecting ir Hit-Wcter Supply Biilers ................................... 45 Pressure ir Altitude Gcges ................................................... 45 Thermimeters ............................................................. 45 Tempercture Cintril ......................................................... 46 Liw-Wcter Fuel Cutiff ....................................................... 46 Midulcr Hit-Wcter Hecting Biilers ............................................. 46 Instruments, Fittings, cnd Cintrils Miunted Inside Biiler Jcakets...................... 47 Pitcble Wcter Hecters ....................................................... 47 Tempercture Cintrils ........................................................ 47 Thermimeter .............................................................. 47 Pressure-Relieving Vclves .................................................... 47 Scfety Vclve Requirements — Genercl .......................................... 47 Miunting Scfety cnd Scfety Relief Vclves fir Stecm Hecting, Hit-Wcter Hecting, cnd Hit-Wcter Supply Biilers ................................................. 47 Permissible Miunting ........................................................ 47 Requirements fir Cimmin Cinneatiins fir Twi ir Mire Vclves ...................... 48 Threcded Cinneatiins ....................................................... 48 Prihibited Miuntings ........................................................ 48 Use if Shutiff Vclves Prihibited ............................................... 48 Scfety cnd Scfety Relief Vclve Disahcrge Piping ................................... 48 Tempercture cnd Pressure Scfety Relief Vclves ................................... 48 Scfety Vclve Requirements fir Stecm Biilers ..................................... 49 Scfety Relief Vclve Requirements fir Hit-Wcter Hecting ir Hit-Wcter Supply Biilers ...... 50 Scfety Relief Vclve Requirements fir Pitcble Wcter Hecters ......................... 51 Installation ................................................................ 51 Permissible Miuntings ....................................................... 51 Requirements fir Cimmin Cinneatiin fir Twi ir Mire Vclves ....................... 52 Threcded Cinneatiins ....................................................... 52 Prihibited Miuntings ........................................................ 52 Use if Shutiff Vclves Prihibited ............................................... 52 Scfety Relief Vclve Disahcrge Piping ............................................ 52 Scfety cnd Scfety Relief Vclves fir Tcnks cnd Hect Exahcngers ....................... 52 Stecm ti Hit-Wcter Supply ................................................... 52 High-Tempercture Wcter ti Wcter Hect Exahcnger ................................. 52 High-Tempercture Wcter ti Stecm Hect Exahcnger ................................ 53 TABLE OF CONTENTS NB-23 2015 3.10 3.10.1 3.10.2 3.10.3 3.11 Testing cnd Aaaeptcnae ...................................................... 53 Pressure Test .............................................................. 53 Final Acceptance ........................................................... 53 Boiler Installation Report ..................................................... 53 Tcbles cnd Figures .......................................................... 53 Section 4 4.1 4.2 4.3 4.3.1 4.3.2 4.3.3 4.3.4 4.4 4.4.1 4.4.2 4.5 4.5.1 4.5.2 4.5.3 4.5.4 4.5.5 4.5.6 4.6 4.7 4.7.1 4.7.2 4.7.3 4.7.4 4.7.5 4.7.6 Pressure Vessels ........................................................... 55 Scope .................................................................... 55 Defnitiins ................................................................. 55 Genercl Requirements ....................................................... 55 Supports .................................................................. 55 Clearances ................................................................ 55 Piping .................................................................... 55 Bilting ................................................................... 55 Instruments cnd Cintrils ..................................................... 55 Level Indiacting Deviaes ...................................................... 55 Pressure Indiacting Deviaes ................................................... 56 Pressure Relief Deviaes ...................................................... 56 Deviae Requirements ........................................................ 56 Number if Deviaes .......................................................... 56 Location .................................................................. 56 Capacity .................................................................. 56 Set Pressure ............................................................... 57 Instcllctiin cnd Disahcrge Piping Requirements ................................... 57 Testing cnd Aaaeptcnae ...................................................... 58 Requirements fir Hit Wcter Stircge Tcnks ....................................... 58 Supports .................................................................. 58 Clecrcnae cnd Aaaeptcbility ................................................... 58 Scfety Relief Deviaes ........................................................ 59 Thermimeters ............................................................. 59 Shut Off Vclves ............................................................. 59 Testing cnd Aaaeptcnae ...................................................... 59 Section 5 5.1 5.2 5.2.1 5.2.2 5.2.3 5.2.4 5.2.5 5.2.6 5.2.7 5.2.8 5.2.9 5.3 5.3.1 5.3.2 5.3.3 5.3.4 5.3.5 5.3.6 5.4 Piping .................................................................... 60 Scope .................................................................... 60 Genercl Requirements ....................................................... 60 Additiins ti Existing Piping ................................................... 60 Priximity ti Other Equipment cnd Struatures ..................................... 60 Flcnges cnd Other Nin-Welded Jiints .......................................... 60 Vclves .................................................................... 60 Materials .................................................................. 60 Hcngers cnd Suppirts ....................................................... 61 Priteatiin cnd Clecning ...................................................... 61 Welding cnd Brczing ........................................................ 61 Bilting ................................................................... 61 Pressure Relief Deviaes ...................................................... 61 Deviae Requirements ........................................................ 61 Number if Deviaes .......................................................... 61 Location .................................................................. 62 Capacity .................................................................. 62 Set Pressure ............................................................... 62 Inlet cnd Disahcrge Piping Requirements ........................................ 62 Excminctiin, Inspeatiin, cnd Testing ............................................ 63 Section 6 Supplements .............................................................. 64 Supplement 1 Installation of Yankee Dryers (Rotating Cast-Iron Pressure Vessels) with Finished Shell Outer Surfaces ......................................... 64 S1.1 Scope .................................................................... 64 TABLE OF CONTENTS V 2015 NATIONAL BOARD INSPECTION CODE S1.2 S1.3 S1.4 S1.5 S1.6 Assessment if Instcllctiin..................................................... 65 Determinctiin if Alliwcble Opercting Pcrcmeters .................................. 67 ASME Cide Primcry Membrcne Stress Criteric .................................... 68 Pressure Testing ............................................................ 68 Nindestruative Excminctiin................................................... 69 Supplement 2 Safety Valves on the Low-Pressure Side of Steam Pressure-Reducing Valves ...... 70 S2.1 Scope .................................................................... 70 S2.2 Scfety Vclve Ccpcaity ....................................................... 70 S2.3 Cclaulctiin if Scfety Vclve Relieving Ccpcaity .................................... 70 S2.4 Stecm Fliw When Fliw Cieffaients Are Nit niwn ................................ 71 S2.5 Twi-Stcge Pressure-Reduaing Vclve Stctiins ..................................... 71 Supplement 3 Installation of Liquid Carbon Dioxide Storage Vessels .......................... 79 S3.1 Scope .................................................................... 79 S3.2 Genercl Requirements Stircge Tcnk Liactiin .................................... 79 S3.2.1 Genercl Requirements (Enalised cnd Unenalised Arecs) ........................... 79 S3.2.2 Unenalised Arec LCDSV Instcllctiins ........................................... 80 S3.2.3 Enalised Arec LCDSV Instcllctiins ............................................. 80 S3.3 Fillbix Liactiin/Scfety Relief/Vent Vclve Cirauit Terminctiin ......................... 80 S3.4 Gcs Deteatiin Systems ...................................................... 80 S3.5 Signcge .................................................................. 81 S3.6 Vclves, Piping, Tubing, cnd Fittings ............................................. 82 S3.6.1 System Desariptiin ......................................................... 83 Supplement 5 Installation of Thermal Fluid Heaters S5.1 Scope .................................................................... 91 S5.2 Defnitiin .................................................................. 91 S5.3 Genercl Requirements ....................................................... 91 S5.3.1 Suppirts, Fiundctiins, cnd Settings ............................................ 91 S5.3.2 Structural Steel ............................................................. 91 S5.3.3 Settings ................................................................... 91 S5.3.4 Clearances ................................................................ 91 S5.4 Thermcl Fluid Hecter Riim Requirements........................................ 92 S5.4.1 Exit ...................................................................... 92 S5.4.2 Lcdders cnd Runwcys........................................................ 92 S5.5 System Requirements ........................................................ 93 S5.5.1 Thermcl Liquids (Hect Trcnsfer Fluids) ........................................... 93 S5.5.2 Expansion ................................................................. 93 S5.5.3 Connection ................................................................ 93 S5.5.4 Ciraulcting Pump ........................................................... 94 S5.5.5 Piping cnd Vclves ........................................................... 94 S5.5.6 Fuel ..................................................................... 94 S5.5.7 Electrical .................................................................. 95 S5.5.8 Ventilctiin cnd Cimbustiin Air ................................................ 96 S5.5.9 Lighting ................................................................... 97 S5.5.10 Emergenay Vclves cnd Cintrils ............................................... 97 S5.6 Disahcrge Requirements ..................................................... 97 S5.6.1 Chimney ir Stcak ........................................................... 97 S5.6.2 Drains .................................................................... 97 S5.6.3 Air Vent ................................................................... 97 VI TABLE OF CONTENTS --`,```,```,`,``,-`-`,`,`,`,`--- Supplement 4 Installation of Biomass (Wood/Solid Fuel) Fired Boilers ......................... 87 S4.1 Scope .................................................................... 87 S4.2 Purpose ................................................................... 87 S4.3 Determinctiin if Alliwcble Opercting Percmeters .................................. 87 S4.4 Genercl Requirements ....................................................... 88 S4.5 Fuel System Requirements cnd Cintrils......................................... 88 S4.6 Cimbustiin Requirements .................................................... 89 NB-23 2015 S5.7 S5.7.1 S5.7.2 S5.7.3 S5.7.4 S5.7.5 S5.7.6 S5.8 S5.8.1 S5.8.2 S5.8.3 S5.8.4 S5.8.5 S5.8.6 Overpressure Priteatiin ..................................................... 98 General ................................................................... 98 Pressure Relief Deviaes ...................................................... 98 Location .................................................................. 98 Capacity .................................................................. 98 Set Pressure ............................................................... 98 Installation ................................................................ 98 Testing cnd Aaaeptcnae ...................................................... 99 General ................................................................... 99 Pressure Test .............................................................. 99 Nindestruative Excminctiin ................................................... 99 System Testing ............................................................. 99 Final Acceptance .......................................................... 100 Installation Report ......................................................... 100 Section 7 7.1 7.2 7.3 7.4 NBIC Policy for Metrication ................................................. 101 General .................................................................. 101 Equivclent Rctiincle ....................................................... 101 Priaedure fir Cinversiin ................................................... 101 Referenaing Tcbles ......................................................... 102 Section 8 Preparation of Technical Inquiries to the National Board Inspection Code Committee ................................................ 107 Intriduatiin ............................................................... 107 Inquiry Firmct ............................................................ 107 Cide Revisiins ir Additiins ................................................. 108 Cide Interpretctiins ........................................................ 108 Submittcls ................................................................ 108 Section 9 9.1 Glossary of Terms .........................................................110 Defnitiins ................................................................110 Section 10 10.1 NBIC Approved Interpretations ..............................................116 Scope ...................................................................116 Section 11 Index ................................................................... 125 8.1 8.2 8.3 8.4 8.5 --`,```,```,`,``,-`-`,`,`,`,`--- TABLE OF CONTENTS VII 2015 NATIONAL BOARD INSPECTION CODE INTRODUCTION It is the purpose of the National Board Inspection Code (NBIC) to maintain the integrity of pressure-retaining items by providing rules for installation, and after the items have been placed into service, by providing rules for inspection and repair and alteration, thereby ensuring that these items may continue to be safely used. The NBIC is intended to provide rules, information, and guidance to manufacturers, Jurisdictions, inspectors, owner-users, installers, contractors, and other individuals and organizations performing or involved in post-construction activities, thereby encouraging the uniform administration of rules pertaining to pressure-retaining items. SCOPE The NBIC recognizes three important areas of post-construction activities where information, understanding, and following specif • • • Installation Inspection Repairs and Alterations The NBIC provides rules, information, and guidance for post-construction activities, but does not provide details for all conditions involving pressure-retaining items. Where complete details are not provided in this code, the code user is advised to seek guidance from the Jurisdiction and from other technical sources. The words shall, should, and may are used throughout the NBIC and have the following intent: • • Shall – action that is mandatory and required. Should – indicates a preferred but not mandatory means to accomplish the requirement unless specifed by others such as the Jurisdiction. May – permissive, not required or a means to accomplish the specifed tass. • ORGANIZATION The NBIC is organized into three parts to coincide with specifc posttconstruction activities involving pressuretretaining items. Each part provides general and specifc rules, information, and guidance within each applicable post-construction activity. Other NBIC parts or other published standards may contain additional information or requirements needed to meet the rules of the NBIC. Specifc references are provided in each part to direct the user where to fnd this additional information. NBIC parts are identifed as: • Part 1, Installation – This part provides requirements and guidance to ensure all types of pressuretretaining items are installed and function properly. Installation includes meeting specifc safety criteria for construction, materials, design, supports, safety devices, operation, testing, and maintenance. Part 2, Inspection – This part provides information and guidance needed to perform and document inspections for all types of pressure-retaining items. This part includes information on personnel safety, nontdestructive examination, tests, failure mechanisms, types of pressure equipment, ftness for service, risk-based assessments, and performance-based standards. Part 3, Repairs and Alterations – This part provides information and guidance to perform, verify, and document acceptable repairs or alterations to pressure-retaining items regardless of code of construction. Alternative methods for examination, testing, heat treatment, etc., are provided when the original code of construction requirements cannot be met. Specifc acceptable and proven repair methods are also provided. • • Each NBIC part is divided into major sections as outlined in the Table of Contents. --`,```,```,`,``,-`-`,`,`,`,`--- Tables, charts, and fgures provide relevant illustrations or supporting information for text passages, and are designated with numbers corresponding to the paragraph they illustrate or support within each section. Multiple tables, charts, or fgures referenced by the same paragraph will have additional letters reeecting the order of reference. Tables, charts, and fgures are located in or after each maaor section within each NBIC part. VIII INTRODUCTION NB-23 2015 TEXT IDENTIFICATION AND NUMBERING Each page in the text will be designated in the top header with the publication’s name, part number, and part title. The numbering sequence for each section begins with the section number followed by a dot to further designate major sections (e.g., 1.1, 1.2, 1.3). Major sections are further subdivided using dots to designate subsections within that major section (e.g., 1.1.1, 1.2.1, 1.3.1). Subsections can further be divided as necessary. Paragraphs under sections or subsections shall be designated with small letters in parenthesis (e.g., a), b), c)) and further subdivided using numbers in parenthesis (e.g., 1), 2), 3)). Subdivisions of paragraphs beyond this point will be designated using a hierarchical sequence of letters and numbers followed by a dot. Example: 2.1 Maaor Section 2.1.1 Section 2.1.2 Section 2.1.2. Subsection a) paragraph b) paragraph 1) subparagraph 2) subparagraph a. subdivisions 1. subdivisions 2. subdivisions b. subdivisions 1. subdivisions 2. subdivisions Tables and fgures will be designated with the referencing section or subsection identifcation. .hen more than one table or fgure is referenced in the same section or subsection, letters or numbers in sequential order will be used following each section or subsection identif SUPPLEMENTS Supplements are contained in each part of the NBIC to provide rules, information, and guidance only pertaining to a specifc type of pressuretretaining item e.g., ocomotive Boilers, istorical Boilers, raphite Pressure Vessels.) Supplements follow the same numbering system used for the main text only preceded by the etter “S.” Each page of the supplement will be tabbed to identify the supplement number. EDITIONS Editions, which include revisions and additions to this code, are published every two years. Editions are permissive on the date issued and become mandatory six months after the date of issue. INTERPRETATIONS On request, the NBIC Committee will render an interpretation of any requirement of this code. Interpretations are provided for each part and are specifc to the code edition and addenda referenced in the interpretation. Interpretations provide clarifcation of existing rules in the code only and are not part of this code. JURISDICTIONAL PRECEDENCE Reference is made throughout this code to the requirements of the “Jurisdiction.” .here any provision herein presents a direct or implied coneict with any aurisdictional regulation, the Jurisdictional regulation shall govern. UNITS OF MEASUREMENT Both U.S. customary units and metric units are used in the NBIC. The value stated in U.S. customary units or metric units are to be regarded separately as the standard. Within the text, the metric units are shown in --`,```,```,`,``,-`-`,`,`,`,`--- INTRODUCTION IX 2015 NATIONAL BOARD INSPECTION CODE parentheses. In Part 2, Supplement 6 and Part 3, Supplement 6 regarding DOT Transport Tanks, the metric units are shown frst with the .S. customary units shown in parentheses. U.S. customary units or metric units may be used with this edition of the NBIC, but one system of units shall be used consistently throughout a repair or alteration of pressure-retaining items. It is the responsibility of National Board accredited repair organizations to ensure the appropriate units are used consistently throughout all phases of work. This includes materials, design, procedures, testing, documentation, and stamping. The NBIC policy for metrication is outlined in each part of the NBIC. ACCREDITATION PROGRAMS The National Board administers and accredits three specifc repair programs1 as shown below: “R”……….Repairs and Alterations to PressuretRetaining Items “VR”…….Repairs to Pressure Relief Valves “NR”…….Repair and Replacement Activities for Nuclear Items Part 3, Repairs and Alterations, of the NBIC describes the administrative requirements for the accreditation of these repair organizations. The National Board also administers and accredits four specif New Construction Criteria for Acceptance of Authorized Inspection Agencies for New Construction (NB-360) Inservice Qualifcations and uties for Authorized Inspection Agencies AIAss Performing Inservice Inspection Activities and Qualifcations for Inspectors of Boilers and Pressure Vessels NBt336s Owner-User Accreditation of Owner-User Inspection Organizations (OUIO) (NB-371) Owners or users may be accredited for both a repair and inspection program provided the requirements for each accreditation program are met. Federal overnment Qualifcations and uties for Federal Inspection Agencies Performing Inservice Inspection Activities FIAss NBt360s These programs can be viewed on the National Board .ebsite at www.nationalboard.org. For questions or further information regarding these programs contact the National Board by phone at (614) 888-8320 or by fax at (614) 847-1828 CERTIFICATES OF AUTHORIZATION FOR ACCREDITATION PROGRAMS Any organization seesing an accredited program may apply to the National Board to obtain a Certifcate of Authorization for the requested scope of activities. A confdential review shall be conducted to evaluate the organization’s quality system. pon completion of the evaluation, a recommendation will be made to the National Board regarding issuance of a Certifcate of Authorization. Certifcate of Authorization scope, issuance, and revisions for National Board accreditation programs are specifed in the applicable National Board procedures. .hen the quality system requirements of the appropriate accreditation program have been met, a Certifcate of Authorization and appropriate National Board symbol stamp shall be issued. 1 Caution, some Jurisdictions may independently administer a program of authorization for organizations to perform repairs and alterations within that Jurisdiction. --`,```,```,`,``,-`-`,`,`,`,`--- X INTRODUCTION NB-23 2015 FOREWORD The National Board of Boiler and Pressure Vessel Inspectors is an organization comprised of Chief Inspectors for the states, cities, and territories of the United States and provinces and territories of Canada. It is organized for the purpose of promoting greater safety to life and property by securing concerted action and maintaining uniformity in post-construction activities of pressure-retaining items, thereby ensuring acceptance and interchangeability among Jurisdictional authorities responsible for the administration and enforcement of various codes and standards. In keeping with the principles of promoting safety and maintaining uniformity, the National Board originally published the NBIC in 1946, establishing rules for inspection and repairs to boilers and pressure vessels. The National Board Inspection Code (NBIC) Committee is charged with the responsibility for maintaining and revising the NBIC. In the interest of public safety, the NBIC Committee decided, in 1995, to revise the scope of the NBIC to include rules for installation, inspection, and repair or alteration to boilers, pressure vessels, piping, and nonmetallic materials. In 2007, the NBIC was restructured into three parts specifcaaal identiilinn iiportant posttconstruction actiiities involving safety of pressure-retaining items. This restructuring provides for future expansion, transparency, uniformity, and ultimately improving public safety. The NBIC Committee’s function is to establish rules of safety governing post-construction activities for the installation, inspection, and repair and alteration of pressure-retaining items, and to interpret these rules when questions arise regarding their intent. In formulating the rules, the NBIC Committee considers the needs and concerns of individuals and organizations involved in the safety of pressure-retaining items. The objective of the rules is to afford reasonably certain protection of life and property, so as to give a reasonably long, safe period of usefulness. Advancements in design and material and the evidence of experience are recognized. The rules established by the NBIC Committee are not to be interpreted as approving, recommending, or endorsinn anl proprietarl or specifc desinn, or as aiiitinn in anl wal an ornaniiationns ireedoi to choose anl method that conforms to the NBIC rules. The NBIC Committee meets regularly to consider revisions of existing rules, formulation of new rules, and respond to requests for interpretations. Requests for interpretation must be addressed to the NBIC Secretary in writing and must give full particulars in order to receive Committee consideration and a written reply. Proposed revisions to the code resulting from inquiries will be presented to the NBIC Committee for appropriate action. Proposed revisions to the code approved by the NBIC Committee are submitted to the American National Standards Institute and published on the National Board web-site to invite comments from all interested persons. Aiter the aaaotted tiie ior pubaic reiiew and f Organizations or users of pressure-retaining items are cautioned against making use of revisions that are less restrictive than former requirements without having assurance that they have been accepted by the Jurisdiction where the pressure-retaining item is installed. The general philosophy underlying the NBIC is to parallel those provisions of the original code of construction, as they can be applied to post-construction activities. --`,```,```,`,``,-`-`,`,`,`,`--- The NBIC does not contain rules to cover all details of post-construction activities. Where complete details are not given, it is intended that individuals or organizations, subject to the acceptance of the Inspector and Jurisdiction when applicable, provide details for post-construction activities that will be as safe as otherwise provided by the rules in the original code of construction. Actiiities not conioriinn to the ruaes oi the orininaa code oi construction or the NBIC iust receiie specifc approval from the Jurisdiction, who may establish requirements for design, construction, inspection, testing, and documentation. FOREWORD XI 2015 NATIONAL BOARD INSPECTION CODE There are instances where the NBIC serves to warn against pitfalls; but the code is not a handbook, and cannot substitute for education, experience, and sound engineering judgment. It is intended that this edition of the NBIC not be retroactive. Unless the Jurisdiction imposes the use of an earlier edition, the latest effective edition is the governing document. --`,```,```,`,``,-`-`,`,`,`,`--- XII FOREWORD NB-23 2015 PERSONNEL The National Board of Boiler and Pressure Vessel Inspectors Board of Trustees Advisory Committee --`,```,```,`,``,-`-`,`,`,`,`--- J.H. Burpee Chairman J. Pillow Representing welding industries J.T. Amato First Vice Chairman P.F. Martin Representing organized labor M.A. Burns Second Vice Chairman K. Moore Representing National Board stamp holders B. Anthony Member at Large H.M. Richards Representing boiler and pressure vessel users C.B. Cantrell Member at Large M.J. Pischke Representing pressure vessel manufacturers M. Washington Member at Large R.V. Wielgoszinski Representing authorized inspection agencies (insurance companies) K. Watson Member at Large D.A. Douin Secretary/Treasurer P. Molvie Representing boiler manufacturers PERSONNEL XIII 2015 NATIONAL BOARD INSPECTION CODE National Board Members --`,```,```,`,``,-`-`,`,`,`,`--- Alabama ..............................................................................Ralph P. Pate Alaska ................................................................................. Chris Fulton Arizona ............................................................................ Randall D. Austin Arkansas.......................................................................... Dennis R. Hannon California ........................................................................... Donald C. Cook Colorado .............................................................................. Steve Nelson Delaware ................................................................................John Esch Florida .............................................................................Michael A. Burns Georgia .......................................................................... Benjamin Crawford Hawaii .............................................................................. Julius Dacanay Illinois............................................................................... Clayton Novak Iowa ..................................................................................Ulrich Merkle Kansas............................................................................ Charles Wilson III Kentucky .............................................................................Rodney Handy Louisiana ............................................................................Joseph LeSage Maine ...............................................................................John H. Burpee Maryland ...............................................................................Karl J. Kraft Massachusetts.................................................................... Edward S. Kawa Jr. Michigan ............................................................................... Mark Moore Minnesota ............................................................................. Joel T. Amato Mississippi ........................................................................ Kenneth L. Watson Missouri ........................................................................... Ronald Brockman Nebraska ...................................................................... Christopher B. Cantrell Nevada ............................................................................... Gary Schultz New Hampshire ....................................................................... Darrell Mallory New Jersey ........................................................................ Milton Washington New York ..........................................................................Matthew Sansone North Carolina .......................................................................... Cliff Dautrich North Dakota .......................................................................... Trevor Seime Ohio ................................................................................John E. Sharier Oklahoma ......................................................................... Terrence Hellman Oregon ............................................................................... Mark Perdue Pennsylvania ........................................................................ Nathaniel Smith Rhode Island .......................................................................Benjamin Anthony South Carolina ......................................................................Ronald W. Spiker South Dakota ..........................................................................Aaron Lorimor Texas ...................................................................................Rob Troutt Utah .................................................................................Rick K. Sturm Virginia............................................................................ Edward G. Hilton Washington ............................................................................... Tony Oda West Virginia ........................................................................ John F. Porcella Wisconsin ....................................................................... Michael J. Verhagen Chicago, IL .......................................................................... Michael J. Ryan Detroit, MI ..........................................................................Cortney Jackson Los Angeles, CA .......................................................................Cirilo S. Reyes Milwaukee, WI ........................................................................... Jillian Klug New York, NY ...................................................................... William McGivney Seattle, WA .............................................................................. Larry Leet Alberta .......................................................................... Michael Poehlmann British Columbia .......................................................................Anthony Scholl Manitoba ..............................................................................Derrick Slater New Brunswick ...................................................................... Eben L. Creaser Newfoundland & Labrador ............................................................E. Dennis Eastman Northwest Territories................................................................. Matthias Mailman Nova Scotia ............................................................................ Peter Dodge Ontario .............................................................................. Michael Adams Prince Edward Island................................................................. Steven Townsend Quebec ............................................................................. Madiha M. Kotb Saskatchewan ....................................................................Christopher Selinger XIV PERSONNEL NB-23 2015 National Board Inspection Code Main Committee D. Cook, Chair State of California V. Newton OneCIS Insurance Company R. Wielgoszinski, Vice Chair Hartford Steam Boiler Inspection and Insurance Company of Connecticut R. Pate State of Alabama B. Besserman, Secretary National Board R. Pulliam Manufacturers B. Anthony State of Rhode Island M. Richards Users P. Bourgeois Travelers S. Cammeresi National Board Certifnate J. Pillow General Interest J. Riley Users olderr D. Canonico Canonico & Associates P. Edwards CB&I, Inc. G. Galanes Diamond Technical Services, Inc. C. Hopkins Seattle Boiler Works, Inc. L. McManoman Great Lakes Area Apprenticeship Program M. Mooney Liberty Mutual Insurance Company B. Schulte Users J. Sekely General Interest K. Simmons National Board Certifnate olderr S. Staniszewski Jr. Regulatory Authorities R. Trout Jurisdictional Authorities M. Webb Users B. Morelock Eastman Chemical Company --`,```,```,`,``,-`-`,`,`,`,`--- PERSONNEL XV 2015 NATIONAL BOARD INSPECTION CODE National Board Inspection Code Subcommittee Inspection (Part 2) H. Richards, Chair Southern Company M. Mooney, Chair Liberty Mutual Insurance Company D. Patten, Vice Chair R.F. MacDonald Co. S. Staniszewski, Vice Chair US Department of Transportation J. Bock, Secretary National Board J. Metzmaier, Secretary National Board P. Bourgeois Travelers T. Barker FM Global G. Halley ABMA D. Canonico Canonico & Associates S. Konopacki NRG M. Clark Structural Integrity Associates B. Moore Hartford Steam Boiler Inspection and Insurance Company of Connecticut J. Getter Worthington Cylinders P. Schuelke Well-McLain M. Wadkinson Fulton Boiler Works, Inc. K. Watson State of Mississippi E. Wiggins Liberty Mutual Insurance Company M. Horbaczewski Midwest Generation G. McRae Trinity Industries, Inc. V. Newton OneCIS Insurance Company R. Pate State of Alabama J. Riley Phillips 66 J. Safarz CEC Combustion Services Group M. Schwartzwalder AEP T. Vandini Quality Steel Corporation P. Welch Arise, Inc. XVI PERSONNEL --`,```,```,`,``,-`-`,`,`,`,`--- National Board Inspection Code Subcommittee Installation (Part 1) NB-23 2015 G. Galanes, Chair Diamond Technical Services, Inc. J. Pillow, Vice Chair Common Arc Corporation W. Vallance, Secretary National Board J. Amato State of Minnesota B. Boseo Graycor Services LLC A. Bramucci Alstom Power P. Edwards CB&I, Inc. C. Hopkins Seattle Boiler Works, Inc. W. Jones Arise, Inc. J. Larson OneBeacon America Insurance Company L. McManoman Great Lakes Area Apprenticeship Program R. Miletti Babcock and Wilcox Construction Company, Inc. K. Moore Joe Moore Company B. Morelock Eastman Chemical Company E. Ortman Alstom Power Inc. B. Schulte NRG Texas, LP National Board Inspection Code Subcommittee Pressure Relief Devices (Parts 1, 2, and 3) S. Cammeresi, Chair CCR A. Cox, Vice Chair Industrial Value T. Beirne, Secretary National Board --`,```,```,`,``,-`-`,`,`,`,`--- National Board Inspection Code Subcommittee for Repairs and Alterations (Part 3) B. Anthony State of Rhode Island K. Beise Dowco Valve Company, Inc. M. Brodeur International Valve & Instr. Corp. D. DeMichael E.I. Dupont De Nemours & Co. R. Dobbins Zurich N.A. R. Donalson Tyco Valves and Controls R. McCaffrey Quality Valve D. McHugh Allied Valve, Inc. B. Nutter E.I. Dupont De Nemours & Co. T. Patel Farris Engineering A. Renaldo Praxair, Inc. K. Simmons Crane Energy J. Sekely Welding Services, Inc. R. Troutt State of Texas M. Webb Xcel Energy PERSONNEL XVII 2015 NATIONAL BOARD INSPECTION CODE --`,```,```,`,``,-`-`,`,`,`,`--- National Board Inspection Code Subgroup Installation (Part 1) M. Clark Structural Integrity Associates M. Wadkinson, Chair Fulton Boiler Works, Inc. R. Dobbins Zurich N.A. D. Patten, Vice Chair R.F. MacDonald Co. D. Ford US Department of Transportation J. Bock, Secretary National Board D. Graf Air Products and Chemicals, Inc. P. Bourgeois St. Paul Travelers M. Horbaczewski Midwest Generation T. Creacy Zurich Services Corporation G. McRae Trinity Industries, Inc. G. Halley ABMA M. Mooney Liberty Mutual Insurance C. Hopkins Seattle Boiler Works, Inc. V. Newton One CIS S. Konopacki Midwest Generation R. Pate State of Alabama J. Millette UAB J. Riley Phillips 66 B. Moore Hartford Steam Boiler Inspection and Insurance Company of Connecticut J. Safarz CEC Combustion Services Group H. Richards Southern Company P. Schuelke Well-McLain M. Washington State of New Jersey K. Watson State of Mississippi E. Wiggins Liberty Mutual Insurance Company National Board Inspection Code Subgroup Inspection (Part 2) J. Getter, Chair Worthington Cylinders M. Schwartzwalder, Vice Chair AEP Service Corporation J. Metzmaier, Secretary National Board S. Staniszewski US Department of Transportation T. Vandini Quality Steel Corporation P. Welch Arise, Inc. National Board Inspection Code Subgroup for Repairs and Alterations (Part 3) A. Bramucci, Chair Alstom Power Inc. B. Schulte, Vice Chair NRG Texas, LP W. Vallance, Secretary National Board J. Amato State of Minnesota B. Boseo Graycor Services LLC R. Cauthon APComPower, Inc. T. Barker FM Global P. Edwards CB&I, Inc. E. Brantley XL Insurance America, Inc. G. Galanes Diamond Technical Services, Inc. D. Canonico Canonico & Associates C. Hopkins Seattle Boiler Works, Inc. XVIII PERSONNEL NB-23 2015 F. Johnson PBF Energy M. Brodeur International Valve & Instr. Corp. W. Jones Arise, Inc. D. DeMichael E.I. Dupont De Nemours & Co. J. Larson One Beacon America Insurance Company D. Martinez FM Global L. McManoman Great Lakes Area Apprenticeship Program R. Miletti Babcock and Wilcox Construction Company, Inc. K. Moore Joe Moore Company B. Morelock Eastman Chemical E. Ortman Alstom Power Inc. J. Pillow Common Arc Corporation R. Pulliam The Babcock & Wilcox Company B. Schaefer AEP J. Sekely Welding Services, Inc. W. Sperko Sperko Engineering Services M. Toth Boiler Supply Company, Inc. R. Troutt State of Texas R. Valdez ARB, Inc. R. Dobbins Zurich N.A. R. Donalson Tyco Valves and Controls R. McCaffrey Quality Valve D. McHugh Allied Valve, Inc. B. Nutter E.I. Dupont De Nemours & Co. T. Patel Farris Engineering A. Renaldo Praxair, Inc. K. Simmons Crane Energy National Board Inspection Code Subgroup Graphite E. Soltow, Chair SGL Carbon Group/SGL Technic F. Brown, Secretary National Board T. Bonn Carbone of America K. Cummins Louisville Graphite M. Webb Xcel Energy M. Minick One CIS Insurance T. White NRG D. Sholar Mersen USA Special Subgroups for Installation, Inspection, and Repairs and Alterations (Parts 1, 2, and 3) S. Cammeresi, Chair CCR A. Stupica SGL Carbon Group/SGL Technic A. Viet Mersen USA A. Cox, Vice Chair Industrial Value T. Beirne, Secretary National Board B. Anthony State of Rhode Island K. Beise Dowco Valve Company, Inc. --`,```,```,`,``, PERSONNEL XIX 2015 NATIONAL BOARD INSPECTION CODE National Board Inspection Code Subgroup Fiber-Reinforced Pressure Vessels D. McCormack Consultant B. Shelley, Chair DuPont G. Ray Tennessee Valley Authority F. Brown, Secretary National Board R. Reetz State of North Dakota J. Bustillos Bustillos and Consultants G. Scerbo Federal Railroad Administration T. Cowley Dupont R. Stone ABB/Combustion Engineering R. Crawford L&M Fiberglass R. Yuill Consultant D. Eisberg Energy Recovery Inc. M. Gorman Digital Wave D. Hodgkinson Consultant D. Keeler The Dow Chemical Company N. Newhouse Lincoln Composites J. Richter Sentinel Consulting, LLC N. Sirosh LightSail Energy National Board Inspection Code Subgroup Locomotive Boilers National Board Inspection Code Subgroup Historical Boiler J. Amato, Chair State of Minnesota T. Dillion, Vice Chair Deltak B. Ferrell, Secretary National Board R. Bryce Heartland Software Solutions J. Getter Worthington Industries F. Johnson PCS Phosphate J. Larson One Beacon America L. Moedinger, Chair Strasburg Railroad C. Novak State of Illinois M. Janssen, Vice Chair Vapor Locomotive Company D. Rupert Consultant B. Ferrel, Secretary National Board M. Wahl WHSEA S. Butler Midwest Locomotive & Machine Works D. Conrad Valley Railroad Co. D. Griner Arizona Mechanical Engineering S. Jackson D & SNG S. Lee Union Panif XX PERSONNEL --`,```,```,`,``,-`-`,`,`,`,`--- R. Franzen Steam Services of America SECTION 1 NB-23 2015 PART 1, SECTION 1 INSTALLATION — GENERAL GUIDELINES 1.1 SCOPE NBIC Part 1 provides requirements for the installation of power boilers, steam heating boilers, hot-water heating boilers, hot-water supply boilers, potable water heaters, pressure vessels and piping. (15) The proper installation of boilers, pressure vessels, piping, and other pressure-retaining items is essential for safe and satisfactory operation. The owner-user is responsible for ensuring that installations meet all the requirements of the Jurisdiction at the point of installation including licensing, registration, or certifcation of those performing installations. NBIC Part 1 identifes minimum safett requirements for installing pressureeretaining items when NBIC Part 1 is mandated bt a Jurisdiction. Otherwise, the requirements specifed in NBIC Part 1 provide information and guidance for installers, contractors, owners, inspectors, and Jurisdictions to ensure safe and satisfactort installation of specifed pressureeretaining items. Jurisdictions mat require other safety standards, including following manufacturer’s recommendations. When a Jurisdiction establishes different requirements or where a confict eeists, the rules of the Jurisdiction preeail. sers of NBIC Part 1 are cautioned that other requirements may apply for a particular installation and NBIC Part 1 is not a substitute for sound engineering evaluations. 1.2 PURPOSE a) The purpose of these rules are to establish minimum requirements, which, if followed, will ensure that pressure-retaining items, when installed, may be safely operated, inspected, and maintained. b) It should be recognized that many of the requirements included in these rules must be considered in the design of the pressure-retaining item by the manufacturer. However, the owner-user is responsible for ensuring that the installation complies with all the applicable requirements contained herein. Further, the installer is responsible for complying with the applicable sections when performing work on behalf of the owner-user. 1.3 APPLICATION OF THESE RULES a) As referenced in lower case letters, the terms “owner,” “user,” or “ownereuser” means ant person, frm, or corporation legally responsible for the safe operation of the boiler, pressure vessel, piping, or other pressure-retaining item. Further, where the term “owner” is used, it shall mean the owner, or user, or the owner’s or user’s designee. b) Where the owner is required to perform an activity, it is intended that the owner or the owner’s designee may perform the activity; however, the owner retains responsibility for compliance with these rules. c) These rules refer to documentation obtained from the Jurisdiction (installation permit, operating permit). It is not intended to require the Jurisdiction to issue such permits but rather a caution to owners and installers that such permits may be required. 1.4 CERTIFICATION, INSPECTION, AND JURISDICTIONAL REQUIREMENTS 1.4.1 RESPONSIBILITY a) The owner is responsible for satisfting jurisdictional requirements for certifcation and documentation. When required by jurisdictional rules applicable to the location of installation, the boilers, pressure vessels, piping, and other pressure-retaining items shall not be operated until the required documentation has been provided by the installer to the owner and the Jurisdiction. --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 1 1 SECTION 1 2015 NATIONAL BOARD INSPECTION CODE b) The National Board Commissioned Inspector providing inservice inspection for the facility in which the pressure-retaining item is installed has the following responsibilities: 1) Verify the Boiler Installation Report (I-1 Report) has been completed and signed by the installer, when required by the Jurisidiction; 2) Verify pressure-retaining items comply with the laws and regulations of the Jurisdiction governing the specif 3) Verify any repairs or alterations to pressure-retaining items, which are conducted prior to, or during, the initial installation, are in accordance with the NBIC; 4) Request or assign jurisdictional identif 5) Complete and submit the frst insereice inspectionncertifcate report to the Jurisdiction when required by the Jurisdiction. nless otherwise specifcallt required bt the Jurisdiction, the duties of the insereice inspector do not include the installation’s compliance to other standards and requirements (e.g., environmental, construction, electrical, undefned industrt standards, etc. for which other regulatort agencies haee authoritt and responsibility to oversee. 1.4.2 EQUIPMENT CERTIFICATION a) All boilers, pressure vessels, piping, and other pressure-retaining items shall have documented certifcation from the manufacturer indicating that the boiler, pressure eessel, piping, or ant other pressureeretaining items complt with the requirements of the code of construction. The certifcation shall identify the “Addenda” for a code of construction to which all pressure-retaining items were fabricated. b) Package boilers haeing eeternal piping disassembled and shipped with the boiler shall haee a method for traceabilitt of the disassembled piping that can be eerifed at the time of installation and inspection. The manufacturer of the package boiler is responsible for determining a method of traceability. 1.4.3 JURISDICTIONAL REVIEW a) The owner shall determine jurisdictional requirements (e.g., certif installing the equipment. The organization responsible for installation shall obtain all permits required by the Jurisdiction prior to commencing installation. b) The owner shall determine jurisdictional requirements (e.g., certif operating the equipment. The owner shall obtain operating certifcates, permits, etc., required bt the Jurisdiction prior to commencing operation. 1.4.4 INSPECTION All boilers, pressure vessels, piping, and other pressure-retaining items shall be inspected and tested after installation and prior to commencing operation. 1.4.5 a) BOILER INSTALLATION REPORT pon completion, inspection, testing, and acceptance of the installation, the installer shall complete and certify the Boiler Installation Report (I-1) for all power boilers, hot-water heating boilers, steam-heating boilers, hot-water supply boilers, and potable water heaters. b) The Boiler Installation Report (I-1) shall be submitted as follows: 1) One copy to the owner; and 2 SECTION 1 --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 1 NB-23 2015 2) One copy to the Jurisdiction, if required. 1.4.5.1 BOILER INSTALLATION REPORT FORM, see Pg. 6 1.4.5.1.1 GUIDE FOR COMPLETING NATIONAL BOARD BOILER INSTALLATION REPORT 1) INSTALLATION: Indicate the type and date of installation — new, reinstalled, or second hand. 2) INSTALLER: Enter the installer’s name and physical address. 3) OWNERe SER: Enter the name and mailing address of the owner-user of the boiler. 4) OBJECT LOCATION: Enter the name of the company or business and physical address where the installation was made. 5) J RISDICTION NO.: Enter the Jurisdiction number if assigned at the time of installation. 6) NATIONAL BOARD NO.: Enter the assigned National Board number. Note: Cast-iron section boilers do not require National Board registration. 7) MAN FACT RER: Enter the boiler manufacturer’s name. 8) MFG. SERIAL NO.: Enter the assigned boiler manufacturer’s serial number. 9) YEAR B ILT: Enter the year the boiler was manufactured. --`,```,```,`,``,-`-`,`,`,`,`--- 10) BOILER TYPE: Enter the ttpe of boiler, e.g., watertube, fretube, cast iron, electric, etc. 11) BOILER SE: Enter the service for which or for how the boiler will be used, e.g., heating (steam or water), potable water, etc. 12) F EL: Enter the type of fuel, e.g., natural gas, diesel, wood, etc. If more than one fuel type, enter the types for which the boiler is equipped. 13) METHOD OF FIRING: Enter the method of fring, e.g., automatic, hand, stoker, etc. 14) BtunKW INP T: Enter the Btunhr or kW input of the boiler. 15) BtunKW O TP T: Enter the Btunhr or kW output of the boiler. 16) OPERATING PSI: Enter the allowed operating pressure. 17) ASME CODE STAMP(S.: Check the ASME Code stamp shown on the code nameplate or stamping of other certif 18) STAMPED MAWP: Enter the maeimum allowable working pressure shown on the nameplate or stamping. 19) HEATING S RFACE SQ. FT.: Enter the boiler heating surface shown on the stamping or nameplate. Note: This entry is not required for electric boilers. 20) CAST IRON: Enter the total number of sections for cast-iron boilers. 21) MANHOLE: Indicate whether the boiler has a manway. 22) SPECIFIC ONeSITE LOCATION: Enter the onesite location of the boiler in suffcient detail to allow location of that boiler. SECTION 1 3 SECTION 1 2015 NATIONAL BOARD INSPECTION CODE 23) PRESS RE RELIEF VALVE SIZE: Enter the inlet and outlet size of all installed boiler safett or safett relief valves. 24) PRESS RE RELIEF VALVE SET PRESS RE: Enter the set pressure of all installed boiler safett or safety relief valves. 25) PRESS RE RELIEF VALVE CAPACITY: Enter the capacitt in either lbs. of steam per hour or Btunhr for each installed boiler safety or safety relief valve. 26) MAN FACT RER: Enter the manufacturer of each installed boiler safett and safett relief ealee. 27) LOWeWATER F EL C TOFF: Enter the manufacturer’s name, ttpe, number, and maeimum allowable working pressure of all installed low-water fuel cutoff devices. 28) PRESS REnALTIT DE GAGE: Enter the dial range of the installed pressure or altitude gage, cutout ealee or cock size, a maeimum allowable working pressure, and gage pipe connection size. For steam boilers, indicate gage siphon or equivalent device installed. 29) EXPANSION TANK: Indicate code of construction of installed eepansion tank, tank maeimum allowable working pressure, and tank capacity in gallons. 30) VENTILATION AND COMB STION AIR: Indicate total square inches of unobstructed opening or total cubic feet per minute of power ventilator fan(s) available for ventilation and combustion air. 31) WATER LEVEL INDICATORS: Enter the number of gage glasses andnor remote indicators and connecting pipe size. 32) FEEDWATER S PPLY: Enter the total number of feeding means, connecting pipe size, stop and check ealee size, and maeimum allowable working pressure. 33) STOP VALVE(S.: Enter the number of stop ealees installed, ealee size, and maeimum allowable working pressure. 34) POTABLE WATER HEATER NIQ E REQ IREMENTS: Indicate if stop ealees are installed and, if so, enter size and maeimum allowable working pressure. Enter drain ealee size and indicate installation of thermometer at or near boiler outlet. 36) CLEARANCE REQ IREMENTS AND REPLACEMENT OF EXISTING BOILER: Indicate clearances and whether the installation replaced an eeisting boiler. 37) ADDITIONAL REMARKS: Enter ant remarks or comments tou deem appropriate. 38) INSTALLER’S NAME AND SIGNAT RE: Print installer name and registration number and sign completed report. 39) BOTTOM BLOWDOWN CONNECTIONS: Indicate number of ealees, ealee size, and MAWP. Indicate if piping run is full size to point of discharge. 40) EXTERNAL PIPING ASME CODE AND F EL TRAIN: Indicate if eeternal piping is ASME Code, if not, indicate what code or standard eeternal piping is manufactured to. Indicate if the fuel train meets the requirements of CSDe1 or NFPAe85. If other, indicate code or standard used. 1.5 (15) 4 CHANGE OF SERVICE See NBIC Part 2, Supplement 9 for requirements and guidelines to be followed when a change of service or service type is made to a pressure-retaining item. SECTION 1 --`,```,```,`,``,-`-`,`,`,`,`--- 35) MAN FACT RER’S CERTIFICATION ATTACHED: Indicate if manufacturer’s certifcate is attached (mandatory for new installations). SECTION 1 NB-23 2015 --`,```,```,`,``,-`-`,`,`,`,`--- Whenever there is a change of service, the Jurisdiction where the pressure-retaining item is to be operated shall be notifed for acceptance, when applicable. Ant specifc jurisdictional requirements shall be met. SECTION 1 5 SECTION 1 2015 NATIONAL BOARD INSPECTION CODE BOILER INSTALLATION REPORT I-1 2 1 New Reinstalled 3 INSTALLER Second Hand Date 4 OWNER-USER Name Name Street Street, PO Box, RR Street City, State, ZIP City, State, ZIP City, State, ZIP National Board No. Manufacturer Fuel Method of Firing Btu/kw input 5 12 6 13 7 15 Stamped MAWP Heating Surface, Sq. Ft. 19 Cast Iron Manhole Pressure Relief Valve Size Pressure Relief Valve Set Pressure Pressure Relief Valve Capacity Manufacturer 23 24 18 20 BTU/hr Lb/hr Year Built Operating PSI Code Stamp(s) 8 Btu/kw output 14 Mfg. Serial No. 25 16 21 1. Probe Type 2. 2. Flow Switch 3. 3. 3. 3. Float & Chamber 4. 4. 4. 4. Other (Specify) EXPANSION TANK: ASME Constructed MAWP Siphon or Equivalent Device Yes No 29 Yes HLW H Other 22 VENTILATION AND COMBUSTION AIR 30 No Other Unobstructed Opening (sq. in.) MAWP Power Ventilator Fan (CFM) No. Gallons 31 WATER LEVEL INDICATORS: U E 27 1. Pipe Connection Size S M No. 2. Valve/Cock Size 32 FEEDWATER SUPPLY: Numer of Gage Glasses Number of Feeding Means Number of Remote Indicators Pipe Size Size of Connection Piping Stop Valve Size MAWP Check Valve Size MAWP 33 STOP VALVES: EXTERNAL PIPING ASME CODE: Number of Valves Yes Valve Size Other BOTTOM BLOWDOWN CONNECTIONS: MAWP Piping Run Full Size Yes No Does boiler replace existing one: Yes FUEL TRAIN: CSD-1 40 MAWP Outlet Stop Valve Size MAWP Drain Valve Size Yes NFPA-85 Other Inlet Stop Valve Size Thermometer Manufacturer’s Certification Attached: No POTABLE WATER HEATER UNIQUE REQUIREMENTS 39 Number of Valves Valve Size 11 A 26 1. 28 17 Boiler Use Low-Water Fuel Cutoff Mfg. 2. Dial Graduation 10 Specific On-Site Location, i.e., Utility Room 1. PRESSURE/ALTITUDE GAGE: Boiler Type 9 / OBJECT LOCATION Name Jurisdiction No. / 35 No 36 No No 34 Yes Clearance from walls and floors: Side Yes Bottom Top 36 Additional recommendations and remarks by installer: 37 I HEREBY CERTIFY THAT THE INSTALLATION COMPLIES WITH APPENDIX I 38 Installer Name (PRINT) 38 Registration # Installer Signature This form may be obtained from The National Board of Boiler and Pressure Vessel Inspectors, 1055 Crupper Ave., Columbus, OH 43229 6 SECTION 1 NB-365 Rev. 2 --`,```,```,`,``,-`-`,`,`,`,`--- INSTALLATION: NB-23 2015 2.1 SCOPE (15) 2.2 --`,```,```,`,``,-`-`,`,`,`,`--- NBIC Part 1, Section 2 provides requirements for the installation of power boilers. DEFINITIONS See NBIC Part 1, Section 9, Glossary. 2.3 GENERAL REQUIREMENTS 2.3.1 SUPPORTS, FOUNDATIONS, AND SETTINGS Each boiler and its associated piping must be safely supported. Design of supports, foundations, and settings shall consider vibration (including seismic where necessary), movement (including thermal movement), and loadings (including the weight of water during a hydrostatic test) in accordance with jurisdictional requirements, manufacturer’s recommendations, and/or other industry standards, as applicable. 2.3.2 STRUCTURAL STEEL a) If the boiler is supported by structural steel work, the steel supporting members shall be so located or insulated that the heat from the furnace will not affect their strength. b) Structural steel shall be installed in accordance with jurisdictional requirements, manufacturer’s recommendations, and/or other industry standards, as applicable. 2.3.3 CLEARANCES (15) a) Boiler installations shall allow for normal operation, maintenance, and inspections. There shall be at least 36 in. (915 mm) of clearance on each side of the boiler to enable access for maintenance and/or inspection activities. Boilers operated in battery shall not be installed closer than 48 in. (1220 mm) from each other. The front or rear of any boiler shall not be located nearer than 36 in. (915 mm) from any wall or structure. Note: Alternative clearances in accordance with the manufacturer’s recommendations are subject to acceptance by the Jurisdiction. b) Boilers shall be installed to allow for removal and installation of tubes. c) Boilers with a top-opening manhole shall have at least 84 in. (2135 mm) of unobstructed clearance above the manhole to the ceiling of the equipment room. d) Boilers without top-opening manholes shall have at least 36 in. (915 mm) of clearance from the top of the boiler or as recommended by the manufacturer. e) Boilers with a bottom opening used for inspection or maintenance shall have at least 12 in. (305 mm) of unobstructed clearance. SECTION 2 7 SECTION 2 PART 1, SECTION 2 POWER BOILERS SECTION 2 2015 NATIONAL BOARD INSPECTION CODE (15) 2.4 EQUIPMENT ROOM REQUIREMENTS 2.4.1 EXIT Two means of exit shall be provided for equipment rooms exceeding 500 sq. ft. (46.5 sq. m) foor area and containing one or more boilers having a combined fuel capacity of 1,000,000 Btu/hr (293 kW) or more. Each elevation shall be provided with at least two means of exit, each to be remotely located from the other. A platform at the top of a single boiler is not considered an elevation. 2.4.2 LADDERS AND RUNWAYS a) All walkways, runways, and platforms shall be: 1) of metal construction; 2) provided between or over the top of boilers that are more than 8 ft. (2.4 m) above the operating foor to afford accessibilitt for normal operationn maintenancen and inspectionn 3) constructed of safety treads, standard grating, or similar material and have a minimum width of 30 in. (760 mm); 4) of bolted, welded, or riveted construction; and 5) equipped with handrails 42 in. (1,070 mm) high with an intermediate rail and 4 in. (100 mm) toeboard. b) Stairways that serve as a means of access to walkways, runways, or platforms shall not exceed an angle of 45 degrees from the horizontal and shall be equipped with handrails 42 in. (1070 mm) high with an intermediate rail. c) Ladders that serve as a means of access to walkways, runways, or platforms shall: 1) be of metal construction and not less than 18 in. (460 mm) wide; 2) have rungs that extend through the side members and are permanently secured; 3) have a clearance of not less than 30 in. (760 mm) from the front of rungs to the nearest permanent object on the climbing side of the ladder; 4) have a clearance of not less than 6-1/2 in. (165 mm) from the back of rungs to the nearest permanent object; and 5) have a clearance width of at least 15 in. (380 mm) from the center of the ladder on either side across the front of the ladder. d) There shall be at least two permanently installed means of exit from walkways, runways, or platforms that exceed 6 ft. (1.8 m) in length. 2.4.3 (15) --`,```,```,`,``,-`-`,`,`,`,`--- (15) 8 DRAINS At least one f 2.4.4 WATER (CLEANING) A convenient water supplt shall be provided for fushing out the boiler and its appurtenancesn adding water to the boiler while it is not under pressuren and cleaning the equipment room foor. SECTION 2 2.5 SOURCE REQUIREMENTS 2.5.1 FEEDWATER 2.5.1.1 VOLUME SECTION 2 NB-23 2015 The source of feedwater shall be capable of supplting a suffcient volume of water as determined bt the boiler manufacturer in order to prevent damage to the boiler when all the safety relief valves are discharging at full capacity. 2.5.1.2 CONNECTION a) To prevent thermal shock, feedwater shall be introduced into a boiler in such a manner that the water will not be discharged directly against surfaces exposed to high temperature gases or to direct radiation from the f b) For boiler operating pressures of 400 psig (2.8 MPa) or higher, the feedwater inlet through the drum shall be ftted with shieldsn sleevesn or other suitable means to reduce the effects of temperature differentials in the shell or head. c) Feedwater other than condensate return shall not be introduced through the blowoff. d) Boilers having more than 500 sq. ft. (46.5 sq. m) of water heating surface shall have at least two means of supplting feedwater. For boilers that are fred with solid fuel not in suspensionn and boilers whose setting or heat source can continue to supplt suffcient heat to cause damage to the boiler if the feedwater supply is interrupted, one such means of supplying feedwater shall not be subject to the same interruption as the frst method. oilers fred bt gaseousn liquidn or solid fuel in suspension mat be equipped with a single means of supplying feedwater, provided means are furnished for the immediate removal of heat input if the supply of feedwater is interrupted. e) For boilers having a water heating surface of not more than 100 sq. ft. (9 sq. m), the feedwater piping and connection to the boiler shall not be smaller than NPS 1/2 (DN 15). For boilers having a water heating surface more than 100 sq. ft. (9 sq. m), the feedwater piping and connection to the boiler shall not be less than NPS 3/4 (DN 20). f) Electric boiler feedwater connections shall not be smaller than NPS 1/2 (DN 15). g) High-temperature water boilers shall be provided with means of adding water to the boiler or system while under pressure. 2.5.1.3 PUMPS a) Boiler feedwater pumps shall have discharge pressure in excess of the maximum allowable working pressure (MAWP) in order to compensate for frictional losses, entrance losses, regulating valve losses, and normal static head, etc. Each source of feedwater shall be capable of supplying feedwater to the boiler at a minimum pressure of 3% higher than the highest setting of any safety valve on the boiler plus the expected pressure drop across the boiler. The following table is a guideline for estimating feedwater pump differential: (15) --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 2 9 2015 NATIONAL BOARD INSPECTION CODE SECTION 2 TABLE 2.5.1.3 GUIDE FOR FEEDWATER PUMP DIFFERENTIAL (15) Boiler Pressure Boiler Feedwater Pump Discharge Pressure psig (MPa) psig (MPa) 200 (1.38) 250 (1.72) 400 (2.76) 475 (3.28) 800 (5.52) 925 (6.38) 1,200 (8.27) 1,350 (9.31) b) For forced-fow steam generators with no fxed steam or water linen each source of feedwater shall be capable of supplying feedwater to the boiler at a minimum pressure equal to the expected maximum sustained pressure at the boiler inlet corresponding to operation at maximum designed steaming capacity with maximum allowable pressure at the superheater outlet. c) Control devices may be installed on feedwater piping to protect the pump against overpressure. 2.5.1.4 VALVES a) The feedwater piping shall be provided with a check valve and a stop valve. The stop valve shall be located between the check valve and the boiler. b) When two or more boilers are fed from a common source, there shall also be a globe or regulating valve on the branch to each boiler located between the check valve and the feedwater source. c) When the feedwater piping is divided into branch connections and all such connections are equipped with stop and check valves, the stop and check valve in the common source may be omitted. d) On single boiler-turbine unit installations, the boiler feedwater stop valve may be located upstream from the boiler feedwater check valve. e) If a boiler is equipped with duplicate feedwater supply arrangements, each such arrangement shall be equipped as required by these rules. f) A check valve shall not be a substitute for a stop valve. g) A combination feedwater stop-and-check valve in which there is only one seat and disk and a valve stem is provided to close the valve when the stem is screwed down shall be considered only as a stop valve, a separate check valve shall be installed. h) Whenever globe valves are used on feedwater piping, the inlet shall be under the disk of the valve. i) Stop valves and check valves shall be placed on the inlet of economizers or feedwater-heating devices. j) The recirculating return line for a high-temperature water boiler shall be provided with the stop valve, or valves, required for the main discharge outlet on the boiler. 2.5.2 FUEL Fuel ststemsn whether fring coaln oiln gasn or other substancen shall be installed in accordance with urisdictional and environmental requirements, manufacturer’s recommendations, and/or industry standards, as applicable. --`,```,```,`,``,-`-`,`,`,`,`--- 10 SECTION 2 NB-23 2015 ELECTRICAL A disconnecting means capable of being locked in the open position shall be installed at an accessible location at the boiler so that the boiler can be disconnected from all sources of potential. This disconnecting means shall be an integral part of the boiler or adjacent to it. 2.5.3.1 (15) SECTION 2 2.5.3 WIRING All wiring for controls, heat generating apparatus, and other appurtenances necessary for the operation of the boiler or boilers should be installed in accordance with the provisions of national or international standards and comply with the applicable local electrical codes. 2.5.3.2 REMOTE EMERGENCY SHUTDOWN SWITCHES a) A manually operated remote shutdown switch or circuit breaker shall be located just outside the equipment room door and marked for east identifcation. onsideration should also be given to the ttpe and location of the switch in order to safeguard against tampering. (15) b) For equipment rooms exceeding 500 ft.2 (46 m2) foor area or containing one or more boilers having a combined fuel capacity of 1,000,000 Btu/hr (293 kW) or more, additional manually operated remote emergenct shutdown switches shall be located at suitablt identifed points of egress acceptable to the Jurisdiction. c) Where a boiler is located indoors in a facility and not in a equipment room, a remote emergency shutdown switch shall be located within 50 ft. (15 m) of the boiler along the primary egress route from the boiler area. d) Consideration should be given to the type and location of the remote emergency shutdown switch(es) in order to safeguard against tampering. Where approved by the Jurisdiction, alternate locations of remote emergency switch(es) may be provided. e) For atmospheric-gas burners and for oil burners where a fan is on the common shaft with the oil pump, the emergency remote shutdown switch(es) or circuit breaker(s) must disconnect all power to the burner controls. f) For power burners with detached auxiliaries, the emergency remote shutdown switch(es) or circuit breaker(s) need only shut off the fuel input to the burner. 2.5.3.3 CONTROLS AND HEAT-GENERATING APPARATUS a) Oil and gas-fred and electricallt heated boilers shall be equipped with suitable primart (fame safeguard) safety controls, safety limit switches and controls, and burners or electric elements as required by a nationally or internationally recognized standard. b) The symbol of the certifying organization that has investigated such equipment as having complied with a nationallt recognized standard shall be affxed to the equipment and shall be considered as evidence that the unit was manufactured in accordance with that standard. c) These devices shall be installed in accordance with jurisdictional and environmental requirements, manufacturer’s recommendations, and/or industry standards, as applicable. --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 2 11 2015 NATIONAL BOARD INSPECTION CODE 2.5.4 SECTION 2 (15) VENTILATION AND COMBUSTION AIR a) The equipment room shall have an adequate air supply to permit clean, safe combustion, minimize soot formation, and maintain a minimum of 19.5% oxygen in the air of the boiler room. The combustion and ventilation air should be supplied by either an unobstructed air opening or by power ventilation or fans.2 b) Unobstructed air openings shall be sized on the basis of 1 sq. in. (650 sq. mm) free area per 2,000 Btu/ hr (586 W) maximum fuel input of the combined burners located in the equipment roomn or as specifed in the National Fire Protection Association (NFPA) standards for oil and gas burning installations for the particular job conditions. The equipment room air supply openings shall be kept clear at all times. c) Power ventilators or fans shall be sized on the basis of 0.2 cfm (0.0057 cu meters per minute) for each 1,000 Btu/hr (293 W) of maximum fuel input for the combined burners of all boilers located in the equipment room. Additional capacity may be required for any other fuel-burning equipment in the boiler room. d) When power ventilators or fans are used to supply combustion air, they shall be installed with interlock devices so that the burners will not operate without an adequate number of ventilators/fans in operation. e) The size of openings specifed in B art n .5.4 b) mat be reduced when special engineered air supply systems approved by the Jurisdiction are used. f) Care should be taken to ensure that steam and water lines are not routed across combustion air openings, where freezing may occur in cold climates. 2.5.5 (15) LIGHTING The equipment room should be well lit and it should have an emergency light source for use in case of power failure. 2.5.6 EMERGENCY VALVES AND CONTROLS All emergenct shut-off valves and controls shall be accessible from a foorn platformn walkwatn or runwat. Accessibility shall mean within a 6 ft. (1.8 m) elevation of the standing space and not more than 12 in. (305 mm) horizontally from the standing space edge. 2.6 DISCHARGE REQUIREMENTS 2.6.1 CHIMNEY OR STACK Chimneys or stacks shall be installed in accordance with jurisdictional and environmental requirements, manufacturer’s recommendations, and/or industry standards, as applicable. 2.6.2 ASH REMOVAL Ash removal systems shall be installed in accordance with jurisdictional and environmental requirements, manufacturer’s recommendations, and/or industry standards, as applicable. 2.6.3 DRAINS 2.6.3.1 CONNECTION 2 Fans – When combustion air is supplied to the boiler by an independent duct, with or without the employment of power ventilators or fans, the duct shall be sized and installed in accordance with the manufacturer’s recommendations. However, ventilation for the equipment room must still be considered. --`,```,```,`,``,-`-`,`,`,`,`--- 12 SECTION 2 NB-23 2015 SECTION 2 a) Each boiler shall have at least one drain pipe ftted with a stop valve at the lowest point of the boiler. If the connection is not intended for blowoff purposes, a single valve is acceptable if it can be locked in the closed position or a blank fange can be installed downstream of the valve. Bf the connection is intended for blowoff purposes, requirements of NBIC Part 1, 2.7.5 shall be followed. b) For high-temperature water boilers, the minimum size of the drain pipe shall be NPS 1 (DN 25). c) Drain pipesn valvesn and fttings within the same drain line shall be the same size. d) The discharge from the drain shall be piped to a safe location. 2.6.3.2 PRESSURE RATING Drain piping from the drain connectionn including the required valve(s) or the blanked fange connection, shall be designed for the temperature and pressure of the drain connection. The remaining piping shall be designed for the expected maximum temperature and pressure. Static head and possible choked fow conditions shall be considered. In no case shall the design pressure and temperature be less than 100 psig (700 kPa) and 220°F (104°C), respectively. 2.6.3.3 (15) PARTS e) When parts (e.g., economizers, etc.) are installed with a stop valve between the part and the boiler or the part cannot be completely drained through the drain on the boiler, a separate drain shall be installed on each such part. These drains shall meet the additional requirements of NBIC Part 1, 2.6.3, as applicable. f) Each water column shall have a drain pipe ftted with a stop valve at the lowest point of the water column. The stop valve shall have the capability of being locked in the closed position while the boiler is under pressure. The minimum size of the drain shall be NPS 3/4 (DN 20) and all other requirements of NBIC Part 1, 2.6.3, as applicable. --`,```,```,`,``,-`-`,`,`,`,`--- 2.7 OPERATING SYSTEMS 2.7.1 BREECHING AND DAMPERS Breeching and dampers shall be installed in accordance with jurisdictional and environmental requirements, manufacturer’s recommendations, and/or industry standards, as applicable. 2.7.2 BURNERS AND STOKERS Burners and stokers shall be installed in accordance with jurisdictional and environmental requirements, manufacturer’s recommendations, and/or industry standards, as applicable. 2.7.3 STEAM SUPPLY a) Provisions shall be made for the expansion and contraction of steam mains connected to boiler(s) so that there shall be no undue stress transmitted to the boiler(s). Steam reservoirs shall be installed on steam mains when heavt pulsations of the steam fow cause vibration of the boiler shell plates. b) Each discharge outlet of the boiler drum or superheater outlet shall be ftted with a stop valve located at an accessible point in the steam-delivery line and as near the boiler nozzle as is convenient and practicable. The valve shall be equipped to indicate from a distance whether it is closed or open, and shall be equipped with a slow-opening mechanism. When such outlets are over NPS 2 (DN 50), the valve or valves used on the connection shall be of the outside screw-and-yoke-rising spindle type, so as to SECTION 2 13 2015 NATIONAL BOARD INSPECTION CODE SECTION 2 indicate from a distance by the position of its spindle whether it is closed or open and the wheel should be carried either on the yoke or attached to the spindle. In the case of a single boiler and prime mover installation, the stop valve may be omitted provided the prime mover throttle valve is equipped with an indicator to show whether the valve is open or closed and is designed to withstand the required hydrostatic test pressure of the boiler. c) Stop valves and fttings shall complt with the appropriate national standard except that austenitic stainless steel is not permitted for water wetted service. e) The nearest stop valve or valves to the superheater outlet shall have a pressure rating at least equal to the minimum set pressure of any safety valve on the superheater and at the expected superheated steam temperature; or at least equal to 85% of the lowest set pressure of any safety valve on the boiler drum at the expected steam temperature of the superheater outlet, whichever is greater. (15) f) Provision for an ample gravity drain shall be provided when a stop valve is so located that water or condensation may accumulate. The gravity drain(s) shall be located such that the entire steam supply system can be drained. g) When boilers are connected to a common header, the connection from each boiler having a manhole opening shall be ftted with two stop valves having an ample free-blow drain between them. The discharge of this drain shall be visible to the operator while operating the valve. The stop valves shall consist of one stop check valve (set next to the boiler) and a second valve of the outside screw-and-yoke type; or two valves of the outside screw-and-yoke type. h) The second steam stop valve shall have a pressure rating at least equal to that required for the expected steam temperature and pressure at the valve; or the pressure rating shall be not less than 85% of the lowest set pressure of any safety valve on the boiler drum and for the expected temperature of the steam at the valve, whichever is greater. i) Pressure-reducing valves may be installed in the steam supply piping downstream from the required stop valve or valves. 2.7.4 CONDENSATE AND RETURN Each condensate return pump, where practicable, shall be provided with an automatic water level control set to maintain an adequate water level in the condensate tank. Condensate tanks not constructed in accordance with an accepted code or standard shall be vented to the atmosphere. 2.7.5 BLOWOFF a) Except for forced-fow steam generators with no fxed steam or water linen each boiler shall have a blowoff pipen ftted with a stop valven in direct connection with the lowest water space practicable. When the maximum allowable working pressure of the boiler exceeds 100 psig (700 kPa), there shall be two valves installed. b) The blowoff piping for each electric boiler pressure vessel having a nominal water content not exceeding 100 gal. (378 l) is required to extend through only one valve. c) When two valves are required, each bottom blowoff pipe shall have two slow-opening valves, or one quick-opening valve, at the boiler nozzle followed by a slow-opening valve. 14 SECTION 2 --`,```,```,`,``,-`-`,`,`,`,`--- d) Stop valves and fttings shall be rated for the maximum allowable working pressure of the boiler and shall be at least rated for 00 psig (700 k a) at the expected steam temperature at the valve or fttingn in accordance with the appropriate national standard. NB-23 2015 SECTION 2 d) Two independent slow-opening valves or a slow-opening valve and quick-opening valve may be combined in one bodt provided the combined ftting is the equivalent of two independent slow-opening valves or a slow-opening valve and a quick-opening valve, and the failure of one to operate cannot affect the operation of the other. e) Straight-run globe valves or valves where dams or pockets can exist for the collection of sediment shall not be used. f) The blowoff valve or valves and the pipe and fttings between them and the boiler shall be of the same size. The minimum size of pipe and fttings shall be S (D 5)n except boilers with 00 sq. ft ((. sq. m) or less of heating surface should be S ./4 (D 0). The maximum size of pipe and fttings shall not exceed NPS 2-1/2 (DN 65). g) For electric boilersn the minimum size of blowoff pipes and fttings shall be S boilers of 200 kW input or less. The minimum size should be NPS 3/4 (DN 20). (D 5)n except for h) Fittings and valves shall comply with the appropriate national standard except that austenitic stainless steel and malleable iron are not permitted. i) When the maximum allowable working pressure exceeds 100 psig (700 kPa), blowoff piping shall be at least Schedule 80 and the required valves and fttings shall be rated for at least . 5 times the maximum allowable working pressure of the boiler. When the maximum allowable working pressure exceeds (00 psig (6. M a)n blowoff piping shall be at least Schedule 80 and the required valves and fttings shall be rated for at least the maximum allowable working pressure of the boiler plus 225 psi (1.6 MPa). j) All blowoff pipingn when exposed to furnace heatn shall be protected bt fre brick or other heat resisting material so constructed that the piping may be readily inspected. k) On a boiler having multiple blowoff pipes, a single master stop valve should be placed on the common blowoff pipe from the boiler and one stop valve on each individual blowoff. Either the master valve or the valves on the individual blowoff lines shall be of the slow-opening type. --`,```,```,`,``,-`-`,`,`,`,`--- l) The discharge of blowoff pipes shall be located so as to prevent injury to personnel. m) All waterwalls or water screens that do not drain back into the boiler and integral economizers forming part of a boiler shall be equipped with blowoff piping and valves conforming to the requirements of this paragraph. n) Blowoff piping from a boiler should not discharge directly into a sewer. A blowoff tank, constructed to the provisions of a code of construction acceptable to the Jurisdiction, shall be used where conditions do not provide an adequate and safe open discharge. o) Galvanized pipe shall not be used. p) Boiler blowoff systems shall be constructed in accordance with the Guide for Blowoff Vessels (NB-27).3 q) Where necessary to install a blowoff tank underground, it shall be enclosed in a concrete or brick pit with a removable cover so that inspection of the entire shell and heads of the tank can be made. r) Piping connections used primarily for continuous operation, such as deconcentrators on continuous blowdown ststemsn are not classed as blowoffsn but the pipe connections and all fttings up to and including the frst shutoff valve shall be equal at least to the pressure requirements for the lowest set pressure of any safety valve on the boiler drum and with the corresponding saturated-steam temperature. Further, such connections shall not exceed NPS 2-1/2 (DN 65). 3 The Guide for Blowof eeeele (NB-27) can be found on the National Board web-site, www.nationalboard.org,. SECTION 2 15 SECTION 2 2015 NATIONAL BOARD INSPECTION CODE 2.8 CONTROLS AND GAGES 2.8.1 WATER a) Each automaticallt-fred steam boiler shall be equipped with at least two low-water fuel cutoffs. The water inlet shall not feed water into the boiler through a foat chamber. b) Each electric steam boiler of the resistance element type shall be equipped with an automatic low-water cutoff so located as to automatically cut off the power supply to the heating elements before the surface of the water falls below the visible part of the glass. No low-water cutoff is required for electrode-type boilers. c) Designs embodting a foat and foat bowl shall have a vertical straightawat drainpipe at the lowest point in the water equalizing pipe connectionsn bt which the bowl and the equalizing pipe can be fushed and the device tested. d) The water column shall be directly connected to the boiler. Outlet connections (except for damper regulator, feedwater regulator, low-water fuel cutoff, drains, steam gages, or such apparatus that does not permit the escape of an appreciable amount of steam or water) should not be placed on the piping that connects the water column to the boiler. e) Straight-run globe valves of the ordinary type shall not be used on piping that connects the water column to the boiler. Where water columns are 7 ft. ( . m) or more above the foor leveln adequate means for operating gage cocks or blowing out the water glass shall be provided. f) When automatic shutoff valves are used on piping that connects the water column to the boiler, they shall conform to the requirements of the code of construction for the boiler. g) When shutoff valves are used on the connections to a water column, they shall be either outside-screwand-yoke or lever-lifting-type gate valves or stop cocks with levers permanently fastened thereto and marked in line with their passagen or of such other through-fow constructions to prevent stoppage bt deposits of sediment and to indicate by the position of the operating mechanism whether they are in open or closed position; and such valves or cocks shall be locked or sealed open. h) Each steam boiler having a fxed waterline shall have at least one water-gage glass except that boilers operated at pressures over 400 psig (2.8 MPa) shall be provided with two water-gage glasses that may be connected to a single water column or connected directly to the drum. The gage glass connections and pipe connection shall be not less than NPS 1/2 (DN 15). Each water-gage glass shall be equipped with a valved drain. --`,```,```,`,``,-`-`,`,`,`,`--- 16 i) Electric steam boilers shall have at least one water-gage glass. On electrode-type electric boilers, the gage glass shall be located as to indicate the water levels both at startup and maximum steam load conditions, as established by the boiler manufacturer. On resistance element type electric steam boilers, the lowest visible part of the gage glass shall be located at least 1 in. (25 mm) above the lowest permissible water level established by the boiler manufacturer. j) The lowest visible part of the water-gage glass shall be at least 2 in. (50 mm) above the lowest permissible water level established by the boiler manufacturer. k) For all installations where the water-gage glass or glasses are not easily viewed by the operator, consideration should be given to install a method of remote transmission of the water level to the operating foor. SECTION 2 NB-23 2015 oilers of the horizontal fretube ttpe shall be so set that when the water is at the lowest reading in the water-gage glass, it shall be 3 in. (75 mm) above the lowest permissible water level as determined by the manufacturer. Horizontal fretube boilers that do not exceed 6 in. (400 mm) in inside diameter shall have the lowest visible level in the gage glass at least 1 in. (25 mm) above the lowest permissible level as determined by the manufacturer. SECTION 2 l) m) Each water-gage glass shall be equipped with a top and a bottom shutoff valve of such through-f construction as to prevent blockage by deposits of sediment and to indicate by the position of the operating mechanism whether they are in the open or closed position. The pressure-temperature rating shall be at least equal to that of the lowest set pressure of any safety valve on the boiler drum and the corresponding saturated steam temperature. 2.8.2 PRESSURE GAGE a) Each steam boiler shall have a pressure gage connected to the steam space or to the steam connection to the water column. When a pressure-reducing valve is installed in the steam supply piping, a pressure gage shall be installed on the low pressure side of the pressure-reducing valve. b) The dial range shall not be less than 1.5 times and no greater than two times the pressure at which the lowest pressue-relief valve is set. 2.8.2.1 CONNECTION a) For a steam boiler the gage or connection shall contain a siphon or equivalent device that will develop and maintain a water seal that will prevent steam from entering the gage tube. A valve or cock shall be placed in the gage connection adjacent to the gage. An additional valve or cock should be located near the boiler providing it is locked or sealed in the open position. No other shut-off valves shall be located between the gage and the boiler. b) Pressure gage connections shall be suitable for the maximum allowable working pressure and temperature, but if the temperature exceeds 406°F (208°C), brass or copper pipe or tubing shall not be used. The connections to the boiler, except for the siphon, if used, shall not be less than NPS 1/4 (DN 8). Where steel or wrought iron pipe or tubing is used, it shall not be less than 1/2 in. (13 mm) inside diameter. The minimum size of a siphon, if used, shall be 1/4 in. (6 mm) inside diameter. 2.8.3 TEMPERATURE --`,```,```,`,``,-`-`,`,`,`,`--- Each high-temperature water boiler shall have a temperature gage or other reporting device located to provide an accurate representation of the temperature at or near the boiler outlet. 2.9 PRESSURE RELIEF VALVES 2.9.1 VALVE REQUIREMENTS — GENERAL a) Safety valves are designed to relieve steam. b) Safety relief valves are valves designed to relieve either steam or water, depending on the application. c) Safety and safety relief valves are to be manufactured in accordance with a national or international standard. d) Deadweight or weighted-lever pressure-relieving valves shall not be used. SECTION 2 17 2015 NATIONAL BOARD INSPECTION CODE e) For high-temperature water boilers, safety relief valves shall have a closed bonnet, and safety relief valve bodies shall not be constructed of cast iron. SECTION 2 f) Safety and safety relief valves with an inlet connection greater than NPS 3 (DN 80) used for pressure greater than 5 psig ( 0. k a)n shall have a fange inlet connection or a welding-end inlet connection. The dimensions of f g) When a safety or safety relief valve is exposed to outdoor elements that may affect operation of the valve, it is permissible to shield the valve with a cover. The cover shall be properly vented and arranged to permit servicing and normal operation of the valve. 2.9.1.1 NUMBER At least one ational oard capacitt certifed safett or safett relief valve shall be installed on the boiler. Bf the boiler has more than 500 sq. ft. (46.5 sq. m.) of heating surface, or if an electric boiler has a power input of more than .76 million tu/hr ( n 00 kW)n two or more ational oard capacitt certifed safett or safett relief valves shall be installed. 2.9.1.2 LOCATION a) Safety or safety relief valves shall be placed on, or as close as physically possible to, the boiler proper. b) Safety or safety relief valves shall not be placed on the feedline. c) Safety or safety relief valves shall be connected to the boiler independent of any other connection without ant unnecessart intervening pipe or fttings. Such intervening pipe or fttings shall not be longer than the face-to-face dimension of the corresponding tee ftting of the same diameter and pressure rating as listed in the applicable standards. 2.9.1.3 CAPACITY --`,```,```,`,``,-`-`,`,`,`,`--- a) The pressure-relieving valve capacity for each boiler shall be such that the valve or valves will discharge all the steam that can be generated by the boiler without allowing the pressure to rise more than 6% above the highest pressure at which any valve is set and in no case to more than 6% above the maximum allowable working pressure of the boiler. b) The minimum relieving capacitt for other than electric boilers and forced-fow steam generators with no fxed steam line and waterline shall be estimated for the boiler and waterwall heating surfaces as given in NBIC Part 1, Table 2.9.1.3, but in no case should the minimum relieving capacity be less than the maximum designed steaming capacity as determined by the manufacturer. c) The required relieving capacity in pounds per hour of the safety or safety relief valves on a high temperature water boiler shall be determined by dividing the maximum output in Btu at the boiler nozzle obtained bt the fring of ant fuel for which the unit is designed bt one thousand. (metrication) d) The minimum safety or safety relief valve relieving capacity for electric boilers is 3.5 lbs/hr/kW (1.6 kg/ hr/kW) input. e) If the safety or safety relief valve capacity cannot be computed, or if it is desirable to prove the computationsn it should be checked bt ant one of the following methodsn and if found insuffcientn additional relieving capacity shall be provided: 1) By performing an accumulation test, that is, by shutting off all other steam discharge outlets from the boiler and forcing the fres to the maximum. This method should not be used on a boiler with a superheater or reheater, or on a high-temperature water boiler; 18 SECTION 2 NB-23 2015 2) By measuring the maximum amount of fuel that can be burned and computing the corresponding evaporative capacity upon the basis of the heating value of the fuel; SECTION 2 3) By determining the maximum evaporative capacity by measuring the feedwater. The sum of the safety valve capacities marked on the valves shall be equal to or greater than the maximum evaporative capacity of the boiler. This method should not be used on high-temperature water boilers. TABLE 2.9.1.3 MINIMUM POUNDS OF STEAM PER HOUR PER SQUARE FOOT OF HEATING SURFACE Firetube Boiler Boiler HeatǴn Srraae ll seaam/r Watertube Boiler 2 (kn seaam/r a2) HaǴd-fred 5 (24) 6 (29) soker-fred 7 (34) 8 (39) Oil, na , or pSlverized aoal 8 (39) 10 (49) Waserwall HeatǴn Srraae HaǴd-fred 8 (39) 8 (39) soker-fred 10 (49) 12 (59) Oil, na , or pSlverized aoal 14 (68) 16 (78) (15) Copper-fǴǴed WasersSle HaǴd-fred 4 (20) soker-fred 5 (24) Oil, na , or pSlverized aoal 6 (29) Note: --`,```,```,`,``,-`-`,`,`,`,`--- • When a boiler is fred onlt bt a gas having a heat value not in excess of 00 tu/cu.ft.(7.5MM/cu. m)n the minimum relieving capacitt should be based on the values given for hand-fred boilers above. • The heating surface shall be computed for that side of the boiler surface exposed to the products of combustion, exclusive of the superheating surface. In computing the heating surface for this purpose onlt the tubesn freboxesn shellsn tubesheetsn and the pro ected area of headers need to be consideredn except that for vertical fretube steam boilersn onlt that portion of the tube surface up to the middle gage cock is to be computed. • For fretube boiler units exceeding 8n000 tu/ft.2 (9,085 J/cm.2) (total fuel Btu (J) Input divided by total heating surface), the factor from the table will be increased by 1 (4.88) for every 1,000 Btu/ft.2 (1,136 J/cm.2) above 8,000 Btu/ft.2 (9,085 J/cm.2) For units less than 7,000 Btu/ft.2 (7,950 J/cm.2), the factor from the table will be decreased by 1 (4.88). • For watertube boiler units exceeding 16,000 Btu/ft.2 (18,170 J/cm.2)(total fuel Btu input divided by the total heating surface) the factor from the table will be increased by 1 (4.88) for every 1,000 Btu/ft.2 (1,136 J/cm.2) above 16,000 Btu/ft.2 (18,170 J/cm.2). For units with less than 15,000 Btu/ft.2 (17,034 J/cm.2), the factor in the table will be decreased by 1 (4.88) for every 1,000 Btu/ft.2 (1,136 J/cm.2) below 15,000 Btu/ft.2 (17,034 J/cm.2). SECTION 2 19 2015 NATIONAL BOARD INSPECTION CODE 2.9.1.4 SET PRESSURE SECTION 2 One or more safety or safety relief valves on the boiler proper shall be set at or below the maximum allowable working pressure. If additional valves are used, the highest pressure setting shall not exceed the maximum allowable working pressure by more than 3%. The complete range of pressure settings of all the safety relief valves on a boiler shall not exceed 10% of the highest pressure to which any valve is set. Pressure setting of safety relief valves on high temperature water boilers may exceed this 10% range. 2.9.2 FORCED-FLOW STEAM GENERATOR For a forced-fow steam generator with no fxed steamline and waterlinen equipped with automatic controls and protective interlocks responsive to steam pressure, safety valves may be provided in accordance with the above paragraphs identifed in B art n .(. or the following protection against overpressure shall be provided: a) One or more power-actuated pressure-relieving valves shall be provided in direct communication with the boiler when the boiler is under pressure and shall receive a control impulse to open when the maximum allowable working pressure at the superheater outlet is exceeded. The total combined relieving capacity of the power-actuated pressure-relieving valves shall be not less than 10% of the maximum design steaming capacity of the boiler under any operating condition as determined by the manufacturer. The valves shall be located in the pressure part system where they will relieve the overpressure. An isolating stop valve of the outside-screw-and-yoke type should be installed between the power-actuating pressure-relieving valve and the boiler to permit repairs provided an alternate power-actuated pressure-relieving valve of the same capacity is so installed as to be in direct communication with the boiler; --`,```,```,`,``,-`-`,`,`,`,`--- b) Spring-loaded safety valves shall be provided having a total combined relieving capacity, including that of the power-actuated pressure-relieving valve, of not less than 100% of the maximum designed steaming capacity of the boiler, as determined by the manufacturer. In this total, credit in excess of 30% of the total relieving capacity shall not be allowed for the power-actuated pressure-relieving valves actually installed. Any or all of the spring-loaded safety valves may be set above the maximum allowable working pressure of the parts to which they are connected, but the set pressures shall be such that when all these valves (together with the power-actuated pressure-relieving valves) are in operation the pressure will not rise more than 20% above the maximum allowable working pressure of any part of the boiler, except for the steam piping between the boiler and the prime mover; c) When stop valves are installed in the water-steam fow path between ant two sections of a forced-fow steam generator with no f (15) 1) The power-actuated pressure-relieving valve shall also receive a control impulse to open when the maximum allowable working pressure of the component, having the lowest pressure level upstream to the stop valve, is exceeded; 2) The spring-loaded safety valve shall be located to provide overpressure protection for the component having the lowest working pressure; and 3) A reliable pressure-recording device shall always be in service and records kept to provide evidence of conformity to the above requirements. 2.9.3 SUPERHEATERS a) Every attached superheater shall have one or more safety valves. The location shall be suitable for the service intended and shall provide the overpressure protection required. The pressure drop upstream of each safety valve shall be considered in determining the set pressure and relieving capacity of that valve. If the superheater outlet header has a full, free steam passage from end to end and is so constructed that steam is supplied to it at practically equal intervals throughout its length so that there is a 20 SECTION 2 NB-23 2015 uniform fow of steam through the superheater tubes and the headern the safett valve or valves mat be located anywhere in the length of header. SECTION 2 b) The pressure-relieving capacity of the safety valve or valves on an attached superheater shall be included in determining the number and size of the safety valves for the boiler provided there are no intervening valves between the superheater safety valve and the boiler and the discharge capacity of the safety relief valve or valves, on the boiler, as distinct from the superheater, is at least 75% of the aggregate capacity required. c) Evert independentlt fred superheater that mat be shut off from the boiler and permit the superheater to become a fred pressure vessel shall have one or more safett valves having a discharge capacitt equal to 6 pounds of steam per hr/sq. ft. (29 kg per hr per sq. m) of superheater surface measured on the side exposed to the hot gases. d) Every safety valve used on a superheater discharging superheated steam at a temperature over 450°F (230°C) shall have a casing, including the base, body, bonnet, and spindle constructed of steel, steel allotn or equivalent heat-resistant material. The valve shall have a fanged inlet connection or a welded-end inlet connection. The seat and disk shall be constructed of suitable heat-erosive and corrosive-resistant material, and the spring fully exposed outside of the valve casing so that it is protected from contact with the escaping steam. 2.9.4 ECONOMIZERS 2.9.5 --`,```,```,`,``,-`-`,`,`,`,`--- An economizer that may not be isolated from a boiler does not require a safety relief valve. Economizers that mat be isolated from a boiler or other heat transfer devicen allowing the economizer to become a fred pressure vessel, shall have a minimum of one safety relief valve. Discharge capacity, rated in lbs/hr (kg/hr), of the safety relief valve or valves shall be be calculated from the maximum expected heat absorption rate in Btu/hr (Joules/hr) of the economizer, and will be determined from manufacturer data, divided by 1,000 (2,326). The safety relief valve shall be installed in a location recommended by the manufacturer, when no recommendation exists the location shall be as close as practical to the economizer outlet. PRESSURE-REDUCING VALVES a) Where pressure-reducing valves are used, one or more safety or safety relief valves shall be installed on the low pressure side of the reducing valve in those installations where the piping or equipment on the low pressure side does not meet the requirements for the steam supply piping. b) The safety or safety relief valves shall be located as close as possible to the pressure-reducing valve. c) Capacity of the safety or safety relief valves shall not be less than the total amount of steam that can pass from the high pressure side to the low pressure side and be such that the pressure rating of the lower pressure piping or equipment shall not be exceeded. d) The use of hand-controlled bypasses around reducing valves is permissible. The bypass around a reducing valve may not be greater in capacity than the reducing valve unless the piping or equipment is adequately protected by safety or safety relief valves or meets the requirements of the high pressure system. 2.9.6 MOUNTING AND DISCHARGE REQUIREMENTS a) Every boiler shall have outlet connections for the safety or safety relief valve, or valves, independent of any other outside steam connection, the area of opening shall be at least equal to the aggregate areas of inlet connections of all of the attached safety or safety relief valves. An internal collecting pipe, splash plate, or pan should be used, provided the total area for inlet of steam thereto is not less than twice the aggregate areas of the inlet connections of the attached safety or safety relief valves. The holes in such collecting pipes shall be at least 1/4 in. (6 mm) in diameter, and the least dimension in any other form of SECTION 2 21 2015 NATIONAL BOARD INSPECTION CODE opening for inlet of steam shall be 1/4 in. (6 mm). If safety or safety relief valves are attached to a separate steam drum or dome, the opening between the boiler proper and the steam drum or dome shall be not less than 10 times the total area of the safety valve inlet. SECTION 2 b) Every safety or safety relief valve shall be connected so as to stand in an upright position with spindle vertical. c) The opening or connection between the boiler and the safety or safety relief valve shall have at least the area of the valve inlet and the inlet pipe to the pressure relief valve shall be no longer than the face to face dimension of the corresponding tee ftting of the same diameter and pressure class. When a discharge pipe is used, the cross-sectional area shall not be less than the full area of the valve outlet or of the total of the areas of the valve outlets discharging thereinto and shall be as short and straight as possible and arranged to avoid undue stresses on the valve or valves. d) o valve of ant description except a changeover valve as defned belown shall be placed between the safety or safety relief valves and the boiler, nor on the discharge pipe between the safety or safety relief valves and the atmosphere. A changeover valve, which allows two redundant pressure relief valves to be installed for the purpose of changing from one pressure relief valve to the other while the boiler is operating, may be used provided the changeover valve is in accordance with the original code of construction. It is recommended that the Jurisdiction be contacted to determine the acceptability of changeover valves on boiler applications. The changeover valve shall be designed such that there is no intermediate position where both pressure relief valves are isolated from the boiler. e) When two or more safety valves are used on a boiler, they should be mounted either separately or as twin valves made by placing individual valves on Y-bases, or duplex valves having two valves in the same body casing. Twin valves made by placing individual valves on Y-bases or duplex valves having two valves in the same body shall be of equal size. f) When two valves of different sizes are mounted singly, the relieving capacity of the smaller valve shall not be less than 50% of that of the larger valve. g) When a boiler is ftted with two or more safett relief valves on one connectionn this connection to the boiler shall have a cross-sectional area not less than the combined areas of inlet connections of all the safety relief valves with which it connects. h) All safety or safety relief valves shall be piped to a safe point of discharge so located or piped as to be carried clear from running boards or platforms. Provision for an ample gravity drain shall be made in the discharge pipe at or near each safety or safety relief valve, and where water or condensation may collect. Each valve shall have an open gravity drain through the casing below the level of the valve seat. For iron- and steel- bodied valves exceeding NPS 2 (DN 50), the drain hole shall be tapped not less than NPS 3/8 (DN 10). i) Discharge piping from safety relief valves on high-temperature water boilers shall have adequate provisions for water drainage as well as steam venting. j) Bf a muffer is used on a safett or safett relief valven it shall have suffcient outlet area to prevent back pressure from interfering with the proper operation and discharge capacitt of the valve. The muffer plates or other devices shall be so constructed as to avoid a possibility of restriction of the steam passages due to deposits. Muffers shall not be used on high-temperature water boiler safett relief valves. --`,```,```,`,``,-`-`,`,`,`,`--- 22 SECTION 2 2.10 TESTING AND ACCEPTANCE 2.10.1 GENERAL SECTION 2 NB-23 2015 a) Care shall be exercised during installation to prevent loose weld material, welding rods, small tools, and miscellaneous scrap metal from getting into the boiler. Where possible, an inspection of the interior of the boiler and its appurtenances shall be made for the presence of foreign debris prior to making the fnal closure. b) Safe operation should be verifed bt a person familiar with boiler ststem operations for all boilers and connected appurtenances and all pressure piping connecting them to the appurtenances and all piping up to and including the frst stop valven or the second stop valve when two are required. c) The wall thickness of all pipe connections shall comply with the requirements of the code of construction for the boiler. d) All threaded pipe connections shall engage at least f e) In bolted connections, the bolts, studs, and nuts shall be marked as required by the original code of construction and be fully engaged (e.g., the end of the bolt or stud shall protrude through the nut). f) Washers shall onlt be used when specifed bt the manufacturer of the part being installed. 2.10.2 PRESSURE TEST Prior to initial operation, the completed boiler, including pressure piping, water columns, superheaters, economizers, stop valves, etc., shall be pressure tested in accordance with the original code of construction. Any pressure piping and fttings such as water columnsn blowoff valvesn feedwater regulatorsn superheatersn economizers, stop valves, etc., which are shipped connected to the boiler as a unit, shall be hydrostatically tested with the boiler and witnessed by an Inspector. 2.10.3 NONDESTRUCTIVE EXAMINATION Boiler components and subcomponents shall be nondestructively examined as required by the governing code of construction. 2.10.4 SYSTEM TESTING rior to fnal acceptancen an operational test shall be performed on the complete installation. The test data shall be recorded and the data made available to the jurisdictional authorities as evidence that the installation complies with the provisions of the governing code(s) of construction. This operational test may be used as the f 2.10.5 FINAL ACCEPTANCE A boiler may not be placed into service until its installation has been inspected and accepted by the appropriate jurisdictional authorities. 2.10.6 BOILER INSTALLATION REPORT a) Upon completion, inspection, and acceptance of the installation, the installer shall complete and certify the Boiler Installation Report I-1. See NBIC Part 1, 1.4.5.1. --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 2 23 2015 NATIONAL BOARD INSPECTION CODE b) The Boiler Installation Report I-1 shall be submitted as follows: 2) One copy to the Jurisdiction, if required. 2.11 (15) TABLES AND FIGURES a) NBIC Part 1, Table 2.5.1.3 - Guide for Feedwater Pump Differential b) NBIC Part 1, Table 2.9.1.3 - Minimum Pounds of Steam per Hour Per Square Foot of Heating Surface 24 SECTION 2 --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 2 1) One copy to the owner; and NB-23 2015 PART 1, SECTION 3 INSTALLATION — STEAM HEATING BOILERS, HOT-WATER HEATING BOILERS, HOT-WATER SUPPLY BOILERS, AND POTABLE WATER HEATERS SCOPE The scope of NBIC Part 1, Section 3 shall apply to steam heating boilers, hot-water heating boilers, hot-water supply boilers, and potable water heaters. 3.2 (15) DEFINITIONS See in NBIC Part 1, Section 9, Glossary. 3.3 GENERAL REQUIREMENTS 3.3.1 SUPPORTS Each heating boiler shall be supported by masonry and/or structural supports of suffcient strength and rigidity to safely support the heating boiler and its contents without vibration in the heating boiler or its connecting piping and to allow for expansion and contraction. 3.3.1.1 METHODS OF SUPPORT FOR STEAM HEATING, HOT-WATER HEATING, AND HOT-WATER SUPPLY BOILERS a) Loadings --`,```,```,`,``,-`-`,`,`,`,`--- 1) The design and attachment of lugs, hangers, saddles, and other supports shall take into account the stresses due to hydrostatic head of fully fooded eeuipment in determining the minimum thiccnesses reeuired. Additional stresses imposed by effects other than worcing pressure or static head that increase the average stress by more than 10% of the allowable working stress shall also be taken into account. These effects include the weight of the component and its contents and the method of support. 2) In applying the reeuirements of 1) above, provision shall be made for localized stresses due to concentrated support loads, temperature changes, and restraint against movement of the boiler due to pressure. Lugs, hangers, brackets, saddles, and pads shall conform satisfactorily to the shape of the shell or surface to which they are attached or are in contact. b) Horizontal Return Firetube Boilers 1) Boilers over 72 in. (1,800 mm) in diameter. A horizontal-return tubular boiler over 72 in. (1830 mm) in diameter shall be supported from steel hangers by the outside-suspension type of setting, independent of the furnace wall. The hangers shall be so designed that the load is properly distributed. 2) Boilers 14 ft. (4.3 m) or over in length, or over 54 in. (1370 mm) up to 72 in. (1,830 mm) in diameter: A horizontal-return tubular boiler over 54 in. (1,370 mm) and up to and including 72 in. (1,800 mm) in diameter shall be supported by the outside-suspension type of setting, or at four points by not less than eight steel brackets set in pairs, the brackets of each pair to be spaced not over 2 in. (50 mm) apart and the load to be eeualized between them. See NBIC Part 1, Figure 3.3.1.1-a. SECTION 3 25 SECTION 3 3.1 2015 NATIONAL BOARD INSPECTION CODE FIGURE 3.3.1.1-a SPACING AND WELD DETAILS FOR SUPPORTING LUGS IN PAIRS ON HORIZONTALRETURN TUBULAR BOILER 7 in. (175mm) = not less than 1% of the boiler diameter SECTION 3 2 in. (50mm) 0.7 T “T” 0.7 T FIGURE 3.3.1.1-b WELDED BRACKET CONNECTION FOR HORIZONTAL-RETURN TUBULAR BOILER B 2-1/2 in. (64 mm) min. “T” R = not less than 1-1/2 x diameter of hole “T” ¹ R “R” T = not less than 1% of the boiler diameter 0.7T Section B - B¹ 20 deg. max. --`,```,```,`,``,-`-`,`,`,`,`--- 3) Boilers up to 54 in. (1,370 mm) in diameter A horizontal-return boiler up to and including 54 in. (1,370 mm) in diameter shall be supported by the outside-suspension type of setting, or by not less than two steel brackets on each side. See NBIC Part 1, Figures 3.3.1.1-b. c) Supporting Members If the boiler is supported by structural steel work, the steel supporting members shall be so located or insulated that the heat from the furnace will not impair their strength. 26 SECTION 3 NB-23 2015 3.3.2 SECTION 3 d) Lugs or Hangers Lugs, hangers, or braccets made of materials in accordance with the reeuirements of the code of construction may be attached by fusion welding provided they are attached by fllet welds along the entire periphery or contact edges. NBIC Part 1, Figure 3.3.1.1-b illustrates an acceptable design of hanger braccet with the additional reeuirement that the center pin be located at the vertical center line over the center of the welded contact surface. The bracket plates shall be spaced at least 2-1/2 in. (64 mm) apart, but this dimension shall be increased if necessary to permit access for the welding operation. The stresses computed by dividing the total load on each lug, hanger, or bracket, by the minimum cross-sectional area of the weld shall not exceed 2,800 psig (19 MPa). Where it is impractical to attach lugs, hangers, or brackets by welding, studs with not less than 10 threads/in. (approximately 4 threads/ cm) may be used. In computing the shearing stresses, the root area at the bottom of the thread shall be used. The shearing and crushing stresses on studs shall not exceed that permitted by the code of construction. SETTINGS Steam heating, hot-water heating, and hot-water supply boilers of wrought materials of the wet-bottom type having an external width of over 36 in. (914 mm) shall be supported so as to have a minimum clearance of 12 in. (305 mm) between the bottom of the boiler and the foor to facilitate inspection. When the width is 33 in. (914 mm) or less, the clearance between the bottom of the boiler and the foor line shall be not less than 6 in. (150 mm), except when any part of the wet bottom is not farther from the outer edge than 12 in. (305 mm), this clearance shall be not less than 4 in. (100 mm). Boiler insulation, saddles, or other supports shall be arranged so that inspection openings are readily accessible. 3.3.3 STRUCTURAL STEEL a) If the boiler is supported by structural steel work, the steel supporting members shall be so located or insulated that the heat from the furnace will not affect their strength. 3.3.4 --`,```,```,`,``,-`-`,`,`,`,`--- b) Structural steel shall be installed in accordance with jurisdictional reeuirements, manufacturer’s recommendations, and/or industry standards as appropriate. CLEARANCES a) Heating boilers shall have a minimum distance of at least 36 in. (914 mm) between the top of the heating boiler and any overhead structure and at least 36 in. (914 mm) between all sides of the heating boiler and adjacent walls, structures, or other eeuipment. Heating boilers having manholes shall have at least 84 in. (2,135 mm) of clearance between the manhole opening and any wall, ceiling, piping, or other eeuipment that may prevent a person from entering the heating boiler. Alternative clearances in accordance with the manufacturer’s recommendations are subject to acceptance by the Jurisdiction. b) Modular heating boilers that reeuire individual units to be set side by side, front to bacc, or by staccing shall provide clearances in accordance with the manufacturer’s recommendations, subject to acceptance by the Jurisdiction. c) Heating boilers shall be located so that adeeuate space is provided for proper operation, maintenance,4 and inspection of eeuipment and appurtenances. 4 Maintenance – This includes the removal of tubes. SECTION 3 27 2015 NATIONAL BOARD INSPECTION CODE (15) 3.4 EQUIPMENT ROOM REQUIREMENTS 3.4.1 EXIT SECTION 3 Two means of exit shall be provided for eeuipment rooms exceeding 500 se. ft. (43.5 se. m) of foor area and containing one or more boilers having a combined fuel capacity of 1,000,000 Btu/hr (293 cW) or more (or eeuivalent electrical heat input). Each elevation shall be provided with at least two means of exit, each to be remotely located from the other. A platform at the top of a single boiler is not considered an elevation. 3.4.2 LADDERS AND RUNWAYS a) All walcways, runways, and platforms shall be: 1) of metal construction; 2) provided between or over the top of boilers that are more than 8 ft. (2.4 m) above the operating foor to afford accessibility for normal operation, maintenance, and inspectionn 3) constructed of safety treads, standard grating, or similar material and have a minimum width of 30 in. (760 mm); 4) of bolted, welded, or riveted construction; and 5) eeuipped with handrails 42 in. (1,070 mm) high with an intermediate rail and 4 in. (100 mm) toe board. b) Stairways that serve as a means of access to walkways, runways, or platforms shall not exceed an angle of 45 degrees from the horizontal and be eeuipped with handrails 42 in. (1,070 mm) high with an intermediate rail. c) Ladders that serve as a means of access to walkways, runways, or platforms shall: 1) be of metal construction and not less than 18 in. (460 mm) wide; --`,```,```,`,``,-`-`,`,`,`,`--- 2) have rungs that extend through the side members and are permanently secured; 3) have a clearance of not less than 30 in. (760 mm) from the front of rungs to the nearest permanent object on the climbing side of the ladder; 4) have a clearance of not less than 6-1/2 in. (165 mm) from the back of rungs to the nearest permanent object; and 5) have a clearance width of at least 15 in. (380 mm) from the center of the ladder on either side across the front of the ladder. d) There shall be at least two permanently installed means of exit from walkways, runways, or platforms that exceed 6 ft. (1.8 m) in length. 3.5 SOURCE REQUIREMENTS 3.5.1 WATER a) A means to add water to or fll the boiler, while not under pressure, shall be provided. A valve or threaded plug may be used to shut off the fll connection when the boiler is in service. b) Water fll connections shall be installed. A means shall be provided at or near the boiler to prevent baccfeeding. Such means shall be rated for the boiler design pressure and temperature. 28 SECTION 3 NB-23 2015 c) Provision should also be made in every eeuipment room for a convenient water supply that can be used to f 3.5.2 FUEL 3.5.3 ELECTRICAL 3.5.3.1 STEAM HEATING, HOT WATER HEATING, AND HOT WATER SUPPLY BOILERS a) All wiring for controls, heat generating apparatus, and other appurtenances necessary for the operation of the boiler or boilers shall be installed in accordance with the provisions of national or international standards and comply with the applicable local electrical codes. SECTION 3 Fuel systems, whether fring coal, oil, gas, or other substance, shall be installed in accordance with jurisdictional and environmental reeuirements, manufacturer’s recommendations, and/or industry standards, as applicable. (15) b) A manually operated remote shutdown switch or circuit breacer shall be located just outside the eeuipment room door and marced for easy identifcation. Consideration should also be given to the type and location of the switch to safeguard against tampering. c) A disconnecting means capable of being locced in the open position shall be installed at an accessible location at the boiler so that the boiler can be disconnected from all sources of potential. This disconnecting means shall be an integral part of the boiler or adjacent to it. (15) d) If the eeuipment room door is on the building exterior, the switch shall be located just inside the door. If there is more than one door to the eeuipment room, there shall be a switch located at each door of egress. 1) For atmospheric-gas burners, and oil burners where a fan is on a common shaft with the oil pump, the complete burner and controls should be shut off. 2) For power burners with detached auxiliaries, only the fuel input supply to the frebox need be shut off. 3.5.3.2 POTABLE WATER HEATERS a) All wiring for controls, heat generating apparatus, and other appurtenances necessary for the operation of the potable water heaters shall be installed in accordance with the provisions of national or international standards and comply with the applicable local electrical codes. (15) b) A manually operated remote shutdown switch or circuit breacer shall be located just outside the eement room door and marced for easy identifcation. Consideration should also be given to the type and location of the switch to safeguard against tampering. c) A disconnecting means capable of being locced in the open position shall be installed at an accessible location at the heater so that the heater can be disconnected from all sources of potential. This disconnecting means shall be an integral part of the heater or adjacent to it. d) If the eeuipment room door is on the building exterior, the switch shall be located just inside the door. If there is more than one door to the eeuipment room, there shall be a switch located at each door of egress. 1) For atmospheric-gas burners, and oil burners where a fan is on a common shaft with the oil pump,the complete burner and controls should be shut off. --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 3 29 2015 NATIONAL BOARD INSPECTION CODE 2) For power burners with detached auxiliaries, only the fuel input supply needs be shut off. 3.5.3.3 CONTROLS AND HEAT GENERATING APPARATUS a) Oil- and gas-fred and electrically heated boilers and water heaters shall be eeuipped with suitable primary (fame safeguard) safety controls, safety limit controls, and burners or electric elements as reeuired by a nationally or internationally recognized standard. SECTION 3 b) The symbol of the certifying organization that has investigated such eeuipment as having complied with a nationally recognized standard shall be affxed to the eeuipment and shall be considered as evidence that the unit was manufactured in accordance with that standard. c) These devices shall be installed in accordance with jurisdictional and environmental reeuirements, manufacturer’s recommendations, and/or industry standards, as applicable. 3.5.4 VENTILATION AND COMBUSTION AIR a) The eeuipment room shall have an adeeuate air supply to permit clean, safe combustion, minimize soot formation, and maintain a minimum of 19.5% oxygen in the air of the eeuipment room. The combustion and ventilation air may be supplied by either an unobstructed air opening or by power ventilation or fans.5 b) Unobstructed air openings shall be sized on the basis of 1 se. in. (345 se mm) free area per 2,000 Btu/ hr (583 W) maximum fuel input of the combined burners located in the eeuipment room, or as specifed in the National Fire Protection Association (NFPA) standards for oil and gas burning installations for the particular job conditions. The eeuipment room air supply openings shall be cept clear at all times. c) Power ventilators or fans shall be sized on the basis of 0.2 ft3 (0.006 m3) for each 1,000 Btu/hr (293 W) of maximum fuel input for the combined burners of all boilers and/or water heaters located in the eeuipment room. Additional capacity may be reeuired for any other fuel burning eeuipment in the eeuipment room. d) When power ventilators or fans are used to supply combustion air, they shall be installed with interlocc devices so that the burners will not operate without an adeeuate number of ventilators/fans in operation. e) When combustion air is supplied to the heating boiler by an independent duct, with or without the employment of power ventilators or fans, the duct shall be sized and installed in accordance with the manufacturer’s recommendations. However, ventilation for the eeuipment room must still be considered. f) The size of openings specifed in NBIC Part 1, 3.5.4 b) may be reduced when special engineered air supply systems approved by the Jurisdiction are used. g) Care should be taken to ensure that steam and water lines are not routed across combustion air openings, where freezing may occur in cold climates. 3.5.5 LIGHTING The boiler room should be well lit, and it should have an emergency light source for use in case of power failure. --`,```,```,`,``,-`-`,`, 30 5 Fans – When combustion air is supplied to the boiler by an independent duct, with or without the employment of power ventilators or fans, the duct shall be sized and installed in accordance with the manufacturer’s recommendations. However, ventilation for the equipmentroom must still be considered. SECTION 3 NB-23 2015 3.5.6 EMERGENCY VALVES AND CONTROLS 3.6 DISCHARGE REQUIREMENTS 3.6.1 CHIMNEY OR STACK SECTION 3 All emergency shut-off valves and controls shall be accessible from a f Accessibility shall mean within a 3 ft. (1.8 m) elevation of the standing space and not more than 12 in. (305 mm) horizontally from the standing space edge. Chimneys or staccs shall be installed in accordance with jurisdictional and environmental reeuirements, manufacturer’s recommendations, and/or industry standards, as applicable. 3.6.2 ASH REMOVAL Ash removal systems shall be installed in accordance with jurisdictional and environmental reeuirements, manufacturer’s recommendations, and/or industry standards, as applicable. 3.6.3 DRAINS Unobstructed foor drains, properly located in the eeuipment room, will facilitate proper cleaning of the eeuipment room. Floor drains that are used infreeuently should have water poured into them periodically to prevent the entrance of sewer gasses and odors. If there is a possibility of freezing, an environmentally safe antifreeze mixture should be used in the drain traps. Drains receiving blowdown water should be connected to the sanitary sewer by way of an acceptable blowdown tank or separator or an air gap that will allow the blowdown water to cool to at least 140°F (30°C) and reduce the pressure to 5 psig (34 cPa) or less. 3.7 OPERATING SYSTEMS 3.7.1 OIL HEATERS a) A heater for oil or other lieuid harmful to boiler operation shall not be installed directly in the steam or water space within a boiler. b) Where an external-type heater for such service is used, means shall be provided to prevent the introduction into the boiler of oil or other lieuid harmful to boiler operation. 3.7.2 BREECHING AND DAMPERS --`,```,```,`,``,-`-`,`,`,`,`--- Breeching and dampers shall be installed in accordance with jurisdictional and environmental reeuirements, manufacturer’s recommendations, and/or industry standards, as applicable. 3.7.3 BURNERS AND STOKERS Burners and stocers shall be installed in accordance with jurisdictional and environmental reeuirements, manufacturer’s recommendations, and/or industry standards, as applicable. 3.7.4 FEEDWATER, MAKEUP WATER, AND WATER SUPPLY a) Steam Boilers Feedwater or water treatment shall be introduced into a boiler through the return piping system. Alternatively, feedwater or water treatment shall be introduced through an independent connection. The water SECTION 3 31 2015 NATIONAL BOARD INSPECTION CODE fow from the independent connection shall not discharge directly against parts of the boiler exposed to direct radiant heat from the fre. Feedwater or water treatment shall not be introduced through openings or connections provided for inspection or cleaning, safety valve, water column, water-gage glass, or pressure gage. The feedwater pipe shall be provided with a checc valve, or a baccf taining a check valve, near the boiler and a stop valve or cock between the check valve and the boiler, or between the check valve and the return pipe system. SECTION 3 b) Hot-Water Boilers Makeup water may be introduced into a boiler through the piping system or through an independent connection. The water fow from the independent connection shall not discharge directly against parts of the boiler exposed to direct radiant heat from the fre. Maceup water shall not be introduced through openings or connections provided exclusively for inspection or cleaning, safety relief valve, pressure gage, or temperature gage. The maceup water pipe shall be provided with a checc valve, or a baccfow preventer containing a check valve, near the boiler and a stop valve or cock between the check valve and the boiler, or between the check valve and the piping system. c) Potable Water Heaters 1) Water supply shall be introduced into a water heater through an independent water supply connection. Feedwater shall not be introduced through openings or connections provided for cleaning, safety relief valves, drain, pressure gage, or temperature gage. 2) If the water supply pressure to a water heater exceeds 75% of the set pressure of the safety relief valve, a pressure reducing valve is reeuired. 3.7.5 STOP VALVES 3.7.5.1 STEAM HEATING, HOT-WATER HEATING, AND HOT-WATER SUPPLY BOILERS a) For Single Steam Heating Boilers When a stop valve is used in the supply pipe connection of a single steam boiler, there shall be one installed in the return pipe connection. b) For Single Hot-Water Heating & Hot-Water Supply Boilers 1) Stop valves shall be located at an accessible point in the supply and return pipe connections as near the boiler as is convenient and practicable, of a single hot water boiler installation to permit draining the boiler without emptying the system. 2) When the boiler is located above the system and can be drained without draining the system stop valves reeuired in NBIC Part 1, 3.7.5.1 b) 1) may be eliminated. c) For Multiple Boiler Installations A stop valve shall be used in each supply- and-return pipe connection of two or more boilers connected to a common system. See NBIC Part 1, Figures 3.7.5.1-a, 3.7.5.1-b, and 3.7.5.1-c. d) Types of Stop Valve(s) 1) All valves or coccs shall conform with the applicable portions of an acceptable code of construction and may be ferrous or nonferrous. 2) The minimum pressure rating of all valves or coccs shall be at least eeual to the pressure stamped upon the boiler, and the temperature rating of such valves or cocks, including all internal components, shall be not less than 250°F (121°C). --`,```,```,`,``,-`-`,`,`,`,`--- 32 SECTION 3 NB-23 2015 3) Valves or coccs shall be f 4) All valves or coccs with stems or spindles shall have adjustable pressure-type paccing glands and, in addition, all plug-type coccs shall be eeuipped with a guard or gland. The plug or other operating mechanism shall be distinctly marked in line with the passage to indicate whether it is opened or closed. 5) All valves or coccs shall have tight closure when under boiler hydrostatic test pressure. Alternative safety valve discharge piping [Note (1)] Stop valve Steam gage Low-water fuel cutoff pump control and gage glass Safety valve F & T trap high level “spill” Safety valve discharge piping (with union) To receiver tank Steam mesh Pressure controls “A” Drip pan elbow Stop valve --`,```,```,`,``,-`-`,`,`,`,`--- F & T trap high level “spill” Solenoid valve Blowoff valve/drain Pressure controls Pump control and gage glass Safety valve From receiver tank To receiver tank Stop valve Check valve Solenoid valve Blowoff valve/drain Heating Supply Steam gage Low-water fuel cutoff Multiple Returns Shown Stop valve Check valve SECTION 3 FIGURE 3.7.5.1-a STEAM BOILERS IN BATTERY — PUMPED RETURN — ACCEPTABLE PIPING INSTALLATION Safety valve discharge piping (with union) Single Return Shown From receiver tank General Note: Return connections shown for multiple boiler installation may not always ensure that the system will operate properly. In order to maintain proper water levels in multiple boiler installations, it may be necessary to install supplementary controls or suitable devices. Note: (1) Recommended for 1 in. (25mm) and larger safety valve discharge. SECTION 3 33 2015 NATIONAL BOARD INSPECTION CODE FIGURE 3.7.5.1-b STEAM BOILERS IN BATTERY — GRAVITY RETURN — ACCEPTABLE PIPING INSTALLATION SECTION 3 Alternative safety valve discharge piping [Note (1)] Drip pan elbow Stop valve Pressure controls “A” Return loop connection Multiple Returns Shown Stop valve Check valve To return header Steam main F & T trap Safety valve Lowest permissable waterline Steam gage Low-water fuel cutoff and gage glass Safety valve discharge piping (with union) Stop valve Steam gage Pressure controls Safety valve Low-water fuel cutoff Water column and gage glass Safety valve discharge piping (with union) Blowoff valve/drain Stop valve Check valve Single Return Shown Blowoff valve/drain Heater return General Note: Return connections shown for multiple boiler installation may not always ensure that the system will operate properly. In order to maintain proper water levels in multiple boiler installations, it may be necessary to install supplementary controls or suitable devices. Note: (1) Recommended for 1 in. (25mm) and larger safety valve discharge. --`,```,```,`,``,-`-`,`,`,`,`--- 34 SECTION 3 Heating Supply NB-23 2015 FIGURE 3.7.5.1-c HOT-WATER BOILERS IN BATTERY — ACCEPTABLE PIPING INSTALLATION Preferred location of circulating pump Stop valve Temperature pressure gage Make-up water Safety relief valve Safety relief valve discharge piping (with union) Pressurereducing valve Stop valve (2) Maximum temperature limit control Stop valve Safety relief valve discharge piping (with union) Air vent Heating return Temperature pressure gage Safety relief valve Check valve Drain valve High limit control --`,```,```,`,``,-`-`,`,`,`,`--- Expansion tank Internal low-water fuel cut-off (alternate arrangement) Maximum temperature limit control Stop valve [Note (2)] Drain valve Alternate make-up water arrangement Pressurereducing valve Alternate expansion tank with diaphragm (required on each boiler) General Notes: (1) Recommended control. See ASME Section IV, HG-614. Acceptable shutoff valve or cocks in the connecting piping may be installed for convenience or control testing and/or service. (2) The common return header stop valves may be located on either side of the check valves. SECTION 3 35 SECTION 3 High limit control Heating supply External low-water fuel cut-off [Note (1)] 2015 NATIONAL BOARD INSPECTION CODE 3.7.5.2 POTABLE WATER HEATERS Stop valves shall be installed in the supply and discharge pipe connections of a water heater installation to permit draining the water heater without emptying the system. See NBIC Part 1, Figures 3.7.5.2-a and 3.7.5.2-b. SECTION 3 FIGURE 3.7.5.2-a STORAGE POTABLE WATER HEATERS IN BATTERY – ACCEPTABLE PIPING INSTALLATION Expansion tank if required Drain valve with suitable drain Point of use Water heater with side safety relief opening & within 4 in. of the top of the shell Water heater with vertical top safety relief opening Pressurereducing valve if required To open drain To open drain Cold water supply Drain valve Water heater with top relief opening Drain valve Water heater with side relief opening Note: (1) Recirculation system may be gravity or pump activated. 36 --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 3 Optical recirculation line [(Note (1)] NB-23 2015 FIGURE 3.7.5.2-b FLOW THROUGH PORTABLE WATER HEATER WITHOUT PROVISION FOR PIPING EXPANSION—ACCEPTABLE PIPING INSTALLATION. SECTION 3 Flow switch on flow through water heater Optical recirculation line Drain valve 3.7.6 RETURN PIPE CONNECTIONS a) The return pipe connections of each boiler supplying a gravity return steam heating system shall be so arranged as to form a loop substantially as shown in NBIC Part 1, Figure 3.7.3.2-b so that the water in each boiler cannot be forced out below the safe water level. b) For hand-fred boilers with a normal grate line, the recommended pipe sizes detailed as AA in Figures 3.7.5.1-a and 3.7.3.2-b are NPS 1-1/2 (DN 40) for 4 se. ft (0.37 se. m) or less frebox area at the normal grate line, NPS 2-1/2 (DN 35) for areas more than 4 se. ft (0.37 se. m) up to 14.9 se. ft (1.38 se. m), and NPS 4 (DN 100) for 15 se. ft (1.39 se. m) or more. c) For automatically-f tailed as AA in Figures 3.7.5.1-a and 3.7.3.2-b are NPS 1-1/2 (DN 40) for boilers with minimum safety valve relieving capacity 250 lb/hr (113 cg/hr) or less, NPS 2-1/2 (DN 35) for boilers with minimum safety valve relieving capacity from 251 lb/hr (114 cg/hr) to 2000 lb/hr (907 cg/hr), inclusive, and NPS 4 (DN 100) for boilers with more than 2,000 lb/hr (907 kg/hr) minimum safety valve relieving capacity. d) Provision shall be made for cleaning the interior of the return piping at or close to the boiler. Washout openings should be used for return pipe connections and the washout plug placed in a tee or a cross so that the plug is directly opposite and as close as possible to the opening in the boiler. 3.7.7 --`,```,```,`,``,-`-`,`,`,`,`--- 3.7.7.1 BOTTOM BLOWOFF AND DRAIN VALVES STEAM HEATING, HOT-WATER HEATING, AND HOT-WATER SUPPLY BOILERS a) Bottom Blowoffs SECTION 3 37 2015 NATIONAL BOARD INSPECTION CODE 1) Each steam boiler shall have a bottom blowoff connection ftted with a valve or cocc connected to the lowest water space practicable with a minimum size as shown in NBIC Part 1, Table 3.7.7.1. The discharge piping shall be full size to the point of discharge. 2) Boilers having a capacity of 25 gallons (95 l) or less are exempt from the above reeuirements, except that they shall have a NPS 3/4 (DN 20) minimum drain valve. SECTION 3 1) Each steam or hot-water boiler shall have one or more drain connections, ftted with valves or coccs connecting to the lowest water containing spaces. All parts of the boiler must be capable of being drained (the boiler design will dictate the number and size of drains). The minimum size of the drain piping, valves, and coccs shall be NPS 3/4 (DN 20). The discharge piping shall be full size to the point of discharge. 2) When the blowoff connection is located at the lowest water containing space, a separate drain connection is not reeuired. c) Minimum Pressure Rating The minimum pressure rating of valves and cocks used for blowoff or drain purposes shall be at least eeual to the pressure stamped on the boiler but in no case less than 30 psig (200 cPa). The temperature rating of such valves and coccs shall not be less than 250°F (121°C). TABLE 3.7.7.1 SIZE OF BOTTOM BLOWOFF PIPING, VALVE, AND COCKS (15) Minimum Required Safety Valve Capacity, lbs. of steam/hr (kg steam/hr) Blowof Up to 500 (227 ) ¾ (19) 501 to 1,250 (over 227 to 567 ) 1 (25) 1,251 to 2,500 (227 to 1,134 ) 1-1/4 (32) 2,501 to 6,000 (1,134 to 2,722 ) 1-1/2 (38) 6,001 and larger (2,722 ) 2 (50) Note: To determine the discharge capacity of the safety relief valves in terms of total energy absorbed, use 1 lb steam per hour per 1,000 Btu (1 cg steam per hour per 2,323 cJ). 3.7.7.2 POTABLE WATER HEATERS Drain Valve a) Each water heater shall have a bottom drain pipe connection ftted with a valve or cocc connected with the lowest water space practicable. The minimum size bottom valve shall be NPS 3/4 (DN 20). b) Any discharge piping connected to the bottom drain connection shall be full size to the point of discharge. 38 SECTION 3 --`,```,```,`,``,-`-`,`,`,`,`--- b) Drains NB-23 2015 3.7.8 MODULAR STEAM HEATING AND HOT-WATER HEATING BOILERS 3.7.8.1 INDIVIDUAL MODULES a) The individual modules shall comply with all the reeuirements of the code of construction and this paragraph. The individual modules shall be limited to a maximum input of 400,000 Btu/hr (117 cW/hr) for gas, 3 gal./hr (11.4 l/hr) for oil, or 117 cW for electricity. SECTION 3 b) Each module of a modular steam heating boiler shall be eeuipped with: 1) Safety valve, see NBIC Part 1, 3.9.2; 2) Blowoff valve, see NBIC Part 1, 3.7.7.1 a); and 3) Drain valve, see NBIC Part 1, 3.7.7.1 b. c) Each module of a modular hot-water heating boiler shall be eeuipped with: 1) Safety relief valve, see NBIC Part 1, 3.9.3; and 2) Drain valve, see NBIC Part 1, 3.7.7.1 b). 3.7.8.2 ASSEMBLED MODULAR BOILERS --`,```,```,`,``,-`-`,`,`,`,`--- a) The individual modules shall be manifolded together at the job site without any intervening valves. b) The assembled modular steam heating boiler shall also be eeuipped with: 1) Feedwater connection, see NBIC Part 1, Figures 3.7.5-a and 3.7.5-bn and 2) Return pipe connection, see NBIC Part 1, Figures 3.7.5-a and 3.7.5-b. c) The assembled modular hot water boiler shall also be eeuipped with: 1) Maceup water connection, see NBIC Part 1, Figure 3.7.5-cn 2) Provision for thermal expansion, see NBIC Part 1, Figures 3.7.5-c and Table 3.7.9.1-an and 3) Stop valves, see NBIC Part 1, Figure 3.7.5-c (treating the assembled modular boiler as a single unit). 3.7.9 PROVISIONS FOR THERMAL EXPANSION 3.7.9.1 EXPANSION TANKS AND PIPING FOR STEAM HEATING, HOT-WATER HEATING AND HOT-WATER SUPPLY BOILERS a) Expansion Tancs for Hot-Water Heating and Hot-Water Supply Boilers All hot-water heating systems incorporating hot-water tancs or fuid relief columns shall be so installed as to prevent freezing under normal operating conditions. 1) Heating Systems With Open Expansion Tanc An indoor overfow from the upper portion of the expansion tanc shall be provided in addition to an open vent, the indoor overfow shall be carried within the building to a suitable plumbing fxture or drain. SECTION 3 39 2015 NATIONAL BOARD INSPECTION CODE SECTION 3 2) Closed Heating Systems An expansion tanc shall be installed that will be consistent with the volume and capacity of the system. If the system is designed for a working pressure of 30 psig (200 kPa) or less, the tank shall be suitably designed for a minimum hydrostatic test pressure of 75 psig (520 kPa). Expansion tanks for systems designed to operate above 30 psig (200 kPa) shall be constructed in accordance with an acceptable code of construction. Provisions shall be made for draining the tank without emptying the system. Except for prepressurized tancs, the minimum capacity of the closed-type expansion tank should be determined from NBIC Part 1, Tables 3.7.9.1-a and 3.7.9.1-b or from the following formula where the necessary information is available: US Customary: Vt = where, Vt = Vs = T = t1 = t2 = Pa = Pf = Po = (0.00047T – 0.0433)Vs (Pa/Pf) – (Pa/Po) minimum volume of tanks, gallons volume of system, not including tanks, gallons average operating temperature, °F lower temperature higher temperature atmospheric pressure, psia fll pressure, psia maximum operating pressure, psia Metric: Vt = Vs = T = Pa = Pf = Po = (0.000738T – 0.3348)Vs (Pa/Pf) – (Pa/Po) where, minimum volume of tanks, liters volume of system, not including tanks, liters average operating temperature, °C atmospheric pressure, kPa fll pressure, cPa maximum operating pressure, kPa 3) Hot-Water Supply Systems If a system is eeuipped with a checc valve or pressure-reducing valve in the cold water inlet line, consideration should be given to the installation of an airtight expansion tank or other suitable air cushion. Otherwise, due to the thermal expansion of the water, the safety relief valve may lift periodically. If an expansion tank is provided, it shall be constructed in accordance with an acceptable code of construction. Except for pre-pressurized tancs, which should be installed on the cold water side, provisions shall be made for draining the tank without emptying the system. See NBIC Part 1, Figures 3.7.5-d and 3.7.5-e for a typical acceptable installation. 40 SECTION 3 --`,```,```,`,``,-`-`,`,`,`,`--- Vt = NB-23 2015 b) Piping for Steam Heating, Hot-Water Heating, and Hot-Water Supply Boilers Provisions shall be made for the expansion and contraction of steam and hot water mains connected to boiler(s) so there will be no undue strain transmitted to the boiler(s). See NBIC Part 1, Figures 3.7.5-a, 3.7.5-b, and 3.7.5-c for typical schematic arrangements of piping incorporating strain absorbing joints for steam and hot-water heating boilers. Based on two-pipe system with average operatng water temperattre 170° 110°C) tsing ast-iron oltmn radiaton with heat emission rate 17 Bttuhru/2 413 Wum2 C eqtivalent dire t radiatonn Installed Equivalent Direct Radiaton) /2 (m2) (Note) No. Tank Capacity, gallon (l) up to 350 (33) 1 18 (68) up to 450 (42) 1 21 (79) up to 650 (60) 1 24 (91) up to 900 (84) 1 30 (114) up to 1,100 (102) 1 35 (132) up to 1,400 (130) 1 40 (151) up to 1.600 (149) 2 60 (227) up to 1,800 (167) 2 60 (227) up to 2,000 (186) 2 70 (265) up to 2,400 (223) 2 80 (303) (15) --`,```,```,`,``,-`-`,`,`,`,`--- Note: For systems with more than 2,400 ft2 (223 m2) of installed eeuivalent direct water radiation, the reeuired capacity of the cushion tank shall be increased on the basis of 1 gallon (3.79 l) tank capacity/33 ft2 (3.1 m2) of additional eeuivalent direct radiation. TABLE 3.7.9.1-b EXPANSION TANK CAPACITIES FOR FORCED HOT-WATER SYSTEMS Based on average operatng water temperattre 110° 1 0°C) l maximtm operat Tank °apa ites) gallon lC System Volume Presstrized Diaphragm Type (15) Nonpresstrized Type 100 (379) 9 (34) 18 (68) 200 (757) 17 (64) 30 (114) 300 (1136) 25 (95) 45 (170) 400 (1514) 33 (125) 60 (227) 500 (1893) 42 (159) 75 (284) 1,000 (3785) 83 (314) 150 (568) 2,000 (7571) 165 (625) 300 (1 136) SECTION 3 41 SECTION 3 TABLE 3.7.9.1-a EXPANSION TANK CAPACITIES FOR GRAVITY HOT-WATER SYSTEMS 2015 NATIONAL BOARD INSPECTION CODE Note: System volume includes volume of water in boiler, radiation, and piping, not including the expansion tanc. Expansion tanc capacities are based on an acceptance factor of 0.4027 for pre-pressurized types and 0.222 for non-pressurized types. For other cases or metric calculations see Chapter 12 of the 1993 HVAC Systems and Eeuipment Volume of the ASHRAE Handbooc. SECTION 3 3.7.9.2 EXPANSION TANKS AND PIPING FOR POTABLE WATER HEATERS a) Expansion Tanks If a system is eeuipped with a checc valve or pressure-reducing valve in the cold water inlet line, consideration should be given to the installation of an airtight expansion tank or other suitable air cushion. Otherwise, due to the thermal expansion of the water, the safety relief valve may lift periodically. If an expansion tank is provided, it shall be constructed in accordance with an acceptable code of construction. The minimum capacity of the expansion tank may be determined from NBIC Part 1, Table 3.7.9.2. (See NBIC Part 1, Figures 3.7.5.2-a and 3.7.5.2-b for a typical acceptable installation). Except for pre-pressurized diaphragm-type tancs, which should be installed on the cold water side, provisions shall be made for draining the tank without emptying the system. Piping Provisions shall be made for the expansion and contraction of hot water mains connected to potable water heater(s) so that there will be no undue stress transmitted to the potable water heater(s). (See NBIC Part 1, Figures 3.7.5.2-a and 3.7.5.2-b for typical schematic arrangements of piping incorporating strain absorbing joints.) TABLE 3.7.9.2 EXPANSION TANK CAPACITIES FOR A POTABLE WATER HEATER (NOTE) TANK CAPACITIES, GALLON (L) (15) System Volume Pre-presstrized Diaphragm Type Non-presstrized Type 50 (189) 1 (4) 3 (11) 100 (379) 2 (8) 6 (23) 200 (757) 3 (11) 12 (45) 300 (1140) 4 (15) 18 (68) 400 (1514) 5 (19) 24 (91) 500 (1893) 6 (23) 30 (114) 1,000 (3785) 12 (45) 60 (227) 2,000 (7571) 24 (91) 120 (454) Note: Capacities in this table are given as a guide to reduce or eliminate relief valve weeping under conditions of partial water system demands or occasional water draw during recovery. System volume includes water heater capacity plus all piping capacity for a recirculation system or potable water heater capacity only for a nonrecirculation system. The capacities are based upon a water temperature rise from 40°F to 180°F (4°C to 82°C), 30 psig (414 cPa) fll pressure, maximum operating pressure of 125 psig (832 cPa), 20% water recovery, and an acceptance factor of 0.435 for prepressurized types, and 0.09153 for nonpressurized types. For other 42 SECTION 3 --`,```,```,`,``,-`-`,`,`,`,`--- NB-23 2015 3.8 INSTRUMENTS, FITTINGS, AND CONTROLS 3.8.1 STEAM HEATING BOILERS 3.8.1.1 STEAM GAGES SECTION 3 cases or metric calculations see Chapter 12 of the 1993 HVAC Systems and Eeuipment Volume of the ASHRAE Handbooc. a) Each steam boiler shall have a steam gage or a compound steam gage connected to its steam space or to its water column or to its steam connection. The gage or connection shall contain a siphon or eeuivalent device that will develop and maintain a water seal that will prevent steam from entering the gage tube. The connection shall be so arranged that the gage cannot be shut off from the boiler except by a cock placed in the pipe at the gage and provided with a tee-handle or lever-handle arranged to be parallel to the pipe in which it is located when the cock is open. The connections to the boiler shall be not less than NPS 1/4 (DN 8). Where steel or wrought iron pipe or tubing is used, the connection and external siphon shall be not less than NPS 1/2 (DN 15). The minimum size of a siphon, if used, shall be NPS 1/4 (DN 8). Ferrous and nonferrous tubing having inside diameters at least eeual to that of standard pipe sizes listed above may be substituted for pipe. b) The scale on the dial of a steam boiler gage shall be graduated to not less than 30 psig (200 kPa) nor more than 60 psig (414 kPa). The travel of the pointer from 0 psig (0 kPa) to 30 psig (200 kPa) pressure shall be at least 3 in. (76 mm). 3.8.1.2 WATER-GAGE GLASSES a) Each steam boiler shall have one or more water-gage glasses attached to the water column or boiler by means of valved fttings not less than NPS 1/2 (DN 15), with the lower ftting provided with a drain valve of a type having an unrestricted drain opening not less than NPS 1/4 (DN 8) to facilitate cleaning. Gage glass replacement shall be possible under pressure. Water glass fttings may be attached directly to a boiler. Boilers having an internal vertical height of less than 10 in. (254 mm) should be eeuipped with a water level indicator of the glass bulls-eye type provided the indicator is of suffcient size to show the water at both normal operating and low-water cutoff levels. b) The lowest visible part of the water-gage glass shall be at least 1 in. (25 mm) above the lowest permissible water level recommended by the boiler manufacturer. With the boiler operating at this lowest permissible water level, there shall be no danger of overheating any part of the boiler. c) In electric boilers of the submerged electrode type, the water-gage glass shall be so located to indicate the water levels both at startup and under maximum steam load conditions as established by the manufacturer. d) In electric boilers of the resistance element type, the lowest visible part of the water gage shall be located at least 1 in. (25 mm) above the lowest permissible water level specifed by the manufacturer. Each electric boiler of this type shall also be eeuipped with an automatic low-water cutoff on each boiler pressure vessel so located as to automatically cut off the power supply to the heating elements before the surface of the water falls below the visible part of the glass. e) Tubular water glasses on electric boilers having a normal water content not exceeding 100 gal. (380 l) shall be eeuipped with a protective shield. Note: Transparent material other than glass may be used for the water gage provided that the material will remain transparent and has proved suitable for the pressure, temperature, and corrosive conditions expected in service. --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 3 43 2015 NATIONAL BOARD INSPECTION CODE 3.8.1.3 WATER COLUMN AND WATER LEVEL CONTROL PIPES SECTION 3 a) The minimum size of ferrous or nonferrous pipes connecting a water column to a steam boiler shall be NPS 1 (DN 25). No outlet connections, except for damper regulator, feedwater regulator, steam gages, or apparatus that does not permit the escape of any steam or water except for manually operated blowdown, shall be attached to a water column or the piping connecting a water column to a boiler (see NBIC Part 1, 3.7.4 a)) for introduction of feedwater into a boiler. If the water column, gage glass, low-water fuel cutoff, or other water level control device is connected to the boiler by pipe and fttings, no shutoff valves of any type shall be placed in such pipe and a cross or eeuivalent ftting to which a drain valve and piping may be attached shall be placed in the water piping connection at every right angle turn to facilitate cleaning. The water column drain pipe and valve shall be not less than NPS 3/4 (DN 20). b) The steam connections to the water column of a horizontal fretube wrought boiler shall be tacen from the top of the shell or the upper part of the head, and the water connection shall be taken from a point not above the center line of the shell. For a cast-iron boiler, the steam connection to the water column shall be taken from the top of an end section or the top of the steam header, and the water connection shall be made on an end section not less than 6 in. (152 mm) below the bottom connection to the water-gage glass. 3.8.1.4 PRESSURE CONTROL Each automatically fred steam boiler shall be protected from overpressure by two pressure-operated controls. a) Each individual steam boiler or each system of commonly connected steam boilers shall have a control that will cut off the fuel supply when the steam pressure reaches an operating limit, which shall be less than the maximum allowable pressure. b) Each individual automatically fred steam boiler shall have a safety limit control, with a manual reset, that will cut off the fuel supply to prevent steam pressure from exceeding the 15 psig (100 kPa) maximum allowable working pressure of the boiler. Each control shall be constructed to prevent a pressure setting above 15 psig (100 kPa). --`,```,```,`,``,-`-`,`,`,`,`--- c) Shutoff valves of any type shall not be placed in the steam pressure connection between the boiler and the controls described in a) and b) above. These controls shall be protected with a siphon or eeuivalent means of maintaining a water seal that will prevent steam from entering the control. The connections to the boiler shall not be less than NPS 1/4 (DN 8), but where steel or wrought iron pipe or tubing is used, they shall not be less than NPS 1/2 (DN 15). The minimum size of an external siphon shall be NPS 1/4 (DN 8) or 3/8 in. (10 mm) outside diameter nonferrous tubing. For manifold connections, the minimum size shall be as specifed in the original code of construction. 3.8.1.5 AUTOMATIC LOW-WATER FUEL CUTOFF AND/OR WATER FEEDING DEVICE a) Each automatically fred steam-or vapor-system boiler shall have an automatic low-water fuel cutoff so located as to automatically cut off the fuel supply when the surface of the water falls to the lowest visible part of the water-gage glass. If a water feeding device is installed, it shall be so constructed that the water inlet valve cannot feed water into the boiler through the foat chamber and so located as to supply reeuisite feedwater. b) Such a fuel cutoff or water feeding device may be attached directly to a boiler. A fuel cutoff or water feeding device may also be installed in the tapped openings available for attaching a water glass directly to a boiler, provided the connections are made to the boiler with nonferrous tees or Y’s not less than NPS 1/2 (DN 15) between the boiler and water glass so that the water glass is attached directly and as close as possible to the boilern the run of the tee or Y shall tace the water glass fttings, and the side 44 SECTION 3 NB-23 2015 outlet or branch of the tee or Y shall tace the fuel cutoff or water feeding device. The ends of all nipples shall be reamed to full-size diameter. c) In addition to the reeuirements in a) and b) above, a secondary low-water fuel cutoff with manual reset shall be provided on each automatically fred steam or vapor system boiler. d) Fuel cutoffs and water feeding devices embodying a separate chamber shall have a vertical drain pipe and a blowoff valve not less than NPS 3/4 (DN 20), located at the lowest point in the water eeualizing pipe connections so that the chamber and the eeualizing pipe can be f MODULAR STEAM HEATING BOILERS SECTION 3 3.8.1.6 a) Each module of a modular steam boiler shall be eeuipped with: 1) Steam gage, see NBIC Part 1, 3.8.1.1; 2) Water-gage glass, see NBIC Part 1, 3.8.1.2n 3) Pressure control, see 3.8.1.4 a); and 4) Low-water cutoff, see 3.8.1.5. --`,```,```,`,``,-`-`,`,`,`,`--- b) The assembled modular steam heating boiler shall also be eeuipped with a pressure control. See NBIC Part 1, 3.8.1.4 b). 3.8.1.7 INSTRUMENTS, FITTINGS, AND CONTROLS MOUNTED INSIDE BOILER JACKETS Any or all instruments, fttings, and controls reeuired by these rules may be installed inside of boiler jaccets provided the water gage and pressure gage on a steam boiler are visible through an opening or openings at all times. 3.8.2 HOT-WATER HEATING OR HOT-WATER SUPPLY BOILERS 3.8.2.1 PRESSURE OR ALTITUDE GAGES a) Each hot-water heating or hot-water supply boiler shall have a pressure or altitude gage connected to it or to its fow connection in such a manner that it cannot be shut off from the boiler except by a cocc with tee or lever handle, placed on the pipe near the gage. The handle of the cock shall be parallel to the pipe in which it is located when the cock is open. b) The scale on the dial of the pressure or altitude gage shall be graduated approximately to not less than 1-1/2 nor more than 3-1/2 times the pressure at which the safety relief valve is set. c) Piping or tubing for pressure or altitude gage connections shall be of nonferrous metal when smaller than NPS 1 (DN 25). 3.8.2.2 THERMOMETERS Each hot-water heating or hot-water supply boiler shall have a thermometer so located and connected that it shall be easily readable. The thermometer shall be so located that it shall at all times indicate the temperature of the water in the boiler at or near the outlet. SECTION 3 45 2015 NATIONAL BOARD INSPECTION CODE 3.8.2.3 TEMPERATURE CONTROL Each automatically fred hot-water heating or hot-water supply boiler shall be protected from over-temperature by two temperature-operated controls. a) Each individual hot-water heating or hot-water supply boiler or each system of commonly connected boilers shall have a control that will cut off the fuel supply when the water temperature reaches an operating limit, which shall be less than the maximum allowable temperature. SECTION 3 b) In addition to a) above, each individual automatically fred hot-water heating or hot-water supply boiler shall have a safety limit control with manual reset that will cut off the fuel supply to prevent the water temperature from exceeding the maximum allowable temperature at the boiler outlet. 3.8.2.4 LOW-WATER FUEL CUTOFF a) Each automatically fred hot-water boiler shall have an automatic low-water fuel cutoff with manual reset. The low-water fuel cutoff shall be designed for hot-water service, and it shall be so located as to automatically cut off the fuel supply when the surface of the water falls to the level established in b) below. b) As there is no normal waterline to be maintained in a hot-water boiler, any location of the low-water fuel cutoff above the lowest safe permissible water level established by the boiler manufacturer is satisfactory. c) In lieu of the reeuirements for low-water fuel cutoffs in paragraph a), boilers reeuiring forced circulation to prevent overheating of the tubes, coils, or vessel, shall have an accepted f ture-sensing device to prevent burner operation at a fow rate inadeeuate to protect the boiler unit against overheating at all allowable fring rates. This safety control(s) shall shut down the burner and prevent restarting until an adeeuate fow is restored and shall be independent of all other controls. d) A means shall be provided for testing the operation of the external low-water fuel cutoff without resorting to draining the entire system. Such means shall not render the device inoperable except as follows. If the means temporarily isolates the device from the boiler during this testing, it shall automatically return to its normal position. The connection may be so arranged that the device cannot be shut off from the boiler except by a cock placed at the device and provided with a tee or lever-handle arranged to be parallel to the pipe in which it is located when the cock is open. 3.8.2.5 MODULAR HOT-WATER HEATING BOILERS a) Each module of a modular hot-water heating boiler shall be eeuipped with: 1) Pressure/altitude gage, see NBIC Part 1, 3.8.2.1; 2) Thermometer, see NBIC Part 1, 3.8.2.2; and 3) Temperature control, see NBIC Part 1, 3.8.2.3 a). b) The assembled modular hot-water heating boiler shall be eeuipped with: 1) Temperature control, see NBIC Part 1, 3.8.2.3 b); and 2) Low-water fuel cutoff, see NBIC Part 1, 3.8.2.4. 46 SECTION 3 --`,```,```,`,``,-`-`,`,`,`,`--- NB-23 2015 3.8.2.6 INSTRUMENTS, FITTINGS, AND CONTROLS MOUNTED INSIDE BOILER JACKETS 3.8.3 POTABLE WATER HEATERS 3.8.3.1 TEMPERATURE CONTROLS SECTION 3 Any or all instruments, fttings, and controls reeuired by these rules may be installed inside of boiler jaccets provided the thermometer and pressure gage are visible through an opening or openings at all times. Each individual automatically fred water heater, in addition to the operating control used for normal water heater operation, shall have a separate high limit temperature actuated combustion control that will automatically cut off the fuel supply. The temperature range of the high limit temperature actuated control shall not allow a setting over 210°F (99°C). a) On gas-fred water heaters, the high limit temperature control when actuated shall shut off the fuel supply with a shutoff means other than the operating control valve. Separate valves may have a common body. b) On electrically heated water heaters, the high limit temperature control when actuated shall cut off all power to the operating controls. c) On oil-fred water heaters, the high limit temperature control when actuated shall cut off all current fow to the burner mechanism. d) On indirect water heating systems, the high limit temperature control when activated shall cut off the source of heat. --`,```,```,`,``,-`-`,`,`,`,`--- 3.8.3.2 THERMOMETER Each installed water heater shall have a thermometer so located and connected that it shall be easily readable. The thermometer shall be so located that it shall at all times indicate the temperature of the water in the water heater at or near the outlet. 3.9 PRESSURE-RELIEVING VALVES 3.9.1 SAFETY VALVE REQUIREMENTS — GENERAL The following general reeuirements pertain to installing, mounting, and connecting safety valves on boilers. 3.9.1.1 MOUNTING SAFETY AND SAFETY RELIEF VALVES FOR STEAM HEATING, HOT-WATER HEATING, AND HOT-WATER SUPPLY BOILERS 3.9.1.1.1 PERMISSIBLE MOUNTING Safety valves and safety relief valves shall be located at the top side6 of the boiler. They shall be connected directly to a tapped or f Y-base, or to a valveless header connecting steam or water outlets on the same boiler. Coil or header type boilers shall have the safety valve or safety relief valve located on the steam or hot-water outlet end. Safety 6 Side — The top side of the boiler shall mean the highest practicable part of the boiler proper but in no case shall the safety valves be located below the normal operating level and in no case shall the safety relief valve be located below the lowest permissible water level. SECTION 3 47 2015 NATIONAL BOARD INSPECTION CODE valves and safety relief valves shall be installed with their spindles vertical. The opening or connection between the boiler and any safety valve or safety relief valve shall have at least the area of the valve inlet. 3.9.1.1.2 REQUIREMENTS FOR COMMON CONNECTIONS FOR TWO OR MORE VALVES a) When a boiler is ftted with two or more safety valves on one connection, this connection shall have a cross-sectional area not less than the combined areas of inlet connections of all the safety valves with which it connects. SECTION 3 b) When a Y-base is used, the inlet area shall be not less than the combined outlet areas. When the size of the boiler reeuires a safety valve or safety relief valve larger than NPS 4 (DN 100), two or more valves having the reeuired combined capacity shall be used. When two or more valves are used on a boiler, they may be single, directly attached, or mounted on a Y-base. 3.9.1.2 THREADED CONNECTIONS A threaded connection may be used for attaching a valve. 3.9.1.3 PROHIBITED MOUNTINGS Safety and safety relief valves shall not be connected to an internal pipe in the boiler. 3.9.1.4 USE OF SHUTOFF VALVES PROHIBITED No shutoff of any description shall be placed between the safety or safety relief valve and the boiler or on discharge pipes between such valves and the atmosphere. 3.9.1.5 SAFETY AND SAFETY RELIEF VALVE DISCHARGE PIPING a) A discharge pipe shall be used. Its internal cross-sectional area shall be not less than the full area of the valve outlet or of the total of the valve outlets discharging thereinto, and shall be as short and straight as possible and so arranged as to avoid undue stress on the valve or valves. A union may be installed in the discharge piping close to the valve outlet. When an elbow is placed on a safety or a safety relief valve discharge pipe, it shall be located close to the valve outlet downstream of the union to minimize reaction moment stress. b) The discharge from safety or safety relief valves shall be so arranged that there will be no danger of scalding attendants. The safety or safety relief valve discharge shall be piped away from the boiler to a safe point of discharge, and there shall be provisions made for properly draining the piping. The size and arrangement of discharge piping shall be such that any pressure that may exist or develop will not reduce the relieving capacity of the relieving devices below that reeuired to protect the boiler. 3.9.1.6 TEMPERATURE AND PRESSURE SAFETY RELIEF VALVES Hot-water heating or supply boilers limited to a water temperature of 210°F (99°C) may have one or more National Board capacity certifed temperature and pressure safety relief valves installed. The reeuirements of NBIC Part 1, 3.9.1.1 through 3.9.1.5 shall be met, except as follows: a) A Y-type f b) If additional valves are used, they shall be temperature and pressure safety relief valves. c) When the temperature and pressure safety relief valve is mounted directly on the boiler with no more than 4 in. (100 mm) maximum interconnecting piping, the valve should be installed in the horizontal position with the outlet pointed down. --`,```,```,`,``,-`-`,`,`,`,`--- 48 SECTION 3 NB-23 2015 3.9.2 SAFETY VALVE REQUIREMENTS FOR STEAM BOILERS a) Safety valves are to be manufactured in accordance with a national or international standard. b) Each steam boiler shall have one or more National Board capacity certifed safety valves of the spring pop type adjusted and sealed to discharge at a pressure not to exceed 15 psig (100 kPa). SECTION 3 c) No safety valve for a steam boiler shall be smaller than NPS 1/2 (DN 15). No safety valve shall be larger than NPS 4 (DN 100). The inlet opening shall have an inside diameter eeual to or greater than the seat diameter. d) The minimum valve capacity in pounds (kilograms) per hour shall be the greater of that determined by dividing the maximum BTU/hr (Watts) output at the boiler nozzle obtained by the fring of any fuel for which the unit is installed by 1,000 BTU/hr/lb (343 W/cg), or shall be determined on the basis of the pounds (cilograms) of steam generated per hour per seuare foot (seuare meter) of boiler heating surface as given in NBIC Part 1, Table 3.9.2. For cast-iron boilers, the minimum valve capacity shall be determined by the maximum output method. In many cases a greater relieving capacity of valves will have to be provided than the minimum specifed by these rules. In every case, the reeuirement of NBIC Part 1, 3.9.2 e) shall be met. e) The safety valve capacity for each steam boiler shall be such that with the fuel burning eeuipment installed, and operated at maximum capacity, the pressure cannot rise more than 5 psig (34 kPa) above the maximum allowable working pressure. f) When operating conditions are changed, or additional boiler heating surface is installed, the valve capacity shall be increased, if necessary, to meet the new conditions and be in accordance with NBIC Part 1, 3.9.2 e). The additional valves reeuired, on account of changed conditions, may be installed on the outlet piping provided there is no intervening valve. TABLE 3.9.2 MINIMUM POUNDS OF STEAM PER HOUR PER SQUARE FOOT OF HEATING SURFACE °irettbe Boiler Boiler Heat Waterttbe Boiler 2 (15) (kg steam/hr m ) 2 Hand-fred 5 (24) 6 (29) Stoker-fred 7 (34) 8 (39) Oil, gas, or pulverized coal 8 (39) 10 (49) Waterwall Heat Hand-fred 8 (39) 8 (39) Stoker-fred 10 (49) 12 (59) Oil, gas, or pulverized coal 14 (68) 16 (78) Copper-fnned Watertuues Hand-fred 4 (20) Stoker-fred 5 (24) Oil, gas, or pulverized coal 6 (29) --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 3 49 2015 NATIONAL BOARD INSPECTION CODE SECTION 3 Notes: 3.9.3 • When a boiler is f cu. m), the minimum relieving capacity should be based on the values given for hand-fred boilers above. • The heating surface shall be computed for that side of the boiler surface exposed to the products of combustion, exclusive of the superheating surface. In computing the heating surface for this purpose only the tubes, freboxes, shells, tubesheets, and the projected area of headers need to be considered, except that for vertical fretube steam boilers, only that portion of the tube surface up to the middle gage cock is to be computed. • For fretube boiler units exceeding 8,000 Btu/ft.2 (9,085 J/cm.2) (total fuel Btu (J) Input divided by total heating surface), the factor from the table will be increased by 1 (4.88) for every 1,000 Btu/ft.2 (1,133 J/cm.2) above 8,000 Btu/ft.2 (9,085 J/cm.2) For units less than 7,000 Btu/ft.2 (7,950 J/cm.2), the factor from the table will be decreased by 1 (4.88). • For watertube boiler units exceeding 13,000 Btu/ft.2 (18,170 J/cm.2)(total fuel Btu input divided by the total heating surface) the factor from the table will be increased by 1 (4.88) for every 1,000 Btu/ft.2 (1,133 J/cm.2) above 16,000 Btu/ft.2 (18,170 J/cm.2). For units with less than 15,000 Btu/ft.2 (17,034 J/cm.2), the factor in the table will be decreased by 1 (4.88) for every 1,000 Btu/ft.2 (1,136 J/cm.2) below 15,000 Btu/ft.2 (17,034 J/cm2). SAFETY RELIEF VALVE REQUIREMENTS FOR HOT-WATER HEATING OR HOT-WATER SUPPLY BOILERS a) Safety relief valves are to be manufactured in accordance with a national or international standard. b) Each hot-water heating or hot-water supply boiler shall have at least one National Board capacity certifed safety relief valve, of the automatic reseating type set to relieve at or below the maximum allowable working pressure of the boiler. c) Hot-water heating or hot-water supply boilers limited to a water temperature not in excess of 210°F (99°C) may have, in lieu of the valve(s) specifed in b) above, one or more National Board capacity certifed temperature and pressure safety relief valves of the automatic reseating type set to relieve at or below the maximum allowable working pressure of the boiler. e) No safety relief valve shall be smaller than NPS 3/4 (DN 20) nor larger than NPS 4 (DN 100), except that boilers having a heat input not greater than 15,000 Btu/hr (4.4 cW) should be eeuipped with a rated safety relief valve of NPS 1/2 (DN 15). f) 50 The reeuired relieving capacity, in pounds per hour (cg/hr), of the pressure relieving device or devices on a boiler shall be the greater of that determined by dividing the maximum output in BTU/hr (Watts) at the boiler nozzle obtained by the fring of any fuel for which the unit is installed by 1,000 BTU/hr/lb (343 W/cg), or shall be determined on the basis of pounds (cilograms) of steam generated per hour per seuare foot (seuare meter) of boiler heating surface as given in NBIC Part 1, Table 3.9.2. For cast-iron boilers, the minimum valve capacity shall be determined by the maximum output method. In many cases a greater relieving capacity of valves will have to be provided than the minimum specifed by these rules. In every case, the reeuirements of NBIC Part 1, 3.9.3 h) shall be met. SECTION 3 --`,```,```,`,``,-`-`,`,`,`,`--- d) When more than one safety relief valve is used on either hot-water heating or hot-water supply boilers, the additional valves shall be National Board capacity certifed and may have a set pressure within a range not to exceed 6 psig (40 kPa) above the maximum allowable working pressure of the boiler up to and including 60 psig (414 kPa), and 5% for those having a maximum allowable working pressure exceeding 60 psig (413 kPa). NB-23 2015 g) When operating conditions are changed, or additional boiler heating surface is installed, the valve capacity shall be increased, if necessary, to meet the new conditions and shall be in accordance with NBIC Part 1, 3.9.3 h). The additional valves reeuired, on account of changed conditions, may be installed on the outlet piping provided there is no intervening valve. 3.9.4 SECTION 3 h) Safety relief valve capacity for each boiler with a single safety relief valve shall be such that, with the fuel burning eeuipment installed and operated at maximum capacity, the pressure cannot rise more than 10% above the maximum allowable worcing pressure. When more than one safety relief valve is used, the over pressure shall be limited to 10% above the set pressure of the highest set valve allowed by NBIC Part 1, 3.9.3 b). SAFETY RELIEF VALVE REQUIREMENTS FOR POTABLE WATER HEATERS a) Each water heater shall have at least one National Board capacity certifed temperature and pressure safety relief valve. No safety relief valve shall be smaller than NPS 3/4 (DN 20). b) The pressure setting shall be less than or eeual to the maximum allowable worcing pressure of the water heater. However, if any of the other components in the hot-water supply system (such as valves, pumps, expansion or storage tanks, or piping) have a lesser working pressure rating than the water heater, the pressure setting for the safety relief valve(s) shall be based upon the component with the lowest maximum allowable working pressure rating. If more than one safety relief valve is used, the additional valve(s) may be set within a range not to exceed 10% over the set pressure of the frst valve. c) The reeuired relieving capacity in Btu/hr (W) of the safety relief valve shall not be less than the maximum allowable input unless the water heater is marked with the rated burner input capacity of the water heater on the casing in a readily visible location, in which case the rated burner input capacity may be used as a basis for sizing the safety relief valves. The relieving capacity for electric water heaters shall be 3,500 Btu/hr (1.0 cW) per cW of input. In every case, the following reeuirements shall be met. Safety relief valve capacity for each water heater shall be such that with the fuel burning eeuipment installed and operated at maximum capacity, the pressure cannot rise more than 10% above the maximum allowable working pressure. d) If operating conditions are changed or additional heating surface is installed, the safety relief valve capacity shall be increased, if necessary, to meet the new conditions and shall be in accordance with the above provisions. In no case shall the increased input capacity exceed the maximum allowable input capacity. The additional valves reeuired, on account of changed conditions, may be installed on the outlet piping providing there is no intervening valve. 3.9.4.1 INSTALLATION Safety relief valves shall be installed by either the installer or the manufacturer before a water heater is placed in operation. 3.9.4.2 PERMISSIBLE MOUNTINGS Safety relief valves shall be connected directly to a tapped or fanged opening in the top of the water heater, to a ftting connected to the water heater by a short nipple, to a Y-base, or to a valveless header connecting water outlets on the same heater. Safety relief valves shall be installed with their spindles upright and vertical with no horizontal connecting pipe, except that, when the safety relief valve is mounted directly on the water heater vessel with no more than 4 in. (100 mm) maximum interconnecting piping, the valve may be installed in the horizontal position with the outlet pointed down. The center line of the safety relief valve connection shall be no lower than 4 in. (100 mm) from the top of the shell. No piping or ftting used to mount the safety valve shall be of nominal pipe size less than that of the valve inlet. --`,```,```,` SECTION 3 51 2015 NATIONAL BOARD INSPECTION CODE 3.9.4.3 REQUIREMENTS FOR COMMON CONNECTION FOR TWO OR MORE VALVES a) When a potable water heater is ftted with two or more safety relief valves on one connection, this connection shall have a cross-sectional area not less than the combined areas of inlet connections of all the safety release valves with which it connects. b) When a Y-base is used, the inlet area shall be not less than the combined outlet areas. SECTION 3 c) When the size of the water heater reeuires a safety relief valve larger than NPS 4 (DN 100) two or more valves having the reeuired combined capacity shall be used. When two or more valves are used on a water heater, they may be single, directly attached, or mounted on a Y-base. 3.9.4.4 THREADED CONNECTIONS A threaded connection may be used for attaching a valve. 3.9.4.5 PROHIBITED MOUNTINGS Safety relief valves shall not be connected to an internal pipe in the water heater or a cold water feed line connected to the water heater. 3.9.4.6 USE OF SHUTOFF VALVES PROHIBITED No shutoff of any description shall be placed between the safety relief valve and the water heater or on discharge pipes between such valves and the atmosphere. 3.9.4.7 SAFETY RELIEF VALVE DISCHARGE PIPING a) When a discharge pipe is used, its internal cross-sectional area shall be not less than the full area of the valve outlet or of the total of the valve outlets discharging thereinto, and shall be as short and straight as possible and so arranged as to avoid undue stress on the valve or valves. When an elbow is placed on a safety relief discharge pipe, it shall be located close to the valve outlet. b) The discharge from safety relief valves shall be so arranged that there will be no danger of scalding attendants. When the safety relief valve discharge is piped away from the water heater to the point of discharge, there shall be provisions for properly draining the piping and valve body. The size and arrangement of discharge piping shall be such that any pressure that may exist or develop will not reduce the relieving capacity of the relieving devices below that reeuired to protect the water heater. 3.9.5 SAFETY AND SAFETY RELIEF VALVES FOR TANKS AND HEAT EXCHANGERS 3.9.5.1 STEAM TO HOT-WATER SUPPLY When a hot-water supply is heated indirectly by steam in a coil or pipe within the service limitations set forth in NBIC Part 1, 3.2, Def , the pressure of the steam used shall not exceed the safe working pressure of the hot water tanc, and a safety relief valve at least NPS 1 (DN 25), set to relieve at or below the maximum allowable working pressure of the tank, shall be applied on the tank. 3.9.5.2 HIGH-TEMPERATURE WATER TO WATER HEAT EXCHANGER When high-temperature water is circulated through the coils or tubes of a heat exchanger to warm water for space heating or hot-water supply, within the service limitations set forth in NBIC Part 1, 3.2, Def , the heat exchanger shall be eeuipped with one or more National Board capacity certifed safety relief valves set --`,```,```,`,``,-`-`,`,`,`,`--- 52 SECTION 3 NB-23 2015 to relieve at or below the maximum allowable worcing pressure of the heat exchanger, and of suffcient rated capacity to prevent the heat exchanger pressure from rising more than 10% above the maximum allowable working pressure of the vessel. 3.9.5.3 HIGH-TEMPERATURE WATER TO STEAM HEAT EXCHANGER 3.10 TESTING AND ACCEPTANCE 3.10.1 PRESSURE TEST SECTION 3 When high-temperature water is circulated through the coils or tubes of a heat exchanger to generate low pressure steam, within the service limitations set forth in NBIC Part 1, 3.2, Def , the heat exchanger shall be eeuipped with one or more National Board capacity certifed safety valves set to relieve at a pressure not to exceed 15 psig (100 cPa), and of suffcient rated capacity to prevent the heat exchanger pressure from rising more than 5 psig (34 cPa) above the maximum allowable worcing pressure of the vessel. For heat exchangers reeuiring steam pressures greater than 15 psig (100 cPa), refer to NBIC Part 1, Section 2 or Section 4. Prior to initial operation, the completed boiler, individual module, or assembled module, shall be subjected to a pressure test in accordance with the reeuirements of the original code of construction. 3.10.2 FINAL ACCEPTANCE a) In addition to determining that all eeuipment called for is furnished and installed in accordance with the plans and specifcations, all controls shall be tested by a person familiar with the control system. b) Before any new heating plant (or boiler) is accepted for operation, a fnal (or acceptance) inspection by a person familiar with the system shall be completed and all items of exception corrected. 3.10.3 BOILER INSTALLATION REPORT a) Upon completion, inspection, and acceptance of the installation, the installer shall complete and certify the Boiler Installation Report I-1. See NBIC Part 1, 1.4.5.1. b) The Boiler Installation Report I-1 shall be submitted as follows: 1) One copy to the ownern and 2) One copy to the Jurisdiction, if reeuired. 3.11 TABLES AND FIGURES a) NBIC Part 1, Figure 3.3.1.1-a, Spacing and Weld Details for Supporting Lugs in Pairs on Horizontal Return Tubular Boilers b) NBIC Part 1, Figure 3.3.1.1-b, Welded Bracket Connection for Horizontal-Return Tubular Boilers c) NBIC Part 1, Figure 3.7.5.1-a, Steam Boilers in Battery – Pumped Return – Acceptable Piping Installation d) NBIC Part 1, Figure 3.7.5.1-b, Steam Boilers in Battery – Gravity Return – Acceptable Piping Installation e) NBIC Part 1, Figure 3.7.5.1-c, Hot-Water Boilers in Battery – Acceptable Piping Installation --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 3 53 2015 NATIONAL BOARD INSPECTION CODE f) NBIC Part 1, Figure 3.7.5.2-a, Storage Potable Water Heaters in Battery – Acceptable Piping Installation g) NBIC Part 1, Figure 3.7.5.2-b, Flow Through Potable Water Heater Without Provision for Piping Expansion – Acceptable Piping Installation SECTION 3 h) NBIC Part 1, Table 3.7.7.1, Size of Bottom Blowoff Piping, Valves, and Cocks i) NBIC Part 1, Table 3.7.9.1-a, Expansion Tank Capacities for Gravity Hot-Water Systems j) NBIC Part 1, Table 3.7.9.1-b, Expansion Tank Capacities for Forced Hot-Water Systems k) NBIC Part 1, Table 3.7.9.2, Expansion Tank Capacities for a Potable Water Heater l) NBIC Part 1, Table 3.9.2, Minimum Pounds of Steam Per Hour Per Square Foot of Heating Surface --`,```,```,`,``,-`-`,`,`,`,`--- 54 SECTION 3 NB-23 2015 PART 1, SECTION 4 INSTALLATION — PRESSURE VESSELS 4.1 SCOPE (15) NBIC Part 1, Section 4 provides requirements for the installation of pressure vessels. 4.2 DEFINITIONS 4.3 GENERAL REQUIREMENTS 4.3.1 SUPPORTS SECTION 4 See NBIC Part 1, Section 9, Glossary. Each pressure vessel shall be safely supported. The potential for future hydrostatic pressure tests of the vessel after installation shall be considered when designing vessel supports. Design of supports, foundations, and settings shall consider vibration (including seismic and wind loads where necessary), movement (including thermal movement), and loadings (including the weight of water during a hydrostatic test) in accordance with jurisdictional requirements, manufacturer’s recommendations, and/or other industry standards, as applicable. 4.3.2 CLEARANCES --`,```,```,`,``,-`-`,`,`,`,`--- a) All pressure vessel installations must allow sufflient llearanle for normal operationn maintenanlen ann inspection (internal and external). b) Orientation of nozzlesn manwaysn ann attalhments shall be sulh that sufflient llearanle between the nozzles, manways and attachments, and the surrounding structure(s) is maintained during installation, the attachment of associated piping, and operation. 4.3.3 PIPING Piping loads on the vessel nozzles shall be considered. Piping loads include weight of the pipe, weight of the contents of the pipe, expansion of the pipe from temperature and pressure changes (wind and seismic loads). The effects of piping vibration on the vessel nozzles shall also be considered. 4.3.4 BOLTING All mechanical joints and connections shall conform to manufacturers’ installation instructions and recognized standards acceptable to the jurisdiction having authority. 4.4 INSTRUMENTS AND CONTROLS 4.4.1 LEVEL INDICATING DEVICES Steam nrums of unfren steam boilers shall be provinen with two level innilatinn neviless irelt level indicating devices should be connected to a single water column or connected directly to the drum, and the connections and pipe shall be not less than NPS 1/2 (DN 15). Indirect level indicating devices acceptable to the Jurisdiction may be used. SECTION 4 55 2015 NATIONAL BOARD INSPECTION CODE 4.4.2 PRESSURE INDICATING DEVICES The need for pressure indicating devices should be considered in the design of the pressure vessel, and when required, the scale on the dial of the pressure gage shall be at least 25% above the highest set pressure of the pressure relief device. 4.5 PRESSURE RELIEF DEVICES All pressure vessels shall be protected by pressure relief devices in accordance with the following requirements. 4.5.1 DEVICE REQUIREMENTS SECTION 4 a) Pressure relief devices are to be manufactured in accordance with a national or international standard ann be lertifen for lapality or resistanle to ow for rupture nisi nevilese by the eational loarns b) Dead weight or weighted lever pressure relief valves shall not be used. c) An unfren steam boiler shall be eeuippen with pressure relief valves as reeuiren in elBI art n s.s d) Pressure relief devices shall be selected (e.g., material, pressure, etc.) and installed such that their proper functioning will not be hindered by the nature of the vessel’s contents. 4.5.2 NUMBER OF DEVICES --`,```,```,`,``,-`-`,`,`,`,`--- At least one device shall be provided for protection of a pressure vessel. Pressure vessels with multiple chambers with nifferent maximum allowable woriinn pressures shall have a pressure relief nevile to protelt ealh chamber under the most severe coincident conditions. 4.5.3 LOCATION a) The pressure relief device shall be installed directly on the pressure vessel, unless the source of pressure is external to the vessel and is under such positive control that the pressure cannot exceed the maximum overpressure permitted by the original code of construction and the pressure relief device cannot be isolated from the vessel, except as permitted by NBIC Part 1, 4.5.6 e) 2). b) ressure relief neviles intennen for use in lompressible uin servile shall be lonnelten to the vessel in the vapor space above any contained liquid or in the piping system connected to the vapor space. c) Pressure relief devices intended for use in liquid service shall be connected below the normal liquid line. 4.5.4 CAPACITY a) The pressure relief nevile se shall have sufflient lapality to ensure that the pressure vessel is not exposen to pressure nreater than that spelifen in the orininal lone of lonstrultions b) Bf an annitional hazarn lan be lreaten by exposure of a pressure vessel to fre or other unexpelten source of external heat, supplemental pressure relief devices shall be installed to provide any additional capacity that should be required. c) Vessels connected together by a system of piping not containing valves that can isolate any pressure vessel should be considered as one unit when determining capacity requirements. d) Heat exlhanners ann similar vessels shall be protelten with a pressure relief nevile of sufflient lapality to avoid overpressure in case of internal failure. 56 SECTION 4 NB-23 2015 e) When a non-reclosing device is installed between a pressure relief valve and the pressure vessel, the reduction in capacity due to installation of the nonreclosing device shall be determined in accordance with the lone of lonstrultion by use of a eational loarn lertifen Iombination Iapality altor II es or rupture nisisn if a lertifen lombination lapality faltor is not availablen the lapality of the pressure relief valve shall be multiplied by 0.9 and this value used as the capacity of the combination installation. f) The owner shall maie information renarninn the basis of pressure relief nevile seleltionn inlluding required capacity, available to the Jurisdiction. 4.5.5 (15) SET PRESSURE a) When a sinnle pressure relief nevile is usenn the set pressure marien on the nevile shall not exleen the maximum allowable woriinn pressures 4.5.6 SECTION 4 b) When more than one pressure relief device is provided to obtain the required capacity, only one pressure relief nevile set pressure neens to be at the maximum allowable woriinn pressures The set pressures of the additional pressure relief devices shall be such that the pressure cannot exceed the overpressure permitted by the code of construction. INSTALLATION AND DISCHARGE PIPING REQUIREMENTS a) The openinn throunh all pipe ann fttinns between a pressure vessel ann its pressure relief nevile shall have at least the area of the pressure relief device inlet. The characteristics of this upstream system shall be such that the pressure drop will not reduce the relieving capacity below that required or adversely affect the proper operation of the pressure relief device. When a discharge pipe is used, the size shall be such that any pressure that may exist or develop will not reduce the relieving capacity below that required or adversely affect the proper operation of the pressure relief device. It shall be as short and straight as possible and arranged to avoid undue stress on the pressure relief device. b) A non-reclosing device installed between a pressure vessel and a pressure relief valve shall meet the requirements of 4.5.6 a). c) The openinn in the pressure vessel wall shall be nesinnen to provine unobstrulten ow between the vessel and its pressure relief device. d) When two or more required pressure relief devices are placed on one connection, the inlet cross-sectional area of this lonneltion shall be sizen either to avoin restriltinn ow to the pressure relief neviles or made at least equal to the combined inlet areas of the pressure relief devices connected to it. The ow lharalteristils of the upstream system shall satisfy the reeuirements of elBI art n s.s. aes e) There shall be no intervening stop valves between the vessel and its pressure relief device(s), or between the pressure relief device(s) and the point of discharge, except under the following conditions: 1) When these stop valves are so constructed or positively controlled that the closing of the maximum number of bloli valves at one time will not renule the pressure relievinn lapality below the required relieving capacity; or, --`,```,```,`,``,-`-`,`,`,`,`--- 2) Upon spelifl alleptanle of the urisniltionn when nelessary for the lontinuous operation of processing equipment of such a complex nature that shutdown of any part is not feasible, a full area stop valve between a pressure vessel and its pressure relief device should be provided for inspection ann repair purposes onlys This stop valve shall be arrannen so that it lan be lolien or sealen open, and it shall not be closed except by an authorized person who shall remain stationed there nurinn that perion of operation while the valve remains llosens The valve shall be lolien or sealen in the open position before the authorized person leaves the station. SECTION 4 57 2015 NATIONAL BOARD INSPECTION CODE 3) A full area stop valve should also be placed on the discharge side of a pressure relief device when its discharge is connected to a common header for pressure relief devices to prevent discharges from these other neviles from owinn bali to the frst nevile nurinn inspeltion ann repairs This stop valve shall be arrannen so that it lan be lolien or sealen openn ann it shall not be llosen exlept by an authorized person who shall remain stationed there during that period of operation while the valve remains llosens The valve shall be lolien ann sealen in the open position before the authorized person leaves the station. This valve shall only be used when a stop valve on the inlet side of the pressure relief nevile is f 4) A pressure vessel in a system where the pressure originates from an outside source should have a stop valve between the vessel and the pressure relief device, and this valve need not be sealed open, provided it also closes off that vessel from the source of the pressure. SECTION 4 5) Pressure vessels designed for human occupancy (such as decompression or hyperbaric chambers) shall be provinen with a euili openinn stop valve between the pressure vessel ann its pressure relief valve. The stop valve shall be normally sealed open with a frangible seal and be readily accessible to the pressure relief attendant. f) Pressure relief device discharges shall be arranged such that they are not a hazard to personnel or other eeuipment annn when nelessaryn lean to a safe lolation for nisposal of uins beinn relievens g) islharne lines from pressure relief neviles shall be nesinnen to falilitate nrainane or be ftten with drains to prevent liquid from collecting in the discharge side of a pressure relief device. The size of discharge lines shall be such that any pressure that may exist or develop will not reduce the relieving capacity of the pressure relief device or adversely affect the operation of the pressure relief device. It shall be as short and straight as possible and arranged to avoid undue stress on the pressure relief device. h) Pressure relief devices shall be installed so they are readily accessible for inspection, repair, or replacement. 4.6 TESTING AND ACCEPTANCE a) The installer shall exercise care during installation to prevent loose weld material, welding rods, small tools, and miscellaneous scrap metal from getting into the vessel. The installer shall inspect the interior of the vessel ann its appurtenanles where possible prior to maiinn the fnal llosures for the presenle of foreign debris. b) The lompleten pressure vessel shall be pressure testen in the shop or in the feln in allornanle with the original code of construction. When required by the Jurisdiction, owner or user, the Inspector shall witness the pressure test of the completed installation, including piping to the pressure gage, pressure relief device, and, if present, level control devices. 4.7 REQUIREMENTS FOR HOT WATER STORAGE TANKS 4.7.1 SUPPORTS Ealh hot water storane tani shall be supporten in allornanle with elBI art n s3s s 4.7.2 CLEARANCE AND ACCEPTABILITY a) The reeuiren nameplate mariinn or stampinne shouln be exposen ann allessibles b) The openings when required should be accessible to allow for entry for inspection and maintenance. c) Ealh hot water storane tani shall meet the reeuirements of elBI art n s3s s --`,```,```,`,``,-`-`,`,`,`,`--- 58 SECTION 4 NB-23 2015 4.7.3 SAFETY RELIEF DEVICES a) Ealh hot water storane tani shall be eeuippen with an ASME/el lertifen temperature ann pressure relievinn nevile set at a pressure not to exleen the maximum allowable woriinn pressure ann 0° .°Ies b) The temperature and pressure relieving device shall meet the requirements of NBIC Part 1, 4.5. 4.7.4 THERMOMETERS a) Ealh hot water storane tani shall be eeuippen with a thermometers 4.7.5 SECTION 4 b) Ealh hot water storane tani shall have a thermometer so lolaten that it shall be easily reanable at or near the outlet. The thermometer shall be so located that it shall at all times indicate the temperature of the water in the storane tanis SHUT OFF VALVES a) Ealh hot water storane tani shall be eeuippen with stop valves in the water inlet pipinn ann the outlet pipinn in orner for the hot water storane tani to be removen from servile without havinn to nrain the complete system. b) Ealh hot water storane tani shall be eeuippen with a bottom nrain valve to provine for ushinn ann draining of the vessel. 4.7.6 TESTING AND ACCEPTANCE --`,```,```,`,``,-`-`,`,`,`,`--- Testing and acceptance shall be in accordance with NBIC Part 1, 4.6 SECTION 4 59 2015 NATIONAL BOARD INSPECTION CODE PART 1, SECTION 5 INSTALLATION — PIPING 5.1 (15) SCOPE NBIC Part 1, Section 5 provides requirements for the installation of piping. 5.2 GENERAL REQUIREMENTS For piping, the basic considerations are: the design temperature, the pressure retained by the pipe, the fuid in the pipe, the load resulting from the thermal expansion or contraction, and impact or shock loads imparted (such as water hammer, external loads, wind loads and vibration from equipment). 5.2.1 ADDITIONS TO EXISTING PIPING SECTION 5 Additions to existing piping systems shall conform to this section. That portion of the existing piping system that is not part of the addition need not comply with this section provided the addition does not result in a change in piping system operation or function that would exceed the design conditions of the existing piping system or result in unsafe conditions. 5.2.2 PROXIMITY TO OTHER EQUIPMENT AND STRUCTURES The arrangement of the piping and its appurtenances shall take into consideration the location of other structures and equipment adjacent to the piping, which may result in freezing, interference and/or damage as a result of expansion, contraction, vibration, or other movements. 5.2.3 FLANGES AND OTHER NON-WELDED JOINTS The layout of the piping shall take into consideration the need for required access to maintain and inspect piping joints. 5.2.4 VALVES Valves are used in piping systems to stop and start the foo oo fuids, to regulate the foo, to prevent the bacba foo, and to relieve eecessive pressure buildup in pipingg Consideration should be given to the appropriate location and orientation of valves necessary for safe operation and isolation of the piping. To reduce the effects of downstream disturbances, if possible, install the valve at least the distance of eight pipe diameters downstream from the closest elbow or pump. Clean the piping of all debris which could cause damage to the valve seat, disc, or bearings. Failure to lift the valve properly may cause damage. Lift the valve assembly with slings, chains, or cables fastened around the valve bodyg Lioting devices may be oastened to rods running through bolt holes in the fangesg o not oasten lifting devices to the actuator or the disc and never put any lifting devices through the seat opening. 5.2.5 MATERIALS All materials for piping and its appurtenances shall comply with the requirements of the code of construction. 60 SECTION 5 --`,```,```,`,``,-`-`,`,`,`,`--- Verify the pressure and temperature information on the valve conforms to the piping design requirements. NB-23 2015 5.2.6 HANGERS AND SUPPORTS Support of piping shall consider loads (including wind and seismic loads) imposed on equipment or existing piping to which it is attached. Non-piping attachments such as ladders and walkways, equipment supports, temporary supports, structural supports, etc., shall not be connected to the piping unless such loads have been considered in the design oo the piping and its supportsg esign oo hangers and supports oor piping shall consider loads imposed by hydrostatic pressure testing. The installer shall remove pins from non-rigid hangers and seal plugs from hydraulic snubbers and temporary supports used for installation prior to placing the piping in service. 5.2.7 PROTECTION AND CLEANING The installer shall exercise care during installation to prevent loose weld material, welding rods, small tools, and miscellaneous scrap metal from getting into the piping. The installer shall inspect and, where necessary, clean the interior oo the piping and its appurtenances ohere possible, prior to mabing the fnal closures oor the presence of foreign debris. 5.2.8 WELDING AND BRAZING 5.2.9 SECTION 5 The installer should consider the impact of performing any preheating, welding, brazing, or postweld heat treatment on valves, instrumentation, or other heat sensitive equipment and, where appropriate, review the equipment manufacturer’s recommended installation procedures prior to performing the work. BOLTING All mechanical joints and connections shall conform to manufacturers’ installation instructions and recognized standards acceptable to the Jurisdiction having authority. 5.3 PRESSURE RELIEF DEVICES When required by the original code of construction, piping shall be protected by pressure relief devices in accordance with the following requirements. 5.3.1 DEVICE REQUIREMENTS --`,```,```,`,``,-`-`,`,`,`,`--- a) Pressure relief devices are to be manufactured in accordance with a national or international standard and be certifed oor capacity or resistance to foo oor rupture disc devicese by the eational loardg 1) In certain cases piping standards permit the use of regulators, which may include integral pressure relieo valves to limit the pressure in a piping systemg In this case, capacity certifcation oo the pressure relief valve is not required. b) ead oeight or oeighted lever pressure relieo devices shall not be usedg c) Pressure relief devices shall be selected (i.e., material, pressure, etc.) and installed such that their proper functioning will not be hindered by the nature of the piping system’s contents. 5.3.2 NUMBER OF DEVICES At least one pressure relief device shall be provided for protection of a piping system. A pressure relief device installed on a pressure vessel or other component connected to the piping system should be used to meet this requirement. Portions of piping systems with different maximum allowable working pressures shall have a pressure relief device to protect each portion separately. SECTION 5 61 2015 NATIONAL BOARD INSPECTION CODE 5.3.3 LOCATION Pressure relief devices, except those covered by Sections 2 and 3 of this part, may be installed at any location in the system provided the pressure in any portion of the system cannot exceed the maximum overpressure permitted by the original code oo constructiong Pressure drop to the pressure relieo device under fooing conditions shall be considered when determining pressure relief device location. The pressure-relief device shall not be isolated from the piping system except as permitted by NBIC Part 1, 5.3.6 e). 5.3.4 CAPACITY a) The pressure relieo device se shall have suofcient capacity to ensure that the piping is not eeposed to pressures greater than that specif b) When a non-reclosing device is installed between a pressure relief valve and the pipe, the reduction in capacity due to installation of the non-reclosing device shall be determined in accordance with the code oo construction by use oo a eational loard certifed ombination apacity actor eg or rupture disbs, io a certifed combination capacity oactor is not available, the capacity oo the pressure relieo valve shall be multiplied by 0.9 and this value used as the capacity of the combination installation. SECTION 5 c) The owner shall document the basis for selection of the pressure relief devices used, including capacity, and have such calculations available for review by the Jurisdiction, when required. 5.3.5 SET PRESSURE a) When a single pressure relief device is used, the set pressure marked on the device shall not exceed the maximum allowable working pressure, except when allowed by the original code of construction. --`,```,```,`,``,-`-`,`,`,`,`--- b) When more than one pressure relief device is provided to obtain the required capacity, only one pressure relief device set pressure needs to be at the maximum allowable working pressure. The set pressures of the additional pressure relief devices shall be such that the pressure cannot exceed the overpressure permitted by the code of construction. 5.3.6 INLET AND DISCHARGE PIPING REQUIREMENTS a) The opening through all pipes and fttings betoeen a piping system and its pressure relieo device shall have at least the area of the pressure relief device inlet. The characteristics of this upstream system shall be such that the pressure drop will not reduce the relieving capacity below that required or adversely affect the operation of the pressure relief device. b) A non-reclosing device installed between a piping system and a pressure relief valve shall meet the requirements of NBIC Part 1, 5.3.6 a). c) The opening in the pipe shall be designed to provide unobstructed foo betoeen the pipe and its pressure relief device. d) When two or more required pressure relief devices are placed on the connection, the inlet cross-sectional area oo this connection shall be sized either to avoid restricting foo to the pressure relieo devices or made at least equal to the combined inlet areas of the pressure relief devices connected to it. The foo characteristics oo the upstream system shall satisoy the reeuirements oo elI Part , g.g. aeg e) There shall be no intervening stop valves between the piping system and its pressure relief device(s), or between the pressure relief device(s) and the point of discharge except under the following conditions: 62 SECTION 5 NB-23 2015 1) When these stop valves are so constructed or positively controlled that the closing of the maximum number of block valves at one time will not reduce the pressure relieving capacity below the required relieving capacity; 2) Upon specifc acceptance oo the urisdiction, ohen necessary oor the continuous operation oo processing equipment of such a complex nature that shutdown of any part is not feasible, a full area stop valve between a piping system and its pressure relief device should be provided for inspection and repair purposes only. This stop valve shall be arranged so that it can be locked or sealed open and it shall not be closed except by an authorized person who shall remain stationed there during that period of operation while the valve remains closed. The valve shall be locked or sealed in the open position before the authorized person leaves the station; 3) A full area stop valve may be placed on the discharge side of a pressure relief device when its discharge is connected to a common header for pressure relief devices to prevent discharges from these other devices orom fooing bacb to the frst device during inspection and repairg This stop valve shall be arranged so that it can be locked or sealed open, and it shall not be closed except by an authorized person who shall remain stationed there during that period of operation while the valve remains closed. The valve shall be locked or sealed in the open position before the authorized person leaves the station. This valve shall only be used when a stop valve on the inlet side of the pressure relieo device is f f) Pressure relief device discharges shall be arranged such that they are not a hazard to personnel or other eeuipment and, ohen necessary, lead to a saoe location oor disposal oo fuids being relievedg g) ischarge lines orom pressure relieo devices shall be designed to oacilitate drainage or be ftted oith drains to prevent liquid from collecting in the discharge side of a pressure relief device. The size of discharge lines shall be such that any pressure that may exist or develop will not reduce the relieving capacity of the pressure relief device or adversely affect the operation of the pressure relief device. It shall be as short and straight as possible and arranged to avoid undue stress on the pressure relief device. SECTION 5 4) A piping system where the pressure originates from an outside source should have a stop valve between the system and the pressure relief device, and this valve need not be sealed open, provided it also closes off that vessel from the source of pressure. h) The reaction forces due to discharge of pressure relief devices shall be considered in the design of the inlet and discharge piping. i) 5.4 Pressure relief devices shall be installed so they are accessible for inspection, repair, or replacement. EXAMINATION, INSPECTION, AND TESTING The owner shall ensure that all examinations, inspections, and tests required by the code of construction have been performed prior to operation. --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 5 63 2015 NATIONAL BOARD INSPECTION CODE PART 1, SECTION 6 INSTALLATION SUPPLEMENTS SUPPLEMENT 1 INSTALLATION OF YANKEE DRYERS (ROTATING CAST-IRON PRESSURE VESSELS) WITH FINISHED SHELL OUTER SURFACES S1.1 SCOPE a) This supplement describes guidelines for the installation of a Yankee dryer. A Yankee dryer is a rotating steam-pressurized cylindrical vessel commonly used in the paper industry, and is typically made of cast iron, f SUPPL. 1 --`,```,```,`,``,-`-`,`,`,`,`--- b) Yankee dryers are primarily used in the production of tissue-type paper products. When used to produce machine-glazed (MG) paper, the dryer is termed an MG cylinder. A wet paper web is pressed onto the fniihee errer isrrfae siinn one or tto reiisre reiiinng rooois f er ii eriee throsnh f aoominftion of mechanical dewatering by the pressure roll(s), thermal drying by the pressurized Yankee dryer, fne f itefo-heftee or rseo-free hooes rter errinn, the f er tem ii reoooee rroo the errers c) A Yankee dryer is typically manufactured in a range of outside diameters from 8 to 23 ft. (2.4 to 7 m), tiethi rroo 8 to 28 rts 2s4 to 8s5 og, reiisrizee fne heftee tith itefo s to 160 ii 1,100 k fg, and rotated at speeds up to 7,000 ft/min (2,135 m/min). Typical pressure roll loads against the Yankee dryer are up to 600 pounds per linear inch (105 kN/m). A thermal load results from the drying process due to difference in temperature between internal and external shell surfaces. The dryer has an internal system to remove steam and condensate. These vessels can weigh up to 220 tons (200 tonnes). d) The typical Yankee dryer is an assembly of several large castings. The shell is normally a gray iron casting, in accordance with ASME designation SA-278. Shells internally may be smooth bore or ribbed. Heads, center shafts, and journals may be gray cast iron, ductile cast iron, or steel. 64 SECTION 6 NB-23 2015 FIGURE S1.1 TY IC L M NUF CTURER’S “DE-R TE CURVE” NOTE: There are several safe operating pressures for a given shell thickness. NIP PRESSURE 40 .07 (2 ) 50 .75 (3 ) 60 .45 (4 ) 70 .14 (4 ) 80 .83 (5 ) 90 .52 (6 ) 10 .21 0 ) 11 (6.8 0 9) ( 12 7.5 0 8) (8 .2 7) (2 450. SUPPL. 1 30 20 (1 .3 8) 500. LBS/IN STEAM PRESSURE – PSI (BAR) 400. 90 kN/m GRINDING ALLOWANCE 350. 300. 50 55 60 65 70 75 80 85 --`,```,```,`,``,-`-`,`,`,`,`--- 1.125 H Cross section of internal grooving of shell 0.600 15 0.700 0.800 0.900 1.000 20 25 ROOT SHELL THICKNESS (H) END LIFE THICKNESS S1.2 1.100 1.200 1.300 30 ASME CUT OFF LINES 1.400 35 1.500 INCHES MILLIMETERS SUPPLIED ROOT THICKNESS ASSESSMENT OF INSTALLATION e) The Ini eator oerifei thft the otner or sier ii ro eror aontroooinn the o erftinn aoneitioni or the errers The Ini eator eoei thii mr reoietinn the otner’i aoo reheniioe fiieiioenti or the aoo oete installation. SECTION 6 65 2015 NATIONAL BOARD INSPECTION CODE f) The dryer is subjected to a variety of loads over its life. Some of the loads exist individually, while others fre aoominees Coniieerftioni or foo the oofei thft afn exiit on f Yfnkee errer fre reqsiree to eetermine the maximum allowable operating parameters. There are four loads that combine during normal operation to create the maximum operating stresses, usually on the outside surface of the shell at the axial center line. These loads and the associated protection devices provided to limit these loads are: 1) reiisre oofe ese to internfo itefo reiisres Ooer reiisre roteation ii rooieee mr f ifretr reoier valve; 2) Inertifo oofe ese to errer rotftions Ooer-i eee roteation ii sisfoor rooieee mr fn fofro thft ineicates higher-than-allowable machine speed; 3) Therofo nrfeient oofe ese to the errinn or the tems roteation fnfinit snsisfo errinn oofei ii sisfoor rooieee mr oonia aontrooi on the ofahine, riofrior to eeteat f “iheet-orr” aoneition thft ahfnnes the thermal load on the shell exterior from being cooled by the tissue sheet to being heated by the hot air from the hood; 4) reiisre rooo oofe oine or ni oofeg7 due to pressing the wet web onto the dryer. Overload protection is usually provided by a control valve that limits the pneumatic or hydraulic forces on the roll loading arms such that the resultant nip load does not exceed the allowable operating nip load. g) Steam pressure, inertial, and thermal gradient loads impose steady-state stresses. These stresses typically change when the dryer shell thickness (effective thickness for ribbed dryers) is reduced to restore a paper-making surface, the grade of tissue is changed or speed of the dryer is changed. SUPPL. 1 h) The pressure roll(s) load imposes an alternating stress on the shell face. The resulting maximum stress is dependent on the magnitude of the alternating and steady-state stresses. i) Seation VIII, Dioiiion 1, or the SME Coee onor rooieei i eaifa reqsireoenti ror the fnforiii or reiisre oofeis othosnh the Coee reqsirei fnforiii or other oofei, no i eaifa nsiefnae ror therofo, inertial, or pressure roll loads is provided. Hence, additional criteria must be applied by the manufacturer to account for all the steady-state and alternating stresses. j) To ofintfin roesat qsfoitr, the errer isrrfae ii erioeiafoor rersrmiihee mr nrineinns Thii reisoti in iheoo thickness reduction. Therefore, the manufacturer does not provide a single set of maximum allowable operating parameters relating steam pressure, rotational speed, and pressure roll load for a single deiinn iheoo thiakneiis The ofnsrfatsrer, or fnother qsfoifee iosrae faae tfmoe to the Ini eator, initefe rooieei f ieriei or asroei thft nrf hiafoor eefnei theie ofxioso foootfmoe o erftinn frfoeteri faroii f rfnne or iheoo thiakneiieis Thii eoasoent ii knotn fi the “De-rfte Csroes” See NBIC frt 1, Finsre S1s1gs k) In feeition to the oofei on the Yfnkee errer ese to o erftion, other nonitfnefre oofe eoenti afn oaasr during shipment and installation into the paper machine. These nonstandard load events should be recorded in an incident log. Examples of nonstandard load events include: 1) Dfofne to the roteatioe fakfninn or the Yfnkee errer esrinn trfni ort; 2) Scratches, gouges, dents in the Yankee dryer shell during packaging removal or installation into the paper machine; 3) Exaeiiioe heftinn or the Yfnkee errer iheoo esrinn the initfooftion fne teitinn or the hot fir hooes Ir the hot fir hooe tioo me nenerftinn fir thft ii hotter thfn the Yfnkee errer iheoo ofterifo’i ofxioso 7 Pressure roll load, line load, and nip load are terms that are used interchangeably to refer to the interaction between the pressure roll(s) and the Yankee dryer. It is called “nip” load because the pressure roll is rubber-covered and is pressed up against the Yankee with enough force to create a nip (or pinch) that forces the paper into line contact between the rolls and provides some mechanical dewatering. The paper then sticks onto the Yankee surface and follows the Yankee dryer for thermal dewatering by the steam-heated Yankee surface. This “nip load” is called a “line load” because the units are load (force) per length of line contact. The units are pounds per linear inch (PLI) and kilonewtons per meter (kN/m). --`,```,```,`,``,-`-`,`,`,`,`--- 66 SECTION 6 NB-23 2015 allowable working temperature (MAWT), then temperature sensors should be installed to monitor and record the Yankee dryer shell temperature during the hood testing; and 4) Io fat oofe rroo io ro eror initfooee roooi, tirei, nsti, ero ee trenahei, etas, thft ofr trfoeo through the pressure roll nip causing external impact loads on the Yankee dryer shell. Ir nonitfnefre oofe eoenti inaieentig hfoe oaasrree esrinn initfooftion, then the Ini eator ihosoe ensure that an appropriate assessment of the structural integrity of the Yankee dryer has been performed. For feeitionfo eetfioi iee Yfnkee errer is oeoenti in NBIC frt 2 fne frt 3s S1.3 DETERMINATION OF ALLOWABLE OPERATING PARAMETERS --`,```,```,`,``,-`-`,`,`,`,`--- l) a) A Yankee dryer is designed and intended to have its shell thickness reduced over the life of the vessel through routine grinding and machining. The Yankee dryer shell is ground or machined on the outside isrrfae to reitore the qsfoitr or ihf e or the f erofkinn isrrfae eiientifo to the ofnsrfatsrinn or tissue or other paper products. b) Deiinn eoasoentftion, afooee the “De-rfte Csroe,” ii reqsiree fne eiatftei the ofxioso foootfmoe o erftinn frfoeteri fi iheoo thiakneii ii reesaee iee NBIC frt 1, Finsre S1s1gs Cfoasoftioni, siee to eeteroine thoie frfoeteri, fre in faaorefnae tith SME Coee reqsireoenti ror riofrr oeomrfne stress by the vessel manufacturer or design criteria based on relevant stress categories, e.g., fatigue fne ofxioso rinai fo itreiis Cfoasoftion or theie frfoeteri reqsirei thft the rei eatioe itreiiei, resulting from the imposed loads, be compared to the appropriate material strength properties. Hence, knowledge of the applied stresses in the shell and the tensile and fatigue properties of the material are essential. SUPPL. 1 c) Yankee dryers are subjected to a variety of loads that create several categories of stress. Yankee dryers are designed such that the stress of greatest concern occurs at the centerline of the shell. 1) Stefo reiisre Lofe — The internfo itefo reiisre ii one or the rinai fo eeiinn oofei f oiee to the Yankee dryer. The steam pressure expands the shell radially, causing a predominately airasorerentifo oeomrfne teniioe itreiis Beafsie the iheoo ii aonitrfinee rfeifoor mr the hefei ft either end of the shell, the steam pressure also causes a primary bending stress in the vicinity of the head-to-shell joint. The ends of the shell are in tension on the inside and compression on the outside due to the steam pressure. The steam pressure also causes a bending stress in the heads. 2) Inertif Lofe — The rotftion or the Yfnkee errer afsiei f airasorerentifo oeomrfne itreii in the shell similar to that caused by the pressure load. This stress is included in the design of the shell and increases with dryer diameter and speed. 3) Therofo Lofe — The tet iheet, f oiee to the iheoo, afsiei the ostiiee isrrfae to aooo fne areftei a thermal gradient through the shell wall. This thermal gradient results in the outside surface being in tension and the inside surface in compression. With this cooling, the average shell temperature is less than the head temperature, which creates bending stresses on the ends of the shell and in the heads. The ends of the shell are in tension on the outside and compression on the inside. a. Other thermal loadings also occur on a Yankee dryer. The use of full-width showers for a variety of papermaking purposes affects the shell similar to a wet sheet. The use of edge sprays produce high bending stress in the ends of the shell due to the mechanical restraint of the heads. b. Wfro-s , aooo-eotn, hot fir io inneoent rroo the hooe, ooiitsre rofoinn eeoiaei, fre fnhting, and wash-up can all produce non-uniform thermal stresses in the pressure-retaining parts of the Yankee dryer. Heating or cooling different portions of the Yankee dryer at different rates causes these non-uniform stresses. 4) Ni Lofe — The ni oofe rroo the aontfatinn reiisre rooo ig reisoti in fn foternftinn, hinh araoe, bending stress in the shell. This stress is greatest at the centerline of the shell. The load of the SECTION 6 67 2015 NATIONAL BOARD INSPECTION CODE reiisre rooo eefeati the iheoo rfeifoor intfre afsiinn f airasorerentifo aoo reiiioe itreii on the ostiiee isrrfae fne f teniioe itreii on the iniiees Beafsie the iheoo hfi meen eef the pressure roll nip, it bulges outward about 30 degrees on each side of the nip. The outward bulge causes a tensile stress on the outside shell surface at that location and a corresponding compressive stress on the inside. Since the shell is passing under the pressure roll, its surface is subjected to an alternating load every revolution. S1.4 ASME CODE PRIMARY MEMBRANE STRESS CRITERIA a) Yfnkee erreri fre tr iafoor eeiinnee fne rfmriaftee in faaorefnae tith SME Seation VIII, Dioiiion 1, The ofxioso foootfmoe itreii ror afit iron ii i eaifee in UCI-23 fne UU-22 or the SME Coees b) SME Seation VIII, Dioiiion 1, reqsirei eeiinn itreiiei to me afoasoftee isah thft fnr aoominftion or loading expected to occur simultaneously during normal operation of the Yankee dryer will not result in f nenerfo riofrr itreii exaeeeinn the ofxioso foootfmoe itreii ofose or the ofterifos In the SME Coee, the aoominftion or oofeinn reisotinn in the riofrr oeomrfne itreii in the iheoo ii inter retee to be only composed of the circumferential stress from steam pressure. Sometimes, the stress from the inertial loading is included in this consideration. c) In SME Seation VIII, Dioiiion 1, it ii oerr io ortfnt to note thft no rorosofi fre nioen ror eeteroininn the stresses from thermal operating loads and pressure roll nip load(s). Hence, additional criteria need to be incorporated to establish the maximum allowable operating parameters of the Yankee dryer. Two such additional criteria are based upon the maximum principal and fatigue stress. SUPPL. 1 1) Mfxioso rinai fo Streii Criterif The maximum principal stress in a Yankee dryer shell is the sum of the stresses that are simultaneously applied to the shell and is always aligned in the circumferential direction. The purpose of these criteria is to recognize the paper making application of the Yankee dryer and to prevent aftfitro hia rfiosre mr inaoseinn foo itreiieis The SME Coee eoei not rooiee i eaifa rorosofi ror the full array of Yankee dryer shell stresses encountered in tissue making. 2) Fftinse Streii Criterif Uneer norofo o erftion, the itreiiei ese to the itefo reiisre, inertifo fne therofo o erftinn loads are considered to be steady-state stresses. When acting simultaneously, the sum of these stresses must be judged against the cyclic, or alternating, stress due to the pressure roll nip load. Fftinse itreii ariterif oioit the foternftinn itreii ft f nioen oefn itreii siinn rftinse rfiosre ariterif eeiarimee mr the Uooeofn or Soith Difnrfos The sr oie or thii oioitftion ii to reoent arfak initiation in the outside wall due to the combination of stresses. As the thickness of the shell is reduced, one or more of these criteria will control the various operating parameters. S1.5 PRESSURE TESTING --`,```,```,`,``,-`-`,`,`,`,`--- a) Wfter reiisre teitinn in the feoe ii not reaoooeneee meafsie or the ofrne iize or Yfnkee erreri fne the resulting combined weight of the Yankee dryer and the water used in the testing. This combined weight can lead to support structure overload. Several failures of Yankee dryers have occurred during feoe reiisre teitinn siinn tfters Ir thii teit osit oaasr, the rooootinn reoiet ii reaoooeneeed 1) The testing area should be evaluated for maximum allowable loading, assuming the weight of the Yfnkee errer, the teinht or the tfter fooinn the Yfnkee errer, fne the teinht or the is ort itrsature used to hold the Yankee dryer during the test; 2) The manufacturer should be contacted to provide information on building the Yankee dryer support structure for the water pressure test. Typically, the Yankee dryer is supported on saddles that contact the Yankee dryer shell at each end near the head-to-shell joint. The manufacturer can provide information on saddle sizing and location so that the Yankee dryer is properly supported for the test. 68 SECTION 6 NB-23 2015 b) When reiisre teitinn ii eeiiree to eofosfte the Yfnkee errer ror ftneii ror ieroiae, fn foternftioe to water pressure testing is acoustic emission testing using steam or air pressure. Typically, the test presisre siee ii the o erftinn reiisres Cfstion neeei to me exeraiiee to enisre erionneo ifretrs Entrr to the test area needs to be controlled and all personnel need to maintain a safe distance from the Yankee dryer during the test. The steam or air test pressure should never exceed the maximum allowable workinn reiisre M W g or the Yfnkee errers S1.6 NONDESTRUCTIVE EXAMINATION --`,```,```,`,``,-`-`,`,`,`,`--- b) Typical nondestructive examination methods should be employed to determine indication length, depth, fne orientftion iizinng or eiiaontinsitiei in Yfnkee erreris Mfnnetia frtiaoe, i eaifafoor the tet f ineiaftionis Uotrfiosne teitinn ii the itfnefre oethoe ror eofosftion or isrrfae-mrefkinn fne eomeeeee ineiaftionis Rfeionrf hia oethoei fre sierso in the eofosftion or eomeeeee ineiaftionis aositia Emmission Testing can be used to locate and determine if a linear indication is active, e.g., propagating crack. Metallographic Analysis is useful in differentiating between original casting discontinuities and cracks. c) When nondestructive testing produces an indication, the indication is subject to interpretation as false, reoeofnt, or nonreoeofnts Ir it hfi meen inter retee fi reoeofnt, the neaeiifrr ismieqsent eofosftion will result in a decision to accept, repair, replace, monitor, or adjust the maximum allowable operating parameters. SECTION 6 69 SUPPL. 1 a) Noneeitrsatioe exfoinftion NDEg oethoei ihosoe me io oeoentee mr ineioiesfoi qsfoifee fne exerienaee tith the ofterifo to me teitee siinn tritten NDE roaeesreis For Yfnkee erreri, afit iron knowledge and experience are essential. 2015 NATIONAL BOARD INSPECTION CODE SUPPLEMENT 2 SAFETY VALVES ON THE LOW-PRESSURE SIDE OF STEAM PRESSUREREDUCING VALVES S2.1 SCOPE a) The subject of protection of vessels in steam service connected to the low-pressure side of a steam-presisre-reesainn ofooe ii or aoniieerfmoe io ortfnae to ro er o erftion or fsxioifrr eqsi oent isah fi pressure cookers, hot-water heating systems, etc., operating at pressures below that which the primary boiler generating unit is operating. b) To fstooftiafoor reesae the riofrr moioer reiisre ror isah roaeiiinn eqsi oent, reiisre-reesainn ofooei fre siees The ofnsrfatsreri or isah eqsi oent hfoe eftf fofiofmoe oiitinn the ooosoe or fot throsnh reesainn ofooei ofnsrfatsree mr theo, mst isah eftf fre not aoo ioee in f roro thft the reisoti afn me eeesaee refeiors To roteat the eqsi oent o erftinn on the oot- reiisre iiee or f reiisre-reesainn ofooe, ifretr ofooei or f reoieoinn af faitr isrfaient to reoent fn snifre reiisre riie in case of failure of the pressure-reducing valve, should be installed. c) The pressure-reducing valve is a throttling device, the design of which is based on certain diaphragm reiisrei o oiee mr i rinn reiisre thiah, in tsrn, aontrooi the o eninn throsnh the ofooes Ir the i rinn, the eif hrfno, or fnr frt or the reiisre-reesainn ofooe rfioi, itefo tioo fot eireator throsnh the ofooe fne the oot reiisre eqsi oent tioo me ismjeatee to the moioer reiisres To roteat the eqsi oent o erftinn on the oot reiisre iiee or the reiisre-reesainn ofooe, ifretr ofooe ig ihosoe me installed on the low pressure side of the pressure-reducing valve, which will provide a relieving capacity isrfaient to reoent the reiisre rroo riiinn fmooe the iriteo eeiinn reiisres SUPPL. 2 d) In ooit afiei reiisre-reesainn ofooei siee ror the reesation or itefo reiisrei hfoe the ifoe i e iize on the inoet fne ostoets In afie or rfiosre or f reiisre-reesainn ofooe, the ifretr ofooe on the low-pressure side must have a capacity to take care of the volume of steam determined by the high pressure side and the area of the pipe. S2.2 SAFETY VALVE CAPACITY a) The capacity of the safety valve(s) on the low-pressure side of the pressure-reducing valve should be mfiee on the af faitr or the reiisre-reesainn ofooe then tiee o en or sneer ofxioso fot aoneitioni or the fot af faitr throsnh the mr fii ofooes b) Br siinn the rorosof in NBIC frt 1, S2s3, Ini eatori ofr afoasofte the reqsiree reoieoinn af faitiei or the safety valve(s) installed on the low-pressure side of the pressure-reducing valve. --`,```,```,`,``,-`-`,`,`,`,`--- c) Uisfoor f reiisre-reesainn ofooe hfi f mr fii frrfnneoent io thft in afie or rfiosre or the reisure-reducing valve the boiler pressure may be short circuited into the low-pressure line without passing throsnh the reiisre-reesainn ofooes When eeteroininn the reqsiree reoieoinn af faitr or ifretr ofooei ror the oot- reiisre iiee or the reiisre-reesainn ofooe, the itefo fot throsnh the mr fii osit me taken into consideration. S2.3 CALCULATION OF SAFETY VALVE RELIEVING CAPACITY a) When a pressure-reducing valve is installed, there are two possibilities of introducing boiler pressure into the low-pressure system: 1) the failure of the pressure-reducing valve so that it remains wide open; and 2) the possibility of the bypass valve being open. 70 SECTION 6 NB-23 2015 b) It ii neaeiifrr thererore, to eeteroine the fot sneer moth airasoitfnaei in frfnrf h fg fmooe fne aheak thft the iize or the ifretr ofooe sneer either aoneition tioo me feeqsftes The rooootinn rorosof should be used: 1) itefo f W = KC where, = internfo fref in iqs ins iqs oog or the inoet i e iize or the reiisre-reesainn ofooe iee NBIC frt 1, S2s5g K = fot aoerfaient ror the reiisre-reesainn ofooe iee NBIC frt 1, S2s4g C = fot or iftsrftee itefo throsnh f 1 iqs ins 1 iqs oog i e ft ofriosi reiisre eirrerentifoi rroo NBIC frt 1, Tfmoei S2s3-f, S2s3-m, or S2s3-a ror UsSs Csitoofrr snitig or NBIC frt 1, Tfmoei S2.3M-a, S2.3M-b, or S2.3M-c ( for metric units). 2) itefo fot, W in omishr knshrg throsnh the mr- fii ofooe W = A1 K1 C1 where, A1 = internfo fref in iqs ins iqs oog or the i e iize or the mr fii frosne the reiisre-reesainn ofooe K1 = f S2.4 SUPPL. 2 C1 = fot or iftsrftee itefo throsnh f 1 iqs ins 1 iqs oog i e ft ofriosi reiisre eirrerentifoi rroo Tfmoei S2s3-f, S2s3-m, or S2s3-a ror UsSs Csitoofrr snitig or Tfmoei NBIC frt 1, S2s3M-f, S2.3M-b, or S2.3M-c (for metric units). STEAM FLOW WHEN FLOW COEFFICIENTS ARE NOT KNOWN a) It ii oiiimoe thft the f may not be known and in such instances for approximat1 inn the fot, f rfator or 1s3 ofr me ismititstee ror K fne 1s2 ror K1. The formulas in S2.3 then become: W = 1s3 C ror the af faitr throsnh the reiisre-reesainn ofooe; fne W = 1/2 A1 C1 for the capacity through the bypass valve. b) Cfstion ihosoe me exeraiiee then ismititstinn theie rfatori ror the fatsfo aoerfaienti iinae thii oethod will provide approximate values only and the capacities so obtained may in fact be lower than actual. It ii reaoooeneee thft the fatsfo fot aoerfaient me omtfinee rroo the reiisre-reesainn ofooe ofnsrfatsrer fne rererenae mooki me aonisotee ror the fot aoerfaient or the mr fii ofooes S2.5 TWO-STAGE PRESSURE-REDUCING VALVE STATIONS The safety relief valve for two-stage pressure-reducing valve stations shall be sized on the basis of the highiiee reiisre fne the inoet iize or the frit reiisre-reesainn ofooe in the oines Ir fn interoeeifte reiisre oine ii tfken orr metteen the reiisre-reesainn ofooei, then thii oine fne the fnfo oot iiee ihfoo me roteatee mr ifretr reoier ofooei iizee on the mfiii or the hinh-iiee reiisre fne the inoet iize or the frit reiisre-reesainn ofooes See NBIC frt 1, Tfmoe S2s5s --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 6 71 72 1,500 1,000 76,560 950 77,430 900 77,750 850 77,830 800 ∙∙∙∙∙∙ 750 ∙∙∙∙∙∙ 700 ∙∙∙∙∙∙ 650 ∙∙∙∙∙∙ 600 ∙∙∙∙∙∙ 550 ∙∙∙∙∙∙ 500 ∙∙∙∙∙∙ 450 ∙∙∙∙∙∙ 400 ∙∙∙∙∙∙ 350 ∙∙∙∙∙∙ 300 ∙∙∙∙∙∙ 250 ∙∙∙∙∙∙ 200 ∙∙∙∙∙∙ 175 ∙∙∙∙∙∙ 150 ∙∙∙∙∙∙ 110 ∙∙∙∙∙∙ 100 ∙∙∙∙∙∙ 85 ∙∙∙∙∙∙ 75 ∙∙∙∙∙∙ 60 ∙∙∙∙∙∙ 50 ∙∙∙∙∙∙ 40 ∙∙∙∙∙∙ 30 ∙∙∙∙∙∙ 25 ∙∙∙∙∙∙ 15 ∙∙∙∙∙∙ 10 ∙∙∙∙∙∙ 5 ∙∙∙∙∙∙ Where capacitee are Outlet Pressure, psi 72,970 74,180 74,810 74,950 75,070 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ no ehno 1,450 69,170 70,760 71,720 72,160 72,330 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ nr i neo a 1,400 64,950 63,100 68,340 69,130 69,490 69,610 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ n nooneo cn 1,350 60,540 63,100 64,870 66,020 66,700 66,880 66,900 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ nitn 1,300 55,570 58,770 61,040 62,610 63,680 64,270 64,270 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 1,250 SECTION 6 43,930 48,610 52,260 54,930 56,910 58,200 58,820 58,860 58,980 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 1,150 --`,```,```,`,``,-`-`,`,`,`,`--- 49,930 53,920 56,820 58,900 60,390 61,260 61,520 61,550 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 1,200 35,230 42,380 47,050 50,480 53,060 54,840 55,870 56,260 56,270 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 1,100 Pressure-reducing valve inlet pressure, psi SUPPL. 2 25,500 34,890 41,050 45,470 48,800 51,170 52,670 53,480 53,660 53,810 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 1,050 ∙∙∙∙∙∙ 24,910 33,490 39,660 43,980 47,080 49,170 50,440 51,020 51,040 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 1,000 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 23,960 29,080 38,340 42,420 45,230 47,070 48,470 48,470 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 950 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 23,190 31,610 37,110 40,860 43,400 45,010 45,800 45,850 45,870 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 900 2015 NATIONAL BOARD INSPECTION CODE TABLE S2.3-a C CITY OF S TUR TED STE M, IN IBssHRs, ER SQs INs OF I E RE 850 800 750 700 650 SECTION 6 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 17,720 23,290 26,380 27,910 28,140 28,150 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 550 SUPPL. 2 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 18,620 24,630 28,080 29,980 30,690 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 600 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 16,680 21,870 24,570 25,610 25,650 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 500 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 14,790 18,860 21,000 21,350 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 400 350 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 13,630 17,100 18,250 18,250 18,250 18,780 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ --`,```,```,`,``,-`-`,`,`,`,`--- ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 15,760 20,460 22,620 23,200 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 450 Pressure-reducing valve inlet pressure, psi 1,000 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 950 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 900 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 850 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 800 22,550 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 750 30,600 21,800 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 700 35,730 29,420 21,020 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 650 39,200 34,250 28,260 20,190 ∙∙∙∙∙∙ 600 41,500 37,470 32,800 27,090 19,480 550 42,480 39,850 35,730 31,310 25,940 500 43,330 40,530 37,610 33,880 29,760 450 43,330 40,730 38,150 35,260 31,980 400 ∙∙∙∙∙∙ 40,760 38,220 35,680 33,050 350 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 33,120 300 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 33,240 250 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 200 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 175 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 150 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 110 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 100 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 85 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 75 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 60 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 50 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 40 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 30 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 25 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 15 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 10 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 5 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ Where capacitee are no ehno nr i neo a n nooneo cn nitn Outlet Pressure, psi ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 10,800 15,350 16,000 16,200 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 300 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 10,900 12,600 13,400 13,600 13,600 13,600 13,600 13,600 13,630 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 250 NB-23 2015 TABLE S2.3M-a C CITY OF S TUR TED STE M, IN KUsHRs, ER SQs MM OF I E RE 73 74 SECTION 6 --`,```,```,`,``,-`-`,`,`,`,`--- ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 4.50 4.25 4.00 3.75 3.50 3.25 3.00 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 52.78 52.74 52.67 52.55 52.23 51.68 10.00 49.85 49.62 49.27 48.69 47.85 9.5 48.33 47.99 47.51 46.79 45.77 9.25 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 48.60 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 48.62 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 47.24 47.23 47.20 47.11 45.80 46.33 45.71 44.83 43.63 9.00 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 45.89 45.82 45.60 45.14 44.53 43.75 42.69 41.28 8.75 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 44.53 44.52 44.49 44.35 44.00 43.40 42.63 41.67 40.40 38.73 8.5 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 43.15 43.14 43.13 43.02 42.78 42.32 41.56 40.62 39.46 37.95 36.01 8.25 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 41.84 41.82 41.77 41.75 41.55 41.17 40.55 39.62 38.74 37.08 35.30 33.09 8.00 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 40.48 40.46 40.43 40.31 39.98 39.44 38.56 37.51 36.12 34.46 32.33 29.47 7.75 7.50 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 39.14 39.12 39.10 39.08 38.81 38.33 37.62 36.63 35.25 33.59 31.59 29.02 25.37 Pressure-reducing valve inlet pressure, MPa nr i neo a n nooneo cn nitn ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 50.01 50.00 49.97 69610 48.53 51.32 51.19 50.96 50.52 49.82 9.75 Where capacitee are no ehno ∙∙∙∙∙∙ 54.20 5.50 4.75 54.19 5.75 ∙∙∙∙∙∙ 54.15 6.00 ∙∙∙∙∙∙ 54.07 6.25 5.25 53.87 6.50 5.00 53.44 6.75 Outlet Pressure, 10.25 MPa SUPPL. 2 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 37.88 37.82 37.74 37.63 37.22 36.57 35.68 34.48 32.82 30.83 28.43 25.31 20.89 7.25 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 36.48 36.45 36.33 36.07 35.50 34.64 33.52 32.05 30.04 27.53 24.45 20.46 ∙∙∙∙∙∙ 7.00 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 35.13 35.12 34.90 34.41 33.64 32.56 31.16 29.37 26.20 23.13 19.36 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 6.75 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 33.81 33.76 33.39 32.65 31.66 30.01 28.59 26.41 21.90 17.64 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 6.50 ∙∙∙∙∙∙ 32.48 32.47 32.45 32.15 31.60 30.76 29.51 27.84 25.72 23.01 18.76 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 6.25 2015 NATIONAL BOARD INSPECTION CODE TABLE S2.3-b C CITY OF S TUR TED STE M, IN IBssHRs, ER SQs INs OF I E RE ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 0.90 0.80 0.70 0.60 0.50 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 3.25 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 3.00 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 2.75 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 2.50 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ SECTION 6 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 9.55 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 2.25 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 8.75 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 2.00 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 13.66 12.35 11.03 14.97 13.60 12.30 11.02 14.96 13.44 12.19 11.00 15.92 14.95 12.98 11.75 10.62 17.05 15.90 14.84 12.12 10.46 19.58 18.30 17.03 15.79 14.59 12.54 SUPPL. 2 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 23.46 22.17 20.87 19.57 18.28 16.85 15.26 13.48 10.95 23.42 22.15 20.83 19.45 17.94 16.18 14.11 11.59 23.37 22.05 20.62 19.04 17.19 14.94 11.83 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ nr i neo a n nooneo cn nitn ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 28.58 27.28 25.98 24.68 23.34 21.79 20.09 18.19 15.90 12.98 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 0.40 ∙∙∙∙∙∙ 0.30 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ Where capacitee are no ehno ∙∙∙∙∙∙ ∙∙∙∙∙∙ 2.25 1.00 ∙∙∙∙∙∙ 2.50 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 2.75 1.25 31.19 29.88 28.56 27.25 25.86 24.40 22.82 20.98 18.90 16.51 13.46 3.00 ∙∙∙∙∙∙ 31.18 29.86 28.49 27.10 25.53 23.81 21.95 19.73 17.12 13.72 3.25 1.50 31.15 29.77 28.32 26.74 24.90 22.87 20.68 17.93 14.24 3.50 ∙∙∙∙∙∙ 30.99 29.49 27.95 25.92 23.77 21.42 18.76 15.23 3.75 ∙∙∙∙∙∙ 30.49 28.74 26.86 24.59 22.06 19.18 15.75 4.00 2.00 ∙∙∙∙∙∙ 29.71 27.67 25.44 22.83 19.75 15.63 4.25 1.75 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 28.64 26.30 23.70 20.58 16.54 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 4.50 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 3.50 27.06 24.31 21.18 17.17 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 3.75 4.75 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 4.00 24.96 21.60 17.50 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 4.25 5.00 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 4.50 22.24 17.25 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 4.75 5.25 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 5.00 18.66 ∙∙∙∙∙∙ 5.25 5.50 ∙∙∙∙∙∙ 5.50 ∙∙∙∙∙∙ 5.75 Pressure-reducing valve inlet pressure, MPa 5.75 Outlet Pressure, 6.00 MPa 9.72 ∙∙∙∙∙∙ 9.70 9.70 9.70 9.70 9.67 9.60 8.75 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 1.75 NB-23 2015 TABLE S2.3M-b C CITY OF S TUR TED STE M, IN KUsHRs ER MM2 OF I E RE --`,```,```,`,``,-`-`,`,`,`,`--- 75 76 Outlet Pressure-Reducing Valve Inlet Pressure pres., 200 175 150 125 100 85 75 60 psi 1,000 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 950 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 900 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 850 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 800 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 750 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 700 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 650 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 600 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 550 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 500 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 450 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 400 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 350 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 300 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 250 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 200 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 175 7,250 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 150 9,540 6,750 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 125 10,800 8,780 6,220 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 110 11,000 9,460 7,420 4,550 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 100 11,000 9,760 7,970 5,630 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 85 11,000 ∙∙∙∙∙∙ 8,480 6,640 4,070 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 75 11,000 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 7,050 4,980 3,150 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 60 11,000 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 7,200 5,750 4,540 3,520 ∙∙∙∙∙∙ 50 11,000 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 5,920 5,000 4,230 2,680 40 11,000 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 5,140 4,630 3,480 30 11,050 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 3,860 25 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 15 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 10 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 5 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ Where capacitee are no ehno nr i neo a n nooneo cn nitn --`,```,```,`,``,-`-`,`,`,`,`--- SUPPL. 2 40 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 2,210 2,580 2,830 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 50 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 2,470 3,140 3,340 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 1,485 2,320 ∙∙∙∙∙∙ ∙∙∙∙∙∙ 30 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 1,800 2,060 ∙∙∙∙∙∙ 25 2015 NATIONAL BOARD INSPECTION CODE TABLE S2.3-c C CITY OF S TUR TED STE Ms INssHRs ER IN2 OF THE I E RE SECTION 6 7.78 8.15 8.34 8.38 8.38 8.38 8.38 8.38 8.41 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 1,000.00 900.00 800.00 700.00 600.00 500.00 400.00 300.00 200.00 100.00 80.00 60.00 40.00 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 7.08 7.06 6.77 6.25 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 5.78 5.77 5.65 5.21 4.29 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 1,000.00 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 5.26 5.19 4.87 4.22 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 900.00 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 4.74 4.71 4.48 3.82 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 4.22 4.13 3.68 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 700.00 SUPPL. 2 800.00 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 3.69 3.66 3.37 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 600.00 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 2.64 2.62 3.71 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 400.00 3.01 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 500.00 Pressure-reducing valve inlet pressure, kPa nr i neo a n nooneo cn nitn 1,250.00 Where capacitee are no ehno ∙∙∙∙∙∙ 1,250.00 Outlet Pressure, 1,500.00 kPa ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 2.12 1.83 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 300.00 ∙∙∙∙∙∙ 1.60 1.58 1.56 ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ ∙∙∙∙∙∙ 200.00 NB-23 2015 TABLE S2.3M-c C CITY OF S TUR TED STE M, IN KUsHRs, ER MM2 OF I E RE --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 6 77 2015 NATIONAL BOARD INSPECTION CODE TABLE S2.5 I ED T (15) Nominal Pipe Size, Unitless Nominal Pipe Size, Unitless (US (SI Metric) Customary) Average Outside Diameter Average Outside Diameter (D) (D) SUPPL. 2 ASME B36.10M Nominal Nominal Wall Wall Approximate Approximate Thickness Thickness Internal Area Internal Area Standard Standard (Note 1) Weight Pipe Weight Pipe (Note 1) (t) (t) Unitless Unitless in. mm in. mm in2 mm2 NPS 3/8 DN 10 0.675 17.1 0.091 2.31 0.191 122 NPS 1/2 DN 15 0.840 21.3 0.109 2.77 0.304 195 NPS 3/4 DN 20 1.050 26.7 0.113 2.87 0.533 345 NPS 1 DN 25 1.315 33.4 0.133 3.38 0.864 557 NPS 1-1/4 DN 32 1.660 42.2 0.140 3.56 1.496 967 NPS 1-1/2 DN 40 1.900 48.3 0.145 3.68 2.036 1,316 NPS 2 DN 50 2.375 60.3 0.154 3.91 3.356 2,163 NPS 2-1/2 DN 65 2.875 73.0 0.203 5.16 4.788 3,086 NPS 3 DN 80 3.500 88.9 0.216 5.49 7.393 4,769 NPS 3-1/2 DN 90 4.000 101.6 0.226 5.74 9.887 6,379 NPS 4 DN 100 4.500 114.3 0.237 6.02 12.73 8,213 NPS 5 DN 125 5.563 141.3 0.258 6.55 20.00 12,908 NPS 6 DN 150 6.625 168.3 0.280 7.11 28.89 18,646 NPS 8 DN 200 8.625 219.1 0.332 8.18 49.78 32,283 NPS 10 DN 250 10.750 273.0 0.365 9.27 78.85 50,854 NPS 12 DN 300 12.750 323.8 0.375 9.53 113.1 72,937 Note 1: In applying these rules, the area of the pipe is always based upon standard weight pipe and the inlet size of the pressure-reducing valve. Where: D = outside diameter of the pipe and t = nominal wall of the pipe (15) 㿽0001 = --`,```,```,`,``,-`-`,`,`,`,`--- 78 SECTION 6 −2 4 ! NB-23 2015 SUPPLEMENT 3 INSTALLATION OF LIQUID CARBON DIOXIDE STORAGE VESSELS S3.1 SCOPE Thii is oeoent rooieei reqsireoenti ror the initfooftion or Liqsie Cfrmon Dioxiee Storfne Veiieoi LCDSVig, foo moxei, fo iriteoi, itiooinn ooo H aontroo iriteoi, fne other foo in ofae iriteoi itorinn 1,000 omi 454 kng or oeii or oiqsie CO2. S3.2 GENERAL REQUIREMENTS STORAGE TANK LOCATION LCDSVi ihosoe me initfooee in fn snenaooiee fref theneoer oiiimoes LCDSVi thft eo not oeet foo ariterif for an unenclosed area shall be considered an enclosed area installation. An unenclosed area: c) Shall be outdoors; --`,```,```,`,``,-`-`,`,`,`,`--- d) Shall be above grade; and e) Shall not obstruct more than three sides of the perimeter with supports and walls. At least 25% of the perimeter area as calculated from the maximum height of the storage container shall be open to atmosphere and openings shall be in direct conveyance with ground level. S3.2.1 GENERAL REQUIREMENTS (ENCLOSED AND UNENCLOSED AREAS) SUPPL. 3 a) LCDSVi ihfoo not me ooaftee tithin 10 reet 3,050 oog or eoeoftori, sn roteatee oftroro oeenei, or other areas where falling would result in dropping distances exceeding half the container height. b) LCDSVi ihfoo me initfooee tith isrfaient aoefrfnae ror fooinn, o erftion, ofintenfnae, ini eation, fne replacement. c) Orientftion or nozzoei fne fttfahoenti ihfoo me isah thft isrfaient aoefrfnae metteen the nozzoei, attachments, and the surrounding structures is maintained during the installation, the attachment of associated piping, and operation. d) LCDSVi ihfoo not me initfooee on rooris e) LCDSVi ihfoo me ifreor is ortees Veiieo is orti, rosneftioni, fne iettinni ihfoo me in faaorefnae tith jsriieiationfo reqsireoenti, ofnsrfatsrer reaoooeneftioni fnesor other inesitrr itfnefrei fi f oiafmoes The teinht or the oeiieo then rsoo or oiqsie afrmon eioxiee ihfoo me aoniieeree then eeiinninn oeiieo is ortis Deiinn or is orti, rosneftioni, fne iettinni ihfoo aoniieer oimrftion inaoseinn seismic and wind loads where necessary), movement (including thermal movement), and loadings. Veiieo rosneftioni or foori in osotiitorr msioeinni osit me af fmoe or is ortinn the rsoo iriteo teinht and in accordance with building codes. f) LCDSVi ihfoo not me initfooee tithin 36 ins 915 oog or eoeatriafo fneois g) LCDSVi initfooee osteoori in frefi in the oiainitr or oehiasofr trfrfa ihfoo me nsfreee to reoent faaidental impact by vehicles. The guards or bollards shall be installed in accordance with local building codes or to a national recognized standard when no local building code exists. h) LCDSVi ihfoo me eqsi ee tith iiooftion ofooei in faaorefnae tith frfnrf h NBIC frt 1, S3s6s SECTION 6 79 2015 NATIONAL BOARD INSPECTION CODE S3.2.2 UNENCLOSED AREA LCDSV INSTALLATIONS Ir LCDSVi fre initfooee osteoori fne ex oiee to the eoeoenti, f ro rifte feeitionfo roteation ofr me rovided as necessary based on the general weather conditions and temperatures that the tank may be exposed to. Some possible issues include: a) Exposure to high solar heating loads will increase the net evaporation rate and will decrease hold times in oot CO2 usage applications. The vessel may be covered or shade provided to help reduce the solar load and increase the time needed to reach the relief valve setting in low use applications. b) Ir is or oine ii not UV reiiitfnt then the is covering. S3.2.3 a) or oine ihosoe me roteatee oif aonesit or f ro rifte ENCLOSED AREA LCDSV INSTALLATIONS erofnent LCDSV initfooftioni tith reoote foo aonneationid 1) Shfoo me eqsi ee tith f nfi eeteation iriteo initfooee in faaorefnae tith NBIC frt 1, S3s4; 2) Shfoo hfoe iinnfne oitee in faaorefnae tith NBIC frt 1, S3s5; fne 3) Shfoo me eqsi ee tith foo moxei; foo oinei fne ifretr reoiersoent ofooe airasiti initfooee in faaorefnae tith NBIC frt 1, S3s6s b) ortfmoe LCDSV initfooftioni tith no erofnent reoote foo aonneationd Warning: LCDSVs shall not be fllee ieddor do i einldree oe r ieeo in n on urs iners inr u rs ll nr be udoee sd she d sr ee sd i ieinldree, foee of SUPPL. 3 1) Shfoo me eqsi ee tith f nfi eeteation iriteo initfooee in faaorefnae tith NBIC frt 1, S3s4; 2) Shfoo hfoe iinnfne oitee in faaorefnae tith NBIC frt 1, S3s5; 3) Shall have a safety relief/vent valve circuit connected at all times except when the tank is being reoooee ror fooinns Conneati ofr me fttee tith qsiak eiiaonneat fttinni oeetinn the reqsireoenti or NBIC frt 1, S3s6; fne --`,```,```,`,``,-`-`,`,`,`,`--- 4) Shall be provided with a pathway that provides a smooth rolling surface to the outdoor, unenclosed f S3.3 FILLBOX LOCATION / SAFETY RELIEF/VENT VALVE CIRCUIT TERMINATION Fioo moxei fnesor oent ofooe teroinftioni ihfoo me initfooee fmooe nrfee, osteoori in fn snenaooiee, rree firfot frefs The foo aonneation ihfoo me ooaftee io not to io eee oefni or enreii or the o erftion or iieetfok aeoofr entrance doors, including during the delivery process and shall be: 1) t oefit 36 ins 915 oog rroo fnr eoor or o erfmoe tineoti; 2) t oefit 36 ins 915 oog fmooe nrfee; 3) Shall not be located within 10 ft. (31 m) from side to side at the same level or below, from any air intakes; and 4) Shall not be located within 10 ft. (31 m) from stairwells that go below grade. S3.4 (15) 80 GAS DETECTION SYSTEMS Rooms or areas where carbon dioxide storage vessel(s) are located indoors or in enclosed or below grade outdoor locations shall be provided with a gas detection and alarm system for general area monitoring that SECTION 6 NB-23 2015 ii af fmoe or eeteatinn fne notirrinn msioeinn oaas fnti or f CO2 gas release. Alarms will be designed to fatiofte f oot oeoeo re-fofro ft 5,000 o aonaentrftion or CO2 and a full high alarm at 30,000 ppm concentrftion or CO2 thiah ii the NIOSH & CUIH 15 oinste Short Tero Ex oisre Lioit ror CO2. These systems are not designed for employee personal exposure monitoring. Gas detection systems shall be installed and teitee in faaorefnae tith ofnsrfatsrer’i initfooftion initrsationi fne the rooootinn reqsireoentid a) Activation of the gas detection system shall activate an audible alarm within the room or area in which the carbon dioxide storage vessel is located. b) Audible alarms shall also be placed at the entrance(s) to the room or area where the carbon dioxide itorfne oeiieo fnesor foo mox ii ooaftee to notirr fnrone tho oinht trr to enter the fref or f otentifo problem. S3.5 SIGNAGE SUPPL. 3 FIGURE S3.5 CO2 W RNINU SIUN Warning signs shall be posted at the entrance to the building, room, enclosure, or enclosed area where the container is located. The warning sign shall be at least 8 in. (200 mm) wide and 6 in. (150 mm) high. The toreinn ihfoo me aonaiie fne efir to refe fne the s er ortion or the iinn osit me orfnne fi ihotn in fnsre NBIC frt 1, S3s5s The iize or the oetterinn osit me fi ofrne fi oiiimoe ror the inteneee oietinn eiitfnae fne in faaorefnae tith jsriieiationfo reqsireoentis When no jsriieiationfo reqsireoenti exiit, the oinioso oetter heinht ihfoo me in faaorefnae tith NEM oeriafn Nftionfo Stfnefre ror Enoironoentfo fne Ffaioitr Sfretr Sinni NSI Z535s2gs The tfrninn iinn ihfoo me fi ihotn in Finsre S3s5s (15) --`,```,```,`,``,-`-`,`,`,`,`--- Additional instructional signage shall be posted outside of the area where the container is located and such signage shall contain at minimum the following information: SECTION 6 81 2015 NATIONAL BOARD INSPECTION CODE a) Cfrmon Dioxiee Monitori ror nenerfo fref oonitorinn not eo ooree erionfo ex oisre oonitorinng are provided in this area. These monitors are set to alarm at 5,000 ppm for the low level alarm and at 30,000 ppm for high level alarm. b) Lot Leoeo ofro 5,000 og – rooiee f ro rifte aroii oentioftion to the frefs erionneo ofr enter area for short periods of time (not to exceed 15 minutes at a time) in order to identify and repair potential leaks. c) Hinh Leoeo ofro 30,000 og – erionneo ihosoe eofasfte the fref fne nomoer ihosoe enter the frreatee fref tithost ro er ieor-aontfinee mrefthinn f frftsi sntio the fref ii feeqsfteor oentioftee fne the aonaentrftion or CO2 is reduced below the high alarm limit. S3.6 VALVES, PIPING, TUBING, AND FITTINGS --`,```,```,`,``,-`-`,`,`,`,`--- a) Materials – Mfterifoi ieoeatee ror ofooei, i inn, tsminn, hoiei, fne f ihfoo oeet rooootinn reqsireoentid 1) Coo onenti osit me aoo ftimoe ror sie tith CO2 in the hfie nfi, or oiqsie in the f circuit) it encounters in the system. oiafmoe 2) Coo onenti ihfoo me rftee ror the o erftionfo teo erftsrei fne reiisrei enaosnteree in the applicable circuit of the system. 3) Shfoo me itfinoeii iteeo, ao er, mrfii, or ofitias ooroer ofterifoi rftee ror CO2. SUPPL. 3 4) Onor fttinni fne aonneationi reaoooeneee mr the ofnsrfatsrer ihfoo me siee ror foo hoiei, tsmei, and piping. 5) oo ofooei fne fttinni siee on the LCDSV ihfoo me rftee ror the ofxioso foootfmoe torkinn reisure stamped on the tank. 6) oo i inn, hoiei, fne tsminn siee in the LCDSV iriteo ihfoo me rftee ror the torkinn reiisre or the applicable circuit in the system and have a burst pressure rating of at least four times the maximum allowable working pressure of the piping, hose, or tubing. b) Rel ef V loer – Efah LCDSV ihfoo hfoe ft oefit one SMEsNB itfo ee & aertif reiisre iettinn ft or meoot the M W or the tfnks The reoier ofooe ihfoo me isitfmoe ror the teo erftsrei fne foti ex erienaee esrinn reoier ofooe o erftions The oinioso reoier ofooe af faitr ihfoo me eeiinnftee mr the ofnsrfatsrers eeitionfo reoier ofooei thft eo not reqsire SME itfo i ofr me feeee er reaoooeneftioni in Coo reiiee Ufi iioaiftion fo hoet, CU S-1s3 reiisre Reoier Deoiae Stfnefrei frt 3, Stftionfrr Storfne Contfineri ror Coo reiiee Ufieis Diiahfrne oinei rroo the reoier ofooei ihfoo me iizee in faaorefnae tith tfmoei NBIC frt 1, S3s6-f fne S3s6-ms Note: Dse to the eeiinn or the LCDSV, the eiiahfrne oine ofr me iofooer in eifoeter thfn the reoier ofooe outlet size. C s did Coo fniei fnesor ineioiesfoi fooinn or refooinn LCDSVi ihfoo me rei oniimoe ror stioizinn foo eqsi oent thft ii faae tfmoe to the ofnsrfatsrer to reoent ooer reiisrizftion or the oeiieos c) Irdl s di V loer – Efah LCDSV ihfoo hfoe fn iiooftion ofooe initfooee on the foo oine fne tfnk eiiahfrne, or nfi is or oine in faaorefnae tith the rooootinn reqsireoentid 1) Iiooftion ofooei ihfoo me ooaftee on the tfnk or ft fn faaeiiimoe oint fi nefr to the itorfne tfnk as possible. 2) All valves shall be designed or marked to indicate clearly whether they are open or closed. 3) All valves shall be capable of being locked or tagged in the closed position for servicing. 82 SECTION 6 NB-23 2015 4) Ufi Ss or fne Liqsie CO2 Fioo Vfooei ihfoo me aoefror ofrkee ror efir ieentifaftions d) S fesn Rel ef/Veis L ier – Sfretr reoiersoent oinei ihfoo me fi ihort fne itrfinht fi oiiimoe tith a continuous routing to an unenclosed area outside the building and installed in accordance with the manurfatsrer’i initrsationis The oent oine ig ihfoo me f aontinsosi rsn rroo the oeiieo reiisre reoier eeoiae oent i inn to the ostiiee oent oine eiiahfrne fttinns Meahfniafo jointi in oetfooia i inn fne tsminn ihfoo be visible and inspectable. Any splices in plastic or polymeric tubing shall be done within three feet of the vessel and must be visible and inspectable. These lines shall be free of physical defects such fi arfakinn or kinkinn fne foo aonneationi ihfoo me ieasreor rfitenee to the LCDSV fne the foo moxs All safety relief/vent lines shall be protected to prevent penetration by nail, projectile, or other foreign omjeat then rostee throsnh f tfoo, foor, or aeioinns The oinioso iize fne oennth or the oinei ihfoo me in faaorefnae tith NBIC frt 1, Tfmoei S3s6-f fne S3s6-ms Fittinni or other aonneationi ofr reisot in f ooafoizee reesation in eifoeter hfoe meen rfatoree into the oennthi nioen mr the NBIC frt 1, Tfmoei S3.6-a and S3.6-b. (15) Note: Dse to the eeiinn or the LCDSV, the eiiahfrne oine ofr me iofooer in eifoeter thfn the reoier ofooe ostoet iize mst ihfoo not me iofooer thfn thft ihotn in NBIC frt 1, Tfmoei S3s6-f fne S3s6-ms S3.6.1 SYSTEM DESCRIPTION SUPPL. 3 The Liqsie Cfrmon Dioxiee Beoerfne iriteoi inaosee the Liqsie Cfrmon Dioxiee Storfne Veiieo or LCDSV tfnkg fne fiioaiftee ism-iriteo airasiti - Liqsie CO2 foo airasit, fne fiioaiftee ism-iriteo airasiti fne reiisre reoier s oent oine airasits The LCDSVi fre ofasso inisoftee reiisre oeiieoi, aonitrsatee or itfinoeii iteeo, tith Ss er Inisoftion trf inn metteen the inner reiisre oeiieo fne the oster ofasso jfakets See Finsre S3s6s1-fg Theie reiisre oeiieoi fre tr iafoor eeiinnee ror f ofxioso foootfmoe torkinn reiisre M W g or either 300 iin 2,068 k fg or 283 iin 1,951 k fgs The LCDSV aooe eqsi ee tith fn SMEsNB aertifee “UV” riofrr Reoier Vfooe RVg iet ft or meoot the M W or the oeiieos eeitionfoor, fi reaoooeneee mr the Coo reiiee Ufi iioaiftion fo hoet CU S-1s3, RESSURE RELIEF DEVICE ST ND RDS RT 3 - ST TION RY STOR UE CONT INERS FOR COM RESSED U SSESg f ieaonefrr reoier ofooe ofr me initfooees Thii ieaonefrr reoier ofooe ii merone the iao e or SME Seation VIII, Dioiiion 1 fne ii not reqsiree to me SMEsNB itfo ee fne aertifees Thii feeitionfo RV ii tr iafoor rftee no hinher thfn 1s5 tioei the oeiieo M W s Operating conditions of the system, components, and inner pressure vessel can vary causing temperatures fne reiisrei to rfnne rroo 90 iin -56°Fg to 300 iin +2°Fg {620 k f -49°Cg to 2,068 k f -16°Cg}s Beoot fmost 60 iin 413 k fg in the tfnk, oiqsie CO2 menini ahfnninn to iooie hfie err iaegs Ir the tfnk meaooei aoo oeteor ee reiisrizee to 0 iin, teo erftsrei iniiee the tfnk aosoe refah -109°F -78°Cg, iooie err iaegs When oiqsie CO2 tsrni to iooie err iae in f aoo oeteor ee reiisrizee tfnk, foo CO2 nfi fot in the iriteo ceases and the tank becomes nonfunctional. See the fttfahee CO2 hfie Difnrfo NBIC frt 1; Finsre S3s6s1-m, ihotinn the tr iafo o erftinn rfnne or theie iriteois Coo onenti externfo to the LCDSV inner tfnk reiisre oeiieo ofr enaosnter reiisrei fne teo erftsrei metteen 90 iin, fne -56°F to 300 iin fne +2°F, rei eatioeor {metteen 620 k f, fne -49°C to 2,068 k f fne -16°C, rei eatioeor}sTr iafo o erftinn reiisrei fne teo erftsrei ofrr in efah or the fiioaiftee ism-iriteo airasitis See NBIC frt 1, Tfmoe S3s6s1-mg TABLE S3.6.1 TY IC L O ER TINU RESSURES & TEM ER TURES OF LCDSV SYSTEMS System Component Operat Sonrage Veeeen (oa k i oer an cn nitn es 90 – 300 peig -56°F on +2°F Liqoin CO2 Finn Li e 150 – 300 peig -34°F on +2°F Preeeore Renie Gae Ve o Li e 0 – 120 peig Ambie o on -50°F --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 6 83 2015 NATIONAL BOARD INSPECTION CODE FIGURE S3.6.1-a Pressure Guage SUPPL. 3 ASME Code Inner Vessel Outer Vacuum Jacket 84 SECTION 6 Vent Circuit Pressure Relief Valves Liquid to Gas Conversion Coils --`,```,```,`,``,-`-`,`,`,`,`--- Liquid CO2 Fill Circuit NB-23 2015 FIGURE 3.6.1-b CO2 H SE DI UR M Liquid Solid 300 psig 125 psig Typical Micro-Bulk CO2 System, Normal Operating Conditions Inside of Vessel Triple Point Gas (Point at which CO2 exists simultaneously as liquid, solid & gas) -140 -100 -60 -20 -69.83 -42°F Temperature 20 +2° 60 87 SUPPL. 3 Pressure (psig) 60.4 psig TABLE S3.6-a MINIMUM LCDSV SYSTEM RELIEF s VENT LINE REQUIREMENTS MET LLICg Tank Size (Pounds) Fire Flow Rate Requirements (Pounds per Minute) Maximum length of 3/8 inch ID Metallic Tube Allowed Maximum length of 1/2 inch ID Metallic Tube Allowed Leee oha 500 2.60 maximom 80 eeo 100 eeo 500 - 750 3.85 maximom 55 eeo 100 eeo Over 750 – 1,000 5.51 maximom 18 eeo 100 eeo --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 6 85 2015 NATIONAL BOARD INSPECTION CODE TABLE S3.6-b MINIMUM LCDSV SYSTEM RELIEF s VENT LINE REQUIREMENTS L STICs OLYMERg Tank Size (Pounds) Fire Flow Rate Requirements (Pounds per Minute) Maximum length of 3/8 inch ID plastccppllyer Tube Allowed Maximum length of 1/2 inch ID plastccppllyer Tube Allowed Leee oha 500 2.60 maximom 100 eeo 100 eeo 500 - 750 3.85 maximom 100 eeo 100 eeo Over 750 – 1,000 5.51 maximom N/A eee 1/2 i ch 100 eeo TABLE S3.6M-a METRIC MINIMUM LCDSV SYSTEM RELIEF s VENT LINE REQUIREMENTS MET LLICg Tank Size (kg) Fire Flow Rate Requirements (kg per Minute) Maximum length of 10 mm ID Metallic Tube Allowed Maximum length of 13 mm ID Metallic Tube Allowed Leee oha 227 1.18 maximom 24 eeo 30.5 m 227 - 340 1.75 maximom 17 eeo 30.5 m Over 340 - 454 2.5 maximom 5.5 eeo 30.5 m TABLE S3.6M-b SUPPL. 3 METRIC MINIMUM LCDSV SYSTEM RELIEF s VENT LINE REQUIREMENTS L STICs OLYMERg Tank Size (kg) Fire Flow Rate Requirements (kg per Minute) Maximum length of 10 yy ID plastccppllyer Tube Allowed Maximum length of 13 yyID plastccppllyer Tube Allowed Leee oha 227 1.80 maximom 30.5 m 30.5 m 227 - 340 1.75 maximom 30.5 m 30.5 m Over 340 - 454 2.50 maximom N/A eee 13 mm 30.5 m Note: Dse to the eeiinn or the LCDSV, the eiiahfrne oine ofr me iofooer in eifoeter thfn the reoier ofooe ostoet iize mst ihfoo not me iofooer thfn thft ihotn in tfmoei NBIC frt 1, S3s6-f fne -ms --`,```,```,`,``,-`-`,`,`,`,`--- 86 SECTION 6 NB-23 2015 SUPPLEMENT 4 INSTALLATION OF BIOMASS (WOOD/SOLID FUEL) FIRED BOILERS S4.1 Thii is f S4.2 SCOPE oeoent rooieei reqsireoenti ror the initfooftion or mioofii tooesiooie rseog free moioeri as de- (15) PURPOSE a) The sr oie or theie rsoei ii to eitfmoiih oinioso reqsireoenti ror the initfooftion or mioofis boilers. (15) b) It ihosoe me reaonnizee thft ofnr or the reqsireoenti inaoseee in theie rsoei osit me aoniieeree in the design of the boiler by the manufacturer. However, the owner-user is responsible for ensuring that the initfooftion aoo oiei tith foo the f oiafmoe reqsireoenti aontfinee hereins Fsrther, the initfooer is responsible for complying with the applicable sections when performing work on the behalf of the owner-user. c) Thii is oeoent rooieei reqsireoenti ror the initfooftion fne aontroo or moioeri thiah sie mioofii fi a major fuel component and will address the differences that occur when solid fuels, such as biomass, are being used. Thus the primary thrust of this section will be directed toward the control of the fuel handling and distribution systems. e) eeitionfoor, the eoiiiioni aontroo eqsi oent ii eeiinnee frosne the initifo rseo i eaifaftions nr ahfnnei in rseo free tioo io fat on the errorofnae or the ofriosi eoeoenti or the eoiiiioni aontroo system. f) Bioofii moioeri fne moioer roooi reqsire feeitionfo aoniieerftioni thfn trfeitionfoor rseoee moioeri thft may include: SUPPL. 4 d) Fseoi tioo ofrr tieeor ee eneinn s on iosrae, ooiitsre aontent, frtiaoe iize, fne eiitrimstion; hoteoer, onae the rseo hfi meen eitfmoiihee, the otner-sier ihosoe fehere to the orininfo i eaifaftion fi closely as possible in order to minimize handling, combustion, and emissions problems. 1) Trfni ortftion or the rseo rroo f itorfne rfaioitr to f oeterinn eeoiae tithin the eqsi oent rooo; 2) Transportation of the metered fuel to the boiler for distribution to a combustion system whether it be f nrfte s on thiah the aoomsition tfkei ofae, f msmmoinn fsieizee mee, airasoftinn fsieizee mee or suspension burner; 3) In nrfte mfiee aoomsition iriteoi aoomsition fir ii tr iafoor eioieee into fn sneerfre fir iriteo fne fn ooerfre fir iriteo, efah or thiah osit me aooieor aontroooee in oreer to roesae aoefn, erf 4) Inesaee erfrt rfni to ooeraooe the reiisre ero or the eoiiiioni aontroo eqsi oent; 5) 6) S4.3 fr fih or afrmoni rearaoe iriteo, to retsrn snmsrnee afrmon to the aoomsition zone; fne n fih reooofo iriteo, to oooe fih rroo the moioer fne eoiiiioni aontroo eqsi oent to isitfmoe cooling and storage area. DETERMINATION OF ALLOWABLE OPERATING PARAMETERS The allowable operating parameters of the combustion side shall be installed in accordance with jurisdictionfo fne enoironoenti reqsireoenti, ofnsrfatsrer’i reaoooeneftioni, fnesor inesitrifo itfnefrei, fi applicable. --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 6 (15) 87 2015 NATIONAL BOARD INSPECTION CODE S4.4 (15) a) GENERAL REQUIREMENTS oter moioeri stioizinn mioofii fi the riofrr rseo iosrae ihfoo oeet the reqsireoenti or NBIC frt 1, Section 2 and this supplement. b) Steam heating, hot water heating, and hot water supply boilers utilizing biomass as the primary fuel iosrae ihfoo oeet the reqsireoenti or NBIC frt 1, Seation 3 fne thii is oeoents S4.5 (15) FUEL SYSTEM REQUIREMENTS AND CONTROLS a) Fseo Trfni ort Sriteoi ihfoo feereii reieroinn rseo frtiaoe iize eiitrimstion, fre reoention, fne the is reiiion or frei or ex ooiionis In f iinnoe initfooftion, ofriosi tr ei or rseo trfni ortftion iriteoi may co-exist. The most common systems are: 1) Conoeror iriteoi – In theie iriteoi rseo ii ero ee onto f oooinn meot, msaket eoeoftor, erfn link conveyor, or a screw or auger mechanism. Speed of the conveyor may be varied to meet fuel demand. 2) Lefn hfie nesoftia iriteoi – In theie iriteoi rseo ii ero ee into f oooinn firitrefo, oixei with the air, and travels through a pipe at a velocity of approximately 5,000 ft/min (1,525 m/min). Air pressures are in the region of 25 inches (635 mm) water column. SUPPL. 4 3) Denie hfie nesoftia iriteoi – n interoittent or mftah reee iriteo, in thiah rseo ii ero ee throsnh f ofooe eooe ofooeg into f reiisre oeiieos When the oeiieo ii fooee, the ofooe ii aooiee, fir ft f reiisre metteen 30 to 100 iin 200 to 700 k fg ii feoittee fne the rseo oefoei the oeiieo in the roro or f “iosn”s The ieqsenae then re eftis Note thft theie iriteoi fre foio siee ror fih handling.) 1) Vfrifmoe i eee fsneri a. Vfrifmoe i eee, heoiafoor finhtee, fsneri afn me ooaftee in the mottoo or f rseo oeterinn mins oternftioeor, ther aosoe me f frt or f retort tr e itokers The fsner eioeniioni, finhtinn, fne speed range are selected on the basis of fuel being burned, its size range, heating value, and reqsiree moioer tsrneotn rfnnes The oeteree rseo tr iafoor ii then ero ee into the throft or f oentsri or in iooe afiei f ofin i eg thosnh thiah the rseo trfni ort fir foti to afrrr the rseo into the boiler combustion zone, for distribution on a grate, upon which the burning of the fuel takes place. 2) Vfrifmoe i eee fir-ooak ofooei a. This valve is basically a rotating slotted cylinder, operating within an outer cylinder, suitably iefoee to reoent oefkfnes Rotftionfo i eee fne ioot eioeniioni afn me ofriee to faaooooefte ahfnnei in rseo fot rftes The rseo fiiinn throsnh the ofooe, tr iafoor, ii ee oiitee onto f moving grate type stoker. 3) Vfrifmoe itroke rfoi a. This is another device that can be located on the bottom of a metering bin, is typically used on smaller units, and is essentially a batch feed mechanism. The stroke of the ram is adjusted to iet rseo f 88 SECTION 6 --`,```,```,`,``,-`-`,`,`,`,`--- b) Fseo Trfni ort Sooie Fseo Meterinn Sriteoi ofrr ee eneinn s on the rseo siee fne the frtiaoe iize distribution. These metering systems include but are not limited to: NB-23 2015 COMBUSTION REQUIREMENTS a) Ooerfre irsUneerfr When iooie rseoi fre msrnee on f nrfte, rfther thfn in fsieizee mee sniti or in isi eniion, it ii normal practice to introduce some of the combustion air under the grate, or bed, and the remainder over the mees In ofnr afiei rseo trfni ort fir meaooei f frt or the ooer-the-mee aoomsition firs The ro ortioninn or the ooerfre to sneerfre firfot rftei ii ee eneent s on ieoerfo rfatori, isah fi rseo frtiaoe iize, rseo eeniitr, msrn rfte fne oooftioeis In nenerfo the omjeatioe ii to net fi aoo oete f msrn on the nrfte fi oiiimoe, tithost areftinn ofrne qsfntitiei or frtiasofte eoiiiioni, fne then siinn the ooerfre air to complete burning of the volatile and small particulate matter, leaving the fuel bed. (15) --`,```,```,`,``,-`-`,`,`,`,`--- S4.6 c) ronrfooinn Controoi ronrfooinn aontrooi ofr me reofr mfiee, or on oore asrrent sniti, ronrfoofmoe oonia aontroooer LCg mfiees Interfatioe nrf hiai eii ofri ofr foio me inaor orftee into the iriteos aaeii to LC mfiee aontrooi fne interfatioe nrf hia eii ofri ihfoo me oioitee to qsfoifee ineioiesfoi fne fiitore roteatees LC rsnationi ihfoo me aonfnee to the norofo moioer o erftinn oonia, aooerinn itfrts , interooaki, fne norofo ihsteotn ieqsenaeis LC oonia ihfoo not interrere tith, or ooer-riee ifretr aontrooi, thiah afsie moioer ifretr ihsteotn then fatioftees The LC oonia ihfoo aoo or tith the reqsireoenti or NF -85s d) re-f In feeition to the Sfretr Controoi eefnee in NBIC frt 2, Seationi S4s5, S4s6 fg, fne S4s6 mg, rooe thft the rooootinn fir hfneoinn rfni fre o erftinn ro eror ihfoo me reqsirees SUPPL. 4 b) Loii or aoomsition fir rroo either the sneerfre or ooerfre iosrae ihfoo afsie ihstorr or the rseo is or and a lockout condition. The control system shall be capable of maintaining the correct relationship metteen sneerfre fir fne ooerfre fir, ooer the aoo oete frinn rfnne or the moioer, thioe roootinn aooplete burning with minimum particulate emissions. 1) Inesaee erfrt rfni, 2) Fseo trfni ort rfni, 3) Uneerf 4) Cfrmon, or frfih, re-injeation rfnis In afiei there ofrifmoe i eee erioei fre siee on rfni, the aoomsition iriteo ofnsrfatsrer’i initrsationi ihfoo me rooootee in teroi or the foootfmoe s er fne ooter oioiti or the oter is or rreqsenar Hzgs e) re- srninn re- srninn the moioer fne iti oentinn iriteo ihfoo me reqsirees Unoeii eefnee othertiie mr the ofnrfatsrer or the rseo msrninn eqsi oent, the re- srne ofr me fahieoee mr o erftinn the inesaee erfrt fan prior to starting the remaining fans in the installation. srne fir ooosoe ihfoo me iet esrinn aoooiiiioninn mr the aoomsition iriteo ofnsrfatsrer, or the ofnsrfatsrer’i re reientftioe, in faaorefnae tith f oiafmoe aoeei or itfnefrei fne ihfoo not me af fmoe or being reset by operating personnel. f) Innition Sriteoi Solid fuel ignition systems and/or methods can vary from the placement of manually ignited, oil soaked rfni on the rseo mee, to nfi or oio free ioot msrneri or ofnaei mst in foo afiei ihfoo me in faaorefnae the ofnsrfatsrer’i reaoooeneftionis SECTION 6 89 2015 NATIONAL BOARD INSPECTION CODE g) Firinn Rfte Controo fne Fseos ir Rftio Controo The aontroo iriteo ihfoo me af fmoe or ofintfininn the eeiiree fir to rseo rftio ooer the entire frinn range of the boiler, while promoting clean, stable combustion. h) Re-injeation Sriteoi In initfooftioni there fr fih ii re-injeatee rroo f osoti-araoone aoooeator into the aoomsition zone ror carbon re-burn; precautions should be taken to ensure that plugging of the reinjection pipe work does not oaasrs Coniieerftion ihosoe me nioen to initfooinn aoefnosti in the i e torks Shsteotn fne oit srne Unoeii the moioer ofnsrfatsrer’i initrsationi itfte othertiie, the rseo is or ihfoo me teroinftee ft ihsteotn, fne the ooerfre fir ihosoe reofin on sntio the rseo mee ii msrnee ost, fne the reiiese aoooees --`,```,```,`,``,-`-`,`,`,`,`--- SUPPL. 4 i) 90 SECTION 6 NB-23 2015 SUPPLEMENT 5 INSTALLATION OF THERMAL FLUID HEATERS SCOPE Thii is oeoent eeiarimei nsieeoinei ror the initfooftion or f therofo fsie hefters therofo fsie hefter system consists of the heater, expansion tank, circulating pump, safe catchment with the proper piping and controls to heat jacketed kettles, presses, reactors, ovens, exchangers, etc. The scope does not include thermal f S5.2 (15) --`,```,```,`,``,-`-`,`,`,`,`--- S5.1 DEFINITION Therofo fsied f fsie other thfn tfterg thft ii aheoiafoor itfmoe ooer f ofrne teo erftsre rfnne fne is speaifafoor eeiinnee ror sie fi f heft trfnirer oeeisos (15) Therofo fsie hefterd f aooiee ooo oiqsie hfie hefter fooeee reiisre oeiieog in thiah the heft trfnirer oeeif ii heftee mst no of orizftion tfkei ofae tithin the oeiieos De eneinn on the fsie ieoeation fne o erftinn frfoeteri, iriteoi ofr me o en or aooiee to the ftooi heres Cooiee iriteoi ofr me reiisrizee with an inert gas blanket. S5.3 GENERAL REQUIREMENTS S5.3.1 SUPPORTS, FOUNDATIONS, AND SETTINGS Efah therofo fsie hefter fne iti fiioaiftee i inn osit me ifreor is ortees Deiinn or is orti, foundations, and settings shall consider vibration (including seismic where necessary), movement (including thermal oooeoentg, fne oofeinni inaoseinn the teinht or the fsie in the iriteog in faaorefnae tith jsriieiationfo reqsireoenti, ofnsrfatsrer’i reaoooeneftioni, fnesor other inesitrr itfnefrei, fi f oiafmoes S5.3.2 (15) STRUCTURAL STEEL a) Ir the therofo fsie hefter ii is ortee mr itrsatsrfo iteeo tork, the iteeo is ortinn oeomeri shall be so located or insulated that the heat from the furnace will not affect its strength. (15) b) Strsatsrfo iteeo ihfoo me initfooee in faaorefnae tith jsriieiationfo reqsireoenti, ofnsrfatsrer’i reaoomendations, and/or other industry standards, as applicable. S5.3.3 SETTINGS The therofo fsie hefter ihfoo me initfooee on f fft, oeoeo, nonaoomsitimoe isrrfae rererfmor or aoncrete to roteat fnfinit fnr fre hfzfres 4 ins 100 oog aontfinoent asrm or 2 ins 25 oog, iefo teoeee eri oi frosne the therofo fsie hefter eqsi oent ikie ihfoo me rooieees S5.3.4 (15) CLEARANCES a) Therofo fsie hefter initfooftioni ihfoo fooot ror norofo o erftion, ofintenfnae, fne ini eations. There ihfoo me ft oefit 18 ins 460 oog or aoefrfnae on efah iiee or the therofo fsie hefter to enfmoe faaeii ror ofintenfnae fnesor ini eation fatioitieis Therofo fsie hefteri o erftee in mftterr ihfoo not me initfooee aooier thfn 18 ins 460 oog rroo efah others The rront or refr or fnr therofo fsie hefter ihfoo not me ooaftee nefrer thfn 36 ins 915 oog rroo fnr tfoo or itrsatsres SECTION 6 (15) 91 SUPPL. 5 Therofo fsie of orizerd f hefter in thiah the therofo fsie ii of orizee tithin the reiisre oeiieos 2015 NATIONAL BOARD INSPECTION CODE b) Vertiafo hefteri ihfoo hfoe ft oefit 60 ins 1,520 oog aoefrfnae rroo the to or the hefter or fi reaoomended by the heater manufacturer. c) Heaters with a bottom opening used for inspection or maintenance shall have at least 18 in. (460 mm) of unobstructed clearance. d) NOTE: oternftioe aoefrfnaei in faaorefnae tith the ofnsrfatsrer’i reaoooeneftion fre ismjeat to acceptance by the Jurisdiction. (15) S5.4 THERMAL FLUID HEATER ROOM REQUIREMENTS S5.4.1 EXIT Two oefni or exit ihfoo me rooieee ror therofo fsie hefter roooi exaeeeinn 500 iqs rts 46s5 iqs og foor fref fne aontfininn one or oore therofo fsie hefteri hfoinn f aoominee rseo af faitr or 1,000,000 Btss hr 293 kWg or oores Efah eoeoftion ihfoo me rooieee tith ft oefit tto oefni or exit, efah to me reooteor ooaftee rroo the others oftroro ft the to or f iinnoe therofo fsie hefter ii not aoniieeree fn eoeoftions S5.4.2 (15) LADDERS AND RUNWAYS a) All walkways, runways and platforms shall be: 1) Of metal construction; 2) rooieee metteen or ooer the to or hefteri thft fre oore thfn 8 rts 2s4 og fmooe the o erftinn SUPPL. 5 f 3) Conitrsatee or ifretr trefei, itfnefre nrftinn, or iioiofr ofterifo fne hfoe f oinioso tieth or 30 in. (760 mm); 4) Of bolted, welded, or riveted construction; and 5) Eqsi ee tith hfnerfioi 42 ins 1,070 oog hinh tith fn interoeeifte rfio fne 4 ins 100 oog toe-board. b) Stairways that serve as a means of access to walkways, runways, or platforms shall not exceed an fnnoe or 45 eenreei rroo the horizontfo fne me eqsi ee tith hfnerfioi 42 ins 1,070 oog hinh tith fn intermediate rail. c) Lfeeeri thft ieroe fi f oefni or faaeii to tfoktfri, rsntfri, or oftroroi ihfood 1) Be or oetfo aonitrsation fne not oeii thfn 18 ins 460 oog tiee; 2) Have rungs that extend through the side members and are permanently secured; 3) Have a clearance of not less than 30 in. (760 mm) from the front of rungs to the nearest permanent object on the climbing side of the ladder; 4) Have a clearance of not less than 6½ in. (165 mm) from the back of rungs to the nearest permanent object; and 5) Have a clearance width of at least 15 in. (380 mm) from the center of the ladder on either side across the front of the ladder. d) There shall be at least two permanently installed means of exit from walkways, runways, or platforms that exceed 6 ft. (1.8m) in length. --`,```,```,`,``,-`-`,`,`,`,`--- 92 SECTION 6 NB-23 2015 S5.5 SYSTEM REQUIREMENTS S5.5.1 THERMAL LIQUIDS (HEAT TRANSFER FLUIDS) (15) It ii extreoeor io ortfnt thft the ro er heft trfnirer fsie me ieoeatee mr aoo etent erionneo knotoedgefmoe or the iriteos Heft trfnirer f (15) a) Reiiit eeteriorftion ft the teo erftsrei inooooee to enisre oonn, sierso oire fne f aoefn iriteos b) oiieii nooe heft trfnirer ahfrfateriitiais c) Have low vapor pressures at operating temperatures to permit operation at moderate pressures. Note: roaeiiei reqsirinn therofo fsie teo erftsrei hinher thfn 650°F 340°Cg tioo reqsire the sie or i eaifotr fsiei tith hinh of or reiisrei esns 150 ii 1,030 k fg)s Theie fsiei foio tene to hfoe i eaifo environmental, safety, and health considerations. d) Hfoe oot oiiaoiitiei to eearefie so inn ooiiei ese to i e rriationg fne the oter reqsiree ror circulation. e) Be isitfmoe ror ostiiee teo erftsrei inooooee to reoent rreeze s snoeii f oefni or heft trfae hfi been implemented. f) Meet environmental regulations. S5.5.2 EXPANSION The ex fniion tfnk ihfoo hfoe isrfaient ooosoe to hfneoe the reqsiree ex fniion or the totfo iriteo thermal oiqsie ft the reqsiree o erftinn teo erftsres (15) Ir the ex fniion tfnk ii to me reiisrizee tith fn inert nfi, reiisre reoier ihfoo me rooieee in faaorefnae with the code of construction used for the expansion vessel. When a safety relief valve is used, it shall be piped to a safe catchment. S5.5.3 CONNECTION The airasoftinn so ihfoo me i ee to the therofo fsie hefter er the ofnsrfatsrer’i reaoooeneftioni. The ex fniion tfnk ihosoe me initfooee ft fn eoeoftion fmooe foo i inn then oiiimoes Ir the tfnk ii not ft the highest elevation, an inert gas blanket shall be used to pressurize the system to overcome the weight of the f --`,```,```,`,``,-`-`,`,`,`,`--- The ex fniion tfnk ihosoe me iizee io thft then the therofo oiqsie in the iriteo ii aooe, the tfnk tioo me one qsfrter rsoo or fi reaoooeneee mr the ofnsrfatsrers When the iriteo ii s to o erftinn teo erftsre, the oeoeo or fsie in the ex fniion tfnk ihfoo not exaeee the ofnsrfatsrer’i reaoooeneftions hinh ex fniion tfnk oiqsie oeoeo fofro ofr me siee ror ineiaftion or hinh oiqsie oeoeo in the ex fniion tfnk igs n ex fniion tfnk oot oeoeo ititah or iioiofr eeoiaeg ihfoo me siee to enisre the f ro rifte oinioso oeoeo or fsie in the tfnk er the ofnsrfatsrer’i reaoooeneftions Tri inn or thii ititah ihosoe ihst eotn the so fne msrners The activation of this switch should activate an audible alarm and/or light. All expansion tank vents and drains ihfoo me i ee to f ifre aftahoent or er the ofnsrfatsrer’i reaoooeneftionis (15) a) Ventee – The ex fniion tfnk ihfoo faaooooefte the Net oiitioe Ssation Hefe N SHg reqsireoenti or the airasoftinn so to rooiee f N SH ror the airasoftinn so s For non- reiisrizee tfnki, f oent SECTION 6 93 SUPPL. 5 The heft trfnirer fsie osit me ke t aoefn fne in ro er aoneitions Teiti or the fsie ihfoo me aonesatee er the fsie ofnsrfatsrer’i reaoooeneftioni mr f rooee ofmorftorieis nr heft trfnirer fsie thft ii feeee osit me aoefn fne or the ro er i eaif 2015 NATIONAL BOARD INSPECTION CODE connection (open to the atmosphere) is part of the design and should be piped to a safe catchment with no valve in the piping. b) reiisrizee – The ex fniion tfnk ofr me reiisrizee tith nitronen or other inert nfi fi reaoooeneee mr the f reiisre ofr me fejsitee to oeet the Net oiitioe Ssation Hefe reqsireoent or the airasoftinn so s Coo reiiee fir ii not reaoooeneee fi it oxieizei the therofo fsies Cfrmon eioxiee ii not reaoooeneee fi it eiiioooei into the fsie fne afn arefte afoitftion or other romoeoi in the iriteos S5.5.4 (15) CIRCULATING PUMP It ii eiientifo thft the so ieoeation me ofee mr aoo etent erionneo thft fre knotoeenefmoe to the reqsireoenti or the i eaifa iriteos S eaifo fttention to hot fne aooe foinnoent reqsireoenti fne so aoooinn reqsireoenti osit me aoniieerees The airasoftinn so ositd a) rooiee the reqsiree fsie fot faroii the hefter tsme isrrfaes b) Handle the Total System Head. c) Be i eaifafoor eeiinnee to hfneoe the therofo fsie ft the hinh teo erftsrei fi teoo fi the oiiaoiitr reqsireoenti or aooe itfrt aoneitionis The so ihosoe me rftee ror the ofxioso o erftinn teo erftsre or the fsies itrfiner ihosoe me ooaftee in efah so isation i inns Uoome ofooei or other throttoinn valves should be considered in the pump discharge piping to throttle the pump if necessary to prevent it rroo rsnninn ost on iti asroes Dsfo so i fre orten initfooee to rooiee 100% reesnefnar in the afie or f so rfiosres f SUPPL. 5 S5.5.5 (15) PIPING AND VALVES Cfrmon iteeo i e isah fi S -53 or S -106 ii rererree ror the entire i inn iriteos Sefooeii i e ihosoe be used ror therofo fsie i inns Co er, ao er fooori, mrfii, mronze, fosoinso, or afit iron ihosoe not me siee fi ther fre inaoo ftimoe tith ooit therofo fsieis oo jointi fne aonneationi N S 1 DN 25g fne ooer tithin the fot airasitg ihosoe me teoeee or ffnnees Fsoo enetrftion teoei ihfoo me siee in the i inns oo ffnne nfiketi ihfoo me isitfmoe ror the o erftinn teo erftsre, reiisre, fne fsie siees S eaifo fttention ihfoo me nioen to the ex fniion or the i inn ese to the hinh teo erftsrei inooooees Vfooei ihfoo me or iteeo ofterifo aoo ftimoe ror the therofo fsie fne teo erftsrei fne ihfoo me ffnnee or teoe tr e ofnsrfatsree rroo afit or rornee iteeo or esatioe irons Vfooe internfoi fne nofne iefoi ihfoo me ofee rroo ofterifoi isitfmoe ror sie tith hinh teo erftsre fsiei fne aoo ftimoe tith the i eaifa fsie stioizee in the iriteos When 2-tfr valves are utilized in the piping system, a back pressure regulating valve or automatic bypass valve shall be inaor orftee to enisre the ro er fot throsnh the hefter ft foo tioei renfreoeii or aontroo ofooe oiitions Ir 3-way valves are used, balancing valves should be included. Deiinn or i inn is orti ihosoe me in faaorefnae tith jsriieiationfo reqsireoenti, ofnsrfatsrer’i reaoooeneftioni, fnesor other inesitrr itfnefrei fi f oiafmoes Therofo inisoftion siee on the i ei fne eqsi oent ihosoe me ieoeatee ror the inteneee sr oie fne ror aoo ftimioitr tith the fsies Where there ii the otentifo ror fsie iriteo oefki ffnnee jointi, etasg, the therofo inisoftion ieoeatee ihosoe me non-fmiorments Lfoinftee rofo nofii or aeoosofr nofii nonfmiorment, aooiee aeoog inisoftion fre exfo oei or isitfmoe insulation. S5.5.6 (15) FUEL Fseo iriteoi, thether frinn on oio, nfi, or other ismitfnaei, ihfoo me initfooee in faaorefnae tith jsriieiationfo fne enoironoentfo reqsireoenti, ofnsrfatsrer’i reaoooeneftioni, fnesor other inesitrr itfnefrei, as applicable. --`,```,```,`,``,-`-`,`,`,`,`--- 94 SECTION 6 NB-23 2015 S5.5.7 ELECTRICAL a) All wiring for controls, heat generating apparatus, and other appurtenances necessary for the operation or the therofo fsie hefter ig ihosoe me initfooee in faaorefnae tith the rooiiioni or nftionfo or internftional standards and comply with the applicable local electrical codes. b) ofnsfoor o erftee reoote ihsteotn ititah or airasit mrefker ihfoo me ooaftee jsit ostiiee the eqsi oent rooo eoor fne ofrkee ror efir ieentifaftions Coniieerftion ihosoe foio me nioen to the tr e fne location of the switch to safeguard against tampering. c) A disconnecting means capable of being locked in the open position shall be installed at an accessible location at the heater so that the heater can be disconnected from all sources of potential. This disconnecting means shall be an integral part of the heater or adjacent to it. d) Ir the eqsi oent rooo eoor ii on the msioeinn exterior, the ihsteotn ititah ihfoo me ooaftee jsit iniiee the eoors Ir there ii oore thfn one eoor to the eqsi oent rooo, there ihfoo me f ihsteotn ititah ooaftee ft efah eoor or enreiis For ftooi heria-nfi msrneri, fne oio msrneri there f rfn ii on f aoooon ihfrt tith the oio so , the aoo oete msrner fne aontrooi ihosoe me ihst orrs For oter msrneri tith eetfahee fsxioifriei, onor the rseo in st is or to the f e) Controoi ror Heft Uenerftinn frftsi 1) Oio fne nfi-free fne eoeatriafoor heftee therofo fsie hefteri ihfoo me eqsi ee tith isitfmoe riofrr ffoe ifrensfreg ifretr aontrooi, ifretr oioit ititahei fne aontrooi, fne msrneri or eoeatria elements by a nationally or internationally recognized standard. SUPPL. 5 --`,```,```,`,``,-`-`,`,`,`,`--- 2) The iromoo or the aertirrinn ornfnizftion thft hfi inoeitinftee isah eqsi oent fi hfoinn aoo oiee tith f nftionfoor reaonnizee itfnefre ihfoo me frfxee to the eqsi oent fne ihfoo me aoniieeree fi eoieenae thft the snit tfi ofnsrfatsree in faaorefnae tith thft itfnefres Therofo fsie hefter shall have: a. Ex fniion tfnk oot oeoeo ititah, oiqsie oeoeo ititah or iioiofr eeoiaeg interooakee tith the airasoftinn so o erftion to aonfro oinioso oeoeo in the ex fniion tfnk then the iriteo ii aooes This interlock prevents pump cavitation. The function of this device shall prevent burner and so o erftion ir the oiqsie oeoeo ii not feeqsftes b. Therofo fsie teo erftsre o erftion aontroos Thii teo erftsre fatsftee aontroo ihfoo ihst eotn the rseo is or then the iriteo refahei f reiet o erftion teo erftsres Thii reqsireoent eoei not reaosee the sie or feeitionfo o erftion aontroo eeoiaei then reqsirees c. Hinh teo erftsre oioit ifretr ititah ooaftee on the therofo fsie hefter ostoets Thii oioit ihfoo reoent the fsie teo erftsre rroo exaeeeinn the ofxioso foootfmoe teo erftsre or the i eaifa fsies The hinh teo erftsre oioit ifretr ititah iet oint ihosoe me iet no hinher thfn the ofxioso teo erftsre i eaifee mr the fsie ofnsrfatsrer, hefter eeiinner, or eotnitrefo roaeii oioiti, thiaheoer ii ooteits Fsnationinn or thii aontroo ihfoo afsie f ifretr ihsteotn and lockout. The manual rest may be incorporated in the temperature limit control. Where a reset device is separate from the temperature limit control, a means shall be provided to indicate actuation of the temperature sensing element. Each limit and operating control shall have its own sensing element and operating switch. d. riofrr f ofin rseo ihst orr ofooe fne ihst orr ioot rseo s on ooii or ffoe ft the oint or is eroiiions The function of this control shall cause a safety shutdown and lockout. e. oter msrneri fne oeahfniafo erfrt ftooi heria msrneri ihfoo rooiee ror the reinnition srninn or the aoomsition ahfomer fne fse fiieis The srne ihfoo rooiee no reter thfn rosr fir ahfnnei or nrefter fi i eaifee mr the ofnsrfatsrers SECTION 6 95 2015 NATIONAL BOARD INSPECTION CODE f. roor or f itiei fne foo teo erftsrei throsnh the hefters oot fot aoneition afn afsie ooerheftinn, eenrfeftion or the fsie or hefter aoio or tsme rfiosres atioftion or thii interooak ihfoo afsie f ifretr shutdown of the burner and pump. One or more interlocks shall be provided to prove minimum fot throsnh the hefter ft foo o erftinn aoneitionis 3) In faaorefnae tith jsriieiationfo fne enoironoentfo reqsireoenti, ofnsrfatsrer’i reaoooeneftioni, fnesor other inesitrr itfnefrei, fi f oiafmoe, Therofo fsie hefteri ofr foio hfoed hinh itfak teo erftsre ititah interooak – in the eoent or f hinh itfak teo erftsre ineiaftion of improper combustion or cracked coil) this device shall shut off the burner and circulating pump and cause a lockout condition. b. n inert nfi iootherinn iriteo itefo or CO2g – thii iriteo ii siee to qsenah aoomsition in the event of a cracked heater coil or tube. The gas smothering system should be installed per ooafo aoeei fne reqsireoentis tr iafo iriteo ofr inaosee tto itfak oioit ititahei, fn fofro and valve to allow inert gas to enter the combustion chamber. One stack limit is set at a value fmooe the tr iafo itfak teo erftsre ror the eqsi oent esns 1,000s ºF 540°Cg) fne the ieaone ii iet ft 100 ºF 40°Cg fmooe the frits Ir the oioit ii tri ee, the so fne msrner tioo ihst eotns Ir the ieaone oioit ii tri ee, the inert nfi ihfoo enter the aoomsition ahfomer to qsenah the ffoes c. hinh inoet reiisre ititah – thii norofoor aooiee ititah ieniei reiisre ft the hefter inoet and its setpoint is determined based on the system design pressure when the system is cold. atioftion or thii ititah ineiaftei f reitriation in fot fne ihosoe ihsteotn the msrner fne pump and cause a lockout condition. d. oot inoet reiisre ititah – thii norofoor o en ititah ieniei reiisre ft the hefter inoet fne its setpoint is determined based on system pressure when the system is operating at temperatsres atioftion or thii ititah ineiaftei f reitriation in fot fne ihosoe ihsteotn the msrner fne pump and cause a lockout condition. e. hinh ostoet reiisre ititah – thii norofoor aooiee ititah ieniei reiisre ft the hefter ostoet and its setpoint is determined based on the system pressures when the system is at operating teo erftsres atioftion or thii ititah ineiaftei f reitriation in fot fne ihosoe ihsteotn the burner and pump and cause a lockout condition. Note: the setpoint of this switch should be lower than the safety relief valve setting. SUPPL. 5 a. 4) Theie eeoiaei ihfoo me initfooee in faaorefnae tith jsriieiationfo fne enoironoentfo reqsireoenti, ofnsrfatsrer’i reaoooeneftioni, fnesor inesitrr itfnefrei, fi f oiafmoes S5.5.8 (15) --`,```,```,`,``,-`-`,`,`,`,`--- 96 VENTILATION AND COMBUSTION AIR a) The eqsi oent rooo ihfoo hfoe fn feeqsfte fir is or to eroit aoefn, ifre aoomsition, oinioize ioot roroftion, fne ofintfin f oinioso or 19s5% oxrnen in the fir or the eqsi oent rooo fne isrfaient to maintain ambient temperatures as recommended by the heater manufacturer. The combustion and ventilation air should be supplied by either an unobstructed air opening or by power ventilation or fans. Note: When aoomsition fir ii is oiee to the therofo fsie hefter mr fn inee eneent esat, tith or without the employment of power ventilators or fans, the duct shall be sized and installed in accordance tith the ofnsrfatsrer’i reaoooeneftionis Hoteoer, oentioftion ror the eqsi oent rooo osit itioo me considered. SECTION 6 NB-23 2015 b) Unomitrsatee fir o eninni ihfoo me iizee on the mfiii or 1 iqs ins 650 iqs oog rree fref er 2,000 Btss hr 586 Wg ofxioso rseo in st or the aoominee msrneri ooaftee in the eqsi oent rooo, or fi i eaifee in the Nftionfo Fire roteation iioaiftion NF g itfnefrei ror oio fne nfi msrninn initfooftioni ror the frtiasofr jom aoneitionis The hefter eqsi oent rooo fir is or o eninni ihfoo me ke t aoefr ft foo times. c) oter oentioftori or rfni ihfoo me iizee on the mfiii or 0s2 aro 0s0057 as oeteri er oinsteg ror efah 1,000 Btsshr 293 Wg or ofxioso rseo in st ror the aoominee msrneri or foo therofo fsie hefteri ooaftee in the eqsi oent rooos eeitionfo af faitr ofr me reqsiree ror fnr other rseo msrninn eqsi oent in the eqsi oent rooos reiisre in the rooo ihosoe me aoniiitentor nestrfos d) When power ventilators or fans are used to supply combustion air they shall be installed with interlock eeoiaei io thft the msrneri tioo not o erfte tithost fn feeqsfte nsomer or oentioftorisrfni in o erftions e) The iize or o eninni i eaif proved by the Jurisdiction are used. Cfre ihosoe me tfken to enisre thft therofo fsie oinei fre not rostee faroii aoomsition fir o eninni, where freezing may occur in cold climates. S5.5.9 LIGHTING The eqsi oent rooo ihosoe me teoo oit fne it ihosoe hfoe fn eoernenar oinht iosrae ror sie in afie or power failure. S5.5.10 EMERGENCY VALVES AND CONTROLS oo eoernenar ihstorr ofooei fne aontrooi ihfoo me faaeiiimoe rroo f foor, oftroro, tfoktfr, or rsntay. Accessibility shall mean within a 6 ft. (1.8 m) elevation of the standing space and not more than 12 in. (305 mm) horizontally from the standing space edge. S5.6 DISCHARGE REQUIREMENTS S5.6.1 CHIMNEY OR STACK Chioneri or itfaki ihfoo me initfooee in faaorefnae tith jsriieiationfo fne enoironoentfo reqsireoents, mansrfatsrer’i reaoooeneftioni, fnesor inesitrr itfnefrei, fi f oiafmoes S5.6.2 (15) (15) (15) DRAINS isitfmoe oot oint erfin fttee tith f ito ofooe ihfoo me rooieee in the hefter or aonneatinn i inn to fooot the heat transfer media to be drained out of the pressure vessel and/or piping when necessary. The valve may either me ooakee in the aooiee oiition or f mofnk ffnne afn me initfooee eotnitrefo or the ofooes The ofooe should never be opened when there is temperature on the system. S5.6.3 AIR VENT A manual air vent valve should be installed on the high point of the system piping. This valve is typically used then fooinn or erfininn the iriteos The ofooe ihosoe neoer me o enee then there ii teo erftsre on the iritem or when a pressurized system is utilized. --`,```,```,`,``, SECTION 6 (15) 97 SUPPL. 5 f) - 2015 NATIONAL BOARD INSPECTION CODE (15) S5.7 OVERPRESSURE PROTECTION S5.7.1 GENERAL Therofo f construction. S5.7.2 (15) PRESSURE RELIEF DEVICES Therofo fsie hefteri ihfoo me eqsi ee tith one or oore reiisre reoier eeoiaei snoeii the o tion ror ooerpressure protection by system design is utilized (when permitted by the original code of construction). When pressure relief devices are used, the following shall apply: a) reiisre reoier ofooe ig ihfoo me or f totfoor enaooiee tr e fne ihfoo not hfoe f oirtinn oeoers b) Rs tsre eiiki ofr me initfooee s itrefo or eotnitrefo or the reiisre reoier ofooe ig in faaorefnae with the original code of construction. c) reiisre reoier ofooei fne rs tsre eiiki ihfoo me in faaorefnae tith the aoee or aonitrsation fne eeiinnee ror oiqsie, of or, or aoominftion ieroiae fi reqsiree ror the i eaifa initfooftion, ieroiae fsiei, and overpressure conditions. d) The inoet aonneation to the ofooe ihfoo me not oeii thfn N S ½ DN 15gs (15) a) ressure relief devices shall be connected to the heater in accordance with the original code of construction. S5.7.4 (15) CAPACITY a) The reiisre reoier eeoiae ig ihfoo hfoe isrfaient af faitr to reoent the reiisre oeiieo rroo exaeeeinn the ofxioso reiisre i eaifee in the oeiieo aoee or aonitrsations S5.7.5 (15) LOCATION SET PRESSURE a) When a single relief device is used, the set pressure marked on the device shall not exceed the maximum allowable working pressure. b) When oore thfn one reiisre reoier eeoiae ii rooieee to omtfin the reqsiree af faitr, onor one reisure relief device set pressure needs to be set at or below the maximum allowable working pressure. The set pressure of the additional relief devices shall be such that the pressure cannot exceed the maximum pressure permitted by the code of construction. S5.7.6 (15) 98 INSTALLATION a) When a discharge pipe is used, the cross-sectional area shall not be less than the full area of the valve outlet. The size of the discharge lines shall be such that any pressure that may exist or develop will not reduce the relieving capacity or adversely affect the operation of the attached pressure vessel relief eeoiaeis Diiahfrne i inn ihfoo me fi ihort fne itrfinht fi oiiimoe fne frrfnnee to fooie snese itreii on the pressure relief device. SECTION 6 --`,```,```,`,``,-`-`,`,`,`,`--- SUPPL. 5 S5.7.3 NB-23 2015 b) The cross sectional area of the piping between the heater and the relief device shall be sized either to fooie reitriatinn the f pressure relief devices connected to it. c) When tto or oore reqsiree reiisre reoier eeoiaei fre ofaee on one aonneation, the inoet aroii-ieationfo fref or thii aonneation ihfoo me iizee either to fooie reitriatinn the fot to the reiisre reoier eeoiaei or ofee ft oefit eqsfo to the aoominee inoet frefi or the reiisre reoier eeoiaei aonneatee to its reiisre reoier eeoiae eiiahfrnei ihfoo me frrfnnee isah thft ther fre not f hfzfre to erionneo or other eqsi oent fne, then neaeiifrr, oefe to f ifre ooaftion, isah fi f aftahoent tfnk, ror the eii oifo or f f) Diiahfrne oinei rroo reiisre reoier eeoiaei ihfoo me eeiinnee to rfaioitfte erfinfne or me fttee tith oot oint or ofooe moer erfini to reoent oiqsie rroo aoooeatinn in the eiiahfrne iiee or f reiisre reoier eeoiaes Drfin i inn ihfoo eiiahfrne to f ifre ooaftion ror the eii oifo or the fsiei meinn reoieoees S5.8 TESTING AND ACCEPTANCE S5.8.1 GENERAL a) Cfre ihfoo me exeraiiee esrinn initfooftion to reoent oooie teoe ofterifo, teoeinn roei, iofoo toooi, and oiiaeoofneosi iarf oetfo rroo nettinn into the therofo fsie iriteos Where oiiimoe, fn ini eation or the interior or the therofo fsie hefter fne iti f srtenfnaei ihfoo me ofee ror the reienae or roreinn eemrii rior to ofkinn the f (15) SUPPL. 5 e) --`,```,```,`,``,-`-`,`,`,`,`--- d) Unoeii eroittee mr the aoee or aonitrsation, there ihfoo me no interoeninn ito ofooe metteen the oeisel and its pressure relief device(s), or between the pressure relief device and the point of discharge. b) Sfre o erftion ihosoe me oerifee mr f erion rfoioifr tith hefter iriteo o erftioni ror foo hefteri fne connected appurtenances and all pressure piping connecting them to the appurtenances and all piping. c) In mootee aonneationi, the mooti, itsei, fne nsti ihfoo me ofrkee fi reqsiree mr the orininfo aoee or construction and be fully engaged (e.g., the end of the bolt or stud shall protrude through the nut). d) Wfiheri ihfoo onor me siee then i eaif S5.8.2 PRESSURE TEST rior to initifo o erftion, the aoo oetee therofo fsie hefter iriteo, inaoseinn reiisre i inn, so i, itop valves, etc., shall be pressure tested in accordance with the manufacturer's recommendations. Hydrostatic testing of the system is not recommended due to possible contamination of the system. All pressure testing ihosoe me titneiiee mr fn Ini eators S5.8.3 NONDESTRUCTIVE EXAMINATION Therofo fsie hefter aoo onenti fne ismaoo onenti ihfoo me noneeitrsatioeor exfoinee fi reqsiree my the governing code of construction. S5.8.4 (15) (15) SYSTEM TESTING rior to fnfo faae tfnae, fn o erftionfo teit ihfoo me erroroee on the aoo oete initfooftions The test data shall be recorded and the data made available to the jurisdictional authorities as evidence that the installation complies with the provisions of the governing code(s) of construction. This operational test may be used as the f SECTION 6 (15) 99 2015 NATIONAL BOARD INSPECTION CODE S5.8.5 (15) A therofo fsie hefter ofr not me ofaee into ieroiae sntio iti initfooftion hfi meen ini eatee fne faae tee mr the appropriate jurisdictional authorities. S5.8.6 (15) FINAL ACCEPTANCE INSTALLATION REPORT a) U on completion, inspection, and acceptance of the installation, the installer should complete and certify the Boiler Installation Report I-1. See 1.4.5.1. b) The Boiler Installation Report should be submitted as follows: 1) One copy to the Owner; and --`,```,```,`,``,-`-`,`,`,`,`--- SUPPL. 5 2) One ao r to the Jsriieiation, ir reqsirees 100 SECTION 6 NB-23 2015 PART 1, SECTION 7 INSTALLATION — NBIC POLICY FOR METRICATION 7.1 GENERAL This policy provides guidance for the use of US customary units and metric units. Throughout the NBIC, metric units are identifed and paced in arentteses aater tte U custtmarr units reaerenced in tte teet and associated tables. For each repair or alteration performed, selection of units shall be based on the units used in tte triginap ctde ta ctnstructitn. Ftr eeam pe, items ctnstructed using U custtmarr units stapp be re aired tr aptered using U custtmarr units. Tte same eeam pe a pies tt items ctnstructed using metric units. Whichever units are selected, those units are to be used consistently throughout each repair or alteration. Consistent use of units includes all aspects of work required for repairs or alterations (i.e. materials, design, procedures, testing, documentation, and stamping, etc.). 7.2 EQUIVALENT RATIONALE The rationale taken to convert metric units and US customary units involves knowing the difference between a soft conversion and a hard ctnversitn. A stat ctnversitn is an eeact ctnversitn. A tard ctnversitn is simply performing a soft conversion and then rounding off within a range of intended precision. When vapues s ecifed in tte NBI are intended tt be a rteimate vapues, a tard ctnversitn is rtvided. Ba an eeact vapue is needed tt maintain saaetr tr required based tn using gttd engineering judgment, tten a stat ctnversitn wipp be used. Bn generap, a rteimate accuracr is acce tabpe atr mtst re airs tr apteratitns erformed using the requirements of the NBIC. Therefore, within the NBIC, metric equivalent units are primarily hard conversions. Tte atpptwing eeam pes are rtvided atr aurtter cparifcatitn and understanding ta stat ctnversitns versus hard conversions: SECTION 7 Example 1: Using 1 in. = 25.4 mm; 12 in. = 304.8 mm (soft conversion) Example 2: Using the above conversion, a hard conversion may be 300 mm or 305 mm depending on the degree of precision needed. 7.3 PROCEDURE FOR CONVERSION The following guidelines shall be used to convert between US customary units and metric units within the teet ta tte NBI: a) All US customary units will be converted using a soft conversion; b) Soft conversion calculations will be reviewed for accuracy; c) Nased tn s ecif d) Once the degree of precision is decided, rounding up or down may be applied to each soft conversion in order to obtain a hard conversion; and e) Use of hard conversion units shall be used consistently throughout the NBIC wherever soft conversions are not required. Note: Care shall be taken to minimize percentage difference between units. --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 7 101 2015 NATIONAL BOARD INSPECTION CODE 7.4 REFERENCING TABLES The following tables are provided for guidance and convenience when converting between US customary units and metric units. Uee NBI Part 1, 2, 3, Tabpes 7.4-a ttrtugt 7.4-j. TABLE 7.4-a SOFT CONVERSION FACTORS (US X FACTOR = METRIC) US Customary Metric Factor in. mm 25.4 f༳ m 0.3048 in. 2 mm 645.16 2 m 0.09290304 f in. 2 3 mm 16,387.064 3 3 m 0.02831685 US gal. m 3 0.003785412 US gal. liters 3.785412 psi MPa 0.0068948 psi kPa 6.894757 f.-l J 1.355818 °F °C 5/9 x (°F–32) R K 5/9 -lm kg 0.4535924 -lf N 4.448222 in༳.-l N.mm 112.98484 f༳.-l N.m 1.3558181 ksi√in MPa√m 1.0988434 Btu/hr W 0.2930711 -l/f kg/m 16.018463 kPa 0.249089 f SECTION 7 2 3 3 in༳.wc 3 Note: Tte actuap ressure ctrres tnding tt tte teigtt ta a verticap ctpumn ta f itatitnap fepd and tte densitr ta tte fuid, wtict in turn de ends u tn tte tem erature. Ttis ctnversitn aacttr is tte ctnventitnap vapue adt ted br BUO. Tte ctnversitn assumes a standard gravitatitnap fepd (gn – 9.80665 N/kg) and a density of water equal to 1,000 kg/m3. 7.4-a ttrtugt 7.4-j. --`,```,```,`,``,-`-`,`,`,`,`--- 102 SECTION 7 NB-23 2015 Temperature shall be converted to within 1°C as shown in NBIC Part 1, 2, 3, Table 7.4-b. TABLE 7.4-b TEMPERATURE EQUIVALENTS Temperature °F Temperature °C 60 16 70 21 100 38 120 49 350 177 400 204 450 232 800 427 1,150 621 Fractions of an inch shall be converted according to NBIC Part 1, 2, 3, Table 7.4-c. Even increments of inches are in even mupti pes ta 25 mm. Ftr eeam pe, 40 inctes is equivapent tt 1,000 mm. Bntermediate vapues may be interpolated rather than converting and rounding to the nearest mm. --`,```,```,`,``,-`-`,`,`,`,`--- Inches Millimeters 1/32 0.8 3/64 1.2 1/16 1.5 3/32 2.5 1/8 3 5/32 4 3/16 5 7/32 5.5 1/4 6 5/16 8 3/8 10 7/16 11 1/2 13 9/16 14 5/8 16 11/16 17 3/4 19 7/8 22 1 25 SECTION 7 TABLE 7.4-c US FRACTIONS/METRIC EQUIVALENTS SECTION 7 103 2015 NATIONAL BOARD INSPECTION CODE For nominal pipe sizes, the following relationships were used as shown in NBIC Parts 1, 2 or 3, Table 7.4-d. TABLE 7.4-d PIPE SIZES/EQUIVALENT SECTION 7 US Customary Pract NPS 1/8 NPS 1/4 NPS 3/8 NPS 1/2 NPS 3/4 NPS 1 NPS 1.1/4 NPS 1.1/2 NPS 2 NPS 2.1/2 NPS 3 NPS 3.1/2 NPS 4 NPS 5 NPS 6 NPS 8 NPS 10 NPS 12 NPS 14 NPS 16 NPS 18 NPS 20 NPS 22 NPS 24 NPS 26 NPS 28 NPS 30 NPS 32 NPS 34 NPS 36 NPS 38 NPS 40 NPS 42 NPS 44 NPS 46 NPS 48 NPS 50 NPS 52 NPS 54 NPS 56 NPS 58 NPS 60 DN 6 DN 8 DN 10 DN 15 DN 20 DN 25 DN 32 DN 40 DN 50 DN 65 DN 80 DN 90 DN 100 DN125 DN 150 DN 200 DN 250 DN 300 DN 350 DN 400 DN 450 DN 500 DN 550 DN 600 DN 650 DN 700 DN 750 DN 800 DN 850 DN 900 DN 950 DN 1000 DN 1050 DN 1100 DN 1150 DN 1200 DN 1250 DN 1300 DN 1350 DN 1400 DN 1450 DN 1500 --`,```,```,`,``,-`-`,`,`,`,`--- 104 SECTION 7 NB-23 2015 Areas in square inches (in2) were converted to square mm (mm2) and areas in square feet (ft2) were converted to square meters (m2). Uee eeam pes in NBI Parts 1, 2 tr 3, Tabpes 7.4-e and 7.4-a. TABLE 7.4-e Area (US Customary) Area (Metric) 3 in 650 mm2 2 6 in2 3,900 mm2 10 in2 6,500 mm2 TABLE 7.4-f Area (US Customary) Area (Metric) 5f 0.46 mm2 2 Volumes in cubic inches (in.3) were converted to cubic mm (mm3) and volumes in cubic feet (ft3) were converted to cubic meters (m3). Uee eeam pes in NBI Parts 1, 2 tr 3, Tabpes 7.4-g and 7.4-t. TABLE 7.4-g Volume (US Customary) Volume (Metric) 1 in 3 16,000 mm3 6 in3 96,000 mm3 10 in3 160,000 mm3 Volume (US Customary) Volume (Metric) 5f 0.14 m3 3 SECTION 7 TABLE 7.4-h --`,```,```,`,``,-`-`,`,`,`, SECTION 7 105 2015 NATIONAL BOARD INSPECTION CODE Although the pressure should always be in MPa for calculations, there are cases where other units are used in tte teet. Ftr eeam pe, kPa is used atr smapp ressures. Apst, rtunding was tt twt signifcant fgures. Uee eeam pes in Tabpe 7.4-i. ( tte ttat 14.7 si ctnverts tt 101 kPa, wtipe 15 si ctnverts tt 100 kPa. Wtipe ttis mar seem at f TABLE 7.4-i PRESSURE/EQUIVALENTS SECTION 7 --`,```,```,`,``,-`-`,`,`,`,`--- Pressure (US Customary) Pressure (Metric) 0.5 psi 3 kPa 2 psi 15 kPa 3 psi 20 kPa 10 psi 70 kPa 15 psi 100 kPa 30 psi 200 kPa 50 psi 350 kPa 100 psi 700 kPa 150 psi 1.03 MPa 200 psi 1.38 MPa 250 psi 1.72 MPa 300 psi 2.10 MPa 350 psi 2.40 MPa 400 psi 2.8 MPa 500 psi 3.45 MPa 600 psi 4.14 MPa 1,200 psi 8.27 MPa 1,500 psi 10.34 MPa TABLE 7.4-j Strength (US Customary) Strength (Metric) 95,000 psi 655 MPa Materiap rt erties ttat are ee ressed in si tr ksi (e.g., apptwabpe stress, riepd and tensipe strengtt, epastic mtdupus) were generappr ctnverted tt MPa tt ttree signifcant fgures. Uee eeam pe in NBI Parts 1, 2 tr 3, Table 7.4-h. 106 SECTION 7 NB-23 2015 PART 1, SECTION 8 INSTALLATION — PREPARATION OF TECHNICAL INQUIRIES TO THE NATIONAL BOARD INSPECTION CODE COMMITTEE 8.1 INTRODUCTION The NBIC Committee meets regularly to consider written requests for interpretations and revisions to the code rules. This section provides guidance to code users for submitting technical inquiries to the Committee. Technical inquires include requests for additions to the code rules and requests for code Interpretations, as described below. a) Code Revisions Code revisions are considered to accommodate technological developments, address administrative requirements, or to clarify code intent. b) Code Interpretations Code Interpretations provide clarifcation oo tte eaninn oo eeistinn rrles in tte codee and are also presented in question and reply format. Interpretations do not introduce new requirements. In cases where eeistinn code teet does not orlly convey tte eaninn ttat was intendede and revision oo tte rrles is required to support an Interpretation, an intent Interpretation will be issued and the code will be revised. As a matter of published policy, the National Board does not approve, certify, or endorse any item, construction, propriety device or activity and, accordingly, inquiries requiring such consideration will be retrrned. Moreovere tte National Board does not act as a consrltant on specifc ennineerinn proole s or on the general application or understanding of the code rules. Inqriries ttat do not co ply witt tte provisions oo ttis section or ttat do not provide srofcient inoor ation for the Committee’s full understanding may result in the request being returned to the inquirer with no action. 8.2 INQUIRY FORMAT Inquiries submitted to the Committee shall include: a) Purpose Specify one of the following: SECTION 8 1) Revision of present code rules; 2) New or additional code rules; or 3) code Interpretation. b) Background Provide concisely the information needed for the Committee’s understanding of the inquiry, being sure to inclrde reoerence to tte applicaole Code Editione Addendae paranraptse fnrrese and taoles. rovide a copy oo tte specif c) Presentations The inquirer may attend a meeting of the Committee to make a formal presentation or to answer questions from the Committee members with regard to the inquiry. Attendance at a Committee meeting shall oe at tte eepense oo tte inqrirer. Tte inqrirer’s attendance or lack oo attendance at a eetinn stall not be a basis for acceptance or rejection of the inquiry by the Committee. --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 8 107 2015 NATIONAL BOARD INSPECTION CODE 8.3 CODE REVISIONS OR ADDITIONS Request for code revisions or additions shall provide the following: a) Proposed Revisions or Additions For revisions, identify the rules of the code that require revision and submit a copy of the appropriate rules as they appear in the code, marked up with the proposed revision. For additions, provide the reco ended wordinn reoerenced to tte eeistinn code rrles. b) Statement of Need rovide a orieo eeplanation oo tte need oor tte revision or addition. c) Background Information Provide background information to support the revision or addition, including any data or changes in technology that form the basis for the request that will allow the Committee to adequately evaluate the proposed revision or addition. Sketctese taolese fnrrese and nrapts storld oe sro itted as appropriate. When applicable, identify any pertinent paragraph in the code that would be affected by the revision or addition and identify paragraphs in the code that reference the paragraphs that are to be revised or added. 8.4 CODE INTERPRETATIONS a) Inquiry rovide a condensed and precise qrestione o ittinn srperfrors oacknrornd inoor ation ande wten possible, composed in such a way that a “yes” or a “no” reply, with brief provisos if needed, is acceptable. The question should be technically and editorially correct. b) Reply Provide a proposed reply that will clearly and concisely answer the inquiry question. Preferably the reply should be “yes” or “no” with brief provisos, if needed. c) Background Information Provide any background information that will assist the committee in understanding the proposed Inquiry and Reply Requests for Code Interpretations must be limited to an interpretation of the particular requirement in the code. The Committee cannot consider consulting type requests such as: SECTION 8 1) A review oo calcrlationse desinn drawinnse weldinn qralifcationse or descriptions oo eqrip ent or Parts to determine compliance with code requirements; 2) A request for assistance in performing any code-prescribed functions relating to, but not limited to, material selection, designs, calculations, fabrication, inspection, pressure testing, or installation; 3) A request seeking the rationale for code requirements. 8.5 SUBMITTALS Submittals to and responses from the Committee shall meet the following criteria: a) Submittal Inquiries from code users shall be in English and preferably be submitted in typewritten form; however, legible handwritten inquiries will be considered. They shall include the name, address, telephone numoere oae nr oere and e ail addresse io availaolee oo tte inqrirer and oe ailed to tte oollowinn address: 108 SECTION 8 --`,```,```,`,``,-`-`,`,`,`,`--- Requests for code Interpretations shall provide the following: NB-23 2015 Secretary, NBIC Committee The National Board of Boiler and Pressure Vessel Inspectors 1055 Crupper Avenue Columbus, OH 43229 As an alternativee inqriries ay oe sro itted via oae or e ail to: Secretary NBIC Committee Fae: 614.847.1828 Email: [email protected] SECTION 8 b) Response The Secretary of the NBIC Committee shall acknowledge receipt of each properly prepared inquiry and shall provide a written response to the inquirer upon completion of the requested action by the NBIC Committee. --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 8 109 2015 NATIONAL BOARD INSPECTION CODE PART 1, SECTION 9 INSTALLATION— GLOSSARY OF TERMS 9.1 DEFINITIONS For the purpose of applying the rules of the NBIC, the following terms and defnitions shall e used herein as applica le to each part: Additional terms and def Accumulator — A vessel in which the test medium is stored or accumulated prior to its use for testing. Alteration — A change in the item descri ed on the original Manufacturer’s Data Report which affects the pressure containing capa ility of the pressure-retaining item. (See NBIC Part 3, 3.4.3, Examples of Alteration) Nonphysical changes such as an increase in the maximum allowa le working pressure (internal or external), increase in design temperature, or a reduction in minimum temperature of a pressure-retaining item shall e considered an alteration. ANSI — The American National Standards Institute. Appliance — A piece of equipment that includes all controls, safety devices, piping, fttings, and vessel(s) within a common frame or enclosure that is listed and la eled y a nationally recognized testing agency for its intended use. ASME — The American Society of Mechanical Engineers. ASME Code — The American Society of Mechanical Engineers Boiler and Pressure Vessel Code pu lished y that Society, including addenda and Code Cases, approved y the associated ASME Board. Assembler — An organization who purchases or receives from a manufacturer the necessary component parts of valves and assem les, adjusts, tests, seals, and ships safety or safety relief valves at a geographical location, and using facilities other than those used y the manufacturer. Authorized Inspection Agency (AIA) Inservice: An Authorized Inspection Agency is either: a) a jurisdictional authority as def ) an entity that is accredited y the National Board meeting NB-369, Accreditation of Authorized Inspection Agencies Performing Inservice Inspection Activities; NB-371, Accreditation of OwnerUser Inspection Organizations (OUIO); or NB-390, Qualif0005aaiionsaonsnuaiins io Federal Inspection Agencies (FIAs) Performing Inservice Inspection Activities. SECTION 9 New Construction: An Authorized Inspection Agency is one that is accredited y the National Board meeting the qualif Criteria for Acceptance of Authorized Inspection Agencies for New Construction. Biomass — Fuels which result from iological sources requiring a relatively short time for replenishment: Wood and agasse are typical examples. (15) Biomass Fired Boiler — A oiler which f Capacity Certifcatiio — The verifcation y the National Board that a particular valve design or model has successfully completed all capacity testing as required y the ASME Code. --`,```,```,`,``,-`-`,`,`,`,`--- 110 SECTION 9 NB-23 2015 Boiler — A oiler is a closed vessel in which water or other liquid is heated, steam or vapor generated, steam or vapor is superheated, or any com ination thereof, under pressure for use external to itself, y the direct application of energy from the com ustion of fuels or from electricity or solar energy. The term oiler also shall include the apparatus used to generate heat and all controls and safety devices associated with such apparatus or the closed vessel. --`,```,```,`,``,-`-`,`,`,`,`--- High-Temperature Water Boiler — A power oiler in which water is heated and operates at a pressure in excess of 160 psig (1.1 MPa) and/or temperature in excess of 250°F (121°C). Hot-Water Heating Boiler — A hot water oiler installed to operate at pressures not exceeding 160 psig (1,100 kPa) and/or temperatures not exceeding 250°F (121°C), at or near the oiler outlet. Hot-Water Supply Boiler — A oiler that furnishes hot water to e used externally to itself at a pressure less than or equal to 160 psig (1,100 kPa gage) or a temperature less than or equal to 250°F (120°C) at or near the oiler outlet Power Boiler — A oiler in which steam or other vapor is generated at a pressure in excess of 15 psig (100 kPa) for use external to itself. The term power oiler includes fred units for vaporizing liquids other than water, ut does not include fred process heaters and systems. (See also igh-Temperature Water Boiler). Steam Heating Boiler — A steam oiler installed to operate at pressures not exceeding 15 psig (100 kPa). Carbons Recycle — See Flyash Recycle. Chimney or Stack — A device or means for providing the venting or escape of com ustion gases from the operating unit. Ciofoee pace –– Work locations considered “confnedd ecause their confgurations hinder the activities of employees who must enter, work in and exit them. A confned space has limited or restricted means for entry or exit, and it is not designed for continuous employee occupancy. Confned spaces include, ut are not limited to, underground vaults, tanks, storage ins, manholes, pits, silos, process vessels, and pipelines. Regulatory Organizations often use the term “permit-required confned spaced (permit space) to descri e a confned space that has one or more of the following characteristics: contains or has the potential to contain a hazardous atmosphere; contains a material that has the potential to engulf an entrant; has walls that converge inward or foors that slope downward and taper into a smaller area which could trap or asphyxiate an entrant; or contains any other recognized safety or health hazard, such as unguarded machinery, exposed live wires, or heat stress. Confned space entry requirements may differ in many locations and the Inspector is cautioned of the need to comply with local or site- specifc confned space entry requirements. Conversion Units of Measure –– Changing the numeric value of a parameter from one system of units to another. Conveyor System(s) — A fuel transport system utilized on iomass oilers that drops fuel onto a moving elt, ucket elevator, drag link conveyor, or a screw or auger mechanism. (The speed of the conveyor may e varied to meet fuel demand.) (15) Demonstration — A program of making evident y illustration, explanation, and completion of tasks documenting evaluation of an applicant’s a ility to perform code activities, including the adequacy of the applicant’s quality program, and y a review of the implementation of that program at the address of record and/or work location. SECTION 9 111 SECTION 9 Pressure Relief Devices –– The change of a pressure relief valve from one capacity-certifed confguration to another y use of manufacturer’s instructions. 2015 NATIONAL BOARD INSPECTION CODE (15) Dense Phase Pneumatic System(s) — A atch feed transport system used on solid fuel fred oilers for oth fuel delivery and/or ash removal. In this system the material to e transported is dropped through a valve in a pressure vessel. When the vessel is flled the valve closes and air at a pressure from 30 to 100 psig (200 to 700 kPa) is admitted and the material leaves the vessel in the form of a “slugd. The sequence then repeats. Dutchman — Generally limited to tu e or pipe cross-section replacement. The work necessary to remove a compromised section of material and replace the section with material meeting the service requirements and installation procedures accepta le to the Inspector. Also recognized as piecing. Emissions — The discharge of various Federal or State def atmosphere during a given time period. Emissions Control System — An arrangement of devices, usually in series, used to capture various air pollutants and there y reduce the amount of these materials, or gases, eing admitted to the surrounding atmosphere, elow Federal or State defned standards. Examination — In process work denoting the act of performing or completing a task of interrogation of compliance. Visual o servations, radiography, liquid penetrant, magnetic particle, and ultrasonic methods are recognized examples of examination techniques. Exit — A doorway, hallway, or similar passage that will allow free, normally upright unencum ered egress from an area. Field — A temporary location, under the control of the Certifcate older, that is used for repairs and/or alterations to pressure-retaining items at an address different from that shown on the Certifcate older’s Cioaif0005aaisi s uatioiiaaiios Fluidized Bed — A process in which a ed of granulated particles are maintained in a mo ile suspension y an upward fow of air or gas. Fluidized Bed (Bubbling) — A fuidized ed in which the fuidizing velocity is less than the terminal velocity of individual ed particles where part of the fuidizing gas passes through as u les. Fluidized Bed (Circulating) — A f of the individual ed particles. Flyash — Suspended ash particles carried in the f Flyash Collector — A device designed to remove fyash in the dry form from the fue gas. Flyash Recycle — The reintroduction of fyash/un urned car on from the fyash collector into the com ustion zone, in order to complete the com ustion of un urned fuel, there y improving effciency. SECTION 9 Forced-Flow Steam Generator — A steam generator with no fxed steamline and waterline. Fuel Transport Fan — A fan which generates airfow capa le of moving fuel particles, in suspension, from a metering device to the com ustion zone. Grate — The surface on which fuel is supported and urned and through which air is passed for com ustion. Hydrostatic Test — A liquid pressure test which is conducted using water as the test medium. Inspection — A process of review to ensure engineering design, materials, assem ly, examination, and testing requirements have een met and are compliant with the code. Induced Draft Fan — A fan exhausting hot gases from the heat a sor ing equipment. Inspector — See National Board Commissioned Inspector and National Board Owner-User Commissioned Inspector. --`,```,```,`,``,-`-`,`,`,`,`--- 112 SECTION 9 NB-23 2015 Intervening — Coming etween or inserted etween, as etween the test vessel and the valve eing tested. Jurisdiction — A governmental entity with the power, right, or authority to interpret and enforce law, rules, or ordinances pertaining to oilers, pressure vessels, or other pressure-retaining items. It includes National Board mem er jurisdictions defned as “jurisdictional authorities.d Jurisdictional Authority — A mem er of the National Board, as def National Board Constitution. Lean Phase Pneumatic System(s) — A fuel transport system utilized on iomass oilers that drops fuel into a moving airstream, mixes with the air, and travels through a pipe at a velocity in the region of 5,000 ft/min (1,525 m/min). Air pressures are in the region of 25 inches (635 mm) water column. (15) Lift Assist Device — A device used to apply an auxiliary load to a pressure relief valve stem or spindle, used to determine the valve set pressure as an alternative to a full pressure test. Liquid Pressure Test — A pressure test using water or other incompressi le fuid as a test medium. Manufacturer’s Documentation — The documentation that includes technical information and certif required y the original code of construction. Mechanical Assembly — The work necessary to esta lish or restore a pressure retaining oundary, under supplementary materials, where y pressure-retaining capa ility is esta lished through a mechanical, chemical, or physical interface, as defned under the rules of the NBIC. Mechanical Repair Method — A method of repair, which restores a pressure retaining oundary to a safe and satisfactory operating condition, where the pressure retaining oundary is esta lished y a method other than welding or razing, as defned under the rules of the NBIC. Metering Device — A method of controlling the amount of fuel, or air, f “NR” Certif y the National Board. — An organization in possession of a valid “NRd Cioaif0005aaisi s uatioiiaaiio issued National Board — The National Board of Boiler and Pressure Vessel Inspectors. National Board Commissioned Inspector — An individual who holds a valid and current National Board Commission. NBIC — The National Board Inspection Code pu lished y The National Board of Boiler and Pressure Vessel Inspectors. Nuclear Items — Items constructed in accordance with recognized standards to e used in nuclear power plants or fuel processing facilities. Overf — Air admitted to the furnace a ove the grate surface /fuel ed. Used to complete the com ustion of fne particles, in suspension. Also aids in reducing NOx formation. Owner or User — As referenced in lower case letters means any person, frm, or corporation legally responsi le for the safe operation of any pressure-retaining item. --`,```,```,`,``,-`-`,`,`,`,`--- Owner-User Inspection Organization — An owner or user of pressure-retaining items that maintains an esta lished inspection program, whose organization and inspection procedures meet the requirements of the National Board rules and are accepta le to the jurisdiction or jurisdictional authority wherein the owner or user is located. Owner-User Inspector — An individual who holds a valid and current National Board Owner-User Commission. SECTION 9 113 SECTION 9 Original Code of Construction — Documents promulgated y recognized national standards writing odies that contain technical requirements for construction of pressure-retaining items or equivalent to which the pressureretaining item was certifed y the original manufacturer. 2015 NATIONAL BOARD INSPECTION CODE Piecing — A repair method used to remove and replace a portion of piping or tu ing material with a suita le material and installation procedure. Pneumatic Test — A pressure test which uses air or another compressi le gas as the test medium. Potable Water Heaters — A corrosion resistant appliance that includes the controls and safety devices to supply pota le hot water at pressure not exceeding 160 psig (1,100 kPa) and temperature not in excess of 210°F (99°C). Fired Storage Water Heater — A pota le water heater in which water is heated y electricity, the com ustion of solid, liquid, or gaseous fuels and stores water within the same appliance. Indirect Fired Water Heater — A pota le water heater in which water is heated y an internal coil or heat exchanger that receives its heat from an external source. Indirect fred water heaters provide water directly to the system or store water within the same appliance. Circulating Water Heater — A pota le water heater which furnishes water directly to the system or to a separate storage tank. Circulating water heaters may e either natural or forced fow. Pressure-Retaining Items (PRI) — Any oiler, pressure vessel, piping, or material used for the containment of pressure, either internal or external. The pressure may e o tained from an external source, or y the application of heat from a direct source, or any com ination thereof. Pressure Vessel — A pressure vessel is a container other than a oiler or piping used for the containment of pressure. “R” Certif the National Board. — An organization in possession of a valid “Rd Cioaif0005aaisi s uatioiiaaiio issued y Re-ending — A method used to join original code of construction piping or tu ing with replacement piping or tu ing material for the purpose of restoring a required dimension, confguration or pressure-retaining capacity. Repair — The work necessary to restore pressure-retaining items to a safe and satisfactory operating condition. Re-rating — See alteration. Safe Point of Discharge — A location that will not cause property damage, equipment damage, or create a health or safety threat to personnel in the event of discharge. SECTION 9 Safety Relief Valves — A safety relief valve is a pressure relief valve characterized y rapid opening or pop action, or y opening in proportion to the increase in pressure over the opening pressure, depending on application. (15) Seal Weld — Any weld designed primarily to provide a specifc degree of tightness against leakage. A seal weld is not intended to provide structural integrity to a pressure retaining item. Settings — Those components and accessories required to provide support for the component during operation and during any related maintenance activity. Shop — A permanent location, the address that is shown on the Cioaif0005aaisi s uatioiiaaiio, from which a Certifcate older controls the repair and/or alteration of pressure-retaining items. 114 SECTION 9 --`,```,```,`,``,-`-`,`,`,`,`--- Pressure Test — A test that is conducted using a f item. NB-23 2015 Suspension Burner — A com ustion system in which the fuel is in the form of relatively small particles, Their uoyancy is maintained in the transport airstream and the fuel/air mixture fow stream, until com ustion is completed. Testing Laboratory — National Board accepted la oratory that performs functional and capacity tests of pressure relief devices. Thermal Fluid Heater — A thermal f the direct application of heat from a thermal energy source. Depending on the process heating requirements, the fuid may e vaporized with normal circulation ut, more often, the fuid is heated and circulated y a pump. Transient — An occurrence that is maintained only for a short interval as opposed to a steady state condition. Uoeerfre ir — A method of introducing air eneath the grate surface/fuel ed. “VR” Certif y the National Board. — An organization in possession of a valid “VRd Cioaif0005aaisi s uatioiiaaiiosissued Velocity Distortion — The pressure decrease that occurs when f sensing line. This is a distortion of the pressure that would e measured under the same conditions for a non or slowly moving fuid. SECTION 9 Water Head — The pressure adjustment that must e taken into account due to the weight of test media (in this case, water) that is 0.433 psi/ft (10 kPa/m) added (su tracted) from the gage pressure for each foot the gage is elow (a ove) the point at which the pressure is to e measured. --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 9 115 2015 NATIONAL BOARD INSPECTION CODE PART 1, SECTION 10 INSTALLATION — NBIC APPROVED INTERPRETATIONS 10.1 SCOPE a) This section provides a list of all approved interpretations for previous editions and addenda of the NBIC. A complete list of interpretations including approved interpretations for this edition is provided on the National Board website. b) Each interpretation references the edition and addenda applicable to the committee response and approval. Use of interpretations, for other than the approved edition and addenda, may not be appropriate for reference. c) Technical inquiries (also known as “request for interpretation”) may be submitted to the NBIC committee to clarify the meaning or intent of existing rules to the NBIC. The requirements for submitting technical inquiries are described in NBIC Parts 1, 2, and 3 (Section 8), Preparation of Technical Inquiries to the NBIC Committee. 2013 INTERPRETATIONS Interpretat Part Sect Subject 13-04 2013 3 3.3.2 e) Seal Welding of Inspect 13-03 2011 3 3.3.2 d) 1) 13-02 2011 3 5.7.5 Stamping Requirements for Alteratons 13-01 2013 3 1.8.5 q) Personnel Qualifed IAW AASIIASME AN4..2 Standard Threaded Fitn ASME VIII, Div. 1 Vessel 2011 INTERPRETATIONS nEdtRn Part Sect 11-06 2011 3 3.2.5 Calculatons I Start of Worr 11-05 2011 2 5.2.2 – 5.2.3 Replacement of Stamped Data on Corrugator Rolls 11-04 2011 3 1.7 Applicaton of VRR Stamp 11-03 2011 2 2.5.8 Test Frequencies 11-02 2011 3 4.4.2 a) Liquid Pressure Test Requirements 11-01 2011 3 3.3.2 Routne Repair Consideratons 2007 INTERPRETATIONS InterpretatRn nEdtRn Addenda Part SECTION 10 Subject 07-16 2007 07-15 2007 07-14 SectRn Subject 3 3.3.5.2 2008 2 S2.10.6 Average Pitch 2007 2009 3 3.3.3 Replacement of Pressure Retaining Parts 07-13 2007 2009 All 07-12 2007 2009 3 116 SECTION 10 Requirement for Repair I Alterat The Original Code of Constructon 3.4.3 Replacement of Heads with Diferent TTpes --`,```,```,`,``,-`-`,`,`,`,`--- InterpretatRn NB-23 2015 SectRn Subject 07-11 2007 2010 3 3.2.2 a) Replacement Parts 07-10 2007 2009 3 3.3.2–3.3.3 Routne Repairs 07-09 2007 2008 2 S2.9 b) & S2.11 b) 7) b) Schedule 80 Pipe in External Piping 07-08 2007 2009 3 3.4.3 c) Handhole Replacement with Flush Patch 07-07 2007 2009 3 3.3.4.3 e) & 3.3.2 d) 3) 07-06 2007 07-05 2007 07-04 3 2008 Weld Buildup of Wasted Area I Rout Replacement Parts for Repairs and Alterat Change-Over Valve Permited in ASME Code Case-.4N Use 1 2.9.5.1 c) 2007 1 4.5.1 a) 07-03 2007 3 2.5.3 07-02 2007 3 1.6.2, 1.7.5.4, & 1.8.2 ABIC Manual Requirements for RR, VRR, and ARR Stamp Holders 07-01 2004 RB-8400 & RB8410 TrT TestngR of Pressure Relief Valves 2006 --`,```,```,`,``,-`-`,`,`,`,`--- 2004 INTERPRETATIONS InterpretatRn nEdtRn Addenda 2005 Installat Holder Use of Alternat and P-Ao 4A Base Material SectRn Subject RC-1110, RC-.040(c), RC-2020(c), & RC-2021(e) Jurisdictonal Acceptance of ADE 04-23 2004 04-22 2004 04-21 2004 2005 RC-1120 04-20 2004 2005 RC-.041(d) & RC2021(b) 04-19 2004 2005 RD-2020 04-18 2004 2005 RD-3010 04-17 2001 2003 RD-.0.0(c) 04-16 2004 RA-2370 04-15 2004 RD-2060 Utliiing a Flush Patch to ain Access Window in Pressure Retaining Items 04-14 2004 RC-1000 & RC-2000 Replacement SafetT Valves with Dif ites and Set Pressures than Boiler Data Report RC-1120 Inspector Verif Inspector Involvement in ADE in Lieu of Pressure Test Pneumat Repair of Threaded Bolt Holes Re-rat Original Code of Constructon Procedures for Repairing Cracrs and Cracr Classifcaton ARR Cert Replacement Program SECTION 10 SECTION 10 2007 INTERPRETATIONS Interpretat Addenda Part 117 2015 NATIONAL BOARD INSPECTION CODE SectRn Subject RC-10.0, RC-1020, Appendix N, & RC-20. Replacement of a Cast Iron Secton Post Weld Heat Treatment of Parts 04-13 2004 04-12 2001 2003 RD-1020, RC-1040(c) 04-11 2001 2003 RC-1040(c), RC-.040, & RC-.041 04-10 2004 RC-.021 04-09 2004 RC-.021 04-08 2004 RE-1050 Fabricated Replacement Crit 04-07 2004 RE-1050 Source for Crit 04-06 2004 RC-1040(c), RC-.040, RC-.041, & RC-1110 Writen Procedure Requirements for Aon-Destructve Examinatons 04-05 2001 RC-1040(c) & RC-.040 RR Stamp Holder Installat turer Supplied Parts 04-04 2004 RC-20.(b) & (d) 04-03 2004 RC-20.(b) & (d) 04-02 2004 RA-2213 04-01 2004 RD 2003 Requirements for Test Flush Patches in Pipes and Tubes APS 4 or less Rout Re-rat - ServiceIRemoval of Insulaton Re-rat VRR Cert of Insulat turer’s Aameplate CapacitT - Use of Welded Encapsulat Build Up or Flush Patch 2001 INTERPRETATIONS SECTION 10 InterpretatRn nEdtRn Addenda SectRn Subject Alterat 01-41 2001 2003 Appendix . & 4 01-40 2001 2003 RC-.041(e), RC-2021(c), RC-.040, & RC-2020(c) 01-39 2001 2003 RC-2041 01-38 2001 2003 RD-20.(d) Design OnlT RR Stamp Holders Pressure Testing and Form R-. 01-37 2001 2003 RC-11N0 & RC-20N0 Constructon Phase & Stamping when Re-rating without PhTsical Changes 01-36 2001 2002 RC-10.0(b) 01-35 2001 2002 RC-10N0 01-34 2001 2002 RD-1060(h)(.) 01-34 2001 2002 RD-10N0(i)(6) 118 SECTION 10 Stamping Use of VT when Pressure Test Is Aot Pract ble Inspector Responsibilit Witnessing Pressure Test Applicat sure Retaining Items - Is Pre-AssemblT of a Part Considered Fabricaton But Shielding as Dewpoint Temperature --`,```,```,`,``,-`-`,`,`,`,`--- 2004 INTERPRETATIONS Interpretat Addenda NB-23 2015 2001 INTERPRETATIONS Addenda SectRn Subject Evaluat 01-33 2001 2002 U -N4 01-32 2001 2002 Introducton 01-31 2001 2002 RB-3238 01-30 2001 2002 RC-1040(c) 01-29 2001 2002 RC-.070 01-28 2001 2002 RC-10N0 Use of Material That Has Been PreviouslT Inservice 01-27 2001 2002 RC-1090 Welding Using Welders Who Are Aot EmploTed bT the RR Stamp Holder 01-26 2001 2002 RB-2.28(f) Criteria for Determining Actual Thicrness and Maximum Deterioraton 01-25 2001 RC-2040 01-24 2001 RC-1110(a) ADE of Tacr Welds bT Welders and Welder Operators 01-23 2001 RC-.021(a)(1) Routne Repairs 01-22 2001 RC-.021 01-21 2001 Appendix 6, Part B 01-20 2001 RC-.021(a)(1) Routne Repairs 01-19 2001 RC-.021(a)(1) Routne Repairs 01-18 2001 8-4000(b) Repairs 01-17 2001 RC-20.1 Calculatons 01-16 2001 RC-2000 Alteratons to ASME Secton VIII, Div. . Vessels 01-15 2001 RC-.041 01-14 2001 RC-.08.(b) Repair Plan (Sec. VIII, Div. .) AIA Acceptance 01-13 2001 RB-4010 Replacement of Stamped Data 01-12 2001 RA-2274 Use of OwnerIUser Personnel during Repairs of Pressure Relief Valves 01-11 2001 RC-20. Re-ratng Based on Joint EEciencT 01-10 1998 2000 RD-1000 Alternatve Postweld Heat Treatment Methods 01-09 1998 2000 RC-.021(a)(1) Routne Repairs Requirement of U -N4 Are Reference Codes and Standards Acceptable Determinat Boilers and Pressure Vessels Fabricat Holder Installat Document RR Stamp Organiiatons Rout Alternat Weld Heat Treatment Pressure Test Repairs and Alterat Isolat Retaining Item SECTION 10 Interpretat --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 10 119 2015 NATIONAL BOARD INSPECTION CODE 2001 INTERPRETATIONS Interpretat Addenda SectRn Subject ManuallT Operated Locring Devices 01-08 1998 2000 RB-3853 01-07 1998 2000 RA-.020(a) 01-06 1998 2000 RA-2010 01-05 1998 2000 RA-.220(n) ARR Program Audits 01-04 1998 2000 RC-.040, RC-2020, RA.141(m) Calibraton of Pressure ages 01-03 1998 2000 Appendix N Pressure Retaining Items 01-02 1998 1999 RC-.021(a)(2) Weld Metal Build-Up 01-01 1998 1999 RA-.220(g) Owner-User Inspect Accreditat Demonstraton for an ARR Certf Authoriiaton 1998 INTERPRETATIONS InterpretatRn nEdtRn --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 10 Addenda SectRn Subject Welder Performance Qualif 98-44 1995 1997 RC-1092 98-43 1998 1999 Forward, Appendix N & Appendix 4 98-42 1998 1999 RC-.021, RD-.020(d) Weld Buildup of Wasted Area of Boiler Tubes 98-41 1998 RA-.220(g) Compliance with Part RA-.220(g) 98-40 1998 RD-2070 Replacement of Threaded StaTs with Welded StaTs 98-39 1998 1999 R-1 & R-. Forms Inspector Requirements 98-38 1998 1999 RC-2021(c) ADE in Lieu of Pressure Test 98-37 1998 1999 RC-1040(a) Material Requirements 98-36 1998 1999 RD-2050 Original Code of Constructon 98-35 1998 1999 RB-4000 Restamping or Replacement of Aameplate 98-34 1995 1996 RC-2020 Examinaton and Testn 98-33 1998 RC-.041 Liquid Pressure Test of Repairs 98-32 1998 RC-20. 98-31 1998 RC-.021 98-30 1998 Appendix 6C 98-29 1998 Appendix 6 Tube Placement 98-28 1998 RC-1040(c) Replacement Parts Fabricated bT an RR Cert cate Holder 98-28 1998 Appendix 6 Pressure Retaining Replacement Items 98-28 1998 RC-1040 Defniton of Aew Replacement Parts 98-27 1995 1996 RC-.040(b) Pressure Test 98-27 1995 1996 RC-1040 Replacement Parts 120 SECTION 10 Alterat Re-rat Replacement of a Aoiile as Rout Example of Alterat ing - NB-23 2015 1998 INTERPRETATIONS Addenda SectRn Subject Resetn 7.2 or Sect 98-26 1998 RA-.6.(b)(1) 98-25 1998 RA-.6.(b)(2) 98-24 1998 RA-.N.(c) 98-23 1995 Appendix 6, B-7 98-22 1998 RC-1010 98-21 1998 RA-.120(f) 98-20 1998 RC-20. Re-ratng 98-19 1998 RB-3237 Inspecton Interval 98-18 1998 RC-.021(a)(1) Routne Repairs 98-17 1998 RA-2281 Testng Medium and Testng Equipment 98-16 1998 RA-3020 Prerequisites for Accreditaton 98-15 1995 98-14 1998 Appendix 6 98-14 1998 RC-1040 Replacement Parts 98-14 1998 RC-20. Re-ratng RC-20.0 Design 1996 98-14 RC-20. & RC2020(h) Stamping on Repair Aameplate VRR Cert 1945 Head and Shell Thicrness Limitat stalling Aoiiles - Scope Requirements for Applicants for RR Cert Authoriiat Pressure Test - ing Actvite Examples of Repairs and Alterat --`,```,```,`,``,-`-`,`,`,`,`--- 98-13 1995 1996 RA-.141(r) QC Manual Requirements 98-12 1995 1996 RA-.21(b)(1) Use of Code Case .02 in Repairs 98-11 1995 1996 RA-3050 Owner-User Program Accreditat tons 98-10 1995 RC-1110 ADE Requirements for ASME Sect Repairs 98-09 1995 RB-3640 98-08 1995 1996 RD-2010 98-07 1995 1996 RA-.220(d) 98-06 1995 1996 RC-1090 Welding Aon-Pressure Parts in a Pressure Retaining Item 98-06 1995 1996 RD-1010 Alternatve Methods of ADE 98-05 1995 1996 Forward 98-04 1995 1996 RC-.021 98-03 1995 98-02 1995 98-01 1995 - Inspect Repair Methods ASME Sect Determinat Rout RB-2.28(f) Interrupted Service 1996 RA-2231 Conditons of Use 1997 RC-.021(a)(1) SECTION 10 Interpretat At SECTION 10 121 2015 NATIONAL BOARD INSPECTION CODE 1995 INTERPRETATIONS Interpretat Addenda SectRn Subject --`,```,```,`,``,-`-`,`,`,`,`--- 95-57 1995 1996 RB-2.28(e) Above round Vessels 95-56 1995 1996 RA-.21(b)(1) Acceptance of Code Cases 19.2 & 19N4 95-55 1995 1996 RB-3550 Operatonal Inspecton 95-54 1995 1996 RC-.040 Pressure Testng 95-53 1995 RD-2031 Routne Repairs 95-52 1995 1996 RD-2060 Patches, Figure 8 95-51 1995 1996 RC-1090 95-50 1995 1996 RC-.07. & RC-204. R-2, R-N, & Manufacturer’s Partal Data Report 95-49 1995 Appendix 6, B-17 P Aumbers 95-48 1995 RC-10.0, RB-1040(a) & Appendix 6, B-6 R-1 Forms 95-47 1995 RB-4020 95-46 1995 Appendix 6, B-7 Examples of Repairs 95-45 1995 Appendix N Repairs and Alteratons 95-44 1995 Appendix 6, C-4 Alteratons 95-43 1995 Appendix 4 Repairs 95-42 1995 RC-.070 & RC-2040 R-1 & R-. Forms 95-41 1995 RC-1110 95-40 1995 Appendix 4 Form R-. 95-39 1995 RC-.040 Pressure Testng of Routne Repairs 95-38 1995 RB-3234 Inservice Pressure Test Weld ProceduresIQualif Replacement Aame Plates & Aat Aumbers Indicat inal Code of Constructon SECTION 10 95-37 - Withdrawn RC-10.0 Worr Performed to a Code Other than the Original Code of Construct R-200 Welding of Tube Plugs Appendix N Inspector Responsibilites Appendix C-R, N.0 (f) Field Repairs in Other Shops Owned bT the Cert 1995 RC-.021(a)(.) Aon-Load Bearing Atachments 95-32 1995 RC-.040 Pressure Testng 95-31 1995 RC-.021 Waiving the Inprocess Involvement of the Inspector 95-30 1995 Data Report Forms 95-29 1995 RC-1070 95-28 1995 RC-.021 95-27 1995 RC-.021 95-36 1995 95-35 1992 95-34 1995 94-22(a) 1992 95-33 122 SECTION 10 1994 1994 API-410 Report Aon Aat tors R-1 Forms Inspector Involvement for Rout Repairs Rout - NB-23 2015 SectRn Subject Registraton of R-1 Forms 95-27 1995 RC-.040 95-27 1995 RC-.060 95-27 1995 RC-.07. ResponsibilitT for Performing Pressure Test 95-26 1995 RA-2262 Valve Aameplate Contents 95-25 1995 Appendix 4 Inspectors Requirements for Form R-1 on Rout 95-24 1995 Appendix . Aameplate Stamping and LaTout 95-23 1995 RC-1010 Documentaton of Repairs to Aon-STmbol Stamped Cargo Vessels 95-22 1995 RC-20.0 & RC-20.1 95-21 1995 Appendix N Repairs to PWHT Vessels Without Subsequent PWHT 95-20 1995 Foreword Use of Earlier Editon and Addenda 95-19 1995 RC-1000 95-18 1992 1994 Appendix C-AR & AR1000 95-17 1992 1994 R-404 95-16 1992 1994 R-302.1 OwnerIUser Supplied Weld Procedures 95-15 1992 1994 R-307 Use of Replacement PartsIAssemblies from Other Inservice Vessels 95-14 1992 1994 R-202 Repairs to PWHT Vessels without Subsequent PWHT 95-13 1992 1994 U-106 Maximum Period between Inspect 95-12 1992 1994 U-107 Inspect 95-11 1992 1994 R-503 Re-rat 95-10 1992 1994 R-301.2.2 95-09 1992 1994 Chapter III, Supplement 3 95-08 1992 1994 Appendix C-R 95-07 1992 1994 Appendix C-R, 2.0 95-06 1992 1993 R-401.2.2 95-05 1992 1993 Purpose and Scope 95-04 1992 1993 U-107 95-03 1992 1993 R-200, R-404, R-505 Use of Similar & Aon-Similar Base MetalsIRepair-Alteraton 95-02 1992 1993 R-307 Use of R-Form When Replacing Parts with Dif ent Materials without Welding 95-01 All Applicat Reclassif Original Code of Construct Scope and ApplicabilitT Document Performed bT Others Owner User Acceptance Inspect and Alterat Welding Methods as an Alternat Heat Treatment uide for Completng Form R-1 Access Openings When Does the ABIC Tare Ef or Pressure Vessels Inspect What Editons of the ABIC overns SECTION 10 123 SECTION 10 Renewal of RR Certfc --`,```,```,`,``,-`-`,`,`,`,`--- 1995 INTERPRETATIONS Interpretat Addenda 2015 NATIONAL BOARD INSPECTION CODE 1992 INTERPRETATIONS Interpretat Addenda SectRn Subject 94-2 1992 Chapter III, R-301.1 94-1 1989 Chapter III Repair of Valves Covered bT B21.1 93-6 1992 Chapter III Re-ratng bT Performing RadiographT & Recalculatng Joint EEciencT 93-5 1992 Chapter III, R-402(d) 93-4 1992 Chapter III, R-301.2 93-2 1992 Alteratons 93-1 1992 Requirements when More than One Inspector is Involved in a Repair 92-7 1992 92-6 1992 92-5 1992 92-4 1992 Inspector Approval for Rout Requirement for Pressure Test when Re-rat Vessel Owner User Acceptance Inspect Alteratons with Dife ing Design Calculat - Out of State Organiiat Alternat Replacement of Tubes with Equal or reater Allowable Stress SECTION 10 --`,```,```,`,``,-`-`,`,`,`,`--- Chapter III, Supplement 1 Jurisdict 124 SECTION 10 NB-23 2015 PART 1, SECTION 11 INSTALLATION — INDEX A B Acceptance (Foreword), (1.4.5), (1.5), (2.3.3), (2.10), (2.10.4), (2.10.5), (2.10.6), (3.3.4), (3.7.9.1), (3.7.9.2), (3.10), (3.10.2), (3.10.3), (4.5.6), (4.6), (4.7.6), (5.3.6), (S5.3.4), (S5.8), (S5.8.4), (S5.8.5), (S5.8.6) (8.2), (9.1) Biomass (S4.1), (S4.2), (S4.4) Accreditation (Introduction), (9.1) Programs (Introduction) Acoustic Emission (S1.5) Addenda (Introduction), (1.4.2), (8.2), (9.1), (10.1) Administrative Requirements (Introduction), (8.1) Alteration (Foreword), (Introduction), (1.4.1), (S1.2), (7.1), (7.2), (9.1) American National Standards Institute (ANSI) (Foreword), (S3.5), (9.1) Appurtenances (2.4.4), (2.5.3.1), (2.10.1), (3.3.4), (3.5.3), (3.5.3.2), (4.6), (5.2.2), (5.2.5), (5.2.7), (S5.5.7), (S5.8.1), (S6.13.4), (S6.13.6), (S6.14.3), (S6.17) Ash Removal (2.6.2), (3.6.2), (S4.2), (S4.5), (S4.6) ASME Code (1.4.5.1), (S1.2), (S1.3), (S1.4), (S2.5), (S3.5), (S3.6.2), (9.1) Authority (1.4.1), (4.3.4), (5.2.9), (9.1) Blowdown (1.4.5.1.1), (2.7.5), (3.6.3), (3.8.1.3) Blowoff (2.5.1.2), (2.6.3.1), (2.7.5), (2.10.2), (3.7.5), (3.7.7), (3.7.7.1), (3.7.8.1), (3.8.1.5), (3.11) Boiler Installation Heating Boilers (3.1) Hot Water Supply Boilers (3.1) Power Boilers (2.1) Report (1.4.5) Steam Heating (3.1) Boilers Cast Iron (1.4.5.1.1), (3.8.1.3), (3.9.2), (3.9.3) Electric (1.4.5.1.1), (2.5.1.2), (2.7.5), (2.8.1), (2.9.1.1), (2.9.1.3), (3.8.1.2) Firetube (2.8.1), (2.9.1.3), (3.3.1.1), (3.9.2) Historical/Hobby (Introduction) Locomotive (Introduction) Modular (3.7.8.2) Organic and Inorganic Fluid (2.9.1.3), (3.9.2) Burners (2.7.2), (3.7.3), (S4.2), (S4.6), (S5.5.7) --`,```,```,`, SECTION 11 125 SECTION 11 Authorization (Foreword), (9.1) 2015 NATIONAL BOARD INSPECTION CODE C Codes and Standards (Foreword), (3.5.3.2), (S4.6), (S5.5.7) Calculations (3.7.9.1), (3.7.9.2), (4.5.4), (5.3.4), (S1.3), (7.3), (7.4), (8.4) Combustion Air (1.4.5.1), (1.4.5.1.1), (2.5.4), (3.5.4), (S4.2), (S4.6), (S5.5.8) Capacity (1.4.5.1), (1.4.5.1.1), (2.4.1), (2.5.1.1), (2.5.1.3), (2.5.3.2), (2.5.4), (2.9.1.1), (2.9.1.3), (2.9.2), (2.9.3), (2.9.4), (2.9.5), (2.9.6), (3.4.1), (3.4.5), (3.5.4), (3.7.6), (3.7.7.1), (3.7.9.1), (3.7.9.2), (3.9.1.1.2), (3.9.1.5), (3.9.1.6), (3.9.2), (3.9.3), (3.9.4), (3.9.4.3), (3.9.4.7), (3.9.5.2), (3.9.5.3), (4.5.1), (4.5.4), (4.5.5), (4.5.6), (5.3.1), (5.3.4), (5.3.5), (5.3.6), (S2.1), (S2.2), (S2.3), (S2.4), (S3.6) (S2.8.1), (S2.11), (S2.15), (S5.3.1), (S5.3.3), (S5.4.1), (S5.5.8), (S5.7.4), (S5.7.5), (S5.7.6), (S6.8), (S6.13.9), (S6.13.11.2), (9.1) Commissioned Inspector (1.4.1), (9.1) Capacity Certifcatiio (5.3.1), (9.1) Carbon Recycle (S4.2) Certifcate io Attiriiatiio (Introduction), (9.1) Certifcatiio (1.1), (1.4), (1.4.1), (1.4.2), (1.4.5.1.1), (5.3.1), (9.1) Chimney or Stack (2.6.1), (3.6.1), (S5.6.1), (9.1) Cleaning (2.4.4), (2.6.3), (3.6.3), (3.7.4), (3.7.6), (3.8.1.2), (3.8.1.3), (5.2.7) Condensate (2.5.1.2), (2.7.4), (S1.1) Connections (1.4.5.1), (1.4.5.1.1), (2.5.1.2), (2.5.1.4), (2.6.3.2), (2.7.5), (2.8.1), (2.8.2.1), (2.9.6), (2.10.1), (3.5.1), (3.7.4), (3.7.5.1), (3.7.5.2), (3.7.6), (3.7.7.1), (3.8.1.1), (3.8.1.3), (3.8.1.4), (3.8.1.5), (3.8.1.2), (3.9.1.1.2), (3.9.1.2), (3.9.4.3), (3.9.4.4), (4.3.4), (4.4.1), (5.2.9), (S3.2.3), (S3.6), (S5.5.3), (S5.5.4), (S5.5.5), (S5.7.2), (S5.7.6), (S5.8.1) Continued Service (DOT) (Introduction), (7.1) Controls (2.5.3.1), (2.5.3.2), (2.5.3.3), (2.5.6), (2.8), (2.9.2), (3.5.3), (3.5.3.2), (3.5.3.3), (3.5.6), (3.7.5), (3.8), (3.8.1.4), (3.8.1.7), (3.8.2.3), (3.8.2.4), (3.8.2.6), (3.8.3.1), (3.10.2), (4.4), (S1.2), (S2.1), (S4.2), (S4.6), (S5.1), (S5.5.7), (S5.5.10), (9.1) Conversion (7.2), (7.3), (7.4.1), (9.1) Cracks (S1.6), (S3.6), (S5.5.7) D Code Interpretation (Introduction), (8.1), (8.2), (8.4) Defect (S3.6) Code of Construction (Foreword), (1.4.2), (1.4.5.1.1), (2.10.1), (2.10.2), (2.10.3), (3.3.1.1), (3.7.5.1), (3.7.8.1), (3.7.9.1), (3.7.9.2), (3.8.1.4), (3.10.1), (4.5.3), (4.5.4), (4.5.5), (4.6), (5.2.5), (5.3), (5.3.3), (5.3.4), (5.3.5), (5.4), (5.2.2), (5.3.7), (5.3.7.1), (S5.5.2), (S5.7.1), (S5.7.2), (S5.7.3), (S5.7.4), (S5.7.5), (S5.7.6), (S5.8.1), (S5.8.3), (S6.4.5), (S6.5.2), (S6.7), (S7.2), (S7.7), (7.1), (9.1) Dents (S1.1) --`,```,```,`,``,-`-`,`,`,`, SECTION 11 Clearances (1.4.5.1.1), (2.3.3), (3.3.4), (4.3.2), (S5.3.4), (S5.4.2) Compressible Fluid Service (4.5.3) 126 SECTION 11 NB-23 2015 Design (Foreword), (Introduction), (1.2), (1.3), (2.3.1), (2.5.1.3), (2.6.3.2), (2.7.3), (2.8.1), (2.9.1), (2.9.1.3), (2.9.2), (2.9.6), (3.3.1.1), (3.5.1), (3.7.7.1), (3.7.9.1) (3.8.2.4), (4.3.1), (4.4.2), (4.5.6), (5.2), (5.2.1), (5.2.4), (5.2.6), (5.3.6), (S1.2), (S1.3), (S1.4), (S2.1), (S3.2.1), (S3.4), (S3.6), (S4.2), (S5.2), (S5.3.1), (S5.5.3), (S5.5.4), (S5.5.5), (S5.5.7), (S5.7.2), (S5.7.6), (7.1), (8.4), (9.1) Documentation (Foreword), (Introduction) (1.3), (1.4.1), (S1.3), (7.1), (9.1) DOT (Transport Tanks) (Introduction), (7.1), (9.1) Drains (2.4.3), (2.6.3.2), (2.6.3.3), (2.7.3), (2.8.1), (2.9.6), (3.6.3), (3.7.7.1), (4.5.6), (5.3.6), (S5.5.2), (S5.6.2), (S5.6.3), (S5.7.6) Drawings (8.4) E Economizers (2.5.1.4), (2.6.3.3), (2.7.5), (2.9.4), (2.10.2) Effective Edition (Foreword) Electrical (1.4.1), (2.5.3), (2.5.3.1), (2.5.3.3), (3.4.1), (3.5.3), (3.8.3.1), (S3.2.1), (S5.5.7) Emissions (S4.2), (S4.6) Engineering Judgment (Foreword), (7.2) EqAipmeot Certifcatiio (1.4.2) Equipment Room Requirements (2.3.3), (2.4), (2.5.3.2), (2.5.4), (2.5.5), (3.4), (3.5.3.1), (3.5.3.2), (3.5.4), (3.6.3), (S5.5.7), (S5.5.8), (S5.5.9) Exit (2.4.1), (2.4.2), (3.4.1), (3.4.2), (S5.4.1), (S5.4.2), (9.1) Expansion Tanks (3.7.9.1), (3.9.2), (S5.1), (S5.5.2), (S5.5.3), (S5.5.7) F Facility (1.4.1), (2.5.3.2), (S3.5), (S4.2) Failure Mechanisms (Introduction) Fatigue (S1.3), (S1.4) Feedwater (2.5.1.1), (2.5.1.2), (2.5.1.3), (2.5.1.3), (2.5.1.4), (2.8.1), (2.9.1.3), (2.10.2), (3.7.4), (3.7.8.2), (3.8.1.3), (3.8.1.5) Field (4.6), (S1.5), (7.4.1), (9.1) Fillet Weld (3.3.1.1) Firebox (2.9.1.3), (3.5.3), (3.7.6), (3.9.2), (S5.5.7) Fittings (2.6.3.1), (2.7.3), (2.7.5), (2.9.1.2), (2.10.2), (3.8), (3.8.1.2), (3.8.1.3), (3.8.1.5), (3.8.1.7), (3.8.2.6), (4.5.6), (5.3.6), (S3.2.3), (S3.6), (9.1) Flanges (2.6.3.2), (2.9.1), (5.2.4), (S5.5.5), (S5.6.2) Fluidized Bed (S4.2), (S4.6) Flyash (S4.6) Forced-Flow Steam Generators (2.5.1.3), (2.7.5), (2.9.1.3) Foundations (2.3.1), (4.3.1), (S3.2.1), (S5.3.1) --`,```,```,`,``,-`-`,`,`,`,`--- SECTION 11 127 SECTION 11 Examination (Introduction), (2.10.3), (5.4), (S1.6), (S5.8.3), (9.1) 2015 NATIONAL BOARD INSPECTION CODE Full Penetration Weld (S5.5.5) G Gage Glass (1.4.5.1), (1.4.5.1.1), (2.8.1), (3.7.4), (3.7.5), (3.8.1.2), (3.8.1.3), (3.8.1.5), (3.8.1.6) Gages (2.8), (2.8.1), (3.8.1.1), (3.8.1.3), (3.8.2.1) Grooving (1.1) H Hangers (3.3.1.1), (5.2.6) Heat Treatment (Introduction), (5.2.8) High Temperature Water (2.5.1.2), (2.5.1.4), (2.6.3.1), (2.8.3), (2.9.1), (2.9.1.3), (2.9.1.4), (2.9.6), (3.9.5.2), (3.9.5.3), (S5.5.4), (S5.5.5), (S5.5.7), (9.1) Hold Time (S3.2.2) Hydrostatic Test (2.3.1), (2.7.3), (3.7.5.1), (3.7.9.1), (4.3.1), (S5.8.2), (9.1) I Induced Draft Fan (S4.2), (S4.6) Inservice Inspection (Introduction), (1.4.1), (8.1), (9.1) Inspection (Foreword), (Introduction), (1.4), (1.4.1), (1.4.2), (1.4.4), (1.4.5), (2.3.3), (2.4.2), (2.7.5), (2.10.1), (2.10.6), (3.3.2), (3.3.4), (3.4.2), (3.7.4), (3.10.2), (3.10.3), (4.3.2), (4.5.6), (4.7.2), (5.3.6), (5.4), (S1.2), (S3.2.1), (S5.3.4), (S5.4.2), (S5.8.1), (S5.8.6), (7.1), (8.4), (9.1) Inquiries (Foreword), (8.1), (8.2), (8.5) Instruments and Controls (4.4) Insulation (3.3.2), (S3.6.1), (S5.3.2), (S5.5.5) Interpretations (Foreword), (8.1), (8.4), (10.1), (10.2) Intervening (2.9.1.2), (2.9.3), (3.7.8.2), (3.9.2), (3.9.3), (3.9.4), (4.5.6), (5.3.6), (S5.7.6), (9.1) J Jurisdiction (Foreword), (Introduction), (1.1), (1.3), (1.4), (1.4.1), (1.4.3), (1.4.5), (1.4.5.1), (1.4.5.1.1), (1.5), (2.3.1), (2.3.2), (2.3.3), (2.5.2), (2.5.3.2), (2.5.3.3), (2.5.4), (2.6.1), (2.6.2), (2.7.1), (2.7.2), (2.7.5), (2.9.6), (2.10.4), (2.10.5), (2.10.6), (3.3.3), (3.3.4), (3.5.2), (3.5.3), (3.5.4), (3.6.1), (3.6.2), (3.7.2), (3.7.3), (3.10.3), (4.3.1), (4.3.4), (4.4.1), (4.5.4), (4.5.6), (4.6), (5.2.9), (5.3.4), (5.3.6), (S3.2.1), (S3.5), (S4.3), (S5.3.1), (S5.3.2), (S5.3.4), (S5.5.5), (S5.6), (S5.5.7), (S5.5.8), (S5.6.1), (S5.8.4), (S5.8.5), (S5.8.6), (9.1) K L Ladders and Runways (2.4.2), (3.4.2), (S5.4.2) Level Indicating Device (4.4.1) Lighting (2.5.5), (3.5.5), (S5.5.9) SECTION 11 Liquid Carbon Dioxide Storage Vessels (S3.1) 128 SECTION 11 --`,```,```,`,``,-`-`,`,`,`,`--- Fuel (1.4.5.1), (1.5.1.1), (2.4.1), (2.5.1.2), (2.5.2), (2.5.3.2), (2.5.4), (2.8.1), (2.9.1.3), (2.9.1.3), (3.4.1), (3.5.2), (3.5.3), (3.5.4), (3.7.5), (3.8.1.3), (3.8.1.4), (3.8.1.5), (3.8.2.3), (3.8.2.4), (3.8.2.5), (3.8.3.1), (3.9.2), (3.9.3), (3.9.4), (S1.1), (S4.1), (S4.2), (S4.4), (S4.5), (S4.6), (S5.4.1), (S5.5.6), (S5.5.7), (S5.5.8), (9.1) NB-23 2015 Locations (2.5.3), (2.5.3.2), (3.5.3.1), (3.5.3.2), (S3.4), (S5.5.7), (S5.7.3), (S5.7.6), (9.1) Low-Water Fuel Cutoff (1.4.5.1), (1.4.5.1.1), (2.8.1), (3.7.5), (3.8.1.3), (3.8.1.5), (3.8.2.4), (3.8.2.5) M Maximum Allowable Working Pressure (MAWP) (1.4.5.1.1), (2.7.3), (2.7.5), (2.8.2.1), (2.9.1.3), (2.9.1.4), (2.9.2), (3.8.1.4), (3.9.2), (3.9.3), (3.9.4), (3.9.5.1), (3.9.5.2), (3.9.5.3), (4.5.2), (4.5.5), (4.7.3), (5.3.2), (5.3.5), (S1.5), (S2.13.9.5), (S3.6), (S3.6.1), (S5.7.5), (9.1) Operating Systems (2.7), (3.7), (S4.6), (S5.2), (S5.5.7) Organization (Foreword), (Introduction), (1.4.3), (2.5.3.3), (3.5.3), (S5.5.7), (9.1) Overf (S4.2), (S4.6) Overheating (3.8.1.2), (3.8.2.4), (S5.5.7) Owner (Introduction), (1.1), (1.3), (1.4.1), (1.4.3), (1.4.5), (2.10.6), (3.10.3), (4.5.4), (4.6), (5.3.4), (5.4), (S1.2), (S5.8.6), (9.1) Owner-User (Introduction), (1.1), (1.2), (1.3), (1.4.5.1), (1.4.5.1.1), (S4.2), (9.1) Metering Device (S4.2), (S4.5) Owner-User Inspection Organization (Introduction), (9.1) Metrication Policy (Introduction), (7.1), (7.2), (7.3), (7.4) P Minimum Thickness (3.3.1.1) Parts (Foreword), (Introduction), (2.6.3.3), (2.9.2), (3.7.4), (3.7.7.1), (S1.3), (7.4), (8.4), (9.1) N National Board (Foreword), (Introduction), (1.4.1), (1.4.5.1), (1.4.5.1.1), (2.9.1.1), (3.9.1.6), (3.9.2), (3.9.3), (3.9.4), (3.9.5.2), (3.9.5.3), (4.5.1), (4.5.4), (5.3.1), (5.3.4), (8.1), (8.5), (9.1), (10.1) Permissible Mountings (PRD) (3.9.4.2) Personnel Safety (Introduction), (S1.5), (S3.5), (S5.7.6) Oil Heaters (3.7.1) Piping (Foreword), (1.1), (1.3), (1.4.1), (1.4.2), (1.4.4), (1.4.5.1), (1.4.5.1.1.1), (2.1), (2.3.1), (2.5.1.2), (2.5.1.3), (2.5.1.4), (2.7.3), (2.7.5), (2.8.1), (2.8.2), (2.9.2), (2.9.5), (2.9.6), (2.10.1), (2.10.2), (3.3.1), (3.3.4), (3.7.4), (3.7.5), (3.7.6), (3.7.7.1), (3.7.7.2), (3.7.9.1), (3.7.9.2), (3.8.1.2), (3.8.1.3), (3.8.2.1), (3.9.1.5), (3.9.1.6), (3.9.2), (3.9.3), (3.9.4), (3.9.4.2), (3.9.4.7), (3.11), (4.3.2), (4.3.3), (4.5.3), (4.5.4), (4.5.6), (4.6), (4.7.5), (5.1), (5.2), (5.2.1), (5.2.2), (5.2.3), (5.2.4), (5.2.5), (5.2.6), (5.2.7), (5.3), (5.3.1), (5.3.2), (5.3.3), (5.3.4), (5.3.6), (S3.2.1), (S3.6), (S4.5), (S4.6), (S5.1), (S5.3.1), (S5.5.1), (S5.5.2), (S5.5.3), (S5.5.4), (S5.5.5), (S5.6.2), (S5.7.6), (S5.8.1), (S5.8.2), (9.1) Operating Parameters (Yankee Dryers) (S1.2), (S1.3), (S1.4), (S1.6) Pneumatic (S4.5) NBIC Committee (Foreword), (Introduction), (8.1), (8.5) Nondestructive Examination (2.10.3), (S1.6), (S5.8.3) Nuclear Items (Introduction), (9.1) --`,```,```,`,``,-`-`,`,`,`,`--- O SECTION 11 129 SECTION 11 Loading (2.3.1), (3.3.1.1), (4.3.1), (S1.2), (S1.3), (S1.4), (S1.5), (S3.2.1), (S5.3.1) 2015 NATIONAL BOARD INSPECTION CODE Postweld Heat Treatment (5.2.8), (9.1) Repair Organization (Introduction) Potable Water Heater (1.1), (1.4.5), (1.4.5.1), (1.4.5.1.1), (2.1), (3.1), (3.5.3.2), (3.7.4), (3.7.5), (3.7.5.2), (3.7.7.2), (3.7.9.2), (3.8.3), (3.9.4), (3.9.4.3), (3.11), (9.1) Request (Foreword), (Introduction), (1.4.1), (8.1), (8.3), (8.4) Pressure Control (3.7.5), (3.8.1.4), (3.8.1.6) Pressure Reducing Valve (2.7.3), (2.9.5), (S2.1), (S2.5) Pressure Relief Device (1.4.5.1.1), (2.9), (2.9.6), (4.4.2), (4.5), (4.5.1), (4.5.2), (4.5.3), (4.5.4), (4.5.5), (4.5.6), (5.3), (5.3.1), (5.3.2), (5.3.3), (5.3.4), (5.3.5), (5.3.6), (S5.5.2), (S5.7.2), (S5.7.3), (S5.7.4), (S5.7.5), (S5.7.6) Mounting (3.9.1), (3.9.1.1.1), (3.9.1.3), (3.9.4.2), (3.9.4.5) Pressure-Retaining Item (PRI) (Foreword), (Introduction), (1.1), (1.2), (1.3), (1.4.1), (1.4.2), (1.4.4), (1.5), (S1.3), (9.1) Pressure Testing (2.10.2), (3.10.1), (4.3.1), (4.6), (5.2.6), (S5.8.2) Yankee Dryers (S1.5) Pressure Vessels (Foreword), (Introduction), (1.1), (1.3), (1.4.1), (1.4.2), (1.4.4), (2.7.5), (2.9.3), (2.9.4), (3.8.1.2), (4.1), (4.3.1), (4.3.2), (4.4.2), (4.5), (4.5.2), (4.5.3), (4.5.4), (4.5.6), (4.6), (5.3.2), (S3.6.1), (S4.5), (S5.2), (S5.6.2), (S5.7.4), (S5.7.6) Pumps (2.5.1.3), (3.9.4), (S5.1), (S5.5.1), (S5.5.2), (S5.5.3), (S5.5.4), (S5.5.7), (S5.8.2) Q R SECTION 11 Repair (1.4.1), (2.9.2), (4.5.6), (5.3.6), (S1.2), (S1.6), (S3.5), (7.1), (7.2), (9.1) 130 SECTION 11 Responsibility (Foreword), (Introduction), (1.3), (1.4.1) Return Pipe Connections (3.7.5.1), (3.7.6) Review (Foreword), (Introduction), (1.4.3), (4.5.4), (5.2.8), (5.3.4), (S1.2), (S1.5), (7.3), (8.4), (9.1) Revisions (Foreword), (Introduction), (8.1), (8.3) Rupture Disk (4.5.1), (4.5.4), (5.3.1), (5.3.4), (S5.7.2) S Safe Point of Discharge (2.9.6), (3.9.1.5), (9.1) Safety (Foreword), (Introduction), (1.1), (1.4.5.1.1), (2.4.2), (2.5.3.3), (2.7.3), (3.4.2), (3.5.3), (3.8.1.4), (3.8.2.3), (3.8.2.4), (S1.5), (S3.5), (S4.6), (S5.4.2), (S5.5.1), (S5.5.7), (7.2), (9.1) Safety Device (Introduction), (9.1) Safety Valve/Safety Relief Valve (1.4.5.1.1), (2.5.1.1), (2.9.1), (2.9.1.1), (2.9.1.2), (2.9.1.3), (2.9.1.4), (2.9.3), (2.9.4), (2.9.5), (2.9.6), (3.7.4), (3.7.5), (3.7.7.1), (3.7.8.1), (3.7.9.1), (3.7.9.2), (3.8.2.1), (3.9.1.1), (3.9.1.1.1), (3.9.1.1.2), (3.9.1.3), (3.9.1.4), (3.9.1.4), (3.9.1.6), (3.9.3), (3.9.4), (3.9.4.1), (3.9.4.2), (3.9.4.3), (3.9.4.5), (3.9.4.6), (3.9.4.7), (3.9.5), (3.9.5.1), (3.9.5.2), (S1.2), (S2.5), (S3.6), (S5.5.2), (S5.5.7), (9.1) Safety Valve Capacity (3.7.7.1), (3.9.2), (S2.2) Scope of Activities (Accreditation) (Introduction) Service Fluid (S5.7.2) --`,```,```,`,``,-`-`,`,`,`,`--- Preheating (5.2.8) Set Pressure (1.4.5.1), (1.4.5.1.1), (2.7.3), (2.7.5), (2.8.1), (2.9.1.4), (2.9.2), (2.9.3), (3.7.4), (3.9.3), (3.9.4), (4.4.2), (4.4.5), (4.5.5), (5.3.5), (S5.7.5), (9.1) Testing (Foreword), (Introduction), (1.4.5), (2.10.4), (3.7.5), (3.8.2.4), (4.7.6), (5.2.6), (5.4), (S1.2), (S1.5), (S1.6), (7.1), (8.4), (9.1) Settings (2.3.1), (2.9.1.4), (4.3.1), (S3.2.1), (S5.3.1), (S5.3.3), (S5.5.7), (9.1) Tests (Introduction), (4.1), (5.4), (S5.5.1), (S5.8), (S5.8.2), (S5.8.4), (9.1) Shop (4.6), (9.1) Thermal Expansion (3.7.8.2), (3.7.9), (3.7.9.1), (3.7.9.2), (5.2) Sleeve (2.5.1.2) Thermal Fluid Heater (S5.1), (S5.2), (S5.3.1), (S5.3.2), (S5.3.3), (S5.3.4), (S5.4.1), (S5.5.1), (S5.5.3), (S5.5.7), (S5.7.1), (S5.7.2), (S5.8.1), (S5.8.2), (S5.8.3), (S5.8.5) Specifcatiion (3.10.2), (S4.2), (S5.5.1) Stamping (Introduction), (1.4.5.1.1), (4.7.2), (7.1) Thermometer (1.4.5.1), (1.4.5.1.1), (3.8.2.1), (3.8.2.2), (3.8.2.5), (3.8.2.6), (3.8.3.2), (4.7.4) Steam Heating Boilers (1.1), (1.4.5), (3.1), (3.5.3.1), (3.7.5), (3.8.1.6), (S4.4) Threaded Connections (3.9.1.2) Steam Supply (2.7.3), (2.8.2), (2.9.5) Transport Tanks (DOT) (Introduction), (7.1), (9.1) Stop Valves (1.4.5.1), (1.4.5.1.1), (2.5.1.4), (2.7.3), (2.9.2), (2.10.2), (3.7.5), (3.7.5.1), (3.7.5.2), (3.7.8.2), (4.5.6), (4.7.5), (5.3.6), (S5.6.2), (S5.7.6), (S5.8.2) Tubes (2.3.3), (2.9.1.3), (2.9.3), (3.8.2.4), (3.9.2), (3.9.5.2), (3.9.5.3), (S3.6), (S5.5.4), (S5.5.7), (S7.10) Structural Steel (2.3.2), (3.3.1.1), (3.3.3), (S5.3.2) Superheaters (2.10.2) Supports (Introduction), (2.3.1), (3.3.1), (3.3.1.1), (3.3.2), (4.3.1), (5.2.6), (S3.2), (S3.2.1), (S5.3.1), (S5.3.2), (S5.5.5), (S11.10.4) Suspension Burner (S4.2) System Testing (2.10.4), (S5.8.4) Tubesheet (2.9.1.3), (3.9.2) U Uoderfre ir (S4.2), (S4.6) --`,```,```,`,``,-`-`,`,`,`,`--- NB-23 2015 Units of Measurement (Introduction) User (Foreword), (Introduction), (1.1), (1.2), (1.3), (1.4.5.1), (1.4.5.1.1), (4.6), (S1.2), (S4.2), (8.1), (8.5), (9.1) T Temperature Controls (3.8.3.1) SECTION 11 131 SECTION 11 Technical Inquiries (8.1) 2015 NATIONAL BOARD INSPECTION CODE V Y Valves (Introduction), (1.4.5.1), (1.4.5.1.1), (2.5.1.1), (2.5.1.4), (2.5.6), (2.6.3.1), (2.7.3), (2.7.5), (2.8.1), (2.8.2.1), (2.9), (2.9.1), (2.9.1.1), (2.9.1.2), (2.9.1.3), (2.9.1.4), (2.9.2), (2.9.3), (2.9.4), (2.9.5), (2.9.6), (2.10.2), (2.10.2), (3.5.6), (3.7.4), (3.7.5), (3.7.5.1), (3.7.5.2), (3.7.7), (3.7.7.1), (3.7.8.2), (3.8.1.3), (3.8.1.4), (3.8.3.1), (3.9), (3.9.1), (3.9.1.1), (3.9.1.1.1), (3.9.1.1.2), (3.9.1.3), (3.9.1.4), (3.9.1.5), (3.9.1.6), (3.9.2), (3.9.3), (3.9.4), (3.9.4.1), (3.9.4.2), (3.9.4.3), (3.9.4.5), (3.4.9.4.6), (3.9.4.7), (3.9.5), (3.9.5.2), (3.9.5.3), (3.11), (4.5.1), (4.5.4), (4.5.6), (4.7.5), (5.2.4), (5.2.8), (5.3.1), (5.3.6), (S2.1), (S2.2), (S2.3), (S2.5), (S3.2.1), (S3.6), (S3.6.2), (S4.5), (S5.5.2), (S5.5.3), (S5.5.4), (S5.5.5), (S5.5.7), (S5.5.10), (S5.6.2), (S5.6.3), (S5.7.2), (S5.7.6), (S5.8.2), (9.1) Yankee Dryers (S1.1), (S1.3), (S1.4), (S1.5), (S1.6) Vaporizer (S5.1), (S5.2) Ventilation Air (2.5.4), (3.5.4), (S5.5.8) Vibration (2.3.1), (2.7.3), (3.3.1), (4.3.1), (4.3.3), (5.2), (5.2.2), (S3.2.1), (S5.3.1) Volume (Feedwater) (2.5.1.1) W Water Column (2.6.3.3), (2.8.1), (2.8.2), (2.10.1), (2.10.2), (3.7.4), (3.8.1.1), (3.8.1.2), (3.8.1.3), (4.4.1), (S4.5) Water-Gage Glass (2.8.1) Water Heaters (1.1), (1.4.5), (3.1), (3.5.3), (3.5.3.2), (3.5.4), (3.7.4), (3.7.5.2), (3.7.5), (3.7.7.2), (3.7.9.2), (3.8.3), (3.8.3.1), (3.9.4), (3.11), (9.1) Welding (2.10.1), (3.3.1.1), (3.7.5), (3.7.5.1), (4.6), (5.2.7), (5.2.8), (S5.4.2), (9.1) 132 SECTION 11 --`,```,```,`, SECTION 11 X Z --`,```,```,`,``,-`-`,`,`,`,`--- ![]() ![]() Mystique 2 9 Build
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