api577-welding inspection & metallurgy

1. Welding Inspection & Metallurgy API ICP Self Study Notes 2014 Facilitators: Fion Zhang/Charlie Chong

2. http://myicp.api.org/DirectorySearch/Search.aspx Expert at works 3. API 577 Advanced Welding Inspection & Metallurgy Professional Program API welcomes highly specialized inspectors, welding engineers, metallurgists and other professionals across the entire petrochemical industry to obtain this certification as a validation of their profound knowledge of welding processes and metallurgy. Completely optional, yet adding significant value to your professional credentials it will show your employers and clients that you have obtained a high level of proficiency and understanding in this important field. API 577 certification is valid for a three-year term. The Initial Application Qualification Requirements Exam Information (Including Body of Knowledge) Purchasing Publications View Exam Calendars & Fees http://www.api.org/certification-programs/individual-certification-programs-icp/icp-certifications/api-577 4. API 577 Advanced Welding Inspection & Metallurgy Professional Program - Exam Information Exam Details 1. API 577 Certification program tests individuals knowledge and expertise in the field of Welding and Metallurgy. Questions on this examination are based on API Recommended Practice 577 Welding Inspection and Metallurgy. 2. There are a total of 70 questions, all multiple-choice and closed-book. 3. The exam is 4 hours long and will be administered via computer at a Prometric computer testing center. 4. This examination has a set passing point of 70%, or 49 correctly answered questions. 5. Papers and books are not allowed in Prometrics computer testing centers. 5. This recommended practice provides guidance to the API authorized inspector on welding inspection as encountered with (1) fabrication and (2) repair of refinery and chemical plant equipment and piping. 6. Charlie Chong/ Fion Zhang : Indo-China ?, People Republic of China. China .,, ?. (40),,-Tiong Hua, ,,,-China" . , "China" "". http://news.ifeng.com/world/detail_2014_03/20/34944726_0.shtml 7. Speaker: Fion Zhang 2014/5/4 8. Content: 1 SCOPE 2 REFERENCES 2.1 Codes and Standards 2.2 Other References 3 DEFINITIONS. 4 WELDING INSPECTION 4.1 General 4.2 Tasks Prior to Welding 4.3 Tasks during Welding Operations 4.4 Tasks Upon Completion of Welding 4.5 Non-conformances and Defects 4.6 NDE Examiner Certification 4.7 Safety Precautions 9. 5 WELDING PROCESSES 5.1 General 5.2 Shielded Metal Arc Welding (SMAW) 5.3 Gas Tungsten Arc Welding (GTAW) 5.4 Gas Metal Arc Welding (GMAW 5.5 Flux Cored Arc Welding (FCAW 5.6 Submerged Arc Welding 5.7 Stud Arc Welding (SW) 10. 6 WELDING PROCEDURE 6.1 General 6.2 Welding Procedure Specification (WPS) 6.3 Procedure Qualification Record (PQR). 6.4 Reviewing a WPS and PQR 7 WELDING MATERIALS 7.1 General 7.2 P-number Assignment to Base Metals 7.3 F-number Assignment to Filler Metals 7.4 AWS Classification of Filler Metals 7.5 A-number 7.6 Filler Metal Selection 7.7 Consumable Storage and Handling 8 WELDER QUALIFICATION 8.1 General 8.2 Welder Performance Qualification (WPQ) 8.3 Reviewing a WPQ 11. 9 NON-DESTRUCTIVE EXAMINATION 9.1 Discontinuities 9.2 Materials Identification 9.3 Visual Examination (VT) 9.4 Magnetic Particle Examination (MT) 9.5 Alternating Current Field Measurement (ACFM) 9.6 Liquid Penetrant Examination (PT) 9.7 Eddy Current Inspection (ET) 9.8 Radiographic Inspection (RT) 9.9 Ultrasonic Inspection (UT) 9.10 Hardness Testing 9.11 Pressure and Leak Testing (LT) 9.12 Weld Inspection Data Recording 12. 10 METALLURGY 10.1 General 10.2 The Structure of Metals and Alloys 10.3 Physical Properties 10.4 Mechanical Properties 10.5 Preheating 10.6 Post-weld Heat Treatment 10.7 Hardening 10.8 Material Test Reports 10.9 Weldability of Steels 10.10 Weldability of High-alloys 13. 11 REFINERY AND PETROCHEMICAL PLANT WELDING ISSUES 11.1 General 11.2 Hot Tapping and In-service Welding 11.3 Lack of Fusion with GMAW-S Welding Process 14. 1 Scope 15. Content: 1 SCOPE 16. This recommended practice provides guidance to the API authorized inspector on welding inspection as encountered with fabrication and repair of refinery and chemical plant equipment and piping. Common welding processes, welding procedures, welder qualifications, metallurgical effects from welding, and inspection techniques are described to aid the inspector in fulfilling their role implementing API 510, API 570, API Std 653 and API RP 582. The level of learning and training obtained from this document is not a replacement for the training and experience required to be an American Welding Society (AWS) Certified Welding Inspector (CWI). 17. This recommended practice provides guidance to the API authorized inspector on welding inspection as encountered with (1) fabrication and (2) repair of refinery and chemical plant equipment and piping. Common welding processes, welding procedures, welder qualifications, metallurgical effects from welding, and inspection techniques are described to aid the inspector in fulfilling their role implementing API 510, API 570, API Std 653 and API RP 582. 18. This recommended practice provides guidance to the API authorized inspector on welding inspection as encountered with fabrication and repair of (a) refinery and (b) chemical plant equipment and piping. 19. This recommended practice provides guidance to the API authorized inspector on welding inspection as encountered with fabrication and repair of (a) refinery and (b) chemical plant equipment and piping. 20. This recommended practice provides guidance to the API authorized inspector on welding inspection as encountered with fabrication and repair of (a) refinery and (b) chemical plant equipment and piping. 21. This recommended practice provides guidance to the API authorized inspector on welding inspection as encountered with fabrication and repair of (a) refinery and (b) chemical plant equipment and piping. 22. This recommended practice provides guidance to the API authorized inspector on welding inspection as encountered with fabrication and repair of (a) refinery and (b) chemical plant equipment and piping. 23. This recommended practice provides guidance to the API authorized inspector on welding inspection as encountered with fabrication and repair of (a) refinery and (b) chemical plant equipment and piping. 24. Keywords: Fulfilling their role implementing API 510, API 570, API Std 653 and API RP 582.- 4 Standards! 25. Charlie Chong/ Fion Zhang API 577 is to aid the inspector in fulfilling their role implementing API 510, API 570, API Std 653 and API RP 582. 26. Charlie Chong/ Fion Zhang API 570 Piping Inspection Code: In-service Inspection, Repair, and Alteration of Piping Systems, Third Edition standard published 11/01/2009 by American Petroleum Institute API 577 is to aid the inspector in fulfilling their role implementing API 510, API 570, API Std 653 and API RP 582. 27. Charlie Chong/ Fion Zhang API Std 653 Tank Inspection, Repair, Alteration, and Reconstruction, Fourth Edition, Includes Addendum 1 (2010), Addendum 2 (2012), Addendum 3 (2013) API 577 is to aid the inspector in fulfilling their role implementing API 510, API 570, API Std 653 and API RP 582. 28. Charlie Chong/ Fion Zhang API RP 582 Recommended Practice Welding Guidelines for the Chemical, Oil, and Gas Industries standard published 11/01/2009 by American Petroleum Institute API 577 is to aid the inspector in fulfilling their role implementing API 510, API 570, API Std 653 and API RP 582. 29. Charlie Chong/ Fion Zhang How this API Standard relates with Exploration and Production (E&P) ? 30. API 510: 8.1 SCOPE AND SPECIFIC EXEMPTIONS This section sets forth the minimum alternative inspection rules for pressure vessels that are exempt from the rules set forth in Section 6 except as referenced in paragraphs 8.4 and 8.5. Except for Section 6, all of the sections in this inspection code are applicable to Exploration and Production (E&P) pressure vessels. These rules are provided because of the vastly different characteristics and needs of pressure vessels used for E&P service. Typical E&P services are vessels associated with drilling, production, gathering, transportation, and treatment of liquid petroleum, natural gas, natural gas liquids, and associated salt water (brine). 31. Typical E&P services are vessels associated with drilling, production, gathering, transportation, and treatment of liquid petroleum, natural gas, natural gas liquids, and associated salt water 32. The level of learning and training obtained from this document is not a replacement for the training and experience required to be an American Welding Society (AWS) Certified Welding Inspector (CWI). http://www.aws.org/w/a/certification/index.html 33. Keywords: The level of learning and training obtained from this document is not a replacement for the training and experience required to be an American Welding Society (AWS) Certified Welding Inspector (CWI). 34. Study Harder 35. This recommended practice does not require all welds to be inspected; nor does it require welds to be inspected to specific techniques and extent. Welds selected for inspection, and the appropriate inspection techniques, should be determined by the welding inspectors, engineers, or other responsible personnel using the applicable code or standard. The importance, difficulty, and problems that could be encountered during welding should be considered by all involved. A welding engineer should be consulted on any critical, specialized or complex welding issues. 36. Problems encountered during welding should be considered by all involved. - Happy Rigger was involved, so he also should be consulted, 37. This recommended practice does not require all welds to be inspected; nor does it require welds to be inspected to specific techniques and extent. . 38. Welds selected for inspection, and the appropriate inspection techniques, should be determined by the (1) welding inspectors, (2) engineers, or (3) other responsible personnel using the applicable code or standard. 39. The importance, difficulty, and problems that could be encountered during welding should be considered by all involved. A welding engineer should be consulted on any critical, specialized or complex welding issues. 40. A welding engineer should be consulted on any critical, specialized or complex welding issues. 41. A welding engineer should be consulted on any critical, specialized or complex welding issues. 42. 2 References 43. Content: 2 REFERENCES 2.1 Codes and Standards 2.2 Other References 44. 2.1 CODES AND STANDARDS The following codes and standards are referenced in this recommended practice. All codes and standards are subject to periodic revision, and the most recent revision available should be used. 45. API API 510 Pressure Vessel Inspection Code: Maintenance, Inspection, Rating, Repair, and Alteration API 570 Piping Inspection Code: Inspection, Repair, Alteration, and Rerating of In-Service Piping Systems RP 578 Material Verification Program for New and Existing Alloy Piping Systems RP 582 Recommended Practice and Supplementary Welding Guidelines for the Chemical, Oil, and Gas Industries Std 650 Welded Steel Tanks for Oil Storage Std 653 Tank Inspection, Repair, Alteration, and Reconstruction Publ 2201 Procedures for Welding or Hot Tapping on Equipment in Service 46. ASME B31.3 Process Piping Boiler and Pressure Vessel Code Section V, Nondestructive Examination; Section VIII, Rules for Construction of Pressure Vessels, Section IX, Qualification Standard for Welding and Brazing Procedures, Welders, Brazers, and Welding and Brazing Operators Practical Guide to ASME Section IX Welding Qualifications ASNT ASNT Central Certification Program CP-189 Standard for Qualification and Certification of Nondestructive Testing Personnel SNT-TC-1A Personnel Qualification and Certification in Nondestructive Testing 47. AWS A2.4 Standard Symbols for Welding, Brazing, and Nondestructive Examination A3.0 Standard Welding Terms and Definitions A5.XX Series of Filler Metal Specifications B1.10 Guide for the Nondestructive Inspection of Welds CASTI CASTI Guidebook to ASME Section IXWelding Qualifications WRC Bulletin 342 Stainless Steel Weld Metal: Prediction of Ferrite Content 48. 2.2 OTHER REFERENCES The following codes and standards are not referenced directly in this recommended practice. Familiarity with these documents may be useful to the welding engineer or inspector as they provide additional information pertaining to this recommended practice. All codes and standards are subject to periodic revision, and the most recent revision available should be used. 49. API RP 572 Inspection of Pressure Vessels RP 574 Inspection Practices for Piping System Components Publ 2207 Preparing Tank Bottoms for Hot Work Publ 2217A Guidelines for Work in Inert Confined Spaces in the Petroleum Industry ASME Boiler and Pressure Vessel Code, Section II, Materials Part C, Specifications for Welding Rods, Electrodes, and Filler Metals Part D, Properties B16.5 Pipe Flanges and Flanged Fittings B16.9 Factory-Made Wrought Steel Butt welding Fittings B16.34 Valves- Flanged, Threaded, and Welding End B31.1 Power Piping 50. AWS JWE Jeffersons Welding Encyclopedia CM-00 Certification Manual for Welding Inspectors NB NB-23 National Board Inspection Code 51. 3 Definitions 52. Content: 3 DEFINITIONS. 53. The following definitions apply for the purposes of this publication: 3.1 actual throat: The shortest distance between the weld root and the face of a fillet weld. 54. Fillet Weld Actual throat Theoretical throat Effective throat Leg size Convexity 55. 3.2 air carbon arc cutting (CAC-A): A carbon arc cutting process variation that removes molten metal with a jet of air. 3.3 arc blow: The deflection of an arc from its normal path because of magnetic forces. 3.4 arc length: The distance from the tip of the welding electrode to the adjacent surface of the weld pool. 3.5 arc strike: A discontinuity resulting from an arc, consisting of any localized remelted metal, heat-affected metal, or change in the surface profile of any metal object. 56. Arc strike 57. Arc blow 58. Arc blow 59. 3.6 arc welding (AW): A group of welding processes that produces coalescence of work pieces by heating them with an arc. The processes are used with or without the application of pressure and with or without filler metal. 3.7 autogenous weld: A fusion weld made without filler metal. 3.8 back-gouging: The removal of weld metal and base metal from the weld root side of a welded joint to facilitate complete fusion and complete joint penetration upon subsequent welding from that side. 3.9 backing: A material or device placed against the backside of the joint, or at both sides of a weld in welding, to support and retain molten weld metal. 3.10 base metal: The metal or alloy that is welded or cut. 3.11 bevel angle: The angle between the bevel of a joint member and a plane perpendicular to the surface of the member. 60. 3.12 burn-through: A non-standard term for excessive visible root reinforcement in a joint welded from one side or a hole through the root bead. Also, a common term used to reflect the act of penetrating a thin component with the welding arc while hot tap welding or in-service welding. 3.13 constant current power supply: An arc welding power source with a volt-ampere relationship yielding a small welding current change from a large arc voltage change. 3.14 constant voltage power supply: An arc welding power source with a volt-ampere relationship yielding a large welding current change from a small voltage change. 3.15 crack: A fracture type discontinuity characterized by a sharp tip and high ratio of length and width to opening displacement. 61. Crack 62. 3.16 defect: A discontinuity or discontinuities that by nature or accumulated effect (for example total crack length) render a part or product unable to meet minimum applicable acceptance standards or specifications. The term designates rejectability. 3.17 direct current electrode negative (DCEN): The arrangement of direct current arc welding leads in which the electrode is the negative pole and workpiece is the positive pole of the welding arc. Commonly known as straight polarity. 3.18 direct current electrode positive (DCEP): The arrangement of direct current arc welding leads in which the electrode is the positive pole and the workpiece is the negative pole of the welding arc. Commonly known as reverse polarity. 3.19 discontinuity: An interruption of the typical structure of a material, such as a lack of homogeneity in its mechanical, metallurgical, or physical characteristics. A discontinuity is not necessarily a defect. 63. 3.20 distortion: The change in shape or dimensions, temporary or permanent, of a part as a result of heating or welding. 3.21 filler metal: The metal or alloy to be added in making a welded joint. 3.22 fillet weld size: For equal leg fillet welds, the leg lengths of the largest isosceles right triangle that can be inscribed within the fillet weld cross section. 3.23 fusion line: A non-standard term for weld interface. 3.24 groove angle: The total included angle of the groove between workpieces. 3.25 heat affected zone (HAZ): The portion of the base metal whose mechanical properties or microstructure have been altered by the heat of welding or thermal cutting. 64. t e 3.1 actual throat: The shortest distance between the weld root and the face of a fillet weld. 3.22 fillet weld size: For equal leg fillet welds, the leg lengths of the largest isosceles right triangle that can be inscribed within the fillet weld cross section. Weld throat = sin 45o x weld size (leg size) 65. HAZ 66. Electrodes 67. HAZ 68. HAZoning 69. HAZ http://www.twi-global.com/technical- knowledge/published-papers/review-of-type-iv- cracking-of-weldments-in-9-12cr-creep-strength- enhanced-ferritic-steels/ 70. 3.26 heat input: the energy supplied by the welding arc to the workpiece. Heat input is calculated as follows: Heat Input Joules/inch = where V = voltage, i = amperage, v =weld travel speed (in./min.) 3.27 hot cracking: Cracking formed at temperatures near the completion of solidification 3.28 inclusion: Entrapped foreign solid material, such as slag, flux, tungsten, or oxide. 3.29 incomplete fusion: A weld discontinuity in which complete coalescence did not occur between weld metal and fusion faces or adjoining weld beads. 3.30 incomplete joint penetration: A joint root condition in a groove weld in which weld metal does not extend through the joint thickness. 71. Hot Cracking 72. Hot cracking 73. Hot cracking These cracks are known as hot cracks because they occur immediately after welds are completed and sometimes while the welds are in progress, when the weld metal tends to solidify from the corners of the base metal to which it is joined. There are 2 major reasons contributing to hot cracking; As the solidification proceeds, the low melting eutectics are concentrated in the center and remain liquid, which is then torn apart by the stress associated with the welding, resulting in a center line crack. Hot cracking occurs when the available supply of liquid weld metal is insufficient to fill the spaces between solidifying weld metal, which are opened by shrinkage strains. http://www.corrosionpedia.com/definition/634/hot-cracking 74. Hot cracking http://en.wikipedia.org/wiki/Cold_cracking#Cold_cracking 75. Both solidification cracking and hot cracking refer to the formation of shrinkage cracks during the solidification of weld metal, although hot cracking can also refer to liquation cracking. Solidification cracks can appear in several locations, and orientations, but most commonly are longitudinal centreline cracks (coincident with the intersection of grains growing from opposite sides of the weld), or 'flare' cracks, again longitudinal, but at an angle to the through-thickness direction ( Fig.1). Where there is a central segregate band in the plate, cracking may extend from this position at the fusion boundary ( Fig.2). The cracks in all locations can be buried ( Fig.3) or surface-breaking. http://www.twi-global.com/technical-knowledge/faqs/material-faqs/faq-what-is-hot- cracking-solidification-cracking/ 76. 3.31 inspector: An individual who is qualified and certified to perform inspections under the proper inspection code or who holds a valid and current National Board Commission. 3.32 interpass temperature, welding: In multipass weld, the temperature of the weld area between weld passes. 3.33 IQI: Image quality indicator. Penetrameter is another common term for IQI. 3.34 joint penetration: The distance the weld metal extends from the weld face into a joint, exclusive of weld reinforcement. 3.35 joint type: A weld joint classification based on five basic joint configurations such as a butt joint, corner joint, edge joint, lap joint, and t-joint. 77. Inspector: An individual who is qualified and certified to perform inspections under the proper inspection code or who holds a valid and current National Board Commission. He/She must be: Qualified and Certified under proper inspection code (AWS/ API/ CSWIP/ Local or National Accreditation?) NBC-National Board Commission certified. 78. Qualified & Certified Inspectors http://acri.mystrategiccompass.com/training/certifications/551 http://www.nationalboard.org/ Expert at works 79. Qualified & Certified Inspectors 80. Qualified & Certified Inspectors 81. Qualified&CertifiedInspectors 82. Figure A-1Joint Types and Applicable Welds 83. Figure A-1Joint Types and Applicable Welds 84. Figure A-1Joint Types and Applicable Welds 85. 3.36 lack of fusion (LOF): A non-standard term indicating a weld discontinuity in which fusion did not occur between weld metal and fusion faces or adjoining weld beads. 3.37 lamellar tear: A subsurface terrace and step-like crack in the base metal with a basic orientation parallel to the wrought surface caused by tensile stresses in the through thickness direction of the base metal weakened by the presence of small dispersed, planar shaped, nonmetallic inclusions parallel to the metal surface. 3.38 lamination: A type of discontinuity with separation or weakness generally aligned parallel to the worked surface of a metal. 3.39 linear discontinuity: A discontinuity with a length that is substantially greater than its width. 3.40 longitudinal crack: A crack with its major axis orientation approximately parallel to the weld axis. 86. lamellar tear 87. Lamellar tear 88. Longitudinal crack 89. 3.41 nondestructive examination (NDE): The act of determining the suitability of some material or component for its intended purpose using techniques that do not affect its serviceability. 3.42 overlap: The protrusion of weld metal beyond the weld toe or weld root. 3.43 oxyacetylene cutting (OFC-A): An oxygen gas cutting process variation that uses acetylene as the fuel gas. 3.44 PMI (Positive Materials Identification): Any physical evaluation or test of a material (electrode, wire, flux, weld deposit, base metal, etc.), which has been or will be placed into service, to demonstrate it is consistent with the selected or specified alloy material designated by the owner/ user. These evaluations or tests may provide either qualitative or quantitative information that is sufficient to verify the nominal alloy composition. 90. PMI 91. PMI 92. PMI 93. PMI 94. PMI 95. PMI 96. 3.45 peening: The mechanical working of metals using impact blows. 3.46 penetrameter: Old terminology for IQI still in use today but not recognized by the codes and standards. 3.47 porosity: Cavity-type discontinuities formed by gas entrapment during solidification or in thermal spray deposit. 3.48 preheat: Metal temperature value achieved in a base metal or substrate prior to initiating the thermal operations. 3.49 recordable indication: Recording on a data sheet of an indication or condition that does not necessarily exceed the rejection criteria but in terms of code, contract or procedure will be documented. 3.50 reportable indication: Recording on a data sheet of an indication that exceeds the reject flaw size criteria and needs not only documentation, but also notification to the appropriate authority to be corrected. All reportable indications are recordable indications but not vice-versa. 97. This is API 577 special way of defining (1) Minor Discontinuities, (2) Significant but Non-Rejectable Discontinuities and (3) Rejectable Discontinuities. recordable indication: Recording on a data sheet of an indication or condition that does not necessarily exceed the rejection criteria but in terms of code, contract or procedure will be documented. reportable indication: Recording on a data sheet of an indication that exceeds the reject flaw size criteria and needs not only documentation, but also notification to the appropriate authority to be corrected. All reportable indications are recordable indications but not vice-versa. 98. Porosity 99. 3.51 root face: The portion of the groove face within the joint root. 3.52 root opening: A separation at the joint root between the workpieces. 3.53 shielding gas: Protective gas used to prevent or reduce atmospheric contamination. 3.54 slag: A nonmetallic product resulting from the mutual dissolution of flux and nonmetallic impurities in some welding and brazing processes. 3.55 slag inclusion: A discontinuity consisting of slag entrapped in the weld metal or at the weld interface. 3.56 spatter: The metal particles expelled during fusion welding that do not form a part of the weld. 3.57 tack weld: A weld made to hold the parts of a weldment in proper alignment until the final welds are made. 100. Slag Inclusions 101. Slag Inclusion 102. Slag inclusions http://www.ge-mcs.com/download/x-ray/GEIT-30158EN_industrial-radiography-image-forming- techniques.pdf 103. Slag Inclusions 104. Porosity 105. 3.58 throat theoretical: The distance from the beginning of the joint root perpendicular to the hypotenuse of the largest right triangle that can be inscribed within the cross-section of a fillet weld. This dimension is based on the assumption that the root opening is equal to zero. 3.59 transverse crack: A crack with its major axis oriented approximately perpendicular to the weld axis. 3.60 travel angle: The angle less than 90 degrees between the electrode axis and a line perpendicular to the weld axis, in a plane determined by the electrode axis and the weld axis. 106. 3.61 tungsten inclusion: A discontinuity consisting of tungsten entrapped in weld metal. 3.62 undercut: A groove melted into the base metal adjacent to the weld toe or weld root and left unfilled by weld metal. 3.63 underfill: A condition in which the weld joint is incompletely filled when compared to the intended design. 107. t e 3.1 actual throat: The shortest distance between the weld root and the face of a fillet weld. 3.22 fillet weld size: For equal leg fillet welds, the leg lengths of the largest isosceles right triangle that can be inscribed within the fillet weld cross section. Weld throat = sin 45o x weld size (leg size) 108. Transverse crack 109. Transverse Cracks 110. Transverse Crack 111. Tungsten Inclusions TIG Welding 112. TIG Welding Tungsten Inclusions 113. TIG Welding Tungsten Inclusions 114. TIG Welding Tungsten Inclusions 115. 3.64 welder certification: Written verification that a welder has produced welds meeting a prescribed standard of welder performance. 3.65 welding: A joining process that produces coalescence of base metals by heating them to the welding temperature, with or without the application of pressure or by the application of pressure alone, and with or without the use of filler metal. 3.66 welding engineer: An individual who holds an engineering degree and is knowledgeable and experienced in the engineering disciplines associated with welding. 3.67 weldment: An assembly whose component parts are joined by welding. 3.68 weld joint: The junction of members or the edges of members which are to be joined or have been joined by welding. 116. Weld Joint weldment: An assembly whose component parts are joined by welding 117. 3.69 weld reinforcement: Weld metal in excess of the quantity required to fill a joint. 3.70 weld toe: The junction of the weld face and the base metal. 118. weld reinforcement weld toe 119. weld reinforcement weld toe 120. weld reinforcement weld toe 121. weld reinforcement weld toe 122. 4 Welding Inspection 123. Content: 4 WELDING INSPECTION 4.1 General 4.2 Tasks Prior to Welding 4.3 Tasks during Welding Operations 4.4 Tasks Upon Completion of Welding 4.5 Non-conformances and Defects 4.6 NDE Examiner Certification 4.7 Safety Precautions 124. 4.1 GENERAL Welding inspection is a critical part of an overall weld quality assurance program. Welding inspection includes much more than just the nondestructive examination of the completed weld. Many other issues are important, such as review of specifications, joint design, cleaning procedures, and welding procedures. Welder qualifications should be performed to better assure the weldment performs properly in service. Welding inspection activities can be separated into three stages corresponding to the welding work process. Inspectors should perform specific tasks; prior to welding, during welding and upon completion of welding, although it is usually not necessary to inspect every weld. 125. 4.2 TASKS PRIOR TO WELDING The importance of tasks in the planning and weld preparation stage should not be understated. Many welding problems can be avoided during this stage when it is easier to make changes and corrections, rather than after the welding is in progress or completed. Such tasks may include: 4.2.1 Drawings, Codes, and Standards 4.2.2 Weldment Requirements 4.2.3 Procedures and Qualification Records 4.2.4 NDE Information 4.2.5 Welding Equipment and Instruments 4.2.6 Heat Treatment and Pressure Testing 4.2.7 Materials 4.2.8 Weld Preparation 4.2.9 Preheat 4.2.10 Welding Consumables 126. 4.2.1 Drawings, Codes, and Standards 127. 4.2.1 Drawings, Codes, and Standards Review drawings, standards, codes, and specifications to both understand the requirements for the weldment and identify any inconsistencies. 128. 4.2.1 Drawings, Codes, and Standards Review drawings, standards, codes, and specifications to both understand the requirements for the weldment and identify any inconsistencies. 4.2.1.1 Quality control items to assess: a. Welding symbols and weld sizes clearly specified (See Appendix A). b. Weld joint designs and dimensions clearly specified (see Appendix A). c. Weld maps identify the welding procedure specification (WPS) to be used for specific weld joints. d. Dimensions detailed and potential for distortion addressed. e. Welding consumables specified (see 7.3, 7.4, 7.6, and Appendix D). f. Proper handling of consumables, if any, identified (see 7.7). g. Base material requirements specified (such as the use of impact tested materials where notch ductility is a requirement in low temperature service). h. Mechanical properties and required testing identified (see 10.4) i. Weather protection and wind break requirements defined. 129. i. Preheat requirements and acceptable preheat methods defined (see 10.5). j. Post-weld heat treatment (PWHT) requirements and acceptable PWHT method defined (see 10.6). k. Inspection hold-points and NDE requirements defined (see Section 9). l. Additional requirements, such as production weld coupons, clearly specified. m. Pressure testing requirements, if any, clearly specified (see 9.11). 4.2.1.2 Potential inspector actions: a. Identify and clarify missing details and information. b. Identify and clarify missing weld sizes, dimensions, tests, and any additional requirements. c. Identify and clarify inconsistencies with standards, codes and specification requirements. d. Highlight potential weld problems not addressed in the design. 130. 4.2.2 Weldment Requirements Review requirements for the weldment with the personnel involved with executing the work such as the design engineer, welding engineer, welding organization and inspection organization. 131. Review requirements for the weldment with the personnel involved with executing the work such as the design engineer, welding engineer, welding organization and inspection organization. 132. Review requirements for the weldment with the personnel involved with executing the work such as the design engineer, welding engineer, welding organization and inspection organization. 133. 4.2.2.1 Quality control items to assess: a. Competency of welding organization to perform welding activities in accordance with codes, standards, and specifications. b. Competency of inspection organization to perform specified inspection tasks. c. Roles and responsibilities of engineers, welding organization, and welding inspectors defined and appropriate for the work. d. Independence of the inspection organization from the production organization is clear and demonstrated. 4.2.2.2 Potential inspector action: Highlight deficiencies and concerns with the organizations to appropriate personnel. 134. 4.2.3 Procedures and Qualification Records Review the WPS(s) and welder performance qualification record (s) (WPQ) to assure they are acceptable for the work. 135. 4.2.3.1 Quality control items to assess: a. WPS(s) are properly qualified and meet applicable codes, standards and specifications for the work (see 6.4). b. Procedure qualification records (PQR) are properly performed and support the WPS(s) (see 6.4). c. Welder performance qualifications (WPQ) meet requirements for the WPS (see 8.3). 4.2.3.2 Potential inspector actions: a. Obtain acceptable WPS(s) and PQR(s) for the work. b. Qualify WPS(s) where required and witness qualification effort. c. Qualify or re-qualify welders where required and witness a percentage of the welder qualifications. 136. ASME IX: ARTICLE II WELDING PROCEDURE QUALIFICATIONS 137. 4.2.4 NDE Information Confirm the NDE examiner(s), NDE procedure(s) and NDE equipment of the inspection organization are acceptable for the work. 4.2.4.1 Quality control items to assess: a. NDE examiners are properly certified for the NDE technique (see 4.6) b. NDE procedures are current and accurate. c. Calibration of NDE equipment is current. 4.2.4.2 Potential inspector actions: a. Identify and correct deficiencies in certifications and procedures. b. Obtain calibrated equipment. 138. 4.2.5 Welding Equipment and Instruments Confirm welding equipment and instruments are calibrated and operate. 4.2.5.1 Quality control items to assess: a. Welding machine calibration is current b. Instruments such as ammeters, voltmeters, contact pyrometers, have current calibrations. c. Storage ovens for welding consumables operate with automatic heat control and visible temperature indication. 4.2.5.2 Potential inspector actions: a. Recalibrate equipment and instruments. b. Replace defective equipment and instruments. 139. Welding Equipment and Instruments 140. Welding Equipment and Instruments 141. 4.2.6 Heat Treatment and Pressure Testing Confirm heat treatment and pressure testing procedures and associated equipment are acceptable. 4.2.6.1 Quality control items to assess: a. Heat treatment procedure is available and appropriate (see 10.6). b. Pressure testing procedures are available and detail test requirements (see 9.11). c. PWHT equipment calibration is current. d. Pressure testing equipment and gauges calibrated and meet appropriate test requirements. 4.2.6.2 Potential inspector actions: a. Identify and correct deficiencies in procedures b. Obtain calibrated equipment 142. Heat Treatment and Pressure Testing 143. 4.2.7 Materials Ensure all filler metals, base materials, and backing ring materials are properly marked and identified and if required, perform PMI to verify the material composition. 144. Materials 145. Materials 146. Materials 147. 4.2.7.1 Quality control items to assess: a. Material test certifications are available and items properly marked (including back-up ring if used; see 10.8). b. Electrode marking, bare wire flag tags, identification on spools of wire, etc. as-specified (see 9.2). c. Filler material markings are traceable to a filler material certification. d. Base metal markings are traceable to a material certification. e. Recording of filler and base metal traceability information is performed. f. Base metal stampings are low stress and not detrimental to the component. g. Paint striping color code is correct for the material of construction. h. PMI records supplement the material traceability and confirm the material of construction (see 9.2). 4.2.7.2 Potential inspector actions: a. Reject non-traceable or improperly marked materials. b. Reject inappropriate materials. 148. 4.2.8 Weld Preparation Confirm weld preparation, joint fit-up, and dimensions are acceptable and correct. 4.2.8.1 Quality control items to assess: a. Weld preparation surfaces are free of contaminants and base metal defects such as laminations and cracks. b. Preheat, if required, applied for thermal cutting c. Hydrogen bake-out heat treatment, if required, performed to procedure. d. Weld joint is free from oxide and sulfide scales, hydrocarbon residue, and any excessive build-up of weld-through primers. e. Weld joint type, bevel angle, root face and root opening are correct. f. Alignment and mismatch is correct and acceptable. g. Dimensions of base materials, filler metal, and weld joint are correct. h. Piping socket welds have proper gap. 4.2.8.2 Potential inspector action: Reject material or correct deficiencies. 149. Weld Preparation- Fit-up & Dimensions 150. 4.2.9 Preheat Confirm the preheat equipment and temperature. 4.2.9.1 Quality control items to assess: a. Preheat equipment and technique are acceptable. b. Preheat coverage and temperature are correct (see 10.5). c. Reheat, if required, applied to thermal cutting operations. d. Preheat, if required, applied to remove moisture. 4.2.9.2 Potential inspector action: Identify and correct deficiencies in the preheat operations. 151. 4.2.10 Welding Consumables Confirm electrode, filler wire, fluxes, and inert gases are as specified and acceptable. 4.2.10.1 Quality control items to assess: a. Filler metal type and size are correct per procedure. b. Filler metals are being properly handled and stored (see 7.7). c. Filler metals are clean and free of contaminants. d. Coating on coated electrodes is neither damaged nor wet. e. Flux is appropriate for the welding process and being properly handled. f. Inert gases, if required are appropriate for shielding and purging. g. Gas composition is correct and meets any purity requirements. h. Shielding gas and purging manifold systems are periodically bled to prevent back filling with air. 4.2.10.2 Potential inspector actions: a. Reject inappropriate materials. b. Identify and correct deficiencies. 152. 4.3 TASKS DURING WELDING OPERATIONS Welding inspection during welding operations should include audit parameters to verify the welding is performed to the procedures. Such tasks may include the following: 4.3.1 Quality Assurance 4.3.2 Welding Parameters and Techniques 4.3.3 Weldment Examination 153. 4.3.1 Quality Assurance Establish a quality assurance and quality control umbrella with the welding organization. 4.3.1.1 Quality control items to assess: a. Welder is responsible for quality craftsmanship of weldments b. Welder meets qualification requirements c. Welder understands welding procedure and requirements for the work. d. Special training and mock-up weldments performed if required. e. Welder understands the inspection hold-points. 4.3.1.2 Potential inspector actions: a. Review welder performance with welding organization. b. See Appendix B. 154. 4.3.2 Welding Parameters and Techniques Confirm welding parameters and techniques are supported by the WPS and WPQ. 4.3.2.1 Quality control items to assess: a. Essential variables are being met during welding. 1. Filler material, fluxes, and inert gas composition/flow rate. 2. Purge technique, flow rate, O2 analysis, etc. 3. Rod warmers energized or where rod warmers are not employed, the welder complies with maximum exposure times out of the electrode oven. 4. Preheating during tack welding and tack welds removed (if required). 5. Welding technique, weld progression, bead overlap, etc. 6. Equipment settings such as amps, volts, and wire feed. 7. Preheat and interpass temperatures. 8. Travel speed (key element in heat input). 9. Heat input (where appropriate). 155. b. Mock-up weldment, if required, meets requirements with welder and welding engineer. c. Welder displays confidence and adheres to good welding practices. 4.3.2.2 Potential inspector actions: a. Review mock-up weldment problems with welding engineer. b. Review welder quality with welding organization. c. See Appendix B. 156. 4.3.3 Weldment Examination Complete physical checks, visual examination, and in-process NDE 4.3.3.1 Quality control items to assess: a. Tack welds to be incorporated in the weld are of acceptable quality. b. Weld root has adequate penetration and quality. c. Cleaning between weld passes and of any back-gouged surfaces is acceptable. d. Additional NDE performed between weld passes and on back-gouged surfaces shows acceptable results. e. In-process rework and defect removal is accomplished. f. In-process ferrite measurement, if required, is performed and recorded. g. Final weld reinforcement and fillet weld size meets work specifications and drawings. 4.3.3.2 Potential inspector action: Reject unacceptable workmanship. 157. In-process ferrite measurement 158. In-process ferrite measurement 159. In-process ferrite measurement Why Dissimilar-Metal Welding is Needed, and How to Select Proper Filler Metals http://www.kobelco-welding.jp/education-center/abc/ABC_1999-02.html 160. Schaeffer diagram 161. Schaeffer diagram 162. 4.4 TASKS UPON COMPLETION OF WELDING Final tasks upon completion of the weldment and work should include those that assure final weld quality before placing the weldment in service. 4.4.1 Appearance and Finish 4.4.2 NDE Review 4.4.3 Post-weld Heat Treatment 4.4.4 Pressure Testing 4.4.5 Documentation Audit 163. 4.4.1 Appearance and Finish Verify post-weld acceptance, appearance and finishing of the welded joints. 4.4.1.1 Quality control items to assess: a. Size, length and location of all welds conform to the drawings/ specifications/Code. b. No welds added without approval. c. Dimensional and visual checks of the weld: identify welding discontinuities, excessive distortion and poor workmanship. d. Temporary attachments and attachment welds removed and blended with base metal. e. Discontinuities reviewed against acceptance criteria for defect classification. 164. f. PMI of the weld, if required, and examiners findings indicate they comply with the specification. g. Welder stamping/marking of welds confirmed. h. Perform field hardness check (see 9.10). 4.4.1.2 Potential inspector actions: Rework existing welds, remove welds and make weld repairs as required. 165. Field hardness check 166. Field hardness check 167. 4.4.2 NDE Review Verify NDE is performed at selected locations and review examiners findings. 4.4.2.1 Quality control items to assess: a. Specified locations examined. b. Specified frequency of examination. c. NDE performed after final PWHT. d. Work of each welder included in random examination techniques. e. RT film quality, IQI placement, IQI visibility, etc. complies with standards. f. Inspector is in agreement with examiners interpretations and findings. g. Documentation for all NDE correctly executed (see 9.11). 168. 4.4.2.2 Potential inspector actions: Require additional NDE to address deficiencies in findings. Checking for delayed cracking of thick section, highly constrained and high strength material joining. Repeat missing or unacceptable examinations. Correct discrepancies in examination records. 169. 4.4.3 Post-weld Heat Treatment Verify post-weld heat treatment is performed to the procedure and produces acceptable results. 4.4.3.1 Quality control items to assess: a. Paint marking and other detrimental contamination removed. b. Temporary attachments removed. c. Machined surfaces protected from oxidation. d. Equipment internals, such as valve internals, removed to prevent damage. e. Equipment supported to prevent distortion. f. Thermocouples fastened properly. g. Thermocouples adequately monitor the different temperature zones and thickest/thinnest parts in the fabrication. 170. h. Temperature monitoring system calibrated. i. Local heating bandwidth is adequate. j. Insulation applied to the component where required for local heating. k. Temperature and hold time is correct. l. Heating rate and cooling rate is correct. m. Distortion is acceptable after completion of the thermal cycle. n. Hardness indicates an acceptable heat treatment (see 10.7). 4.4.3.2 Potential inspector actions: a. Calibrate temperature-monitoring equipment. b. Correct deficiencies before heat treatment. c. Repeat the heat treatment cycle. 171. PWHT Procedure 172. 4.4.4 Pressure Testing Verify pressure test is performed to the procedure. 4.4.4.1 Quality control items to assess: a. Pressure meets test specification. b. Test duration is as-specified. c. Metal temperature of component meets minimum and maximum requirements. d. Pressure drop or decay is acceptable per procedure. e. Visual examination does not reveal defects. 4.4.4.2 Potential inspector actions: a. Either correct deficiencies prior to or during pressure test as appropriate. b. Repeat test as necessary. c. Develop repair plan if defects are identified. 173. Metal temperature of component meets minimum and maximum requirements. 174. 4.4.5 Documentation Audit Perform a final audit of the inspection dossier to identify inaccuracies and incomplete information. 4.4.5.1 Quality control items to assess: a. All verifications in the quality plan were properly executed. b. Inspection reports are complete, accepted and signed by responsible parties. c. Inspection reports, NDE examiners interpretations and findings are accurate (see 9.11). 4.4.5.2 Potential inspector actions: a. Require additional inspection verifications to address deficiencies in findings. b. Repeat missing or unacceptable examinations. c. Correct discrepancies in examination records. 175. 4.5 NON-CONFORMANCES AND DEFECTS At any time during the welding inspection, if defects or non-conformances to the specification are identified, they should be brought to the attention of those responsible for the work or corrected before welding proceeds further. Defects should be completely removed and re-inspected following the same tasks outlined in this section until the weld is found to be acceptable. Corrective action for a non-conformance will depend upon the nature of the non-conformance and its impact on the properties of the weldment. Corrective action may include reworking the weld. See 9.1 for common types of discontinuities or flaws that can lead to defects or non-conformances. 176. 4.6 NDE EXAMINER CERTIFICATION The referencing codes or standards may require the examiner be qualified in accordance with a specific code and certified as meeting the requirements. ASME Section V, Article 1, when specified by the referencing code, requires NDE personnel be qualified with one of the following: a. ASNT SNT-TC-1A b. ANSI/ASNT CP-189 These references give the employer guidelines (SNT-TC-1A) or standards (CP-189) for the certification of NDE inspection personnel. They also require the employer to develop and establish a written practice or procedure that details the employers requirements for certification of inspection personnel. It typically includes the training, and experience prerequisites prior to certification, and recertification requirements. If the referencing code does not list a specific standard to be qualified against, qualification may involve demonstration of competency by the personnel performing the examination or other requirements specified by the owner-user. 177. 4.7 SAFETY PRECAUTIONS Inspectors should be aware of the hazards associated with welding and take appropriate steps to prevent injury while performing inspection tasks. As a minimum, the sites safety rules and regulations should be reviewed as applicable to welding operations. Hazards that the inspector would more commonly encounter in the presence of welding include arc radiation, air contamination, airborne debris, and heat. The arc is a source of visible, ultraviolet and infrared light. As such, eye protection using proper filters and proper clothing to cover the skin should be used. Proper ventilation is necessary to remove air-borne particulates, which include vaporized metals. In areas of inadequate ventilation, filtered breathing protection may be required. The use of gas-shielded processes in confined spaces can create an oxygen deficient environment. Ventilation practice in these instances should be carefully reviewed. Welding can produce sparks and other airborne debris that can burn the eyes. Appropriate precautions are necessary. 178. Sevan Driller II http://www.cosco-shipyard.com/englishNew/detail.asp?classid=8&id=563 179. Sevan Driller I 180. Sevan Driller I 181. 5 Welding Processes 182. Content: 5 WELDING PROCESSES 5.1 General 5.2 Shielded Metal Arc Welding (SMAW) 5.3 Gas Tungsten Arc Welding (GTAW) 5.4 Gas Metal Arc Welding (GMAW 5.5 Flux Cored Arc Welding (FCAW 5.6 Submerged Arc Welding 5.7 Stud Arc Welding (SW) 183. Equipments & Piping 184. http://www.heatecholdings.com/business_pipingSystem_oil.html Equipments & Piping 185. Equipments & Piping 186. Equipments & Piping 187. Equipments & Piping 188. Equipments & Piping 189. Equipments & Piping 190. 5.1 GENERAL The inspector should understand the basic arc welding processes most frequently used in the fabrication and repair of refinery and chemical process equipment. These processes include shielded metal arc welding (SMAW), gas tungsten arc welding (GTAW), gas metal arc welding (GMAW), flux cored arc welding (FCAW), submerged arc welding (SAW), and stud arc welding (SW). Descriptions of less frequently used welding process are available in the referenced material. Each process has advantages and limitations depending upon the application and can be more or less prone to particular types of discontinuities. http://www.substech.com/dokuwiki/doku.php?id=shielded_metal_arc_welding_smaw 191. 5.2 SHIELDED METAL ARC WELDING (SMAW) SMAW is the most widely used of the various arc welding processes. SMAW uses an arc between a covered electrode and the weld pool. It employs the heat of the arc, coming from the tip of a consumable covered electrode, to melt the base metal. Shielding is provided from the decomposition of the electrode covering, without the application of pressure and with filler metal from the electrode. Either alternating current (ac) or direct current (dc) may be employed, depending on the welding power supply and the electrode selected. A constant-current (CC) power supply is preferred. SMAW is a manual welding process. See Figures 1 and 2 for schematics of the SMAW circuit and welding process. 192. 5.2.1 Electrode Covering Depending on the type of electrode being used, the covering performs one or more of the following functions: a. Provides a gas to shield the arc and prevent excessive atmospheric contamination of the molten filler metal. b. Provides scavengers, deoxidizers, and fluxing agents to cleanse the weld and prevent excessive grain growth in the weld metal. c. Establishes the electrical characteristics of the electrode. d. Provides a slag blanket to protect the hot weld metal from the air and enhances the mechanical properties, bead shape, and surface cleanliness of the weld metal. e. Provides a means of adding alloying elements to change the mechanical properties of the weld metal. 193. 5.2.2 Advantages of SMAW Some commonly accepted advantages of the SMAW process include: a. Equipment is relatively simple, inexpensive, and portable. b. Process can be used in areas of limited access. c. Process is less sensitive to wind and draft than other welding processes. d. Process is suitable for most of the commonly used metals and alloys. 5.2.3 Limitations of SMAW Limitations associated with SMAW are: a. Deposition rates are lower than for other processes such as GMAW. b. Slag usually must be removed at stops and starts, and before depositing a weld bead adjacent to or onto a previously deposited weld bead. 194. Shielded metal arc welding 195. Shielded metal arc welding 196. SMAW 197. SMAW 198. SMAW 199. SMAW- Underwater Welding 200. SMAW- Underwater Welding 201. SMAW- Qualification of Underwater Welders 202. SMAW- Structural Welding 203. SMAW- Structural Welding 204. SMAW- WPQ Welder Performance Qualification 205. SMAW- Transmission Pipeline Welding 206. Equipment is relatively simple, inexpensive, and portable. 207. SMAW- Weld Profile 208. SMAW- Weld Profile 209. SMAW- Weld Profile 210. SMAW- Weld Profile 211. SMAW- Weld Profile 212. SMAW- Weld Profile 213. SMAW- Weld Profile 214. SMAW- Weld Profile 215. SMAW- Grinding at Start-Stop 216. SMAW- Tack Welding 217. SMAW- Root Pass + Hot Pass 218. SMAW- Large Tack Weld for Thick Welding 219. SMAW- Pipeline Tie-in Joint 220. SMAW- Pipeline Welding 221. SMAW- WPQ Test Coupon 222. SMAW- WPQ Test Coupon 223. SMAW- WPQ Test Coupon 224. SMAW- AWS Test Positions 225. SMAW- Smiling Experts at Work 226. 5.3 GAS TUNGSTEN ARC WELDING (GTAW) GTAW is an arc welding process that uses an arc between a non- consumable tungsten electrode and the weld pool. The process is used with shielding gas and without the application of pressure. GTAW can be used with or without the addition of filler metal. The CC type power supply can be used with either dc or ac, the choice depends largely on the metal to be welded. Direct current welding is typically performed with the electrode negative (DCEN) polarity. DCEN welding offers the advantages of deeper penetration and faster welding speeds. Alternating current provides a cathodic cleaning (sputtering) that removes refractory oxides from the surfaces of the weld joint, which is necessary for welding aluminum and magnesium. The cleaning action occurs during the portion of the ac wave, when the electrode is positive with respect to the work piece. See Figures 3 and 4 for schematics of the GTAW equipment and welding process. 227. Gas tungsten arc welding 228. Gas tungsten arc welding http://www.substech.com/dokuwiki/doku.php?id=tungsten_inert_gas_arc_welding_tig_gtaw 229. Gas tungsten arc welding 230. The cleaning action occurs during the portion of the ac wave, when the electrode is positive with respect to the work piece. 231. GTAW 232. GTAW 233. 5.3.1 Advantages of GTAW Some commonly accepted advantages of the GTAW process include: a. Produces high purity welds, generally free from defects. b. Little post-weld cleaning is required. c. Allows for excellent control of root pass weld penetration. d. Can be used with or without filler metal, dependent on the application. 5.3.2 Limitations of GTAW Limitations associated with GTAW process are: a. Deposition rates are lower than the rates possible with consumable electrode arc welding processes. b. Has a low tolerance for contaminants on filler or base metals. c. Difficult to shield the weld zone properly in drafty environments. 234. GTAW / TIG Welding 235. GTAW / TIG Weld a. Produces high purity welds, generally free from defects. 236. TIG weld without addition of filler metal- autogenous weld. 237. GTAW / TIG Weld 238. TIG Gas Nozzles 239. Tungsten Electrodes 240. Tungsten Electrodes 241. Tungsten Electrodes 242. Tungsten Electrodes 243. Tungsten- Automation 244. 5.4 GAS METAL ARC WELDING (GMAW) GMAW is an arc welding process that uses an arc between continuous filler metal electrode and the weld pool. The process is used with shielding from an externally supplied gas and without the application of pressure. GMAW may be operated in semiautomatic, machine, or automatic modes. It employs a constant voltage (CV) power supply, and uses either the (1) short circuiting, (2) globular, or (3) spray methods to transfer metal from the electrode to the work: The type of transfer is determined by a number of factors. The most influential are: a. Magnitude and type of welding current. b. Electrode diameter. c. Electrode composition. d. Electrode extension. e. Shielding gas. See Figures 5 and 6 for schematics of the GMAW equipment and welding process. CV 245. Gas metal arc welding GMAW / MIG (metal inert gas) CV 246. Flux cored arc welding (FCAW) CV 247. GMAW http://www.docslide.com/gmaw-fundamentals/ 248. GMAW CV 249. GMAW CV 250. Gas metal arc welding GMAW / MIG (metal inert gas) 251. 5.4.1 Short Circuiting Transfer (GMAW-S) GMAW-S encompasses the lowest range of welding currents and electrode diameters associated with GMAW process. This process produces a fast freezing weld pool that is generally suited for joining thin section, out-of position, or root pass. Due to the fast-freezing nature of this process, there is potential for lack of sidewall fusion when welding thickwall equipment or a nozzle attachment. CV 252. Short Circuit mode http://www.ualberta.ca/~ccwj/videos/files/01_Fundamental%20GMAW%20Metal%20Transfer%20Modes/GMAW_Steel_8 5Ar-15CO2_Short-Circuit_001/GMAW_Steel_85Ar-15CO2_Short-Circuit_001.mp4 253. Short Circuit mode http://www.ualberta.ca/~ccwj/videos/files/05_Tubular%20Wires/GMAW_Ni-WC_70Ar-30CO2_Short- Circuit_001/GMAW_Ni-WC_70Ar-30CO2_Short-Circuit_001.mp4 254. Conceptual schematic of metal transfers in GMAW: (a) short circuit, (b) globular, (c) pulse and (d) spray 255. 5.4.2 Globular Transfer This process encompasses relatively low current (below 250 A). The globular transfer mode is characterized by a drop size with a diameter greater than that of the electrode. In general, this process is limited to the flat position and can produce spatter. CV 256. Globular transfer mode CVhttp://www.ualberta.ca/~ccwj/videos/pages/Intro%20High%20Speed/ 257. Globular transfer mode http://www.ualberta.ca/~ccwj/videos/pages/Intro%20High%20Speed/ http://www.ualberta.ca/~ccwj/videos/files/01_Fundamental%20GMAW%20Metal%20Transfer%20Modes/GMAW_Steel_8 5Ar-15CO2_Globular_001/GMAW_Steel_85Ar-15CO2_Globular_001.mp4 258. Globular transfer mode http://www.ualberta.ca/~ccwj/videos/pages/Intro%20High%20Speed/ http://www.ualberta.ca/~ccwj/videos/files/05_Tubular%20Wires/GMAW_Ni-WC_85Ar-15O2_Globular_001/GMAW_Ni- WC_85Ar-15O2_Globular_001.mp4 259. Globular transfer mode http://www.weldsmith.co.uk/dropbox/cranu/110523_wavefor ms_GMAW_steel/waveforms_GMAW_steel.html 260. Globular transfer mode CV 261. 5.4.3 Spray Transfer The spray transfer mode results in a highly directed stream of discrete drops that are accelerated by arc forces. Spatter is negligible. Due to its high arc forces with high current, applying this process to thin sheets may be difficult. The thickness limitation of the spray arc transfer has been overcome by the use of pulsed GMAW. Pulsed GMAW is a variation of the GMAW in which the current is pulsed to obtain the advantage of spray transfer at the less average currents than that of spray transfer mode. CV 262. Spray transfer mode http://www.ualberta.ca/~ccwj/videos/files/01_Fundamental%20GMAW%20Metal%20Transfer%20Modes/GMAW_Steel_8 5Ar-15CO2_Spray_001/GMAW_Steel_85Ar-15CO2_Spray_001.mp4 263. 5.4.4 Advantages of GMAW Some commonly accepted advantages of the GMAW process include: a. The only consumable electrode process that can be used to weld most commercial metals and alloys. b. Deposition rates are significantly higher than those obtained with SMAW. c. Minimal post-weld cleaning is required due to the absence of a slag. 5.4.5 Limitations of GMAW Limitations associated with GMAW are: a. The welding equipment is more complex, more costly, and less portable than that for SMAW. b. The welding arc should be protected from air drafts that will disperse the shielding gas. c. When using the GMAW-S process, the weld is more susceptible to lack of adequate fusion. CV 264. Pulsed GMAW Modified Spray Mode CV 265. http://www.millerwelds.com/resources/articles/Pulsed-MIG-gmaw-aluminum/ CV Pulsed GMAW Modified Spray Mode 266. Pulse Spray transfer mode http://www.ualberta.ca/~ccwj/videos/files/05_Tubular%20Wires/GMAW_Ni-WC_95Ar-5CO2_Pulsing_001/GMAW_Ni- WC_95Ar-5CO2_Pulsing_001.mp4 267. CV GMAW-MIG 268. CV GMAW-MIG 269. CV GMAW-MIG 270. CV GMAW-MIG 271. CV GMAW-MIG 272. CV GMAW-MIG 273. GMAW- Automation 274. GMAW- Automation 275. GMAW- Automation 276. GMAW- Branch Pipe Welding 277. GMAW- Stainless Steel Piping 278. GMAW- Stainless Steel Piping 279. 5.5 FLUX CORED ARC WELDING (FCAW) FCAW is an arc welding process that uses an arc between continuous tubular filler metal electrode and the weld pool. The process is used with shielding gas evolved from a flux contained within the tubular electrode, with or without additional shielding from an externally supplied gas, and without the application of pressure. Normally a semiautomatic process, the use of FCAW depends on the type of electrodes available, the mechanical property requirements of the welded joints, and the joint designs and fit-up. The recommended power source is the dc constant-voltage type, similar to sources used for GMAW. Figures 7 and 8 show a schematic of FCAW equipment and welding process with additional gas shielding. Figure 9 shows a schematic of the self-shielded FCAW process where no additional gas is used. CV 280. Flux cored arc welding (FCAW) 281. FCAW CV 282. FCAW CV 283. FCAW-Self shield CV 284. CV FCAW-Self shield 285. FCAW 286. FCAW 287. FCAW 288. FCAW 289. 3G FCAW WPQT 290. FCAW CV 291. FCAW http://www.brewerweldingandfabrication.com/OrbitalWelding.htm 292. 5.5.1 Advantages of FCAW Some commonly accepted advantages of the FCAW process include: a. The metallurgical benefits that can be derived from a flux. b. Slag that supports and shapes the weld bead. c. High deposition and productivity rates than other processes such as SMAW. d. Shielding is produced at the surface of the weld that makes it more tolerant of stronger air currents than GMAW. 5.5.2 Limitations of FCAW Limitations associated with FCAW process are: a. Equipment is more complex, more costly, and less portable than that for SMAW. b. Self-shielding FCAW generates large volumes of welding fumes, and requires suitable exhaust equipment. c. Slag requires removal between passes. d. Backing material is required for root pass welding. CV 293. 5.6 SUBMERGED ARC WELDING (SAW) Submerged arc welding is an arc welding process that uses an arc or arcs between a flux covered bare metal electrode(s) and the weld pool. The arc and molten metal are shielded by a blanket of granular flux, supplied through the welding nozzle from a hopper. The process is used without pressure and filler metal from the electrode and sometimes from a supplemental source (welding rod, flux, or metal granules). SAW can be applied in three different modes: semiautomatic, automatic, and machine. It can utilize either a CV or CC power supply. SAW is used extensively in shop pressure vessel fabrication and pipe manufacturing. Figure 10 shows a schematic of the SAW process. Manual Semiautomatic Automatic Machine CV 294. 5.6.1 Advantages of SAW Some commonly accepted advantages of the SAW process include: a. Provides very high metal deposition rates. b. Produces repeatable high quality welds for large weldments and repetitive short (defective) welds. 5.6.2 Limitations of SAW Limitations associated with SAW are: a. A power supply capable of providing high amperage at 100% duty cycle is recommended. b. Weld is not visible during the welding process. c. Equipment required is more costly and extensive, and less portable. d. Process is limited to shop applications and flat position. CV 295. SAW CV 296. Submerged arc welding (SAW) 297. Submerged arc welding (SAW) 298. Submergedarcwelding(SAW) 299. Submerged arc welding (SAW) 300. Submerged arc welding (SAW) 301. Submerged arc welding (SAW) 302. Submerged arc welding (SAW) 303. Submerged arc welding (SAW) 304. SAW Twin electrodes in tandem with guider 305. SAW- Triple Electrodes Set-up (tilted) 306. SAW- Portable single Electrode Unit 307. SAW Experts at Work 308. Spiral welding SAW- API 5LS 309. Spiral Welded SAW Pipes 310. SAW- Pressure Vessel Conical Head Welding 311. SAW- Vessel Internal Welding 312. 2G SAW Tank Semi-Automatic Welding 313. SAW- Spiral Welded Pipes 314. SAW SAW- Internal Welding Leg Cane 315. SAW- Serious Experts at Work 316. SAW- Welding on a Rotorary Wheel Set-up 317. SAW- Vessel Ellipsoidal Disk Head 318. SAW- Pressure Vessel 319. SAW- Pipe Can Welding 320. SAW- Structural Mud Mats 321. SAW- Structural Welding 322. 5.7 STUD ARC WELDING (SW) SW is an arc welding process that uses an arc between a metal stud or similar part and the work piece. Once the surfaces of the parts are properly heated, that is the end of the stud is molten and the work has an equal area of molten pool, they are brought into contact by pressure. Shielding gas or flux may or may not be used. The process may be fully automatic or semiautomatic. A stud gun holds the tip of the stud against the work. Direct current is typically used for SW with the stud gun connected to the negative terminal (DCEN). The power source is a CC type. SW is a specialized process predominantly limited to welding insulation and refractory support pins to tanks, pressure vessels and heater casing. 323. 5.7.1 Advantages of SW Some commonly accepted advantages of the SW process include: a. High productivity rates compared to manually welding studs to base metal. b. Considered an all-position process. 5.7.2 Limitations of SW Limitations of SW are: a. Process is primarily suitable for only carbon steel and low alloy steels. b. Process is specialized to a few applications. 324. Stud arc welding (SW) 325. Stud arc welding (SW) 326. Stud arc welding (SW) 327. Stud arc welding (SW) 328. Stud arc welding (SW) 329. Welding Transfer Modes: SMAW - CC TIG - CC SW - CC SAW - CC or CV GMAW - CV FCAW - CV 330. Further Reading: (Non Examination) Considering the benefits of pulse spray transfer GMAW Understanding transfer modes for GMAW Pulsed GMAW CV & CC Welding ModesOther Interesting Readings 331. 1.0 Considering the benefits of pulse spray transfer GMAW PRACTICAL WELDING TODAY SEPTEMBER/OCTOBER 2001 October 25, 2002 By: Paul Niskala http://www.thefabricator.com/article/arcwelding/considering-the-benefits-of-pulse-spray-transfer-gmaw 332. 1.0 General Pulse spray gas metal arc welding (GMAW) is a versatile welding process. Sometimes welding suppliers and welding managers don't want to try it, because they don't want to change the process they're using, train users, adjust welding processes, or spend money on new equipment. While any pulse spray machine can perform short-circuit transfer, each type of transfer has distinct differences and benefits. 1.1 Three Common Types of Transfer for GMAW Short-circuit ,spray transfer and pulse-spray are the three most common types of GMAW metal transfer. 333. 1.3 The short-circuit process In the short-circuit process, when the wire touches the base metal, it causes a short circuit. The base metal and wire become molten at the point where the wire touches the base metal, and the wire is pinched off. Spatter, in the form of round, molten balls that stick to the base metal, is a result of the sudden separation, or transfer, of the wire. The Short Circuit process can weld sheet metal and commonly is used for joining materials 1/4 in. (6mm) thick or less. Its fast-freezing puddle characteristic makes welding in all positions simple. 334. Short-circuiting is a low-heat-input process, generally less than 20 volts and 200 amps (4000 Volt-Ampere Apparent Power) using small-diameter welding wires no larger than 0.045 in. (1mm) The short-circuit process can weld materials that fit poorly. Besides shielded metal arc welding, it's probably the least expensive GMAW process because of the low welding currents involved, which require smaller, less expensive equipment. Short-circuit also is the most abused process because welders use it frequently for jobs that the process was not designed for, such as welding metals thicker than the process reasonably allows. 335. The short-circuit process is not a deep-penetrating process and is not suited for welding thick materials. It also lacks penetration at the toes of the weld, especially in out-of-position welding, causing cold laps (lack of fusion). Disadvantages of short-circuit include excessive spatter and low deposition rates. It generally is not recommended for aluminum or other alloys, which typically require higher heat input to obtain proper fusion. short-circuiting can be beneficial because: It can be used for welding sheet metal. It can weld materials 1/4 in. (6mm) thick or less. It can be used to weld in all positions. It uses low heat input, generally less than 20 V and 200 amps, using small-diameter welding wires no larger than 0.045 in. (1.2mm) It can weld materials that fit poorly. 336. 1.4 The Spray Transfer Mode Spray transfer uses higher voltage and higher percentages of argon mixtures, 80 percent or better, mixed with carbon dioxide or small amounts of oxygen. This high-energy output causes the droplets to be very small and burn off the wire before short-circuiting occurs. This small stream of droplets creates a fluid spray, which melts the base metal. Using higher operating parameters results in deeper penetration. The biggest benefit of the spray transfer process is its ability to make high-deposition welds on thick carbon steels, stainless steels, aluminum, and other alloys using large-diameter welding wires (0.052 in. and 0.062 in.) (1.3mm 1.6mm) with very little spatter and no cleanup. 337. By using 0.035- and 0.045-in.-dia. (0.9mm 1.2mm) welding wires, you can weld a range of thinner materials with the spray transfer process. It is not recommended for metals 1/8 in. (3mm) or less. Other benefits include no spatter, good fusion, a smooth bead, and weld appearance The biggest drawback of spray transfer is that it can be used only in the flat position because the puddle is so fluid. Both processes can be accomplished with a basic constant-voltage welding power source. Manufacturers have been able to design equipment that controls the weld puddle. Amperage is pulsed from a specified high-low current at predetermined frequencies to control the puddle better and thus allow for out- of-position welding. 338. 1.5 Pulse-Spray Transfer Mode As with any welding process, short-circuit and spray transfer methods of metal transfer in GMAW have their pros and cons. Pulse spray GMAW can be useful for the following reasons: It can weld a variety of metals. It has good penetration. It can weld a wide range of thicknesses. It provides good fusion at the toes of the weld. It can weld faster than short-circuit and globular transfer. It has 90 percent less spatter than short-circuit transfer. It can be used to weld in all positions. It reduces the number of ASME and AWS certifications required. 339. 1.6 Summary Equipment for short-circuit welding can be less expensive than for spray transfer. Any spray machine can perform short-circuit transfer as well, but cost differences exist primarily in the type of gas used. Short-circuit uses less argon and more carbon dioxide, while spray transfer requires more argon and less carbon dioxide. Argon is one of the most expensive industrial welding gases used in GMAW, while carbon dioxide is the least expensive. While any pulse spray machine can perform short-circuit transfer, each type of transfer has distinct differences and benefits. 340. Equipment for short-circuit welding can be less expensive than for spray transfer. Any spray machine can perform short-circuit transfer as well, but cost differences exist primarily in the type of gas used. Short-circuit uses less argon and more carbon dioxide, while spray transfer requires more argon and less carbon dioxide. Argon is one of the most expensive industrial welding gases used in GMAW, while carbon dioxide is the least expensive. By considering the cost, the benefits of short-circuit and spray transfer processes, and your product line, you can decide the best mode of transfer for you. 341. 2.0 Understanding transfer modes for GMAW How they affect filler metal selection PRACTICAL WELDING TODAY NOVEMBER/DECEMBER 2008 DECEMBER 14, 2008 BY: JERRY MATHISON http://www.thefabricator.com/article/consumables/understanding-transfer-modes-for-gmaw 342. 2.0 General The gas metal arc welding (GMAW) process uses four basic modes to transfer metal from the electrode to the workpiece. Each mode of transfer depends on the welding process, the welding power supply, and the consumable, and each has its own distinct characteristics and applications. Several variables dictate the type of transfer you use, including the amount and type of welding current, the electrode chemistry, electrode surface, electrode diameter, shielding gas, and the contact tip-to-work distance. Transfer mode also affects your choice of filler metal used. Choosing wisely can greatly affect your efficiencies and productivity. Short Circuit Globular Spray Pulse-Spray 343. 2.1 Short-circuit Transfer In short-circuit transfer, the electrode touches the work and short circuits, causing the metal to transfer as a result of the short. This happens at a rate of 20 to more than 200 times per second. The advantage of the short-circuit transfer is its low energy. This method is normally used on thin material (6.3mm) inch or less, and for root passes on pipe with no backing. It can be used to weld in all positions. This mode of transfer generally calls for smaller-diameter electrodes, such as 0.6mm,0.8mm, 0.9mm, 1.0mm, and 1.1mm. The welding current must be sufficient to melt the electrode, but if it is excessive, it can cause a violent separation of the shorted electrode, leading to excessive spatter. Using adjustable slope and inductance controls can enhance the transfer to minimize spatter and promote a flatter weld profile. Slope adjustment limits the short-circuit amperage, while inductance adjustments control the time it takes to reach maximum amperage. Proper adjustment of these two factors can produce excellent bead appearance and is essential for short-circuit transfer with stainless steel electrodes. 344. The most predominant solid stainless steel electrodes are ER 308L, ER 309L, and ER 316L. These electrodes are also available in the Si type, such as 308LSi. The LSi types contain more silicon, which increases puddle fluidity and helps the weld puddle to wet out better than the standard alloys. While minor power source adjustments may be needed, both types can be used successfully as long as the specification for the welding consumables permits. For carbon steel electrodes, the electrode classification dictates the silicon level. ER 70S-3 and ER 70S-6 are the most widely used. For pipe applications, ER 70S-2, ER7 0S-4, and ER 70S-7 are sometimes used for open-root work because they offer lower silicon levels. The lower silicon produces a stiffer puddle and gives you more control of the back bead profile. In an open-root weld, you may use an S-6 type electrode with less inductance than an S-2 type electrode because the S-6 type has a higher level of silicon and the puddle is more fluid. 345. Maintaining a constant contact tip-to-work distance in short-circuit transfer is important to maintain a smooth transfer. The most common shielding gas for the short-circuit transfer mode for carbon steel electrodes is: 75 percent argon/25 percent CO2. Numerous three-part shielding gas mixes are also available for carbon steel and stainless steel for this mode of transfer. 346. 2.2 Globular Transfer Globular transfer means the weld metal transfers across the arc in large droplets, usually larger than the diameter of the electrode being used. This mode of transfer -generally is used on carbon steel only and uses 100 percent CO2 shielding gas. The method typically is used to weld in the flat and horizontal positions because the droplet size is large and would be more difficult to control if used in the vertical and overhead positions compared to the short-circuit arc transfer. This mode generates the most spatter; however, when higher currents are used with CO2 shielding and a buried arc, spatter can be greatly reduced. You must use caution with a buried arc because this can result in excessive reinforcement if travel speed isn't controlled. 347. Stainless steel GMAW electrodes normally aren't used in this mode of transfer because their nickel and chrome content (9 to 14 percent nickel and 19 to 23 percent chromium) creates a higher electrical resistance than carbon steel electrodes. In addition to the electrical resistance differences, the use of 100 percent CO2 as a shielding gas could be detrimental to the corrosion resistance of the stainless steel electrodes. Carbon steel ER 70S-3 and ER 70S-6 generally are the electrodes of choice. 348. 2.3 Spray Transfer Mode Spray transfer is named for the spray of tiny molten droplets across the arc, similar to spray coming out of a garden hose when the opening is restricted. Spray transfer usually is smaller than the diameter of the wire and uses relatively high voltage and wire feed speeds or amperage. Unlike short-circuit transfer, once the arc is established, it is on at all times. This method produces very little spatter and is most often used on thick metals in the flat and horizontal positions. 349. Spray Transfer Mode Shield Gas & Transition Current 350. Spray transfer is achieved with high percentages of argon in the shielding gas, generally a minimum of 80 percent. Also called axial spray, this mode uses a current level above what is described as the transition current. The transition current will vary depending on the electrode diameter, shielding gas mixture percentages, and contact tip- to-work distance. When the current level is higher than the transition current, the electrode transfers to the work in very small droplets that can form and detach at the rate of several hundreds per second. Sufficient arc voltage is required to ensure that these small droplets never touch the work, achieving a spatter-free weld. Spray transfer also produces a fingerlike penetration profile. 351. This transfer mode is used mostly in the flat and horizontal positions because it produces a large weld puddle. High deposition rates can be achieved compared to the other transfer modes. Because of the arc length used, it is also more easily influenced by magnetic fields. If this is not controlled, penetration profile, bead appearance, and spatter levels can be negatively affected. 352. The major factor in choosing a carbon steel electrode is sometimes the amount of silicate islands that remain on the weld bead surface. This is especially the case if you need to minimize postweld cleaning time or if the finished product will be painted. For this reason, you might choose an ER 70S-3, ER 70S-4, or ER 70S-7 electrode. With stainless steel electrodes, there is little difference in the bead appearance in the Si types because of the higher energy used in this mode of transfer. The wetting action advantage of the Si types is not necessary, and if they are used it usually is a matter of preference. The effect of the chemistry on the transition current is minimal, but a higher voltage may be required with one alloy compared to another to achieve a true spray. 353. 2.4 Pulse-Spray Transfer Mode In the pulse-spray transfer mode, the power supply cycles between a high spray transfer current and a low background current. This allows for super cooling of the weld pool during the background cycle, making it slightly different than a true spray transfer. Ideally, in each cycle one droplet transfers from the electrode to the weld pool. Because of the low background current, this mode of transfer can be used to weld out of position on thick sections with higher energy than the short-circuit transfer, thus producing a higher average current and improved side-wall fusion. Additionally, it can be used to lower heat input and reduce distortion when high travel speeds are not needed or cannot be achieved because of equipment or throughput limitations. 354. Generally, the same shielding gases used for spray transfer are also used for pulsed-spray mode. The electrodes you can use include all the standard carbon steel and stainless steel types, along with some of the specialty alloys such as INCONEL (625), duplex (2209), and superduplex (2509). With a programmable pulse power supply, most solid-wire alloys can be used with a customized pulse waveform. With all modes of transfer, the wire type will have some effect on the machine settings. In addition, the wire surface will affect the transfer. Manufacturers use different types of arc stabilizers on the wire surface to enhance a smooth transfer. This is why small adjustments must be made when welding with the same type of electrode from different manufacturers. 355. 3.0 Pulsed GMAW Pulsed GMAW is technically a modified spray transfer process. With spray transfer, drops of molten metal are continuously being transferred across the arc. In pulsed spray transfer, the power source rapidly switches the welding output from high peak current to low background current. The peak current pinches off a spray-transfer droplet and propels it toward the weldment for good fusion. The background current maintains the arc, but is too low for metal transfer to occur. Because there is no metal transfer, the weld puddle gets a chance to cool and freeze slightly. Because the heat input is lower, pulsed GMAW eliminates or minimizes burn-through, distortion, heat-affected zone size and loss of mechanical properties. A faster-freezing weld puddle also provides better control on overhead and vertical welds so the puddle doesn't "roll out" of the joint when welding out of position. http://www.millerwelds.com/resources/articles/Pulsed-MIG-GMAW-inverters/ 356. 4.0 CV/CC Transfer Mode A CV power source delivers constant voltage by varying the current to maintain a constant arc length. In this mode, the operator is able to adjust wire feed speed and arc voltage. CV is considered the conventional way to weld aluminum, and fabricators today still choose CV for its simplicity and lower capital cost over other GMAW methods. Welding aluminum with either CC or CV power sources requires high-energy axial spray transfer to melt the base metal and ensure good fusion. To obtain spray arc transfera steady stream of molten metal that sprays across the arcthe welding current must be above a certain minimum transition current. For example, using CV spray transfer with 364-inch aluminum GMAW wire requires a minimum of 135 amps. http://www.thefabricator.com/article/aluminumwelding/tackling-aluminum-gmaw 357. http://www.lincolnelectric.com/en-us/support/process-and-theory/Pages/constant-current-vs-constant-coltage-output.aspx CV/CC Current Transfer Modes: Constant Voltage Power Source Constant Current Power Source Current, ACurrent, A Voltage,V Voltage,V Operating point Operating point 358. http://www.lincolnelectric.com/en-us/support/process-and-theory/Pages/constant-current-vs-constant-coltage-output.aspx Current Transfer Modes: CC 359. 5. Other Interesting Reading: 5.1 Choosing the right shielding gas and supply system for GMAW WWW.THEFABRICATOR.COM JANUARY 2002 July 26, 2001 By: David Bell http://www.thefabricator.com/article/consumables/choosing-the-right-shielding-gas-and-supply-system-for-gmaw 360. End of reading! 361. 6: Welding Procedure 362. Content: 6 WELDING PROCEDURE 6.1 General 6.2 Welding Procedure Specification (WPS) 6.3 Procedure Qualification Record (PQR). 6.4 Reviewing a WPS and PQR 363. WPS/PQR 364. WPS/PQR 365. 6.1 GENERAL Qualified welding procedures are required for welding fabrication and repair of pressure vessels, piping and tanks. They detail the steps necessary to make a specific weld and generally consists of a written description, details of the weld joint and welding process variables, and test data to demonstrate the procedure produces weldments that meet design requirements. While various codes and standards exist for the development of welding procedures, this section reflects criteria described in ASME Section IX. Welding procedures qualified to ASME Section IX are required by API inspection codes for repair welding and are often required by construction codes used in fabrication of new equipment and piping. However, construction codes and proprietary company specifications may have additional requirements or allow specific exceptions so they should be reviewed for each weld application. 366. construction codes and proprietary company specifications may have additional requirements or allow specific exceptions so they should be reviewed for each weld application. 367. construction codes and proprietary company specifications may have additional requirements or allow specific exceptions so they should be reviewed for each weld application. 368. Welding procedures required by ASME Section IX will include a written welding procedure specification (WPS) and procedure qualification record (PQR). The WPS provides direction to the welder while making production welds to ASME code requirements. The PQR is a record of the welding data and variables used to weld a test coupon and the test results used to qualify the welding procedure. It is important to differentiate the PQR and welder performance qualification (WPQ), detailed in Section 7. The purpose of the PQR is to establish the properties of the weldment. The purpose of the WPQ is to establish the welder is capable of making a quality weld using the welding procedure. 369. WPS 6.2 WELDING PROCEDURE SPECIFICATION (WPS) ASME Section IX requires each manufacturer and contractor to develop welding procedures. Whereas this requirement appears repetitious, qualified welding procedure specifications are an important aspect of fabrication quality control. They help each organization recognize the significance of changes in welding variables that may be required on the job, and the effects of the changes on weldment properties. The WPS is but one step for welding fabrication quality assurance. ASME B31.3 allows welding procedure qualification by others, provided it is acceptable to the inspector and meets certain conditions. 370. The completed WPS for a welding process addresses all essential, nonessential, and supplementary essential variables when notch toughness is required. Essential variables affect the mechanical properties of the weld. If they are changed beyond what the reference code paragraph allows for the process, the WPS must be re-qualified. Nonessential variables do not affect the mechanical properties of the weld. They may be changed on the WPS without re-qualifying the welding procedure. Supplementary essential variables apply or when specified by the end user. They are treated as essential variables when they apply. (when notch toughness is required.) 371. ASME B31.3, Chapter V Fabrication, Assembly, and Erection 328.2.2 Procedure Qualification by Others. Each employer is responsible for qualifying any welding procedure that personnel of the organization will use. Subject to the specific approval of the Inspector, welding procedures qualified by others may be used, provided that the following conditions are met: (a) The Inspector shall be satisfied that (1) the proposed welding procedure specification (WPS) has been prepared, qualified, and executed by a responsible, recognized organization with expertise in the field of welding (2) the employer has not made any change in the welding procedure (b) The base material P-Number is either 1, 3, 4 Gr. No. 1 (114 Cr max.), or 8; and impact testing is not required 372. 328.2.3 Performance Qualification by Others. To avoid duplication of effort, an emp

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