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FOR CURRENT COMMITTEE PERSONNEL PLEASE E-MAIL CS@asme.org Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled when REAFFIRMED 2003 PERFORMANCE TEST CODES (Not Intended for Acceptance Testing) ASME PTC 6s Report-1988 [REVISION OF ASME PTC 65 REPORT-1970 (R1985)I TH AE MERICA SN OCIETY United Engineering Center OF MECHANICAL 345 East 47th Street ENGINEERS NewYork, N.Y 10017 Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled wh Procedures for Routine Performance Tests of Steam Turbines This document will be revised when the Society approves the issuance of the next edition, scheduled for 1992 There will be nlo Addenda issued to PTC 6s Report-1988 Please Note: ASME issues written replies to inquiries concerning interpretation of technicai aspects of this document PTC 6s Report-1988 is being issued with an automatic subscription service to the interpretations that will be issued tu it up to the publication of the 1992 Edition ASME is the registered trademark of The American Society of Mechanical Engineers This code or standard was developed under procedures accredited as meeting the criteria for American National Standards The Consensus Committee that approved the code or standard was balanced to assure that individuals from competent and concerned interests have had an opportunity to participate The proposed code o r standard was made available for public review and comment which provides an opportunity for additional pu:blicinput fromindustry, academia, regulatory agencies, and the public-at-large ASME does not "approve," "rate," or "endorse" any item, c:onstruction, proprietary device, or activity ASME 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 or standard 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) affiliated with industry is not to be interpreted as government or industry endorsement of this code or standard ASME accepts responsibility for only those interpretations issued in accordance with governing ASME procedures and policies which preclude the issuance of interpretations by individual volunteers No part of this document may be reproduced in any form, in an electronic retrieval system or otherwise, without the prior writtenpermission of thepublisher Copyright 1989 by THE AMERICAN SOCIETY OF MECHANICAL ENGINEERS All Rights Reserved Printed in the U.S.A Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled wh Date of issuance: December 15, 1989 (This Foreword is not part of ASME PTC s Report-1988.) Users of bothlarge and small turbines haveexperienced an increasing need for procedures for routine turbinetests which trend performance with time The use of full-scale ASME Performance Test Code procedures and instrumentation for this purpose i s expensive and produces information and accuracy beyond that necessary for periodic monitoring When ASME Performance Test Code Committee No was reorganized to revise PTC 6-1 949, it was charged also with developing simplifiedprocedures for periodic tests Because of the routine nature of the tests, these procedures were to emphasize repeatability of results rather than absolute accuracy and thus provide a more economic means of monitoring performance trends This Report reflects the consensus of knowledgeable engineers and contains recommended procedures for collecting sufficiently accurate data to permit analyses of performance trends Recommendations are given which include advance planning, cycle isolation, and suggested presentation of results Emphasis is placed upon the use of accurate instrumentation, approaching measurement uncertainties required by the Code, for the measurement of criticalvariables that are part of the heat-rate equation Other instrumentation i s specified to produce results of good accuracy and of a high degree of repeatability With the application ofautomatic data-loggingand on-line computer systems to the plantcycle, the procedures presented in this Report, when applied to this end, should satisfy the needs of users of both large and small turbines Procedures recommended in this Report are not intended to produce abolute levels of performance If absolute performance level is required, the ASME Test Code for Steam Turbines, PTC 6, 1976, reaffirmed 1985, or the Interim Test Code for an Alternative Procedure for Testing Steam Turbines, PTC 6.1, 1984, should be followed For other levels of accuracy, where the test instrumentation varies from the Test Code specified procedure, the Report by PTC Committee No on ”Guidance for Evaluation of Measurement Uncertainty in Performance Tests of Steam Turbines,” 1985 should be consulted Users of this Report are requested to comment and provide tothe Committee supporting data obtained with these procedures Such comment and repeatability data covering longterm and/or extensive experience will provideguidance for subsequent revisions of this Report User suggestions and data should be submitted to the Secretary, ASME Performance Test Codes Committee, 345 East 47th Street, New York, New York 10017 This Report was approved by the ASME Board on Performance Test Codesand adopted as a standard practice of the Society on May8, 1988 It was approved as an American National Standard by the ANSI Board of Standards Review on September 8, 1988 iii Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled wh FOREWORD iv Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled w All ASME codes are copyrighted, with all rights reserved to the Society Reproduction of should a p this or any other ASME code is a violation of Federal Law Legalities aside, the user preciate that the publishing of the high quality codes that havetypified ASME documents rework diligently to quires a substantial commitment by the Society Thousands of volunteers develop these codes They participate on their own or with a sponsor's assistance and produce documents that meet the requirements of an ASME concensus standard The codes are very valuable pieces ofliterature to industry and commerce, and the effort to improve these "living documents" and develop additional needed codes must becontinued The monies spent for research and further code development,administrative staff support and publication are essential and constitute a substantial drain on ASME The purchase price of these documents helps offset these costs User reproduction undermines this system and represents anadded financial drain on ASME When extra copiesare needed,you are requestedto call or write the ASME Order Department, 2 Law Drive, Box 2300, Fairfield, New Jersey 07007-2300, and ASME will expedite delivery of such copies to you by return mail Please instruct your people to buy required test codes rather thancopy them Your cooperation in this matter is greatly appreciated (The following is the roster of the Committee at the time of approval of this Code.) OFFICERS E W A Campbell, Chairman J.Brailey, Jr., Vice Chairman J.H Karian, Secretary COMMITTEEPERSONNEL M Baltrus, Sargent & Lundy Engineers J.A Booth, General Electric Co P C Albert, Alternate fo Booth, General Electric Co B Bornstein, Consultant E J.Brailey, Jr., New England Power Service Co M Brown, Ontario Hydro W A Campbell, Philadelphia Electric Co K C Cotton, Consultant J S Davis, Jr., Duke Power Co R D Smith, Alternate to Davis, Duke Power Co N R Deming, Consulting Engineer P A DiNenno, lr., Consultant A V Fajardo, Jr., Utility Power Corp C Cartner, Alternate to Fajardo, Utility Power Corp J.H Karian, The American Society of Mechanical Engineers D L Knighton, Black & Veatch Engineers-Architects C H Kostors, Elliott Co J.5 Larnberson, Dresser Rand T H McCloskey, Electric Power Research Institute S S Sandhu, Westinghouse Electric Corp C B Scharp, Consulting Engineer P Scherba, Public Service Electric & Gas Corp I A McAdarns, Alternate to Scherba, Pubic Service Electric 81 Gas Corp E Sundstrorn, Dow Chemical USA (In addition to the above personnel, the Committee is indebted to Ms E Pitchford of Lower Colorado River this Standard.) Authority andH.S Arnold of Public Service Electric & Cas Corp for their efforts on the early work of V Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled w PERSONNEL OF PERFORMANCE TEST CODE COMMITTEE NO ON STEAMTURBINES j Davis, Jr., Chairman Deming, Vice Chairman W Hays, Secretar'y N R A F Armor R L Bannister R j Biese j A Booth B Bornstein W A Crandall H G Crim, jr Davis, Jr N R Deming G J Gerber W Hays R jorgensen D R Keyser j E Kirkland, Jr W G McLean G H Mittendorf, Jr j W Murdock vi S P Nuspl R P Perkins R W Perry A L Plumley C B Scharp J W Siegmund R E Sommerlad I C Westcott Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled BOARD ON PERFORMANCE TEST CODES Foreword Committee Roster Section 10 11 12 13 Figures 2.1 4.1 (a) 4.1 (b) 4.1 (c) 4.2 4.3 4(a) 4.4(b) 4.5 5.1 5.2 5.3 introduction Object Scope and Intent Definitions and Description ot Terms Guiding Principles Instruments and Methods of Measurement Preliminary Test Presentation and Interpretation of TestResults Test for Nonextraction Condensing Turbine With Superheated Inlet Steam Test for Condensing Turbine Regenerative Cycle With Superheated Inlet Steam Test for Condensing Turbine Reheat Regenerative Cycle With Superheated Inlet Steam Test Tor Condensing Turbine Regenerative Cycle With Saturated Inlet Steam Test tor Noncondensing Nonextraction Turbine w i t h Superheated Exhaust Test torNoncondensing Extraction Turbine Special Procedures for Indicating Turbine-Cycle Performance Trends Temperature-Entropy Diagrams Welded Primary Flow Measurement Section Inspection Port for Feedwater FlowNozzle Flanged Primary Flow Measurement Section Alternate Locations for Primary Flow Element Connection Between Calibrated Flow Sections and Manometers BasketTip Guideplate Moisture-Sampling Tube Typical Turbine Valve-Position Test Data Based on Individual SteamPressure Measurements Typical Turbine Valve-Position Test Data Based on Individual Valve-Lift Measurements Stage Group Efficiency by Enthalpy-Drop Method vii iii v 11 17 31 35 53 59 65 87 95 103 115 19 19 20 21 24 27 27 29 32 33 34 Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled w CONTENTS 6.3 6.4 6.5 6.6 6.7 6.8 6.9 6.10 6.1 6.12 6.1 6.14 6.1 6.16 7.1 7.2 8.1 9.1 9.2 9.3 9.4 9.5 9.6 9.7 9.8 10.1 11.1 12.1 13.1 Tables 4.1 8.1 9.1 9.2 9.3 9.4 10.1 11.1 11.2 TypicalBlading Diagram for Single Stage Typical Expansion Lines for a High-pressure Section PartialArc Admission Condensing Turbine Typical Expansion Lines for a High-pressure Section Full-Arc Admission CondensingTurbine Condensing Turbine Last-Stage Steam Flow Versus Stage Pressure Ratio Pressure-Flow Relationship Steam Flow VersusFirst-Stage Nozzle Area Stage Pressure Versus Stage Exit Pressure for Intermediate Stages Pressure or Capability Curve Versus Chronological TestDates Corrected Pressure Deviation Interpretations at Constant Control Valve Opening StagePressureVersus Throttle Steam Flow Single-Stage Efficiency Versus Wheel Speed Partial-Arc Admission Unit Full-ArcAdmission Unit Low-Pressure Turbine Section Efficiency Versus Exhaust Steam Flow or Velocity Illustration of Low-Pressure Turbine Effectiveness Relationships of vdr v, and vtr Instrument Locations Generator Electrical Losses Instrumentation for Routine Performance Tests for Condensing Turbine Regenerative Cycle Superheated Inlet Steam Instrument Locations Loss FactorVersusCrossoverPressure Throttle Pressure Correction Factors Throttle Temperature Correction Factors Reheat Temperature Correction Factors Reheater Pressure-Drop Correction Factors ExhaustPressure Correction Factors Heat RateVersusLoad Instrumentation for Routine Performance Tests for Condensing Turbine Regenerative Cycle With Saturated Inlet Steam Instrument Locations for Noncondensing Nonextraction Turbines Typical Diagram - Noncondensing Extraction Turbine Instrument Locations 36 37 37 38 38 40 40 41 43 44 45 45 46 46 47 52 54 58 60 67 69 77 78 79 80 81 82 88 97 108 117 Location of Primary Water Flow-Measuring Ellement (Fig 4.2) 22 Repeatability of Test Results 64 83 Instrument Uncertainties 84 Load-Correction-Factor Uncertainties 84 Typical Enthalpy-DropUncertainty Values Approximate Repeatability Levels for Reheat-Regenerative Turbines Enthalpy-Drop-Efficiency Tests 85 Summary 93 100 Instrument Uncertainty Flow Correction Factor Uncertainty 100 viii Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled 6.1 6.2, 12.4 13.1 13.2 SteamRate Uncertainty Combined CapabilityUncertainty Repeatability Calculations for Enthalpy-Drop Efficiency Repeatability Calculations for Capability Test Repeatability Calculations for Steam-Rate Test No Extraction Repeatability Calculations for Steam-Rate Test With Extraction : , Power Measurement Instrument Uncertainties Heat Rate Correction Uncertainties , Appendices Cycle A Correction B References Figures A1 A2 A3 A4 A5 A6 A7 A8 A9 A1 A1 A1 Table A- Curves 101 101 104 105 106 107 119 119 121 133 Typical Fossil-Fuel Fired Cycle 123 124 Final FeedwaterTemperature Corrections 125 Auxiliary Extraction Corrections Corrections for Auxiliary Extraction from Cold Heat 126 Corrections for Main Steam and Reheat Steam Desuperheating Flow 127 128 Condensate Subcooling Corrections Condenser Make-up Corrections 128 Typical Light-Water ModeratedNuclearCycle Final Feedwater Temperature Corrections (LWM NuclearCycle) Feed Pump Turbine Extraction Correction (LWM Nuclear Cycle) Condensate SubcoolingCorrection (LWM Nuclear Cycle) Condenser Make-up Correction (LW.M Nuclear Cycle) Equations for Use of Curves for Specified Cycle Corrections Complete Listing of ASME Performance Test Codes ix 129 130 131 131 132 122 135 Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled w 11.3 1.4 12.1 12.2 12.3 FIG A1 TYPICAL FOSSIL FUEL FIRED CYCLE Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled - - - - LL LL m - - TEST VVJO THROTTLE FLOW, X FIG A2FINAL FEEDWATERTEMPERATURE CORRECTIONS Due to top heater terminal difference or extraction pipe pressure drop (different from specified heat balance) Apply curves at constant control valve opening Refer to Table A-1 for correction calculation 124 Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled PROCEDURES FOR ROUTINE PERFORMANCE TESTS OF STEAM TURBINES ASME PTC 6s REPORT-1988 50 ASME PTC 6s REPORT-1988 150 100 EXTRACTION STAGE PRESSURE, psia FIG A3AUXILIARYEXTRACTIONCORRECTIONS (Extraction After Reheater) Auxiliary extraction returns to condenser % auxiliary extraction is % of throtile flow The correction applies to both load and heat rate Refer to Table A-1 for correction calculation 125 200 250 Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled PROCEDURES FOR ROUTINE PERFORMANCE TESTS OF STEAM TURBINES ASME PTC s REPORT-1 988 75 50 A 100 TEST VWO THROTTLE FLOW, % FIG A4 CORRECTIONS FOR AUXILIARY EXTRACTION FROM COLD Auxlllary extractlon returns to condenser % auxlllary extractlon IS % of throttle flow Refer to Table A-1 for correction calculation 126 HEAT Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled w PROCEDURES FOR ROUTINE PERFORMANCE TESTS OF STEAM TURBINES ASME PTC 6s REPORT-1988 a +I LOAD CORR REHEAT STEAM DESUPERHEAT ' - - - LOAD CORR MAIN STEAM DESUPERHEAT 50 75 100 TEST VWO THROTTLE FLOW, % FIG A5 CORRECTIONS FOR M A I N STEAM A N D REHEATSTEAM DESUPERHEATINC FLOW % desuperheating flow is % of throttle flow Desuperheatingflow supply is from feedwater pump Apply corrections at constant main steam and reheat temperatures Refer to Table A-1 for correction calculation 127 Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled PROCEDURES FOR ROUTINE PERFORMANCE TESTS OF STEAM TURBINES 75 100 TEST VWO THROTTLE FLOW, % FIG A6CONDENSATESUBCOOLINGCORRECTIONS Refer to Table A-1 for correction calculation K ae 50 75 TEST VWO THROTTLE FLOW, % FIG A7 CONDENSERMAKE-UPCORRECTIONS Leakage is from main part of steam generator % makeup is % of*throttle flow Refer to Table A-1 for correction calculation 128 100 Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled PROCEDURES FOR ROUTINE PERFORMANCE TESTS OF STEAM TURBINES ASME PTC 6s REPORT-1988 To NSSS \ \ I I \ \ \ Steam No I condenser Gland steam TYPICAL LIGHT-WATER MODERATED NUCLEAR CYCLE No.2 FIG A8 No A Aux turbine Y Condenser Generator b To condenser Feedpump I No Feedwater heater (typical) I Steam reheater No HP turbine r *' \ Moisture reheater separator Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled a W TEST VWO THROTTLE FLOW, % FIG A9FINAL FEEDWATERTEMPERATURE CORRECTIONS (LWM NUCLEAR CYCLE) Due to top heater terminal difference or extraction pipe pressure drop (different from specified heat balance) Apply curves at constant control valve opening For constant thermal power, use values from heat rate curves to obtain load corrections Refer to Table A-1 for correction calculation 130 Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled PROCEDURES FOR ROUTINE PERFORMANCE TESTS OF STEAM TURBINES ASME PTC 6s REPORT-1988 ASME PTC 6s REPORT-1 988 100 75 TEST VWO THROTTLE FLOW, % FIG A10 FEED PUMP TURBINE EXTRACTION CORRECTION (EXTRACTION AFTERREHEATER) (LWM NUCLEAR CYCLE) Auxiliary extraction returns t o condenser % auxiliary extraction is % of throttle flow Refer t o Table A-1 for correction calculation '1 50 I FIG.A1 I 1 75 I I I TEST VWO THROTTLE FLOW, % CONDENSATE SUBCOOLINGCORRECTION (LWM NUCLEAR CYCLE) Refer t o Table A-1 for correction calculation 131 I 100 Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled PROCEDURES FOR ROUTINE PERFORMANCE TESTS OF STEAM TURBINES I I 75 TEST VWO THROTTLE FLOW, % FIG A12 C O N D E N S E R MAKE-UP C O R R E C T I O N (LWM NUCLEAR CYCLE) Leakage i s from main part of steam generator % makeup is % of throttle flow Refer to Table A-1 for correction calculation 132 I 100 Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled PROCEDURES FOR ROUTINE PERFORMANCE TESTS OF STEAM TURBINES ASME PTC 6s REPORT-1988 ASME PTC s REPORT-1988 APPENDIX B REFERENCES ASME Performance Test Code - Steam Turbines, PTC 6-1976 (R1985) ASME Performance Test Code - Interim Test Code For an Alternative Procedure For Testing Steam Turbines, PTC 6.1-1 984 ASME Performance Test Code - Appendix to Code for Steam Turbines, PTC 6A-1982 (R1988) ASME Performance Test Code - Code on Definitions and Values, PTC 2-1980 (R1985) ASME Performance Test Code - Steam Generating Units, PTC 4.1-1964 (R1985) ASME Performance Test Code Supplement - Measurement of Shaft Horsepower, PTC 19.7-1980 ASME Performance Test Code Supplement - Fluid Meters, Part II ASME Performance Test Code Supplement - Pressure Measurement, PTC 19.2-1 987 ASME Performance Test Code Supplement - Quality and Purity of Steam, PTC 19.11-1970 (R1983) ASME Performance Test Code Supplement - Measurement of Rotary Speed, PTC 19.1 3-1961 ASME Performance Test Code Supplement - Electrical Measurement in Power Circuits, PTC 19.6-1955 ASME Performance Test Code Supplement - Temperature Measurement, PTC 19.3-1974 (R1985) ASME Performance Test Code Report - Guidance For Evaluation of Measurement Uncertainty in Performance Tests of Steam Turbines, PTC Report-1985 ASME Steam Tables - Thermodynamics and Transport Properties of Steam, ASME-1 967 ASME Standard - Measurement of Fluid Flow in Pipes Using Orifice, Nozzle, and Venturi, MFC-3M-1985 Bornstein, B., Cotton, K C., “Guidance ForSteam OCT 1982 Turbine Generator Acceptance Tests,” 82-JPGC-PTC 3, Cotton, K.C., Wescott, C., “Methods For Measuring Steam Turbine Generator Performance,” 60-WA-139, NOV 1960 133 Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled PROCEDURES FOR ROUTINE PERFORMANCE TESTS OF STEAM TURBINES PTC PTC - General Instructions .- ., , .1986 - Definitions and Values .1980 (R1985) PTC3.3 1958 (R1985) - Solid Fuels I954 (R1984) - Gaseous Fuels I969 PTC 4.1 - Steam-Generating Units (With 1968 and PTC 3.1 PTC 3.2 PTC 4.1 a PTC 4.1 b PTC 4.2 PTC 4.3 PTC 4.4 PTC PTC PTC 6A PTC Report PTC 6s Report PTC6.1 PTC PTC7.1 PTC 8.2 - Diesel and Burner Fuels 1969 Addenda) (R1985) 1964 Diagram for Testing of a Steam Generator, Fig (Pad of 100) Heat Balance of a Steam Generator, Fig (Pad of 100) - ASME Test Form for Abbreviated Efficiency Test Summary Sheet (Padof 100) (R1985) ., 1964 Calculation Sheet (Pad of 100) : .1964 - Coal Pulverizers 1969 (R1985) - Air Heaters 1968 (R1985) - Gas Turbine Heat Recovery Steam Generators 1981 (R1987) - Reciprocating Steam Engines 1949 - Steam Turbines 1976 - ASME Test for Abbreviated Efficiency Test (R1982) - Appendix A to Test Code for Steam Turbines (With 1958Addenda) , I982 - Guidance for Evaluation of Measurement Uncertainty ,1985 of Steam Turbines , 1988 - Interim Test Code for an Alternative Procedure for Testing Steam Turbines 1984 PTC on Steam Turbines - Interpretations 1977- 1983 - Reciprocating Steam-DrivenDisplacement Pumps 1949 (R1969) - Displacement Pumps , .1962 (R1969) - Centrifugal Pumps (Including 1973 Addendum) 1965 in Performance Tests of Steam Turbines - Procedures for Routine Performance Tests 135 , Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled COMPLETE LISTING OF ASME PERFORMANCE TEST CODES Displacement Compressors Vacuum Pumps and PTC 10 Compressors and Exhausters PTC 11 PTC 12.1 Fans Closed Feedwater Heaters PTC 12.2 PTC 12.3 - PTC 14 - PTC 16 Blowers (With 1972 Errata) - Cas Producers and Continuous Gas Generators EvaporatingApparatus PTC 19.1 PTC 19.2 PTC 19.3 PTC 19.5 - Application, Part II of Fluid Meters: Interim Supplement PTC 18 PTC 18.1 PTC 19.5.1 PTC 19.6 PTC 19.7 PTC 19 1965 (R1986) 1984 1978 (R1987) 1983 1977 (R1984) 1970 (R1985) 1958 (R1985) 1973 (R1985) 1949 1978 (R1984) 1985 1987 1974 (R1986) Steam-Condensing Apparatus Deaerators - Hydraulic Prime Movers - Pumping Mode of Pump/Turbines - Measurement Uncertainty - Pressure Measurement - Temperature Measurement PTC 1970 (R1985) - Reciprocating Internal-Combustion Engines - Electrical Measurements in Power Circuits - Measurement of Shaft Power on Instruments and Apparatus - Weighing Scales PTC 19.10 - Flue and Exhaust Gas Analyses PTc19.11 - Water and Steam in the Power Cycle (Purity and Quality, Lead Detection and Measurement) PTC 19.12 - Measurement of Time PTC 19.13 - Measurement of Rotary Speed PTC19.14 - LinearMeasurements PTC 19.1 - Density Determinations of Solids and Liquids PTC 19.1 - Determination of the Viscosity of Liquids PTC 19.22 - Digital Systems Techniques - Measurement of Indicated Horsepower PTC 19.23 - Guidance Manual for Model Testing PTC 20.1 - Speed and Load Governing Systems for Steam PTC 20.2 - Overspeed Trip Systems for Steam Turbine-Generator PTC 20.3 - Pressure Control Systems Used on Steam Turbine-Generator Units Units TurbineGenerator Units 136 1972 1964 1955 1980 1970 (R1985) 1981 1970 1958 1961 1958 1965 1965 1986 1980 (R1985) 1977 (R1988) 1965 (R1986) 1970 (R1979) Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled PTC PTC 29 - Speed Governing Systems for Hydraulic PTC 25.3 PTC 26 - Dust Separating Apparatus - Gas Turbine Power Plants (R1985) PTC 32.1 .I965 (R1985) - Ion Exchange Equipment I973 (RI 985) - Nuclear Steam Supply Systems ., I969 PTC 32.2 - Methods of Measuring the Performance of Nuclear PTC 33 - Large Incinerators PTC 33a - Appendix to PTC 33-1978 - ASME Form for PTC 31 PTC 36 PTC 38 PTC 39.1 PTC 42 Turbine-Generator Units (R1985) .I979 (R1986) I978 Reactor Fuel in Light Water Reactors Abbreviated Incinerator Efficiency Test (Form PTC 33a-1980) (R1985) I980 (R1987) - Measurement of Industrial Sound 1985 - Determining the Concentration of Particulate Matter in a Gas Stream I980 (R1985) - Condensate Removal Devicesfor Steam Systems 1980 (R1985) - Wind Turbines 1988 The Philosophy of Power Test Codes and Their Development 137 Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled PTC 28 .1941 , , , 1985 - Atmospheric Water Cooling Equipment .1986 - Spray Cooling Systems .I983 - Ejectors , , 1976 (R1982) - Safety and Relief Valves ., I988 - Speed-Governing Systems for Internal Combustion Engine-Generator Units I962 - Determining the Properties of Fine ParticulateMatter 1965 PTC 21 PTC 22 PTC 23 PTC 23.1 PTC 24 Copyrighted material licensed to Stanford University by Thomson Scientific (www.techstreet.com), downloaded on Oct-05-2010 by Stanford University User No further reproduction or distribution is permitted Uncontrolled when