REAFFIRMED 2004 `,,,`,,-`-`,,`,,`,`,,` - FOR CURRENT COMMITTEE PERSONNEL PLEASE E-MAIL CS@asme.org Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale ASME PTC 12.4-1 992 I TH AE M E R I C AS N OCIETY United Engineering Center Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS OF MECHANICA EL NGINEERS 345 East 47th Street Not for Resale New York, N.Y 10017 `,,,`,,-`-`,,`,,`,`,,` - AN AMERICAN NATIONAL STANDARD `,,,`,,-`-`,,`,,`,`,,` - Date of Issuance: May 24, 9 This Standard will be revised when the Society approves the issuance of a new edition There will be no addenda or written interpretations of the requirements of this Standard issued to this edition ASME is the registered trademark of The American Society of Mechanical Engineers This code or standard w a s developed under procedures accredited as meeting the criteria for American National Standards The Consensus Committee that approved the code or standard was balance t o assure that individuals from competent and concerned interests have had an opportunity t o participate The proposed code or standard was made available for public review and comment which provides an opportunity for additional public input from industry, academia, regulatory agencies, and the public-at-large ASME does not "approve," "rate," or "endorse" any item, construction, 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 the determination of the validity of any such patent rights, and the risk of the infringement of such rights, is entirely their o w n responsibility Participation by federal agency representative(s1 or person(s) affiliated with industry is not t o 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 written permission of the publisher Copyright 9 b y THE AMERICAN SOCIETY OF MECHANICAL ENGINEERS All Rights Reserved Printed in U.S.A Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale FOREWORD (This Foreword is not part of ASME PTC 12.4-1992.) Moisture Separator Reheaters (MSRs) were introduced to steam power cycles after the advent of commercial nuclear power A moisture separator, with no reheat was first added to nuclear power cycles to minimize the low pressure (LP) turbine erosion caused by wet steam prevalent in those cycles and improve turbinecycle performance Steam reheat was added later to reduce further the quantity of moisture in the steam passing through the LP turbine and to increase further the efficiency of the LP turbine The first M S R s were susceptible to many modes of failure Great technological advances have occurred over the past 30 years with respect to M S R design and operation These advances increased the reliability and enhanced the performance of the MSR which provided the momentum and justification for M S R upgrades During the 1970s and early 1980s an increasing number of utilities were involved in MSR upgrades which included replacing portions of or their entireMSRs The ASME Board on Performance Test Code was notified in June 1984 that no code existed for the testing and analysis of MSRs PTC-6 (1982) on steam turbines treated the M S R as an integral part of a turbine generator, which it is when purchased as a package The Board authorized the formation of a new performance test code committee to develop a code for the treatment of the MSR as a separate component A new committee was formed and first met in December 1985 Numerous drafts were developed over the next years, each more detailed than the previous Upon the completion of appendices containing a set of sample calculations and a complete uncertainty analysis, the draft was released for the industry review in July of 1990 The comment resolution process, completed in April 1991, strengthened the document The committee was balloted and approved the code draft in July 1991 The Board on Performance Test Codes approved the code in January 1992 This test code has been approved as an American National Standard by the ANSI Board of Standards Review on November 24, 1992 `,,,`,,-`-`,,`,,`,`,,` - Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale PERSONNEL OFP,ERFORMANCE TESTCODECOMMITTEE ONMOISTURE SEPARATOR REHEATERS No 12.4 (The following is the roster of the Committee at the time of approval of this Standard.) OFFICERS Samuel J Korellis, Chairman W Cary Campbell, Vice Chairman Geraldine A Omura, Secretary COMMITTEE PERSONNEL `,,,`,,-`-`,,`,,`,`,,` - Paul G Albert, General Electric Co George L Amodeo, Virginia Power Peter Von Bockh, lngenierschule Beider Basel W Cary Campbell, Southern Company Services H Gay Hargrove, Westinghouse Electric Corp Edwin W Hewitt, Condenser & MSR Consultants Walter A Hill, ENTERGY Samuel J Korellis, Illinois Power Terrance M Lafferty, Tennessee Valley Authority Sherrill Stone, Peerless Manufacturing Co George T Wood, Florida Power & Light Abraham L Yarden, Senior Engineering In addition to the above personnel, the Committee is deeply indebted to Mr Peter Bird, Mr AI Smith, Mr Clement Tam, and Mr Richard Harwood for their contributions in the development of this Code V Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale PERSONNEL OF BOARD ON PERFORMANCE TESTCODES OFFICERS N.R Deming, Chairman D.R Keyser, Vice Chairman W.O Hays Secretary COMMITTEE PERSONNEL A.F Armor W.G McLean R.L Bannister G.H Mittendorf, Jr R.J Biese J.W Murdock J.A Booth S.P Nuspl B Bornstein R.P Perkins H.G Crim, Jr R.W Perry J.S Davis, Jr A.L Plumley N.R Deming C.B Scharp G.J Gerber J.W Siegmund P.M Gerhart R.E Sommerlad R Jorgensen J.W Umstead, IV D.R Keyser J.C Westcott `,,,`,,-`-`,,`,,`,`,,` - Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS vi Not for Resale CONTENTS Object and Scope 1.1 Object 1.2 Scope 1.3 Expected Measurement Uncertainty Definitions and Description of Terms 2.1 Nomenclature 2.2 Definitions Guiding Principles 3.1 Preparation for the Test Introduction 3.2 3.3 3.4 General Test Requirements Test OperatingConditions Test Techniques Instrumentation and Methods of Measurement General Considerations Measurement of Pressure Measurement of Differential Pressure Measurement of Temperature Measurement of Steam Quality Flow Rate Determinations Measurement of Water Levels 4.1 4.2 4.3 4.4 4.5 4.6 4.7 Ill V 3 3 5 7 8 13 13 13 14 15 16 16 24 Computation of Results 5.1 M S R Performance Computation 5.2 Component Pressure Drop 5.3 Terminal Temperature Difference 5.4 Moisture Separator Outlet Quality 5.5 Reference Values 5.6 Sensitivity of Deviation from the Reference Value Test Report 6.1 Introduction 29 29 Appendices A Sample Calculation B Measurement.Uncertainty Calculations .: 33 53 vii Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale 25 25 25 25 26 28 28 `,,,`,,-`-`,,`,,`,`,,` - Foreword CommitteeRoster Figures 3.1 Typical Test Point Locations , 4.1 Water Leg Determination , 4.2 Injection andSamplingPointLocations - MSR Two-Pass Arrangement 4.3 Injection and SamplingPointLocations - MSR Four-Pass Arrangement 4.4 Typical Installation of Injection and Sampling Points 4.5 Oxygen Content of Sample 5.1 Moisture SeparatorReheater - Typical Data Point Locations ~ 11 14 20 21 22 23 27 Tables 3.1 Permissible Deviation of Variables : 5.1 MSR Performance Computations `,,,`,,-`-`,,`,,`,`,,` - Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Vlll Not for Resale 28 `,,,`,,-`-`,,`,,`,`,,` - ASME PTC 12.4-1992 ASME PERFORMANCE TEST CODES Code on MOISTURE SEPARATORREHEATERS SECTION - INTRODUCTION 0.1 dure can be employed to combine the effects of the performanceofthe individual MSR components Therefore,thetestresults will describetheperformance of either individual MSR components or the entire MSR A Moisture Separator Reheater (MSR) is a nuclear power plant component located between the high and low pressure turbines Its purpose is to remove moisture and add superheat to the cycle steam before the steamentersthe low pressure turbine It consumes throttle steam, and may also consume high pressure extraction steam in the heating process The MSR introduces an additional pressure drop in the turbine expansion while accomplishing these functions The use of a properly designed and adequatelyperforming MSR will result in a cycle heat rate improvement 0.3 PTC 1-1991,theCode on GeneralInstructions, should be studied thoroughly before formulating the procedures for testing an MSR The Code on Definitions and Values, PTC 2-1980 (R19851, defines technical terms and numerical constants which are used throughout this Code Unless otherwise specified, instrumentationshould comply with theappropriate supplements of the PTC 19 Series of codes on InstrumentsandApparatus.PTC6-1976,SteamTurbines, should be consulted for isolation and verification methods 0.2 One of the purposes of this test Code i s to consider theseparate functions of moistureseparationand either one or two stages of steam reheat This proce- Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale MOISTURE SEPARATORREHEATERS SECTION ASME PTC 12.4-1992 OBJECT AND SCOPE 1.1 OBJECT (c) Instrumentation applications and methods of measurement; (d) Testing and calculational techniques; and (e) Information contained in the test report This Code provides the procedures, direction, and guidance for the accurate testing of Moisture Separator Reheaters (MSRs) which includes moisture separating and steam reheating components located between the high pressure and low pressure steam turbine The purpose of the Code is to determine the performance of the MSR and to provide guidance in the evaluation of its performance effect on the turbine cycle heat rate with regard to: (a) Moisture Separator Outlet Quality; (b) Reheater Terminal Temperature Difference (TTD) per stage; (c) Cycle Steam pressure drop across applicable component(s); and (d) Excess heating steam flow 1.3 EXPECTED MEASUREMENT UNCERTAINTY By satisfying the instrument accuracy criteria specified in Section and complying with the balance of procedural requirements of this Code, a test will generally provide 95 percent or greater confidence that the measurement of the required performance parameters will yield results for which the bounds of the difference between the final test results and the true value is within &- 10.0 Btu/kW-hr Utilizing techniques specified in PTC 19.1, Measurement Uncertainty, the overall measurement un- certainty i s based on the prescribed instrument accuracies and exampleprecision indices for M S R testing An outline of the calculations conducted to establish the expected overall measurement uncertainty value, noted above, is covered in Appendix B Users of this Code should determine the quality of a Code test by performinga post test uncertainty analysis utilizing PTC 19.1 1.2 SCOPE Requirements are specified by this Code for application on M S R testing in the following areas: (a) Pretest arrangements and agreements; (b) Instrumentation types and accuracies; `,,,`,,-`-`,,`,,`,`,,` - Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale ASME PTC 12.4-1992 MOISTURE SEPARATOR REHEATERS 6.0 6.5 7.0 7.5 8.0 8.5 9.0 9.5 MSR Shell Press Drop (%I GENERAL NOTE: This figure is for illustrative purposes only Specific unit information shouldbe developed FIG A.5 SENSITIVITY TO SHELL PRESSURE,DROP 47 `,,,`,,-`-`,,`,,`,`,,` - Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale 10.0 10.5 11.0 ASME PTC 12.4-1992 GENERAL NOTE: This figure is for illustrative purposes only Specific unit information should be developed FIG A.6 SENSITIVITY TO LP REHEATER TTD 48 Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale `,,,`,,-`-`,,`,,`,`,,` - MOISTURESEPARATORREHEATERS ASME PTC 12.4-1992 MOISTURESEPARATORREHEATERS 0.30 0.25 0.20 0.15 4- m a I m c _ 0.10 m E 0.05 x V 0.00 -0.05 -0 _ 10 _ 20 25 30 55 35 5040 HP Reheater TTD 45 (OF) GENERAL NOTE: This figure isfor illustrative purposes only Specific unit information should be developed FIG A.7 SENSITIVITY TO HP REHEATER TTD 49 Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS `,,,`,,-`-`,,`,,`,`,,` - Not for Resale MOISTURE SEPARATOR REHEATERS `,,,`,,-`-`,,`,,`,`,,` - ASME PTC 12.4-1992 a! m Y [r * a! I c _ a! m c m r V 94.0 94.5 95.0 95.5 96.0 96.5 97.0 97.5 98.0 98.5 99.0 99.5 100.0 M S Outlet Quality (%) GENERAL NOTE: This figure is for illustrative purposes only Specific unit information should be developed FIG A.8 SENSITIVITY T O MS OUTLET QUALITY I :I 'i 50 Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale ASME PTC 12.4-1992 MOISTURE SEPARATOR REHEATERS 0.30 0.25 0.20 0.00 -0.05 -0.10 Excess Steam Flow (% of HS) GENERAL NOTE: This figure is for illustrative purposesonly Specific unit information shouldbe developed FIG A.9 SENSITIVITY T O LP REHEATEREXCESS STEAM FLOW 51 `,,,`,,-`-`,,`,,`,`,,` - Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale 10 MOISTURE SEPARATOR REHEATERS ASME PTC 12.4-1992 0.30 `,,,`,,-`-`,,`,,`,`,,` - 0.25 0.20 I 0.15 a =m 4- Y m a I -ac Is) 0.10 0.06 c m x u 0.00 -0.05 -0.lG a Excess Steam Flow (% of HS) GENERAL NOTE: This figure is for illustrative purposes only Specific unit information shouldbe developed FIG A.10 SENSITIVITY T O H PREHEATEREXCESS STEAM FLOW 52 Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale 10 ASME PTC 12.4-1992 MOISTURE SEPARATOR REHEATERS - MEASUREMENT CALCULATIONS UNCERTAINTY `,,,`,,-`-`,,`,,`,`,,` - APPENDIX 53 Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale MOISTURESEPARATOR ASMEPTC REHEATERS 12.4-1992 TABLE B.l TTD (HP) Test Measurement Cycle Steam Temp Outlet Heating HP Press Steam Effect on TTD Actual Measurement Bias Uncertainty of Test Precision TTD (Bias) l.OO°F/oF f 1°F 1.OOo F f 0.35OF 0.35OoF 1.21°F/% + 0.25% 0.303OF + 0.44% 0.532OF Square Root 0.637OF Sum of the Squares Total Uncertainty Actual Measurement Uncertainty of Test TTD 1.04OF 1.22OF TABLEB.2 CYCLE STEAM FLOW MEASUREMENT UNCERTAINTY Measurement Error Measured Feedwater Flow HP Heating Steam LP Heating Steam MS Drain Flow Packing Leakages Heater Extraction Enthalpy Heater Extraction Enthalpy Final Feedwater Enthalpy -0.32% Enthalpy of Heater Feedwater In Enthalpy of Heater Feedwater Out Enthalpy of Heater Feedwater In Enthalpy of Heater Drain Enthalpy of Heater Drain 1% 5% 5% 10% 10% 20 Btu 40 Btu Btu2 Btu Btu Btu Btu Btu Btu Sensitivity 16% per -0.22% per -0.12% per -0.95% per -0.03% per 0.05% per 0.06% per per -0.32% 0.32% per -0.24% per 0.24% per 0.00% per -0.09% per Total Uncertainty (RMS) 5% 10% 10% Btu Btu 1.1 % -0.22% -0.1 2% -0.95% -0.03% 0.20% 0.48% Btu Btu Btu Btu Btu 0.32% -0.24% 0.24% 0.00% -0.09% 1% 5% 55 `,,,`,,-`-`,,`,,`,`,,` - Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Uncertainty in Cycle Steam Flow Not for Resale % ASME PTC 12.4-1992 MOISTURE SEPARATOR REHEATERS TABLE B.3 TTD (LP) Test Measurement Effd on TTD Actual Measurement Bias Uncertainty of Test TTD (Bias), "F Actual Measurement Precision Uncertainty of Test TTD Precision, Cycle Steam Out Temperature 0.92"FPF 1°F 0.92 0.354'F 0.326 Cycle Steam Out Pressure 0.40°F/% f 0.25% 0.10 0.44% 0.176 Cycle Steam Flow 0.70°F/% f2.0% 1.40 0.032% 0.022 HP Heating Steam Flow 0.68"F/% f5.0% 3.40 f0.288% 0.196 HP Heating Steam Pressure 0.1 8'F/% f0.25% 0.045 0.44% 0.079 HP Heating Steam Quality 0.86"Fl% k0.2596 0.215 NfA HP Drain Temperature 0.10"FPF 1°F 0.10 kO.525"F 0.053 HP Excess Steam Flow O.O2"F/% 10% 0.20 10.632% 0.01 LP Heating Steam Pressure 0.99'F/96 "0.25% 0.248 f0.288% 0.285 Square Root Sum of the Squares 3.81 Total Uncertainty 56 Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS 0.52 3.85"F `,,,`,,-`-`,,`,,`,`,,` - Not for Resale - OF ASMEPTC MOISTURESEPARATORREHEATERS 12.4-1992 TABLE B.4 MOISTURE SEPARATOR OUTLET QUALITY (XMSO) XMSO Test Measurement Effect XMSO on Actual Measurement Bias Uncertainty of Test XMSO (Bias), OIO Actual Measurement (Precision), Precision Uncertainty of Test Oh Cycle Steam Out Temperature 0.0655%1°F f l0F 0.0655 fO.354OF 0.0232 Cycle Steam Out Pressure 0.0249%1% +- 0.25% 0.0062 f 0.40% 0.01 00 Cycle Steam Flow 0.1066%1% f 2.0% 0.21 32 f 0.032% 0.0034 HP Heating Steam Flow 0.0497%/% f 5.0% 0.2485 f 0.288% 0.01 43 HP Heating Steam Pressure 0.01 3%1% f 0.25% 0.0033 f 0.44% 0.0057 HP Heating Steam Quality 0.061 %I% f 0.25% 0.01 53 NIA HP Drain Temperature 0,0101 %I"F f1"F 0.0101 *0.525%°F 0.0053 HP Excess Steam Flow 0.001 2%/% & 10% 0.01 20 f0.632'10 0.0008 LP Heating Steam Flow 0.0485%1% f 5% 0.2425 f 0.2aa% 0.0140 LP Heating Steam Pressure 0.0006%1% f 0.25% 0.0002 f 0.44% 0.0003 LP Heating Steam Quality 0.0452%1% f 1.5 % 0.0678 NIA LP Drain Temperature 0.0071 %I"F f 1oF 0.0071 fO.525OF 0.0037 LPExcess Steam Flow 0.0008%/% f 10% o.ooao f 0.632% 0.0005 - 0.03 0.42 Square Root Sum of the Squares 0.42% `,,,`,,-`-`,,`,,`,`,,` - Total Uncertainty 57 Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale ASMEPTC MOISTURE SEPARATORREHEATERS 12.4DE-1992 TABLE B.5 EXCESS STEAM FLOW Uncertainty of Uncertainty Test ES Flow (Bias), (%) Measurement Treat of Test ES Flow (Precision), (%) & 10.0 ExcessSteam Flow f0.6 10.0% Total Uncertainty TABLEB.6 MSR SHELL PRESSURE DROP Test Measurement Uncertainty of Test Pressure Drop (Bias), (PSID) Uncertainty of Test Pressure Drop (Precision), (PSID) ExcessSteam Flow f0.02 k0.12 Total Uncertainty 0.122 psid TABLE B.7 TOTAL OVERALL TEST UNCERTAINTY Performance Parameter Parameter Effect on Heat Rate Individual Uncertainty Uncertainty of Test Heat Rate, (BtdkW-hr) TTD (HP) f 1.22 O F 1.4 BtulkW-hr/"F 1.71 TTD (LP) f3.85 O F 0.4 Btu/kW-hr/"F 1.54 XMSO f0.42 O F 23 Btu/kW-hr/% 9.66 Shell Pressure Drop f0.122 PSID 6.6 Btu/kW-hdpsid 0.81 ES Flow f 10.0% 0.01Btu/kW-hr/% 0.10 9.96 BtdkW-hr Square Root Sum of the Squares or 0.1 O%, Based upon a typical plant heat rate of 10,000 BtdkW-hr GENERAL NOTE: The precision errors were calculated for the test measurements of interest by the formula: tXS Square Root of (N) Where: s = Standard Deviation t = Students t N = Number of Readings 58 `,,,`,,-`-`,,`,,`,`,,` - Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale COMPLETELISTING OF ASMEPERFORMANCETEST CODES PTC PTC PTC 3.1 PTC 3.2 PTC 3.3 PTC 4.1 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 PTC 6.1 PTC PTC 7.1 PTC 8.2 General Instructions , : I 9 Definitions and Values , I (R1985) Diesel and Burner Fuels , $1958 (R1992) Coal and Coke I 9 Gaseous Fuels , 1974 (R1992) Steam-Generating Units (With 1968 and 1969 Addenda) I (R1991) 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 (Pad of 100) I ASME Test for Abbreviated Efficiency Test Calculation Sheet (Pad of 100) I Coal Pulverizers I 9 (R1991) Air Heaters , I (R1991) Gas Turbine Heat Recovery Steam Generators 1981 (R1992) Reciprocating Steam Engines 1949 , , , , , , , , , , , , , , , -1976 Steam Turbines , , , , , (R1991) Appendix A to Test Code for Steam Turbines 1982 (With 1958 Addenda) Guidance for Evaluation of Measurement Uncertainty in Performance Tests of Steam Turbines 1985 (R1991) Procedures for Routine Performance Tests of Steam Turbines I 8 Interim Test Code for an Alternative Procedure for Testing Steam Turbines I PTC on Steam Turbines- Interpretations 1977- 1983 Reciprocating Steam-Driven Displacement Pumps I 9 (R1969) Displacement Pumps I (R1969) Centrifugal Pumps I 9 `,,,`,,-`-`,,`,,`,`,,` - Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale PTC Displacement Compressors Vacuum Pumps and Blowers (With 1972 Errata) -1970 (R1985) Compressors and Exhausters 1965 PTC IO (R1986) Fans 1984 PTC 11 (R1990) - ClosedFeedwaterHeaters 1978 PTC 12.1 (R198 7) PTC 12.2 - Steam-CondensingApparatus 1983 PTC 12.3 - Deaerators 1977 (R1990) - Moisture SeparatorReheaters 1992 PTC 12.4 PTC 14 - Evaporating Apparatus 1970 (R1991) - GasProducers and Continuous Gas Generators 1958 PTC 16 (R1991) PTC 17 Reciprocating Internal-Combustion Engines 1973 (R1991) PTC 18 Hydraulic Turbines 1992 - Pumping Mode of PumpDurbines 1978 PTC 18.1 (R1984) - Measurement Uncertainty 1985 PTC 19.1 - Pressure Measurement 1987 PTC 19.2 Temperature Measurement 1974 PTC 19.3 (R1986) Application Part I1 of Fluid Meters: Interim Supplement PTC 19.5 on Instruments and Apparatus 1972 Weighing Scales 1964 PTC 19.5.1 Electrical Measurements in Power Circuits 1955 PTC 19.6 Measurement of Shaft Power 1980 PTC 19.7 1970 PTC 19 - Measurement of Indicated Horsepower (R1985) Flue and Exhaust Gas Analyses 1981 PTC 19.10 Water and Steam in the Power Cycle (Purity and Quality, PTC 19.1 Lead Detection and Measurement) 1970 Measurement of Time 1958 PTC 19.12 Measurement of Rotary Speed 1961 PTC 19.13 Linear Measurements 1958 PTC 19.14 Density Determinations of Solids and Liquids 1965 PTC 19.16 Determination of the Viscosity of Liquids 1965 PTC 19.1 Digital Systems Techniques 1986 PTC 19.22 Guidance Manual for Model Testing 1980 PTC 19.23 (R1985) Speed and Load Governing Systems for Steam PTC 20.1 Turbine-Generator Units 1977 (R1988) Overspeed Trip Systems for Steam Turbine-Generator PTC 20.2 Units 1965 (R1986) Pressure Control Systems Used on Steam PTC 20.3 Turbine-Generator Units 1970 (R1979) `,,,`,,-`-`,,`,,`,`,,` - Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale `,,,`,,-`-`,,`,,`,`,,` - PTC 21 PTC 22 PTC 23 PTC 23.1 PTC 24 PTC 25.3 PTC 26 PTC 28 PTC 29 PTC 30 PTC 31 PTC 32.1 PTC32.2 PTC 33 ' PTC 33a PTC 36 PTC 38 PTC 39.1 PTC 40 PTC 42 Matter Collection Equipment 1991 Turbine Power Plants 1985 Atmospheric Water Cooling Equipment 1986(R1992) 1983 Spray Cooling Systems -1976 Ejectors (R1982 ) Safety and Relief Valves 1988 Speed-Governing Systems for Internal Combustion Engine-Generator Units 1962 - Determining the Properties of Fine Particulate Matter 1965 (R1985) - Speed Governing Systems for Hydraulic Turbine-Generator Units 1965 (R1985) - Air Cooled Heat Exchangers 1991 - Ion Exchange Equipment 1973 (R1991) - Nuclear Steam Supply Systems 1974 (R1992) - Methods of Measuring the Performance of Nuclear Reactor Fuel in Light Water Reactors 1979 (R1992) - Large Incinerators 1978 (R1991) - Appendix to PTC 33-1978 - ASME Form for Abbreviated Incinerator Efficiency Test (Form PTC 33a-1980) 1980 (R1987) - Measurement of Industrial Sound 1985 - Determining the Concentration of Particulate Matter in a Gas Stream 1980 (R1985) - Condensate Removal Devices for Steam Systems 1980 (R1985) - FlueGas Desulfurization Units 1991 - Wind Turbines 1988 Particulate Gas The Philosophy of Power Test Codes and Their Development Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale `,,,`,,-`-`,,`,,`,`,,` - Copyright ASME International Provided by IHS under license with ASME No reproduction or networking permitted without license from IHS Not for Resale