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本文(ASME MFC-16-2014 Measurement of Liquid Flow in Closed Conduits With Electromagnetic Flowmeters《用电磁流量计在密封管中对液体流量的测量》.pdf)为本站会员(sofeeling205)主动上传,麦多课文库仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对上载内容本身不做任何修改或编辑。 若此文所含内容侵犯了您的版权或隐私,请立即通知麦多课文库(发送邮件至master@mydoc123.com或直接QQ联系客服),我们立即给予删除!

ASME MFC-16-2014 Measurement of Liquid Flow in Closed Conduits With Electromagnetic Flowmeters《用电磁流量计在密封管中对液体流量的测量》.pdf

1、AN AMERICAN NATIONAL STANDARD ASME MFC-162014(Revision of ASME MFC-162007)Measurement of Liquid Flow in Closed Conduits With Electromagnetic FlowmetersASME MFC-162014(Revision of ASME MFC-162007)Measurement ofLiquid Flow in ClosedConduits WithElectromagneticFlowmetersAN AMERICAN NATIONAL STANDARDTwo

2、 Park Avenue New York, NY 10016 USADate of Issuance: March 14, 2014This Standard will be revised when the Society approves the issuance of a new edition.ASME issues written replies to inquiries concerning interpretations of technical aspects ofthis Standard. Interpretations are published on the Comm

3、ittee Web page and undergo.asme.org/InterpsDatabase. Periodically certain actions of the ASME MFC Committee may bepublished as Cases. Cases are published on the ASME Web site under the MFC Committee Page atgo.asme.org/MFCcommittee as they are issued.Errata to codes and standards may be posted on the

4、 ASME Web site under the Committee Pages toprovide corrections to incorrectly published items, or to correct typographical or grammatical errorsin codes and standards. Such errata shall be used on the date posted.The Committee Page can be found at go.asme.org/MFCcommittee. There is an option availab

5、le toautomatically receive an e-mail notification when errata are posted to a particular code or standard.This option can be found on the appropriate Committee Page after selecting “Errata” in the “PublicationInformation” section.ASME is the registered trademark of The American Society of Mechanical

6、 Engineers.This code or standard was developed under procedures accredited as meeting the criteria for American NationalStandards. The Standards Committee that approved the code or standard was balanced to assure that individuals fromcompetent and concerned interests have had an opportunity to parti

7、cipate. The proposed code or standard was madeavailable for public review and comment that 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

8、, or activity.ASME does not take any position with respect to the validity of any patent rights asserted in connection with anyitems mentioned in this document, and does not undertake to insure anyone utilizing a standard against liability forinfringement of any applicable letters patent, nor assume

9、s any such liability. Users of a code or standard are expresslyadvised that determination of the validity of any such patent rights, and the risk of infringement of such rights, isentirely their own responsibility.Participation by federal agency representative(s) or person(s) affiliated with industr

10、y is not to be interpreted asgovernment or industry endorsement of this code or standard.ASME accepts responsibility for only those interpretations of this document issued in accordance with the establishedASME procedures and policies, which precludes the issuance of interpretations by individuals.N

11、o 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.The American Society of Mechanical EngineersTwo Park Avenue, New York, NY 10016-5990Copyright 2014 byTHE AMERICAN SOCIETY OF MECHANICAL ENGINEERS

12、All rights reservedPrinted in U.S.A.CONTENTSForeword ivCommittee Roster . vCorrespondence With the MFC Committee . vi1 Scope 12 References 13 Definitions and Symbols . 14 Theory and Measurement Technique 15 Flowmeter Descriptions 46 Application Considerations . 47 Equipment Markings. 78 Calibration

13、7Figures4-1 Industrial Electromagnetic Flowmeters 24.2-1 Examples of Electromagnetic Field (Bo) Variation With Time . 34.3-1 Examples of Electrodes for an Electromagnetic Flowmeter . 36.4-1 Electromagnetic Flowmeter System . 5Table3.2-1 Symbols . 2Nonmandatory AppendicesA Added Details Regarding The

14、ory and Measurement Technique 9B Liner Material Guidelines 11C Manufacturer-Specified Accuracy . 13D Calculation Examples 15E Bibliography . 16iiiFOREWORDThis Standard was prepared by Subcommittee 16 of the ASME Committee on the Measurementof Liquid Flow in Closed Conduits. The chair of the subcommi

15、ttee is indebted to the manyindividuals who contributed to this document.Electromagnetic flowmeters were introduced to the process industries in the mid 1950s. Theyquickly became accepted flowmeters for difficult applications. Subsequent improvements in tech-nology and reductions in cost have transf

16、ormed these flowmeters into one of the leading contend-ers for general use in water-based and other electrically conducting liquid applications.Due to differences in design of the various electromagnetic flowmeters in the marketplace, thisStandard cannot address detailed performance limitations in s

17、pecific applications. It covers issuesthat are common to all meters, including application considerations.The flow industry has been changing from the use of the names “primary” and “secondary”to “sensor” and “transmitter.” Previous editions of ASME MFC-16 did use primary and secondaryin their figur

18、es and text. This new edition uses the sensor and transmitter terminology.Suggestions for improvement of this Standard will be welcomed. They should be sent to TheAmerican Society of Mechanical Engineers; Attn: Secretary, MFC Standards Committee; Two ParkAvenue; New York, NY 10016-5990.This revision

19、 was approved an an American National Standard on January 28, 2014.ivASME MFC COMMITTEEMeasurement of Fluid Flow in Closed Conduits(The following is the roster of the Committee at the time of approval of this Standard.)STANDARDS COMMITTEE OFFICERSR. J. DeBoom, ChairZ. D. Husain, Vice ChairD. C. Wyat

20、t, Vice ChairC. J. Gomez, SecretarySTANDARDS COMMITTEE PERSONNELC. J. Blechinger, Honorary Member, ConsultantR. M. Bough, Rolls-Royce Corp.M. S. Carter, Flow Systems, Inc.R. J. DeBoom, ConsultantD. Faber, Contributing Member, Badger Meter, Inc.C. J. Gomez, The American Society of Mechanical Engineer

21、sF. D. Goodson, Emerson Process Management DanielZ. D. Husain, Chevron Corp.C. G. Langford, Honorary Member, ConsultantW. M. Mattar, Invensys/Foxboro Co.SUBCOMMITTEE 16 ELECTROMAGNETIC FLOWMETERSR. J. DeBoom, Chair, ConsultantC. A. Diederichs, Emerson Process Management RosemountM. J. Keilty, Endres

22、s + Hauser Flowtec AGM. M. Lloyd, The Dow Chemical Co.W. M. Mattar, Invensys/Foxboro Co.R. W. Miller, Contributing Member, R. W. Miller however, they shouldnot contain proprietary names or information.Requests that are not in this format may be rewritten in the appropriate format by the Committeepri

23、or to being answered, which may inadvertently change the intent of the original request.ASME procedures provide for reconsideration of any interpretation when or if additionalinformation that might affect an interpretation is available. Further, persons aggrieved by aninterpretation may appeal to th

24、e cognizant ASME Committee or Subcommittee. ASME does not“approve,” “certify,” “rate,” or “endorse” any item, construction, proprietary device, or activity.Attending Committee Meetings. The MFC Standards Committee regularly holds meetings thatare open to the public. Persons wishing to attend any mee

25、ting should contact the Secretary ofthe MFC Standards Committee. Future Committee meeting dates and locations can be found onthe Committee Page at go.asme.org/MFCcommittee.viASME MFC-162014MEASUREMENT OF LIQUID FLOW IN CLOSED CONDUITS WITHELECTROMAGNETIC FLOWMETERS1 SCOPEThis Standard is applicable

26、to industrial electromag-netic flowmeters and their application in the measure-ment of liquid flow. The electromagnetic flowmeterscovered by this Standard utilize an alternating electricalcurrent (AC) or pulsed direct-current (pulsed-DC) togenerate a magnetic field in electrically conductive andelec

27、trically homogeneous liquids or slurries flowing ina completely filled, closed conduit.This Standard does not cover the following:insertion-type electromagnetic flowmeterselectromagnetic flowmeters used in surgical, thera-peutic, or other health and medical applicationsapplications of industrial flo

28、wmeters involvingnonconductive liquidshighly conductive liquids (e.g., liquid metals)2 REFERENCESThe following document forms a part of this Standardto the extent specified herein. The latest edition shallapply.ISO 13359, Measurement of conductive liquid flow inclosed conduits Flanged electromagneti

29、cflowmeters Overall lengthPublisher: International Organization forStandardization (ISO) Central Secretariat, 1, ch. de laVoie-Creuse, Case postale 56, CH-1211, Geneve 20,Switzerland/Suisse3 DEFINITIONS AND SYMBOLS3.1 Definitionsaccuracy of measurement: closeness of the agreementbetween the result o

30、f a measurement and a true valueof the measurand.NOTE: Accuracy is a qualitative concept; for the quantitativeconcept, see uncertainty.calibration: the experimental determination of the rela-tionship between the quantity being measured and thedevice that measures it, usually by comparison with astan

31、dard, then (typically) correcting the output of thatdevice to bring it to the desired value, within a specifiedtolerance, for a particular value of the input.1flowmeter sensor: includes the flow tube, process connec-tions, electromagnetic coils, and electrodes. Flowmetersensor is also known by other

32、 names, e.g., flowmetersensor device, sensor device, and sensor.flowmeter transmitter: includes the electronic transmitter,measurement of the emfv, and, in most cases, the powerfor the electromagnet coils of the flowmeter sensor.meterfactor: the number determined by liquid calibrationthat enables th

33、e output flow signal to be related to thevolumetric flow rate under defined reference conditions;often expressed as the reciprocal of mean K-factor.uncertainty (of measurement): parameter, associated withthe result of a measurement, that characterizes the dis-persion of the values that could reasona

34、bly be attributedto the measurand.verification: provision of objective evidence that a givenitem fulfills requirements.EXAMPLE: Use of independent flow calibration to confirm thatperformance properties and/or legal requirements of a measuringsystem are met.3.2 SymbolsSee Table 3.2-1.4 THEORY AND MEA

35、SUREMENT TECHNIQUEIndustrial electromagnetic flowmeters are composedof the following basic components (see Fig. 4-1):(a) a nonmagnetic tube with a nonconductive innersurface(b) a magnetic field passing through the tube andperpendicular to the axis of the tube at the center of theflow tube(c) a minim

36、um of two electrodes on opposite sidesof the tube in a cross-sectional plane passing throughthe center of the flow tube, the straight line betweenthese two electrodes being perpendicular to the mag-netic field at the center of the flow tube4.1 Flow-Related Electromotive ForceFaradays law of inductio

37、n applied to this physicalconfiguration predicts the generation of an electromo-tive force (a voltage) between the electrodes when aASME MFC-162014Table 3.2-1 SymbolsDimensionsQuantity Note (1) SI Units U.S. Customary UnitsC A dimensionless parameter that depends on the specific design of the . . .

38、. . . . . .flowmeter (see section 4)D Inner diameter of the flow tube L m in.K Meter factor, typically determined by liquid flow calibration M1LT2I m3/s/volt ft3/sec/voltV Flow velocity LT1m/s ft/secBoAverage magnetic field between the electrodes MT2I1tesla . . .q Flow rate, volumetric L3T1m3/s ft3/

39、secemf Electromotive force ML2T3I1volt voltemfcElectrochemical electromotive force ML2T3I1volt voltemfvVelocity-related electromotive force ML2T3I1volt voltemftTransformer-related electromotive force ML2T3I1volt voltemfFElectromotive force per Faradays Law ML2T3I1volt voltNOTE:(1) Dimensions: M pmas

40、s, L plength, T ptime, I p current.Fig. 4-1 Industrial Electromagnetic FlowmetersDFlow tube withnonconductivelinerCoilElectrodeCoilVemfvemfvBo2ASME MFC-162014conductive liquid flows through the flow tube. Thiselectromotive force isemfvpCDBoV (4-1)whereBop magnetic field at the center of the flow tub

41、e,teslaC p a dimensionless parameter that depends onthe specific design of the flowmeterD p inner diameter of the flow tube, memfvp electromotive force, VV p flow velocity (average axial liquid velocity ina cross-sectional plane of the flow tube), m/sFor added details on the theory and measurementte

42、chniques related to electromagnetic flowmeters, seeNonmandatory Appendix A.4.2 Interfering Sources of Electromotive ForceIn addition to the above flow-related electromotiveforce, emfv, two other sources of electromotive force existin modern industrial electromagnetic flowmeters thatmay interfere wit

43、h the measurement of emfv. They arethe electrochemical electromotive force, emfc, and thesensor transformer electromotive force, emft. Since bothof these may be similar to or larger than emfvin magni-tude, using an alternating electromagnetic field andinterval sampling techniques avoids interference

44、 to theflow signal, emfv, from these other two sources.Figure 4.2-1 illustrates three basic methods for alternat-ing the electromagnetic field. For additional informationabout both emfcand emft, see NonmandatoryAppendix A.4.3 Types of ElectrodesAn alternating electromagnetic field generates analtern

45、ating emfv. The following types of electrodes areused with an alternating electromagnetic field:(a) wetted electrodes that protrude through the pipewall/liner into the flow stream see Fig. 4.3-1,illustration (a)(b) nonwetted (capacitive) electrodes located behindor within the tube wall/liner see Fig

46、. 4.3-1,illustration (b)4.4 Calculation of Volumetric Flow RateFrom eq. (4-1), the flow velocity is given byVpemfv/CDBoThe volumetric flow rate, q, is calculated byqpH9266D2V/4Combining these two equations,qpH9266D W emfv/4CBo3Fig. 4.2-1 Examples of Electromagnetic Field (Bo)Variation With Time(c) P

47、ulsed DC Field Varied in a Stepwise FashionWith a Duty Cycle Less Than 100%t (b) Pulsed DC Field Varied in a Stepwise FashionWith a Duty Cycle of 100%t (a) AC Field Varied in a Sinusoidal Fashiont Fig. 4.3-1 Examples of Electrodes for anElectromagnetic Flowmeter(a) WettedB(b) NonwettedBBecause the d

48、iameter, D, dimensionless parameter, C,and the magnetic field, Bo, are fixed in each individualmeter, these values can be grouped together in a singlefactor that is determined through calibration. Thus,qpK W emfvwhereK p meter factor, m3/s/VASME MFC-1620145 FLOWMETER DESCRIPTIONS5.1 Flowmeter Sensor

49、The flowmeter sensor must be designed and selectedto be an integral portion of the piping system (seepara. 6.4). It consists of the following:(a) a flow tube with a nonconductive inside surface(b) a means for integrating it into the pipeline(c) electromagnetic field coils(d) two or more sensing electrodes that may be wettedor nonwetted (see Fig. 4.3-1)(e) a housing to protect the coils and electrodes fromdamage and moistureIt may also include grounding electrodes or groundingrings, which are used to ground the process and theflowmeter senso

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