Emerson Micro Motion 9739 MVD Configuration And Use Manual

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Page 1

CongurationandUseManual

P/NMMI-20016855,Rev .AA

June2010

MicroMotion®9739MVDTransmitters CongurationandUseManual

CongurationOperationMaintenance

Page 2

MicroMotioncustomerservice

LocationTelephoneNumber

U.S.A.800-522-MASS(800-522-6277)(tollfree)

CanadaandLatinAmerica+1303-527-5200(U.S.A.)

Japan35769-6803 Asia

Allotherlocations+656777-8211(Singapore)

U.K.08702401978(toll-free) Europe

Allotherlocations+31(0)318495555(TheNetherlands)

CustomersoutsidetheU.S.A.canalsosendanemailtoow.support@emerson.com.

Copyrightsandtrademarks

MicroMotion,ELITE,MVD,ProLink,MVDDirectConnect,andPlantWebaremarksofoneoftheEmersonProcessManagementfamilyof

companies.Allothertrademarksarepropertyoftheirrespectiveowners.

Page 3

Contents

IGettingstarted............................................................................................................1

Chapter1Beforeyoubegin........................................................................................................3

1.1Safetymessages.............................................................................................3

1.2Obtainversioninformation................................................................................3

1.3Availablecommunicationstools........................................................................3

1.4Additionaldocumentationandresources...........................................................4

1.59739MVDtransmittercongurationworksheet..................................................4

Chapter2Quickstartwiththedisplay.......................................................................................19

2.1Applypower..................................................................................................19

2.2Congurationtipsandtricks...........................................................................19

2.3ConguretheprimarymAoutputtoreportmassowrateinauser-selected

measurementunit..........................................................................................20

2.4Performalooptest........................................................................................21

2.5Zerotheowmeter.........................................................................................23

Chapter3QuickstartwithProLinkII.........................................................................................25

3.1Applypower..................................................................................................25

3.2ConnectwithProLinkII..................................................................................25

3.3Congurationtipsandtricks...........................................................................40

3.4ConguretheprimarymAoutputtoreportmassowrateinauser-selected

measurementunit..........................................................................................41

3.5Performalooptest........................................................................................41

3.6TrimmAoutputs............................................................................................43

3.7Zerotheowmeter.........................................................................................43

3.8Testortunethesystemusingsensorsimulation..............................................44

3.9Backuptransmitterconguration....................................................................46

3.10Enable/disableHARTsecurity........................................................................47

Chapter4QuickstartwiththeFieldCommunicator...................................................................49

4.1Applypower..................................................................................................49

4.2ConnectwiththeFieldCommunicator.............................................................49

4.3Congurationtipsandtricks...........................................................................52

4.4ConguretheprimarymAoutputtoreportmassowrateinauser-selected

measurementunit..........................................................................................53

4.5Performalooptest........................................................................................54

4.6TrimmAoutputs............................................................................................55

4.7Zerotheowmeter.........................................................................................55

4.8Testortunethesystemusingsensorsimulation..............................................56

4.9Enable/disableHARTsecurity........................................................................58

IIReferenceinformationforcommissioning.................................................................59

Chapter5Configureprocessmeasurement...............................................................................61

5.1Characterizetheowmeter.............................................................................61

5.2Conguremassowmeasurement.................................................................64

5.3Congurevolumeowmeasurementforliquidapplications..............................69

5.4Conguregasstandardvolumeowmeasurement..........................................74

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5.5CongureFlowDirection....................................................................................79

5.6Conguredensitymeasurement.....................................................................84

5.7Conguretemperaturemeasurement..............................................................88

5.8Congurepressurecompensation..................................................................90

5.9Congurethepetroleummeasurementapplication...........................................91

5.10Conguretheconcentrationmeasurementapplication.....................................93

Chapter6Configuredeviceoptionsandpreferences..................................................................99

6.1Congurethetransmitterdisplay.....................................................................99

6.2Enableordisableoperatoractionsfromthedisplay.......................................103

6.3Conguresecurityforthedisplaymenus......................................................105

6.4Congurethespeedofthetransmitter’sresponsetochangesinprocess

data............................................................................................................107

6.5Congurealarmhandling.............................................................................108

6.6Congureinformationalparameters..............................................................1 12

Chapter7Integratethemeterwiththecontrolsystem............................................................117

7.1CongurethemAoutputs.............................................................................1 17

7.2Congurethefrequencyoutput.....................................................................124

7.3Congurethediscreteoutput........................................................................129

7.4Congurethediscreteinput..........................................................................134

7.5CongurethemAinput................................................................................136

7.6Conguredigitalcommunications.................................................................138

7.7Congureevents.........................................................................................146

7.8Setuppollingforpressure............................................................................148

7.9Setuppollingfortemperature.......................................................................150

IIIOperations,maintenance,andtroubleshooting......................................................153

Chapter8Transmitteroperation.............................................................................................155

8.1Recordtheprocessvariables.......................................................................155

8.2Viewprocessvariables................................................................................155

8.3Viewtransmitterstatus.................................................................................157

8.4Viewandacknowledgestatusalarms............................................................157

8.5Startandstoptotalizersandinventories........................................................161

8.6Resetmassandvolumetotalizers................................................................162

8.7ResetmassandvolumeinventoriesusingProLinkII......................................163

Chapter9Measurementsupport.............................................................................................165

9.1Optionsformeasurementsupport.................................................................165

9.2Validatethemeter........................................................................................165

9.3Performa(standard)D1andD2densitycalibration.......................................168

9.4PerformaD3andD4densitycalibration(T-Seriessensorsonly)....................171

9.5Performtemperaturecalibration....................................................................174

Chapter10Troubleshooting.....................................................................................................177

10.1TransmitterstatusLEDstates.......................................................................177

10.2Statusalarms..............................................................................................178

10.3Flowproblems.............................................................................................184

10.4Densityproblems.........................................................................................187

10.5Temperatureproblems.................................................................................187

10.6Milliampoutputproblems.............................................................................188

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10.7Frequencyoutputproblems..........................................................................189

10.8Usesensorsimulationfortroubleshooting.....................................................190

10.9Checkpowersupplywiring...........................................................................190

10.10Checksensor-to-transmitterwiring................................................................191

10.11Checkgrounding.........................................................................................191

10.12Checkforradiofrequencyinterference..........................................................191

10.13CheckHARTcommunicationloop.................................................................192

10.14CheckHARTAddressandLoopCurrentMode.......................................................192

10.15CheckHARTburstmode..............................................................................193

10.16CheckmAoutputtrim..................................................................................193

10.17CheckLowerRangeValueandUpperRangeValue.................................................193

10.18CheckmAOutputFaultAction............................................................................193

10.19CheckFrequencyOutputMode...........................................................................193

10.20CheckFrequencyOutputMaximumPulseWidthandFrequencyOutputScaling

Method.........................................................................................................194

10.21CheckFrequencyOutputFaultAction...................................................................194

10.22CheckFlowDirection.......................................................................................194

10.23Checkcutoffs..............................................................................................194

10.24Checkforslugow......................................................................................195

10.25Checkthedrivegain....................................................................................195

10.26Checkthepickoffvoltage.............................................................................197

10.27Checkforelectricalshorts............................................................................198

Appendicesandreference.......................................................................................201

AppendixADefaultvaluesandranges........................................................................................203

A.1Defaultvaluesandranges............................................................................203

AppendixBTransmittercomponentsandinstallationwiring......................................................207

B.1Transmittercomponents...............................................................................207

B.2Transmitter-to-sensorwiring.........................................................................209

B.3Powersupplyterminals................................................................................209

B.4Input/output(I/O)terminals...........................................................................210

AppendixCUsingthetransmitterdisplay...................................................................................213

C.1Componentsofthetransmitterinterface........................................................213

C.2Accessandusethedisplaymenusystem.....................................................215

C.3Displaycodesforprocessvariables..............................................................219

C.4Codesandabbreviationsusedindisplaymenus............................................220

C.5Menumapsforthetransmitterdisplay...........................................................223

AppendixDUsingProLinkIIwiththe9739MVDtransmitter.......................................................231

D.1BasicinformationabouttheProLinkIIsoftwaretool.......................................231

D.2MenumapsforProLinkII.............................................................................232

AppendixEUsingtheFieldCommunicatorwiththe9739MVDtransmitter.................................237

E.1BasicinformationabouttheFieldCommunicator...........................................237

E.2MenumapsfortheFieldCommunicator........................................................238

iii

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Page 7

I I

Gettingstarted

Chapterscoveredinthispart:

♦Beforeyoubegin ♦Quickstartwiththedisplay ♦QuickstartwithProLinkII ♦QuickstartwiththeFieldCommunicator

Page 8

Page 9

Chapter1

Beforeyoubegin

Topicscoveredinthischapter:

♦Safetymessages ♦Obtainversioninformation ♦Availablecommunicationstools ♦Additionaldocumentationandresources

9739MVDtransmittercongurationworksheet

♦

1.1Safetymessages

Safetymessagesareprovidedthroughoutthismanualtoprotectpersonnelandequipment.Readeach safetymessagecarefullybeforeproceedingtothenextstep.

1.2Obtainversioninformation

Tocongure,use,andtroubleshootthetransmitter,youmayneedtoknowtheversioninformationof yourtransmittersoftware,ProLinkIIsoftwareapplication,and/orHARTdevicedescription.

Procedure

SeeTable1-1forinformationonhowtoobtaintheversioninformation.

Table1-1Methodstoobtainversioninformation

ComponentWithdisplayWithProLinkIIWithFieldCommunicator

TransmittersoftwareOFF-LINEMAINT→VER

ProLinkIINotapplicableHelp→AboutProLinkIINotapplicable

HARTdevicedescriptionNotapplicableNotapplicable

View→Installed Options→SoftwareRevisions

Overview→Shortcuts→DeviceInformation→Revisions→Xmtr SoftwareRev

Overview→Shortcuts→DeviceInformation→Revisions→DDRevision

1.3Availablecommunicationstools

Youcanuseavarietyofcommunicationstoolstointerfacewiththe9739MVDtransmitter.

ConfigurationandUseManual

Page 10

Beforeyoubegin

Thefollowingcommunicationstoolsaresupported:

•Transmitterdisplay,ifthetransmitterwasorderedwithadisplay

ProLinkIIsoftware(v2.91orlater)

•

•FieldCommunicator(DDv2orlater)

Tip

YoumaybeabletouseothertoolsfromEmersonProcessManagement,suchasAMSSuite:Intelligent DeviceManagerortheSmartWirelessTHUM™Adapter.UseofAMSortheSmartWirelessTHUM Adapterisnotdiscussedinthismanual.Foryourreference,theAMSinterfaceissimilartothe interface.FormoreinformationontheSmartWirelessTHUMAdapter,refertothedocumentation availableatwww.micromotion.com.

Thismanualprovidesbasicinformationonusingthetransmitterdisplay,ProLinkII,andthe FieldCommunicator.FormoreinformationonusingProLinkII,seetheProLinkIIusermanualavailable ontheMicroMotionwebsite(www.micromotion.com)orontheMicroMotionuserdocumentationCD.For moreinformationonusingFieldCommunicator,seetheFieldCommunicatordocumentationavailable onthe

MicroMotionwebsite(www.micromotion.com).

ProLinkII

1.4Additionaldocumentationandresources

MicroMotionprovidesadditionaldocumentationtosupporttheinstallationandoperationofthe9739 MVDtransmitter.

SeeTable1-2forthedocumentationresourcesavailabletosupportthe9739MVDtransmitter.All documentationresourcesareavailableontheMicroMotionwebsiteatwww.micromotion.comoronthe MicroMotionuserdocumentationCD.

Table1-2Additionaldocumentationandresources

TopicDocument

SensorSensordocumentation

TransmitterinstallationMicroMotion9739MVDTransmitters:Installation

Manual

Hazardousareainstallation

TransmitterelectronicsmoduleupgradeMicroMotion9739MVDT ransmitterElectronicsModule

Seetheapprovaldocumentationshippedwiththe transmitter,ordownloadtheappropriatedocumentation fromthe

InstallationGuide

MicroMotionwebsiteatwww.micromotion.com.

1.59739MVDtransmitterconfigurationworksheet

Usethe9739MVDtransmittercongurationworksheetforbothplanningandrecordingthetransmitter conguration.

Additionally,thecongurationworksheetshowstheparametersthatareaccessiblefromthedifferent communicationstools.Chooseacommunicationstoolthatprovidesaccesstotheparametersthat youplantocongure.

MicroMotion9739MVDTransmitters

Page 11

Table1-39739MVDtransmitterconfigurationsettings

Beforeyoubegin

Configurablewith:

Configuration parameterSettingDisplayProLinkII

SensorType

Flowcalibration factor

Density temperature coefcient(DT)

Temperature calibrationfactor

Massow measurement unit

Ifmassowisa specialunit

Flowdamping

Massowcutoff

Volumetype

StandardGas Density

Volumeow measurement unit

qT-Series(StraightTube)

qOther(CurvedTube)

Basemassunit:

Basetimeunit:

Conversionfactor:

Flowtext:

Totaltext:

qLiquidVolume

qStdGasVolume

üüü

üü

FieldCommunicator

ConfigurationandUseManual

Page 12

Beforeyoubegin

Table1-39739MVDtransmitterconfigurationsettings

Configuration parameterSettingDisplay

Basemassunit:

Basetimeunit:

Ifvolumeowis aspecialunit

Volumeow cutoff

Flowdirection

Conversionfactor:

Flowtext:

Totaltext:

qAbsoluteValue

qBidirectional

qForward

qNegateBidirectional

qNegateForward

qReverse

Density measurement unit

Slugowlow limit

Slugowhigh limit

Slugduration

Densitydamping

Densitycutoff

Temperature measurement unit

q°C

q°F

q°R

qKelvin

Temperature damping

Pressureunits:

Pressure compensation

Flowfactor:

Densityfactor:

Calibrationpressure:

continued

Configurablewith:

ProLinkII

üü

üüü

üü

üüü

üü

üüü

üü

FieldCommunicator

MicroMotion9739MVDTransmitters

Page 13

Beforeyoubegin

Table1-39739MVDtransmitterconfigurationsettings

Configuration parameterSettingDisplay

APItabletype:

qDegreesAPI,reference

temperature60°F

qRelativeDensity/Specic

Gravity,referencetemperature 60°F

Petroleum measurement application(if available)

qkg/m

APIUnits:

atuser-dened referencetemperature (Temperature:____)

qGeneralizedCrudeorJP4

(APIChapter11.1“A”T ables)

qGeneralizedProducts(API

Chapter11.1“B”T ables)

qUserDenedTEC(API

Chapter11.1“C”T ables)

Concentration measurement application(if available)

Weights& Measures application(if available)

Activecurve:

Derivedvariable:

Totalizerresetoptions:

qNotresettablefromdisplayor

digitalcommunications

qResettablefromdigital

communicationsonly

qResettablefrodisplayand

digitalcommunications

qResettablefromdisplayonly

Language:

qEnglish

Transmitter display

qFrench

qGerman

qSpanish

continued

Configurablewith:

üü

ProLinkII

üü

FieldCommunicator

ConfigurationandUseManual

Page 14

Beforeyoubegin

Table1-39739MVDtransmitterconfigurationsettings

Configuration parameterSettingDisplay

Displayvariables:

•Var1:

•Var2:

•Var3:

•Var4:

•Var5:

•Var6:

•Var7:

•Var8:

•Var9:

•Var10:

•Var11:

•Var12:

•Var13:

•Var14:

•Var15:

Updateperiod(100millisecondsto 10,000millisecondsrange;defaultis 200milliseconds):

Autoscroll:

qEnable

qDisable

Autoscrollrate(defaultis10 seconds):

Backlight:

qOn

qOff

Totalizerstart/stop:

qEnabled

qDisabled

Totalizerreset:

qEnabled

qDisabled

continued

Configurablewith:

ProLinkII

üü

üüü

üü

FieldCommunicator

MicroMotion9739MVDTransmitters

Page 15

Beforeyoubegin

Table1-39739MVDtransmitterconfigurationsettings

Configuration parameterSettingDisplayProLinkII

Acknowledgeallalarms:

qEnabled

qDisabled

Ofinemenu:

qEnabled

qDisabled

Alarmpassword:

qEnabled

qDisabled

Responsetime:

qNormal

qSpecial

Tag:

Descriptor:

Message:

Date:

Informational parameters

mAOutput1

Sensorserialnumber:

Sensormodel:

Material:

Flange:

Liner:

ProcessVariable:

Measurementunit:

Lowerrangevalue(LRV):

Upperrangevalue(URV):

Massowcutoff:

Addeddamping:

Faultaction:

qUpscale

qDownscale

qInternalzero

qNone

continued

Configurablewith:

üü

üüü

üü

FieldCommunicator

ConfigurationandUseManual

Page 16

Beforeyoubegin

Table1-39739MVDtransmitterconfigurationsettings

Configuration parameterSettingDisplayProLinkII

FaultLevel:

ProcessVariable:

Measurementunit:

Lowerrangevalue(LRV):

Upperrangevalue(URV):

Massowcutoff:

mAOutput2

Frequency output

Addeddamping:

Faultaction:

qUpscale

qDownscale

qInternalzero

qNone

Faultlevel:

Processvariable:

Scalingmethod:

qFreqency=Flow

qPulses/Unit

qUnits/Pulse

Pulsewidth:

qActiveHigh

qActiveLow

Polarity:

qActiveHigh

qActiveLow

Faultaction:

qUpscale

qDownscale

qInternalzero

qNone

Faultlevel:

Powertype:

qInternal

qExternal

continued

Configurablewith:

üü

üüü

üü

üüü

üü

üüü

üü

üüü

FieldCommunicator

10MicroMotion9739MVDTransmitters

Page 17

Beforeyoubegin

Table1-39739MVDtransmitterconfigurationsettings

Configuration parameterSettingDisplay

Assignment:

qCalibrationinprogress

qDiscreteevent1

qDiscreteevent2

qDiscreteevent3

qDiscreteevent4

qDiscreteevent5

qEvent1

qEvent2

qFaultconditionindication

qFlowswitchindication

Discreteoutput

qForward/Reverseindication

Polarity:

qActiveHigh

qActiveLow

Powertype:

qInternal

qExternal

Faultaction:

qUpscale

qDownscale

qNone

Polarity:

qActiveHigh

qActiveLow

Assignment:

qStartzero:

Discreteinput

qStart/stoptotalizers:

qResetmasstotal:

qResetgasstandardvolume

total:

qResetalltotals:

qResetAPItemperature-

correctedvolumetotal:

continued

Configurablewith:

ProLinkII

üüü

üü

üüü

FieldCommunicator

ConfigurationandUseManual

Page 18

Beforeyoubegin

Table1-39739MVDtransmitterconfigurationsettings

Configuration parameterSettingDisplay

Processvariable:

qExternalpressure

qInternalpressure

mAinput

HARTAddress orModbus Address

Loopcurrent mode(ProLinkII) ormAoutputac-

FieldCom-

tion( municator)

ModbusASCII

qNone

Lowerrangevalue(LRV):

Upperrangevalue(URV):

qEnable

qDisable

qEnable

qDisable

Burstmode

qEnable

qDisable

Burstmode output

qDynamicvariablesandPV

current

qPrimaryvariable

qPVcurrentandpercentageof

range

qReaddevicevariableswith

status

qTransmittervariables

HARTvariables

•Primaryvariable(PV):

•Secondaryvariable(SV):

•Tertiaryvariable(TV):

•Quaternaryvariable(QV):

continued

Configurablewith:

ProLinkII

üüü

üü

FieldCommunicator

12MicroMotion9739MVDTransmitters

Page 19

Beforeyoubegin

Table1-39739MVDtransmitterconfigurationsettings

Configuration parameterSettingDisplay

Digital Communications FaultActions Settings

qUpscale

qDownscale

qReportNAN(NotANumber)

qFlowRatesgotozerovalue=

zeroow

qFlowRatesgotozerovalue

=zeroow.Densityand Temperaturegotozero.

qNoAction

Outputassignment:

Processvariable:

Event1

Type:

qHighalarm

qLowalarm

Setpoint:

Outputassignment:

Processvariable:

Event2

Type:

qHighalarm

qLowalarm

Setpoint:

EventType:

qHI

qLO

qIN

DiscreteEvent1

qOUT

ProcessVariable:

SetpointA:

SetpointB:

continued

Configurablewith:

ProLinkII

üü

FieldCommunicator

ConfigurationandUseManual

Page 20

Beforeyoubegin

Table1-39739MVDtransmitterconfigurationsettings

Configuration parameterSettingDisplay

Action:

qNone(default)

qStartSensorZero

qStart/stopalltotalizers

qResetmasstotal

qResetvolumetotal

qResetgasstandardvolume

total

qResetalltotals

qResettemperature-corrected

volumetotal

qResetCMreferencevolume

total

qResetCMnetmasstotal

qResetCMnetvolumetotal

qIncrementCMmatrix

EventType:

qHI

qLO

qIN

DiscreteEvent2

qOUT

ProcessVariable:

SetpointA:

SetpointB:

continued

Configurablewith:

ProLinkII

üü

FieldCommunicator

MicroMotion9739MVDTransmitters

Page 21

Beforeyoubegin

Table1-39739MVDtransmitterconfigurationsettings

Configuration parameterSettingDisplay

Action:

qNone(default)

qStartSensorZero

qStart/stopalltotalizers

qResetmasstotal

qResetvolumetotal

qResetgasstandardvolume

total

qResetalltotals

qResettemperature-corrected

volumetotal

qResetCMreferencevolume

total

qResetCMnetmasstotal

qResetCMnetvolumetotal

qIncrementCMmatrix

EventType:

qHI

qLO

qIN

DiscreteEvent3

qOUT

ProcessVariable:

SetpointA:

SetpointB:

continued

Configurablewith:

ProLinkII

üü

FieldCommunicator

ConfigurationandUseManual

Page 22

Beforeyoubegin

Table1-39739MVDtransmitterconfigurationsettings

Configuration parameterSettingDisplay

Action:

qNone(default)

qStartSensorZero

qStart/stopalltotalizers

qResetmasstotal

qResetvolumetotal

qResetgasstandardvolume

total

qResetalltotals

qResettemperature-corrected

volumetotal

qResetCMreferencevolume

total

qResetCMnetmasstotal

qResetCMnetvolumetotal

qIncrementCMmatrix

EventType:

qHI

qLO

qIN

DiscreteEvent4

qOUT

ProcessVariable:

SetpointA:

SetpointB:

continued

Configurablewith:

ProLinkII

üü

FieldCommunicator

MicroMotion9739MVDTransmitters

Page 23

Beforeyoubegin

Table1-39739MVDtransmitterconfigurationsettings

Configuration parameterSettingDisplay

Action:

qNone(default)

qStartSensorZero

qStart/stopalltotalizers

qResetmasstotal

qResetvolumetotal

qResetgasstandardvolume

total

qResetalltotals

qResettemperature-corrected

volumetotal

qResetCMreferencevolume

total

qResetCMnetmasstotal

qResetCMnetvolumetotal

qIncrementCMmatrix

EventType:

qHI

qLO

qIN

DiscreteEvent5

qOUT

ProcessVariable:

SetpointA:

SetpointB:

continued

Configurablewith:

ProLinkII

üü

FieldCommunicator

ConfigurationandUseManual

Page 24

Beforeyoubegin

Table1-39739MVDtransmitterconfigurationsettings

Configuration parameterSettingDisplay

Action:

qNone(default)

qStartSensorZero

qStart/stopalltotalizers

qResetmasstotal

qResetvolumetotal

qResetgasstandardvolume

total

qResetalltotals

qResettemperature-corrected

volumetotal

qResetCMreferencevolume

total

qResetCMnetmasstotal

qResetCMnetvolumetotal

qIncrementCMmatrix

Pollingcontrol:

qNone

qPollAsPrimary

qPollAsSecondary

Polledvariable1

ExternalTag:

Variabletype:

qExternalpressure

qExternaltemperature

qNone

Pollingcontrol:

qNone

qPollAsPrimary

qPollAsSecondary

Polledvariable2

ExternalTag:

Variabletype:

qExternalpressure

qExternaltemperature

qNone

continued

Configurablewith:

ProLinkII

üü

FieldCommunicator

MicroMotion9739MVDTransmitters

Page 25

Chapter2

Quickstartwiththedisplay

Topicscoveredinthischapter:

♦Applypower ♦Congurationtipsandtricks ♦ConguretheprimarymAoutputtoreportmassowrateinauser-selected

measurementunit ♦Performalooptest ♦Zerotheowmeter

2.1Applypower

Prerequisites

Beforeyouapplypowertotheowmeter,closeandtightenallhousingcovers.

Topreventignitionofammableorcombustibleatmospheres,makesureallcoversare tightlyclosed.Forhazardousareainstallations,applyingpowertotheunitwhilehousing coversareremovedorloosecancauseanexplosion.

Procedure

Turnontheelectricalpoweratthepowersupply.

Theowmeterwillautomaticallyperformdiagnosticroutines.Fortransmitterswithadisplay,thestatus

LEDwillturngreenandbegintoashwhenthestartupdiagnosticsarecomplete.IfthestatusLED

exhibitsdifferentbehavior,analarmconditionispresent.

Postrequisites

Allowtheelectronicstowarmupforapproximately10minutesbeforerelyingonprocessmeasurements.

Althoughthesensorisreadytoreceiveprocessuidshortlyafterpower-up,theelectronicscantakeup

to10minutestowarmupcompletely.

2.2Configurationtipsandtricks

Reviewthesetipsbeforebeginningconguration.

2.2.1AccesstoOFFLINEmenu

AccesstotheOFFLINEmenumaybedisabled.Tocongurethetransmitterusingthedisplay,youmust

enableaccesstotheOFFLINEmenu.

ConfigurationandUseManual

Page 26

Quickstartwiththedisplay

2.2.2Defaultvaluesandranges

DefaultvaluesandrangesforthemostcommonlyusedparametersareprovidedinAppendixA.

2.3ConfiguretheprimarymAoutputtoreportmassflow

rateinauser-selectedmeasurementunit

Thisprocedureshowsyouhowtoperformthesetasksusingthedisplay.Forallotherconguration

tasks,includingotheroptionsforthemAoutput,seethecongurationsectionsofthismanual.

Note

Thisprocedureassumesthatyouarestartingfromthefactory-defaultconguration.

Procedure

1.Navigatetothecongurationmenu.

a.Atthetransmitterdisplay,activatetheScrollandSelectopticalswitchessimultaneouslyuntil

SEEALARMappearsonthedisplay .

b.ActivateScrollrepeatedlyuntilOFF-LINEMAINTappearsonthedisplay,thenactivateSelect.

c.ActivateScroll-Select-Scroll.

Thisoperatorsequenceisasafetyprecaution,designedtoprotectthetransmitterfrom accidentalcongurationchangescausedbyunintentionalactivationoftheoff-linemenu.

Important

Ifyouhaveenabledadisplaypassword,theScroll-Select-Scrolloperatorsequenceisdisabled. Youarerequiredtoenterapasswordbeforeyoucancontinue.Thedefaultpasswordis1234.

d.ActivateScrolluntilOFF-LINECONFGappearsonthedisplay,thenactivateSelect.

2.SetMassFlowMeasurementUnitasdesired.

a.WhenCONFIGUNITSappearsonthedisplay,activateSelect.

b.WhenUNITSMASSappearsonthedisplay,activateSelect.

c.ActivateScrolltoviewtheoptionsforMassFlowMeasurementUnit.Whenyouseethe

measurementunityouwanttouse,activateSelect. activateSelect.

d.ActivateScrolluntilUNITSEXITappearsonthedisplay ,thenactivateSelect.

3.SetmAOutputProcessVariabletoMassFlowRate.

a.ActivateScrolluntilCONFIGIOappearsonthedisplay ,thenactivateSelect.

IfSTORE/YES?ashesonthedisplay ,

b.WhenAO1appearsonthedisplay,activateSelect.

c.WhenAO1SRCappearsonthedisplay,activateSelect.

d.ActivateScrolltoviewtheoptionsformAOutputProcessVariableoptions.WhenyouseeMFLOW,

activateSelect.IfSTORE/YES?ashesonthedisplay,activateSelect.

4.SetLowerRangeValue(LRV).

20MicroMotion9739MVDTransmitters

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Quickstartwiththedisplay

LowerRangeValuespeciesthevalueofMassFlowRatetoberepresentedbyanoutputlevelof 0mAor4mA.

a.ActivateScrolluntilAO14mAorAO10mAappearsonthedisplay,thenactivateSelect.

b.DeneeachcharacterinLowerRangeV alue,includingthesign.

UseSelecttohighlightaspeciccharacter.UseScrolltosetthevalueofthecharacter.

c.Whenyouhavesetallcharactersasdesired,activateScrollandSelectsimultaneouslyuntil

SAVE/YES?ashesonthedisplay,thenactivateSelecttowritethevaluetotransmittermemory .

5.SetUpperRangeValue(URV).

UpperRangeValuespeciesthevalueofMassFlowRatetoberepresentedbyanoutputlevelof20mA.

a.ActivateScrolluntilAO120mAappearsonthedisplay ,thenactivateSelect.

b.DeneeachcharacterinUpperRangeV alue,includingthesign.

UseSelecttohighlightaspeciccharacter.UseScrolltosetthevalueofthecharacter.

c.Whenyouhavesetallcharactersasdesired,activateScrollandSelectsimultaneouslyuntil

SAVE/YES?ashesonthedisplay,thenactivateSelecttowritethevaluetotransmittermemory .

6.ActivateScrolluntilAOEXITappearsonthedisplay,thenactivateSelect.

7.Returnthedisplaytonormaloperation(displayingprocessdata).

a.ActivateScrolluntilIOEXITappearsonthedisplay,thenactivateSelect.

b.ActivateScrolluntilCONFIGEXITappearsonthedisplay ,thenactivateSelect.

c.ActivateScrolluntilOFF-LINEEXITappearsonthedisplay,thenactivateSelect.

d.ActivateScrolluntilEXITappearsonthedisplay,thenactivateSelect.

Tip

Anotherwaytoexittheoff-linemenuistorelyonthetime-outfeature.Ifyouhavenotused theoff-linemenuforapproximately60seconds,thedisplaywillautomaticallyreturntonormal operation.

2.4Performalooptest

Alooptestisawaytoverifythatthetransmitterandthereceivingdevicearecommunicatingproperly.

AlooptestalsohelpsyouknowwhetheryouneedtotrimmAoutputs.Performingalooptestisnot

arequiredprocedure.However,

outputavailableonyourtransmitter.

Procedure

MicroMotionrecommendsperformingalooptestforeveryinputor

1.TestthemAoutput.

a.ChooseOFFLINEMAINT→SIM→AO1SIM,andselectSET4MAoranothermAoutputvalue.

b.ReadthemAcurrentatthereceivingdeviceandcompareittothetransmitteroutput.

ConfigurationandUseManual

Dotstraversethedisplaywhiletheoutputisxed.

Thereadingsdonotneedtomatchexactly .Ifthevaluesareslightlydifferent,youcancorrect thediscrepancybytrimmingtheoutput.

Page 28

Quickstartwiththedisplay

c.Atthetransmitter,activateSelect.

d.ScrolltoandselectSET20MA.

Dotstraversethedisplaywhiletheoutputisxed.

e.ReadthemAcurrentatthereceivingdeviceandcompareittothetransmitteroutput.

Thereadingsdonotneedtomatchexactly .Ifthevaluesareslightlydifferent,youcancorrect thediscrepancybytrimmingtheoutput.

f.Atthetransmitter,activateSelect.

2.TestthesecondarymAoutput.

ChooseOFFLINEMAINT→SIM→AO2SIM,andrepeatthelooptestforthesecondarymAoutput.

3.Testthefrequencyoutput.

a.ChooseOFFLINEMAINT→SIM→FOSIM,andselectthefrequencyoutputvalue.

Thefrequencyoutputcanbesetto1,10,or15kHz.

Note

IftheWeights&Measuresapplicationisenabledonthetransmitter,itisnotpossibleto performalooptestofthefrequencyoutput,evenwhenthetransmitterisunsecured.

Dotstraversethedisplaywhiletheoutputisxed.

b.Readthefrequencysignalatthereceivingdeviceandcompareittothetransmitteroutput.

c.Atthetransmitter,activateSelect.

4.Testthediscreteoutput.

a.ChooseOFFLINEMAINT→SIM→DOSIM,andselectSETON.

Dotstraversethedisplaywhiletheoutputisxed.

b.Verifythesignalstateatthereceivingdevice.

c.Atthetransmitter,activateSelect.

d.ScrolltoandselectSETOFF.

e.Verifythesignalstateatthereceivingdevice.

f.Atthetransmitter,activateSelect.

5.Readthediscreteinput.

a.Settheremoteinputdevicesothatthedesiredsignalissenttothetransmitter.

b.Atthetransmitter,chooseOFFLINEMAINT→SIM,andselectREADDI.

c.Verifythesignalstateatthetransmitter.

d.Repeattheprocedurefortheothersignalstate.

6.ReadthemAinput.

a.Settheremoteinputdevicesothatthedesiredcurrentissenttothetransmitter.

b.Atthetransmitter,chooseOFFLINEMAINT→SIM,andselectREADMAI.

22MicroMotion9739MVDTransmitters

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Quickstartwiththedisplay

c.Verifythecurrentvalue.

Postrequisites

•IfthemAoutputreadingswereslightlyoffatthereceivingdevice,youcancorrectthisdiscrepancy bytrimmingtheoutput.

•IfthemAoutputreadingwassignicantlyoff(±200microamps),orifatanystepthereadingwas faulty,verifythewiringbetweenthetransmitterandtheremotedevice,andtryagain.

•IfthemAinputreadingwasslightlyoffatthetransmitter,trimandcalibratetheinputatthe remoteinputdevice.

2.5Zerotheflowmeter

Zeroingtheowmeterestablishestheowmeter’spointofreferencewhenthereisnoow.

Prerequisites

Toprepareforthezeroprocedure:

1.Allowtheowmetertowarmupforatleast20minutesafterapplyingpower.

2.Runtheprocessuidthroughthesensoruntilthesensortemperaturereachesthenormalprocess operatingtemperature.

3.Stopowthroughthesensorbyshuttingavalvedownstreamfromthesensor .

4.Ensurethatowhascompletelystoppedthroughthesensor,andthatthesensoriscompletely fullofprocessuid.

5.Checktheowrate.Iftheowrateisclosetozero,youshouldnotneedtozerotheowmeter.

Important

Themeterwaszeroedatthefactory,andshouldnotrequireaeldzero.

Note

Donotzerotheowmeterifahigh-severityalarmisactive.Correcttheproblem,thenzerothe owmeter.Youmayzerotheowmeterifalow-severityalarmisactive.

Procedure

1.InitiateowmeterzerobychoosingOFFLINEMAINT→ZERO→CALZERO,andselectCAL/YES?.

Dotstraversethedisplaywhileowmeterzeroisinprogress.

2.Readthezeroresultonthedisplay.

ThedisplaywillreportCALPASSifthezerowassuccessful,orCALFAILifitwasnot.Ifthezerofails, restorethefactoryzero(ifavailable).

2.5.1Restorefactoryzero

Procedure

Restorethefactoryzerowiththedisplay.

ConfigurationandUseManual

Page 30

Quickstartwiththedisplay

OFFLINEMAINT→RESTOREZERO→RESTORE/YES?

24MicroMotion9739MVDTransmitters

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Chapter3

QuickstartwithProLinkII

Topicscoveredinthischapter:

♦Applypower ♦Connectwith ♦Congurationtipsandtricks ♦ConguretheprimarymAoutputtoreportmassowrateinauser-selected

measurementunit ♦Performalooptest ♦TrimmAoutputs ♦Zerotheowmeter ♦T estortunethesystemusingsensorsimulation ♦Backuptransmitterconguration ♦Enable/disableHARTsecurity

3.1Applypower

Prerequisites

Beforeyouapplypowertotheowmeter,closeandtightenallhousingcovers.

ProLinkII

Topreventignitionofammableorcombustibleatmospheres,makesureallcoversare tightlyclosed.Forhazardousareainstallations,applyingpowertotheunitwhilehousing coversareremovedorloosecancauseanexplosion.

Procedure

Turnontheelectricalpoweratthepowersupply.

Theowmeterwillautomaticallyperformdiagnosticroutines.Fortransmitterswithadisplay,thestatus

LEDwillturngreenandbegintoashwhenthestartupdiagnosticsarecomplete.IfthestatusLED

exhibitsdifferentbehavior,analarmconditionispresent.

Postrequisites

Allowtheelectronicstowarmupforapproximately10minutesbeforerelyingonprocessmeasurements.

Althoughthesensorisreadytoreceiveprocessuidshortlyafterpower-up,theelectronicscantakeup

to10minutestowarmupcompletely.

3.2ConnectwithProLinkII

AconnectionfromProLinkIItoyourtransmitterallowsyoutoreadprocessdata,congurethe

transmitter,andperformmaintenanceandtroubleshootingtasks.

ConfigurationandUseManual

Page 32

QuickstartwithProLinkII

Prerequisites

YoumusthavethefollowingversionofProLinkIIinstalledonyourcomputer:v2.91orlater.

3.2.1ProLinkIIconnectiontypes

The9739MVDtransmitterhasseveralconnectionsoptionsforcommunicatingviaProLinkII.Y ou

chooseaconnectiontypebasedonwhatyouneedtoaccomplishwiththetransmitterandthedigital

communicationsyouareusing.

The

9739MVDtransmittersupportsthefollowingProLinkIIconnectiontypes:

•Serviceportconnections

•HART/Bell202connections

•HART/RS-485connections

•Modbus/RS-4857-bitconnections(ModbusASCII)

•Modbus/RS-4858-bitconnections(ModbusRTU)

Whenselectingaconnectiontype,considerthefollowing:

•Serviceportconnectionsusestandardconnectionparametersthatarealreadydenedin ProLinkII,andthereforeyoudonothavetocongurethem.

•HART/Bell202connectionsusestandardHARTconnectionparametersthatarealreadydenedin ProLinkII.Theonlyparameteryoumustcongureisthetransmitteraddress.

•Theserviceportterminals(AandB)andtheRS-485terminals(26and27)usethesameinternal wiring.IfyouhavewiredthetransmitterforRS-485digitalcommunications,youcannotmake aserviceportconnection.

•Serviceportconnectionsrequireaccesstotheserviceportterminals,whicharelocatedonthe transmitterdisplayandonlyaccessibleafterremovingthehousingcover.Accordingly,service portconnectionsshouldbeusedonlyfortemporaryconnections,andmayrequireextrasafety precautions.

•Modbusconnections,includingserviceportconnections,aretypicallyfasterthanHART connections.

•WhenyouareusingaHARTconnection, windowatatime.Thisisdonetomanagenetworktrafcandoptimizespeed.

•Youcannotmakeaserviceportconnectionwhileanactiveconnectionexistsbetweenthe transmitterandModbushost.

ProLinkIIwillnotallowyoutoopenmorethanone

26MicroMotion9739MVDTransmitters

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QuickstartwithProLinkII

3.2.2Makeaserviceportconnection

Prerequisites

Youwillneedthefollowing:

•Aninstalled,licensedcopyofProLinkII

•AnavailableserialorUSBport

•Oneofthefollowingtypesofsignalconverters:

−RS-232toRS-485signalconverter

−USBtoRS-485signalconverter

•Adaptersasrequired(e.g.9-pinto25-pin)

Important

TheSP(ServicePort)clipsonthedisplayofthe theRS-485terminals26and27ofthetransmitter.IfyouhavewiredthetransmitterforRS-485 digitalcommunications,youmustdirectlyconnecttothetransmitterusingtheRS-485terminalblock connectionsordisconnecttheRS-485terminalconnectionstousetheServicePortconnections.

9739MVDtransmitteraredirectlyconnectedto

Procedure

1.AttachthesignalconvertertoyourPC’sserialorUSBport.

2.Atthetransmitter,removethehousingcovertoaccessthetransmitterdisplay.

Ifthetransmitterisinahazardousarea,donotremovethehousingcoverwhile powerisbeingsuppliedtotheunit.Removingthehousingcoverwhilepoweris suppliedtotheunitcouldcauseanexplosion.T oaccesstransmitterinformationina hazardousenvironment,useacommunicationmethodthatdoesnotrequireremoving thetransmitterhousingcover.

3.ConnecttheleadsonyoursignalconvertertotheSP(ServicePort)clips(AandB)ontheface ofthetransmitter.SeeFigure3-1.

Tip

Usually,butnotalways,theblackleadisRS-485/AandtheredleadisRS-485/B.

ConfigurationandUseManual

Page 34

QuickstartwithProLinkII

Figure3-1ProLinkIIconnectiontoserviceport

APC

B25-to-9pinadapter,ifnecessary;orRS-232toUSBadapter,ifnecessary

CRS-232toRS-485signalconverter

DTransmitter

Notes

•Thisgureshowsaserialportconnection.AUSBportconnectionisalsoavailable.

4.StartProLinkII.

5.ChooseConnection→ConnecttoDevice.

6.SetProtocoltoServicePort.

Tip

Serviceportconnectionsusestandardconnectionparametersandastandardaddress.Y oudonot needtocongurethemhere.

7.SettheCOMPortvaluetothePCCOMportthatyouareusingforthisconnection.

8.ClickConnect.

Iftheconnectionissuccessful:

•Thestatusbarinthemainwindowisupdatedtoshowanactiveconnection.

•TheProcessVariableswindoworCommissioningWizardwindowisdisplayed.

28MicroMotion9739MVDTransmitters

Page 35

Ifanerrormessageappears:

•Switchtheleadsandtryagain.

•EnsurethatyouareusingthecorrectCOMport.

•CheckthephysicalconnectionbetweenthePCandthetransmitter.

3.2.3MakeaHART/Bell202connection

Prerequisites

Youwillneedthefollowing:

•Aninstalled,licensedcopyofProLinkII

•AnavailableserialorUSBport

•Oneofthefollowingtypesofsignalconverters:

−RS-232toBell202signalconverter

−USBtoBell202signalconverter

QuickstartwithProLinkII

•Adaptersasrequired(e.g.9-pinto25-pin)

Important

IftheHARTsecurityswitchissettoON,HARTprotocolcannotbeusedtoperformanyactionthat requireswritingtothetransmitter.Forexample,youcannotchangetheconguration,resettotalizers, orperformcalibrationusingthe HARTsecurityswitchissettoOFF,nofunctionsaredisabled.

YoucanconnectProLinkIItotheHARTclipsonthetransmitter,toanypointinalocalHARTloop,orto anypointinaHARTmultidropnetwork.

Ifthetransmitterisinahazardousarea,donotremovethehousingcoverwhilepoweris beingsuppliedtotheunit.Removingthehousingcoverwhilepowerissuppliedtotheunit couldcauseanexplosion.Toaccesstransmitterinformationinahazardousenvironment, useacommunicationmethodthatdoesnotrequireremovingthetransmitterhousingcover.

FieldCommunicatororProLinkIIwithaHARTconnection.Whenthe

Procedure

1.ToconnecttotheHARTclips:

a.Removethetransmitterhousingcover.

b.AttachtheleadsfromthesignalconvertertotheHARTclipsonthefaceofthetransmitter

andaddresistanceasnecessary .SeeFigure3-2.

ConfigurationandUseManual

ProLinkIImustbeconnectedacrossaresistanceof250–600Ω.

Tip

HARTconnectionsarepolarity-insensitive.Itdoesnotmatterwhichleadyouattachtowhich terminal.

Page 36

QuickstartwithProLinkII

Figure3-2ProLinkIIconnectiontoHARTclips

APC

BHARTinterface

C250–600Ωresistance

DTransmitter

Notes

•Thisgureshowsaserialportconnection.AUSBportconnectionisalsoavailable.

2.ToconnecttoapointinthelocalHARTloop,attachtheleadsfromthesignalconvertertoany pointintheloopandaddresistanceasnecessary.SeeFigure3-3.

ProLinkIImustbeconnectedacrossaresistanceof250–600Ω.

30MicroMotion9739MVDTransmitters

Page 37

Figure3-3ProLinkIIconnectiontolocalHARTloop

APC

BHARTinterface

CAnycombinationofresistorsR1,R2,andR3asnecessarytomeetHARTcommunicationresistance

requirements

DDCSorPLC

ETransmitter

QuickstartwithProLinkII

Notes

•Thisgureshowsaserialportconnection.AUSBportconnectionisalsoavailable.

3.ToconnecttoapointintheHARTmultidropnetwork,attachtheleadsfromthesignalconverterto anypointintheloopandaddresistanceasnecessary.SeeFigure3-4.

ProLinkIImustbeconnectedacrossaresistanceof250–600Ω.

ConfigurationandUseManual

Page 38

QuickstartwithProLinkII

Figure3-4ProLinkIIconnectiontomultidropnetwork

AHARTinterface(toPC)

B250–600Ωresistance

CDevicesonthenetwork

DMasterdevice

Notes

•Thisgureshowsaserialportconnection.AUSBportconnectionisalsoavailable.

4.StartProLinkII.

5.ChooseConnection→ConnecttoDevice.

6.SetProtocoltoHARTBell202.

Tip

HART/Bell202connectionsusestandardconnectionparameters.Youdonotneedtocongure themhere.

7.IfyouareusingaUSBportconnection,enableConverterTogglesRTS.

8.SetAddress/TagtotheHARTpollingaddressconguredinthetransmitter.

32MicroMotion9739MVDTransmitters

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QuickstartwithProLinkII

Tips

•Ifthisisthersttimeyouareconnectingtothetransmitter,usethedefaultaddress:0.

•IfyouarenotinaHARTmultidropenvironment,theHARTpollingaddressistypicallyleft atthedefaultvalue.

•Ifyouareunsureofthetransmitter’saddress,clickPoll.ProLinkIIwillsearchthenetworkand returnalistofthetransmittersthatitdetects.

9.SettheCOMPortvaluetothePCCOMportthatyouareusingforthisconnection.

10.SetMasterasappropriate.

OptionDescription

SecondaryUsethissettingifanotherHARThostsuchas

aDCSisonthenetwork.

PrimaryUsethissettingifnootherhostisonthe

network.TheFieldCommunicatorisnota host.

11.ClickConnect.

Iftheconnectionissuccessful:

•Thestatusbarinthemainwindowisupdatedtoshowanactiveconnection.

•TheProcessVariableswindoworCommissioningWizardwindowisdisplayed.

Ifanerrormessageappears:

•EnsurethatyouareusingthecorrectCOMport.

•VerifytheHARTpollingaddress.

•CheckthephysicalconnectionbetweenthePCandthetransmitter.

•Increaseordecreaseresistance.

3.2.4MakeaHART/RS-485connection

Prerequisites

Youwillneedthefollowing:

•Aninstalled,licensedcopyofProLinkII

•AnavailableserialorUSBport

•Oneofthefollowingtypesofsignalconverters:

−RS-232toRS-485signalconverter

−USBtoRS-485signalconverter

•Adaptersasrequired(e.g.9-pinto25-pin)

ConfigurationandUseManual

Page 40

QuickstartwithProLinkII

Important

FieldCommunicatororProLinkIIwithaHARTconnection.Whenthe

HARTsecurityswitchissettoOFF,nofunctionsaredisabled.

Procedure

1.AttachthesignalconvertertoyourPC’sserialorUSBport.

2.Atthetransmitter,removethehousingcovertoaccesstheRS-485terminalconnections.

3.Toconnectdirectlytothetransmitter,connecttheleadsonyoursignalconvertertoterminals26 (RS-485/A)and27(RS-485/B)onyourtransmitter.SeeFigure3-5.

Figure3-5ProLinkIIconnectiontotransmitterterminals

APC

B25-to-9pinadapter,ifnecessary

CRS-485toRS-232signalconverter

DTransmitter

4.ToconnecttoapointintheRS-485network,connecttheleadsonyoursignalconvertertoany pointinthenetworkandaddresistanceasnecessary.SeeFigure3-6.

MicroMotion9739MVDTransmitters

Page 41

Figure3-6ProLinkIIconnectiontoanRS-485networkusingHART

APC

B25-to-9pinadapter,ifnecessary

CRS-485toRS-232signalconverter

D120-Ω,1/2-wattterminatingresistorsatbothendsofthesegment,ifnecessary

EDCSorPLC(Auto-detectcommunication)

FTransmitter

QuickstartwithProLinkII

Notes

•Thisgureshowsaserialportconnection.AUSBportconnectionisalsoavailable.

5.Toconnecttoapointinamultidropnetwork,attachtheleadsfromthesignalconvertertoany pointinthewire.SeeFigure3-7.

ConfigurationandUseManual

Page 42

QuickstartwithProLinkII

Figure3-7ProLinkIIconnectiontoamultidropnetwork

AHARTinterface(toPC)

BDevicesonthenetwork

CMasterdevice

6.StartProLinkII.

7.ChooseConnection→ConnecttoDevice.

8.Ifnecessary,settheconnectionparameterstomatchtheHART/RS-485parametersconguredin yourtransmitter.

Tominimizecongurationrequirements,the9739MVDtransmitterusesanauto-detectionscheme whenrespondingtoaconnectionrequest.Thetransmitterwillacceptallconnectionrequests withinthelimitsdescribedinTable3-1.

Table3-1Auto-detectionlimits

ParameterOption

Protocol

AddressRespondsto:

Baudrate

Stopbits

ParityEven,odd,none

HART ,ModbusASCII,ModbusRTU

•Serviceportaddress(11 1)

•ConguredHARTaddress(default=0)

•ConguredModbusaddress(default=1)

Standardratesbetween1200and38,400

0,1

9.SettheCOMPortvaluetothePCCOMportthatyouareusingforthisconnection.

MicroMotion9739MVDTransmitters

Page 43

10.SetMasterasappropriate:

OptionDescription

SecondaryUsethissettingifanotherhostsuchasaDCS

isonthenetwork.

PrimaryUsethissettingifnootherhostisonthe

network.TheFieldCommunicatorisnota host.

11.ClickConnect.

Iftheconnectionissuccessful:

•Thestatusbarinthemainwindowisupdatedtoshowanactiveconnection.

•TheProcessVariableswindoworCommissioningWizardwindowisdisplayed.

Ifanerrormessageappears:

•EnsurethatyouareusingthecorrectCOMport.

•CheckthephysicalconnectionbetweenthePCandthetransmitter.

QuickstartwithProLinkII

•Forlong-distancecommunication,orifnoisefromanexternalsourceinterfereswiththe signal,install120-Ω½-Wterminatingresistorsinparallelwiththeoutputatbothendsofthe communicationsegment.

3.2.5MakeaModbus/RS-485connection

Prerequisites

Youwillneedthefollowing:

•Aninstalled,licensedcopyofProLinkII

•AnavailableserialorUSBport

•Oneofthefollowingtypesofsignalconverters:

−RS-232toRS-485signalconverter

−USBtoRS-485signalconverter

•Adaptersasrequired(e.g.9-pinto25-pin)

Procedure

1.AttachthesignalconvertertoyourPC’sserialorUSBport.

2.Atthetransmitter,removethehousingcovertoaccesstheRS-485terminalconnections.

3.Toconnectdirectlytothetransmitter,connecttheleadsonyoursignalconvertertoterminals26 (RS-485/A)and27(RS-485/B)onyourtransmitter.SeeFigure3-8.

ConfigurationandUseManual

Page 44

QuickstartwithProLinkII

Tip

Usually,butnotalways,theblackleadisRS-485/AandtheredleadisRS-485/B.

Figure3-8ProLinkIIconnectiontotransmitterterminals

APC

B25-to-9pinadapter,ifnecessary

CRS-485toRS-232signalconverter

DTransmitter

4.ToconnecttoapointinRS-485network,connecttheleadsonyoursignalconvertertoanypointin thenetworkandaddresistanceasnecessary.SeeFigure3-9.

Restriction

TheModbushostmustnotbecommunicatingwiththetransmitterwhenyoumaketheProLinkII connection.T omaketheconnection,waituntilthehostcommunicationiscomplete,orterminate thehostconnection.

MicroMotion9739MVDTransmitters

Page 45

Figure3-9ProLinkIIconnectiontoRS-485network

APC

B25-to-9pinadapter,ifnecessary

CRS-485toRS-232signalconverter

D120-Ω,1/2-wattterminatingresistorsatbothendsofthesegment,ifnecessary

EDCSorPLC(mustnotbecommunicatingwiththetransmitterduringtheProLinkIIconnection)

FTransmitter

QuickstartwithProLinkII

5.StartProLinkII.

6.ChooseConnection→ConnecttoDevice.

7.Ifnecessary,settheconnectionparameterstomatchtheModbus/RS-485parameterscongured inyourtransmitter.

Tominimizecongurationrequirements,thetransmitterusesanauto-detectionschemewhen respondingtoaconnectionrequest.Thetransmitterwillacceptallconnectionrequestswithinthe auto-detectionlimits(seeT able3-2).

Table3-2Auto-detectionlimits

ParameterOption

Protocol

AddressRespondsto:

Baudrate

Stopbits

Parity

HART,ModbusASCII,ModbusRTU

•Serviceportaddress(11 1)

•ConguredHARTAddress(default=0)

•ConguredModbusAddress(default=1)

Standardratesbetween1200and38,400

0,1

Even,Odd,None

ConfigurationandUseManual

Page 46

QuickstartwithProLinkII

Tip

Ifyoudonotknowthetransmitter’sRS-485communicationsettings,youcanconnectthroughthe serviceport,whichalwaysusesdefaultsettings,oruseanothercommunicationstooltoviewor changethesettings.

8.SettheCOMPortvaluetothePCCOMportthatyouareusingforthisconnection.

9.ClickConnect.

Iftheconnectionissuccessful:

•Thestatusbarinthemainwindowisupdatedtoshowanactiveconnection.

•TheProcessVariableswindoworCommissioningWizardwindowisdisplayed.

Ifanerrormessageappears:

•Switchtheleadsandtryagain.

•EnsurethatyouareusingthecorrectCOMport.

•CheckthephysicalconnectionbetweenthePCandthetransmitter.

•Forlong-distancecommunication,orifnoisefromanexternalsourceinterfereswiththe signal,install120-Ω½-Wterminatingresistorsinparallelwiththeoutputatbothendsofthe communicationsegment.

3.3Configurationtipsandtricks

Reviewthesetipsbeforebeginningconguration.

3.3.1HARTsecurity

HARTsecuritymaybeenabledonthe9739MVDtransmitter.T ocongurethetransmitterusingHART protocol,youmustdisableHARTsecurity.

3.3.2Defaultvaluesandranges

DefaultvaluesandrangesforthemostcommonlyusedparametersareprovidedinAppendixA.

3.3.3Restorethefactoryconfiguration

Restoringthefactorycongurationreturnsthetransmittertoaknownoperationalconguration.

Procedure

1.MakeaconnectionfromProLinkIItoyourtransmitter.

2.ChooseProLink→Conguration→Device→RestoreFactoryConguration.

3.IntheCongurationwindow,clicktheDevicetab.

40MicroMotion9739MVDTransmitters

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QuickstartwithProLinkII

4.ClickRestoreFactoryConguration.

5.ClickOK.

3.4ConfiguretheprimarymAoutputtoreportmassflow rateinauser-selectedmeasurementunit

ThisprocedureshowsyouhowtoperformthesetasksusingProLinkII.Forallothercongurationtasks, includingotheroptionsforthemAoutput,seethecongurationsectionsofthismanual.

Note

Thisprocedureassumesthatyouarestartingfromthefactory-defaultconguration.

Procedure

1.StartProLinkIIandconnecttoyourtransmitter.

2.Setthemeasurementunitformassowrate.

a.ChooseProLink→Conguration.

b.IntheCongurationwindow,clicktheFlowtab.

c.SelectameasurementunitfromtheMassFlowUnitslist,thenclickApply.

3.CongurethemAoutput.

a.IntheCongurationwindow,clicktheAnalogOutputtab.

b.SelectMassFlowRatefromthePrimaryV ariableIslist.

c.EnterappropriatevaluesforLowerRangeValue(LRV)andUpperRangeValue(URV).

LowerRangeValuespeciesthevalueofMassFlowRatetoberepresentedbyanoutputlevelof 0mAor4mA. anoutputlevelof20mA.

4.ClickOKtoapplythechangesandclosetheCongurationwindow.

5.(Optional)ChooseProLink→OutputLevelsandobservethemAoutputreading.

Itshouldvarybetween0mAor4mAand20mAaccordingtothemassowrateofyourprocess.

UpperRangeValuespeciesthevalueofMassFlowRatetoberepresentedby

3.5Performalooptest

9739MVDTransmitterProLink→Test→FixMilliamp1

ProLink→Test→FixMilliamp2 ProLink→Test→FixFreqOut ProLink→Test→FixDiscreteOut ProLink→Test→ReadDiscreteInput ProLink→Test→ReadMilliampInput

Alooptestisawaytoverifythatthetransmitterandthereceivingdevicearecommunicatingproperly.A looptestalsohelpsyouknowwhetheryouneedtotrimmAoutputs.

Alooptestisawaytoverifythatthetransmitterandthereceivingdevicearecommunicatingproperly. AlooptestalsohelpsyouknowwhetheryouneedtotrimmAoutputs.Performingalooptestisnot

ConfigurationandUseManual

Page 48

QuickstartwithProLinkII

arequiredprocedure.However,MicroMotionrecommendsperformingalooptestforeveryinputor outputavailableonyourtransmitter.

Procedure

1.TestthemAoutput.

a.ChooseProLink→Test→FixMilliamp1.

b.Enter0mAor4mAinSetOutputTo.ClickFixmA.

c.ReadthemAcurrentatthereceivingdeviceandcompareittothetransmitteroutput.

Thereadingsdonotneedtomatchexactly .Ifthevaluesareslightlydifferent,youcancorrect thediscrepancybytrimmingtheoutput.

d.ClickUnFixmA.

e.Enter20mAinSetOutputT o.ClickFixmA.

f.ReadthemAcurrentatthereceivingdeviceandcompareittothetransmitteroutput.

Thereadingsdonotneedtomatchexactly .Ifthevaluesareslightlydifferent,youcancorrect thediscrepancybytrimmingtheoutput.

g.ClickUnFixmA.

2.TestthesecondarymAoutput.

ChooseProLink→Test→FixMillamp2,andrepeatthelooptestforthesecondarymAoutput.

3.Testthefrequencyoutput.

Note

IftheWeights&Measuresapplicationisenabledonthetransmitter,itisnotpossibletoperforma looptestofthefrequencyoutput,evenwhenthetransmitterisunsecured.

a.ChooseProLink→Test→FixFreqOut.

b.EnterthefrequencyoutputvalueinSetOutputTo.ClickFixFrequency.

c.Readthefrequencysignalatthereceivingdeviceandcompareittothetransmitteroutput.

d.ClickUnFixFreq.

4.Testthediscreteoutput.

a.ChooseProLink→Test→FixDiscreteOutput.

b.SelectOn.

c.Verifythesignalstateatthereceivingdevice.

d.ClickUnFix.

e.SelectOff.

f.Verifythesignalstateatthereceivingdevice.

g.ClickUnFix.

5.Readthediscreteinput.

a.Settheremoteinputdevicesothatthedesiredsignalissenttothetransmitter.

b.ChooseProLink→Test→ReadDiscreteInput.

c.Verifythesignalstateatthetransmitter.

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QuickstartwithProLinkII

d.Repeattheprocedurefortheothersignalstate.

6.ReadthemAinput.

a.Settheremoteinputdevicesothatthedesiredsignalissenttothetransmitter.

b.ChooseProLink→Test→ReadMAInput.

Postrequisites

•IfthemAoutputreadingswereslightlyoffatthereceivingdevice,youcancorrectthisdiscrepancy bytrimmingtheoutput.

•IfthemAoutputreadingwassignicantlyoff(±200microamps),orifatanystepthereadingwas faulty,verifythewiringbetweenthetransmitterandtheremotedevice,andtryagain.

•IfthemAinputreadingwasslightlyoffatthetransmitter,trimandcalibratetheinputatthe remoteinputdevice.

3.6TrimmAoutputs

TrimmingthemAoutputestablishesacommonmeasurementrangebetweenthetransmitterandthe devicethatreceivesthemAoutput.

TrimmingthemAoutputsisnotarequiredprocedure.However,ifthereisasmalldiscrepancyinthemA readingbetweenthetransmitterandthereceivingdevice,trimmingtheoutputwillcorrectthis.

Note

Anytrimmingperformedontheoutputshouldnotexceed±200microamps.Ifmoretrimmingisrequired, contactMicroMotioncustomersupport.

Procedure

1.ChooseProLink→Calibration→Milliamp1TrimtostartthemAtrimprocedure.

2.FollowtheinstructionsintheguidedmethodtotrimthemAoutput.

3.ChooseProLink→Calibration→Milliamp2TrimtostartthetrimprocedureforthesecondarymAoutput.

4.FollowtheinstructionsintheguidedmethodtotrimthemAoutput.

3.7Zerotheflowmeter

Prerequisites

Toprepareforthezeroprocedure:

1.Allowtheowmetertowarmupforatleast20minutesafterapplyingpower.

2.Runtheprocessuidthroughthesensoruntilthesensortemperaturereachesthenormalprocess operatingtemperature.

3.Stopowthroughthesensorbyshuttingavalvedownstreamfromthesensor .

4.Ensurethatowhascompletelystoppedthroughthesensor,andthatthesensoriscompletely fullofprocessuid.

5.Checktheowrate.Iftheowrateisclosetozero,youshouldnotneedtozerotheowmeter.

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Important

Themeterwaszeroedatthefactory,andshouldnotrequireaeldzero.

Note

Donotzerotheowmeterifahigh-severityalarmisactive.Correcttheproblem,thenzerothe owmeter.Youmayzerotheowmeterifalow-severityalarmisactive.

Procedure

1.ChooseProLink→Calibration→ZeroCalibration.

2.ModifyZeroTime,ifrequired.

ZeroTimecontrolstheamountoftimethetransmittertakestodetermineitszero-owreferencepoint.

•Alongzerotimemayproduceamoreaccuratezeroreference,butismorelikelytoresultin

azerofailure.Thisisduetotheincreasedpossibilityofnoisyow,whichcausesincorrect calibration.

•Ashortzerotimeislesslikelytoresultinazerofailurebutmayproducealessaccuratezero

reference.

ThedefaultZeroTimeis20seconds.Formostapplications,thedefaultZeroTimeisappropriate.

3.ClickPerformAutoZerotoinitiatethezeroprocedure.

TheCalibrationinProgresslightwillturnredduringthezeroprocedure.Attheendoftheprocedure:

•TheCalibrationinProgresslightwillreturntogreenifthezerowassuccessful.

•TheCalibrationFailurelightwillturnredifthezeroprocedurefailed.

4.Incaseoffailure,youhavetwooptions:

OptionDescription

RestorePriorZeroRestorePriorZerorestorestheowmetertothe

zerovalueithadjustpriortostartingthezero procedure.IfyouclosetheFlowCalibration window,youwillnolongerbeabletorestore thepriorzero.

RestoreFactoryZeroRestoreFactoryZeroisavailableonlyifyou

orderedatransmitterandasensortogether.

3.8Testortunethesystemusingsensorsimulation

Sensorsimulationallowsyoutosetspecicvaluesorvaluerangesformassow,density,and temperature.Thetransmitterwillreportthespeciedvaluesandtakeallappropriateactions,e.g.,apply acutoff,activateanevent,orpostanalarm.Y oucanusethisfeaturetotestthesystem’sresponsetoa varietyofprocessconditions,includingboundaryconditions,problemconditions,oralarmconditions,or totunetheloop.

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Whenyouenablesensorsimulation,thesimulatedvaluesarestoredinthesamememorylocations usedforprocessdatafromthesensor.Therefore,thesimulatedvalueswillbeusedthroughout transmitterfunctioning.Forexample,sensorsimulationwillaffect:

•Allmassow,temperature,ordensityvaluesshownonthedisplayorreportedviaoutputs ordigitalcommunications

•Themasstotalandmassinventoryvalues

•Allvolumecalculationsanddata,includingreportedvalues,volumetotals,andvolumeinventories

•Allmass,temperature,density,orvolumevaluesloggedtoDataLogger

Sensorsimulationdoesnotaffectanydiagnosticvalues.

Unlikeactualmassowanddensityvalues,thesimulatedvaluesarenottemperature-compensated (adjustedfortheeffectoftemperatureonthesensor’sowtubes).

Important

Donotenablesensorsimulationunlessyourprocesscantoleratetheeffectsofthesimulatedprocess values.

Procedure

1.ClickProLink→Conguration→SensorSimulation.

2.Enablesensorsimulation.

3.Formassow,setWaveFormasdesiredandentertherequiredvalues.

OptionRequiredvalues

Fixed

Sawtooth

Sine

4.Fordensity,setWaveFormasdesiredandentertherequiredvalues.

FixedValue

Period

Minimum

Maximum

Period

Minimum

Maximum

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OptionRequiredvalues

Fixedvalue

Triangularwave

Sinewave

5.Fortemperature,setWaveFormasdesiredandentertherequiredvalues.

OptionRequiredvalues

Fixedvalue

Triangularwave

FixedValue

Period

Minimum

Maximum

Period

Minimum

Maximum

FixedValue

Period

Minimum

Maximum

Sinewave

6.Observethesystemresponsetothesimulatedvaluesandmakeanyappropriatechangesto thetransmittercongurationortothesystem.

7.Modifythesimulatedvaluesandrepeat.

8.Whenyouhavenishedtestingortuning,disablesensorsimulation.

Period

Minimum

Maximum

3.9Backuptransmitterconfiguration

ProLinkIIprovidesacongurationupload/downloadfunctionwhichallowsyoutosaveconguration setstoyourPC.Thisallowsyoutobackupandrestoreyourtransmitterconguration,andisalsoa convenientwaytoreplicateacongurationacrossmultipledevices.

Procedure

ChooseFile→LoadfromXmtrtoFiletosavethetransmittercongurationtoyourPC.

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3.10Enable/disableHARTsecurity

YouusetheHARTsecurityswitchlocatedonthetransmitterdisplaytodisablecongurationofthe transmitterusingHARTprotocol.WhentheHARTsecurityswitchissettoON,HARTprotocolcannotbe usedtoperformanyactionthatrequireswritingtothetransmitter.Forexample,youcannotchange theconguration,resettotalizers,performcalibration,etc.,usingthe withaHART/Bell202orHART/RS-485connection.WhentheHARTsecurityswitchissettoOFF,no functionsaredisabled.

Important

TheHARTsecurityswitchdoesnotaffectModbuscommunications.

Ifthetransmitterisinahazardousarea,donotremovethehousingcoverwhilepower isbeingsuppliedtotheunit.Removingthehousingcoverwhilepowerissuppliedto theunitcouldcauseanexplosion.ToaccesstheHARTsecurityswitchinahazardous environment,besuretoremovepowerfromthetransmitterbeforeremovingthehousing coverandsettingtheHARTsecurityswitch.

FieldCommunicatororProLinkII

Procedure

1.Removepowerfromthetransmitter.

2.Removethetransmitterhousingcover.

3.MovetheHARTsecurityswitchtothedesiredposition(seeFigure3-10).

Figure3-10HARTsecurityswitch(onblankdisplay)

AHARTsecurityswitch

BUnused

4.Replacethetransmitterhousingcover.

5.Restorepowertothetransmitter.

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Page 55

Chapter4

QuickstartwiththeFieldCommunicator

Topicscoveredinthischapter:

♦Applypower ♦Connectwiththe ♦Congurationtipsandtricks ♦ConguretheprimarymAoutputtoreportmassowrateinauser-selected

measurementunit ♦Performalooptest ♦TrimmAoutputs ♦Zerotheowmeter ♦T estortunethesystemusingsensorsimulation ♦Enable/disableHARTsecurity

4.1Applypower

Prerequisites

Beforeyouapplypowertotheowmeter,closeandtightenallhousingcovers.

FieldCommunicator

Topreventignitionofammableorcombustibleatmospheres,makesureallcoversare tightlyclosed.Forhazardousareainstallations,applyingpowertotheunitwhilehousing coversareremovedorloosecancauseanexplosion.

Procedure

Turnontheelectricalpoweratthepowersupply.

Theowmeterwillautomaticallyperformdiagnosticroutines.Fortransmitterswithadisplay,thestatus

LEDwillturngreenandbegintoashwhenthestartupdiagnosticsarecomplete.IfthestatusLED

exhibitsdifferentbehavior,analarmconditionispresent.

Postrequisites

Allowtheelectronicstowarmupforapproximately10minutesbeforerelyingonprocessmeasurements.

Althoughthesensorisreadytoreceiveprocessuidshortlyafterpower-up,theelectronicscantakeup

to10minutestowarmupcompletely.

4.2ConnectwiththeFieldCommunicator

Prerequisites

ThefollowingHARTdevicedescription(DD)mustbeinstalledontheFieldCommunicator:DDv2.

AconnectionfromtheFieldCommunicatortoyourtransmitterallowsyoutoreadprocessdata,congure

thetransmitter,andperformmaintenanceandtroubleshootingtasks.

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YoucanconnecttheFieldCommunicatortotheHARTclipsonthetransmitter,toanypointinalocal

HARTloop,ortoanypointinaHARTmultidropnetwork.

Ifthetransmitterisinahazardousarea,donotremovethehousingcoverwhilepoweris beingsuppliedtotheunit.Removingthehousingcoverwhilepowerissuppliedtotheunit couldcauseanexplosion.Toaccesstransmitterinformationinahazardousenvironment, useacommunicationmethodthatdoesnotrequireremovingthetransmitterhousingcover.

Important

IftheHARTsecurityswitchissettoON,HARTprotocolcannotbeusedtoperformanyactionthat

requireswritingtothetransmitter.Forexample,youcannotchangetheconguration,resettotalizers,

orperformcalibrationusingthe

HARTsecurityswitchissettoOFF,nofunctionsaredisabled.

FieldCommunicatororProLinkIIwithaHARTconnection.Whenthe

Procedure

1.ToconnecttotheHARTclips:

a.Removethetransmitterhousingcover.

b.AttachtheleadsfromtheFieldCommunicatortotheHARTclipsonthefaceofthetransmitter

andaddresistanceasnecessary.

TheFieldCommunicatormustbeconnectedacrossaresistanceof250–600Ω.

Tip

HARTconnectionsarepolarity-insensitive.Itdoesnotmatterwhichleadyouattachtowhich terminal.

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Figure4-1FieldCommunicatorconnectiontoHARTclips

AFieldCommunicator

B250–600Ωresistance

CTransmitter

QuickstartwiththeFieldCommunicator

2.ToconnecttoapointinthelocalHARTloop,attachtheleadsfromtheFieldCommunicatortoany pointintheloopandaddresistanceasnecessary.SeeFigure4-2.

The

FieldCommunicatormustbeconnectedacrossaresistanceof250–600Ω.

Figure4-2FieldCommunicatorconnectiontolocalHARTloop

AFieldCommunicator

B250–600Ωresistance

CTransmitterterminals

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3.ToconnecttoapointintheHARTmultidropnetwork,attachtheleadsfromtheFieldCommunicator toanypointonthenetwork.SeeFigure4-3.

Figure4-3FieldCommunicatorconnectiontomultidropnetwork

AFieldCommunicator

B250–600Ωresistance

CDevicesonthenetwork

DMasterdevice

4.TurnontheFieldCommunicatorandwaituntilthemainmenuisdisplayed.

5.Ifyouareconnectingacrossamultidropnetwork:

a.SettheFieldCommunicatortopoll.

Thedevicereturnsalladdressesthatarevalid.

b.EntertheappropriateHARTaddress.

ThedefaultHARTaddressis0.However,formultidropoperation,theHARTaddressmustbe uniqueonthenetwork.

6.(Optional)TonavigatetotheOnlinemenu,pressHARTApplication→2Online.

Mostconguration,maintenance,andtroubleshootingtasksareperformedfromtheOnlinemenu.

Tip

YoumayseemessagesrelatedtotheDDoractivealerts.Presstheappropriatebuttonstoignore themessageandcontinue.

4.3Configurationtipsandtricks

Reviewthesetipsbeforebeginningconguration.

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4.3.1HARTsecurity

HARTsecuritymaybeenabledonthe9739MVDtransmitter.T ocongurethetransmitterusingHART protocol,youmustdisableHARTsecurity.

4.3.2Defaultvaluesandranges

DefaultvaluesandrangesforthemostcommonlyusedparametersareprovidedinAppendixA.

4.4ConfiguretheprimarymAoutputtoreportmassflow rateinauser-selectedmeasurementunit

Note

Thisprocedureassumesthatyouarestartingfromthefactory-defaultconguration.

Procedure

1.MakeaconnectionfromtheFieldCommunicatortoyourtransmitter.

2.NavigatetotheOn-LineMenu.

3.Setthemeasurementunitformassowrate.

a.PressCongure→ManualSetup→Measurements→Flow→MassFlowUnit.

b.Selectthedesiredmeasurementunitfromthelist.

c.PresstheleftarrowuntilyouarereturnedtotheManualSetupmenu.

4.CongurethemAoutput.

a.PressInputs/Outputs→mAOutput1→PrimaryVariable.

b.SelectMassFlowRatefromthelist.

c.PressENTERuntilyouarereturnedtothemAOutput1menu.

d.PressmAOutputSettings.

e.PressPVLRVandenteranappropriatevalueforLowerRangeV alue(LRV).

LowerRangeValuespeciesthevalueofMassFlowRatetoberepresentedbyanoutputlevelof 0mAor4mA.

f.PressENTER.

g.PressPVURVandenteranappropriatevalueforUpperRangeValue(LRV).

UpperRangeValuespeciesthevalueofMassFlowRatetoberepresentedbyanoutputlevel of20mA.

h.PressENTER.

5.(Optional)PressOverview→Shortcuts→Variables→Outputs→Current(mAoutput1)andobservethemA outputreading.

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QuickstartwiththeFieldCommunicator

Itshouldvarybetween0mAor4mAand20mAaccordingtothemassowrateofyourprocess.

4.5Performalooptest

Alooptestisawaytoverifythatthetransmitterandthereceivingdevicearecommunicatingproperly. AlooptestalsohelpsyouknowwhetheryouneedtotrimmAoutputs.Performingalooptestisnot arequiredprocedure.However, outputavailableonyourtransmitter.

Procedure

1.TestthemAoutput.

a.PressServiceTools→Simulate→SimulateOutputs→mAOutputLoopTests,andselect4mA.

b.ReadthemAcurrentatthereceivingdeviceandcompareittothetransmitteroutput.

Thereadingsdonotneedtomatchexactly .Ifthevaluesareslightlydifferent,youcancorrect thediscrepancybytrimmingtheoutput.

c.Select20mA.

MicroMotionrecommendsperformingalooptestforeveryinputor

d.ReadthemAcurrentatthereceivingdeviceandcompareittothetransmitteroutput.

Thereadingsdonotneedtomatchexactly .Ifthevaluesareslightlydifferent,youcancorrect thediscrepancybytrimmingtheoutput.

2.TestthesecondarymAoutput.

PressServiceTools→Maintenance→SimulateOutputs→mAOutput2LoopTest,andrepeattheloop testforthesecondarymAoutput.

3.Testthefrequencyoutput.

Note

IftheWeights&Measuresapplicationisenabledonthetransmitter,itisnotpossibletoperforma looptestofthefrequencyoutput,evenwhenthetransmitterisunsecured.

a.PressServiceTools→Simulate→SimulateOutputs→FrequencyOutputTest,andchoosethe

frequencyoutputlevel.

b.Readthefrequencysignalatthereceivingdeviceandcompareittothetransmitteroutput.

c.ChooseEnd.

4.Testthediscreteoutput.

a.PressServiceTools→Simulate→SimulateOutputs→DiscreteOutputTest.

b.ChooseOff.

c.Verifythesignalstateatthereceivingdevice.

d.ChooseOn.

e.Verifythesignalstateatthereceivingdevice.

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QuickstartwiththeFieldCommunicator

f.ChooseEnd.

Postrequisites

•IfthemAoutputreadingswereslightlyoffatthereceivingdevice,youcancorrectthisdiscrepancy bytrimmingtheoutput.

•IfthemAoutputreadingwassignicantlyoff(±200microamps),orifatanystepthereadingwas faulty,verifythewiringbetweenthetransmitterandtheremotedevice,andtryagain.

•IfthemAinputreadingwasslightlyoffatthetransmitter,trimandcalibratetheinputatthe remoteinputdevice.

4.6TrimmAoutputs

TrimmingthemAoutputsisnotarequiredprocedure.However,ifthereisasmalldiscrepancyinthemA readingbetweenthetransmitterandthereceivingdevice,trimmingtheoutputwillcorrectthis.

Note

Anytrimmingperformedontheoutputshouldnotexceed±200microamps.Ifmoretrimmingisrequired, contactMicroMotioncustomersupport.

Procedure

1.PressServiceTools→Maintenance→RoutineMaintenance→TrimmAoutput1tostartthemAtrim procedure.

2.FollowtheinstructionsintheguidedmethodtotrimthemAoutput.

3.ChooseServiceTools→Maintenance→RoutineMaintenance→TrimmAoutput2tostartthetrimprocedure forthesecondarymAoutput.

4.FollowtheinstructionsintheguidedmethodtotrimthemAoutput.

4.7Zerotheflowmeter

Prerequisites

Toprepareforthezeroprocedure:

1.Allowtheowmetertowarmupforatleast20minutesafterapplyingpower.

2.Runtheprocessuidthroughthesensoruntilthesensortemperaturereachesthenormalprocess operatingtemperature.

3.Stopowthroughthesensorbyshuttingavalvedownstreamfromthesensor .

4.Ensurethatowhascompletelystoppedthroughthesensor,andthatthesensoriscompletely fullofprocessuid.

5.Checktheowrate.Iftheowrateisclosetozero,youshouldnotneedtozerotheowmeter.

Important

Themeterwaszeroedatthefactory,andshouldnotrequireaeldzero.

ConfigurationandUseManual

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QuickstartwiththeFieldCommunicator

Note

Donotzerotheowmeterifahigh-severityalarmisactive.Correcttheproblem,thenzerothe owmeter.Youmayzerotheowmeterifalow-severityalarmisactive.

Procedure

Toinitiatetheowmeterzero,pressServiceTools→Maintenance→ZeroCalibration→PerformAutoZero.

ThedisplaywillreportCalibrationinprogress.Whenthecalibrationiscomplete,thedisplayreportsAutozero completeifthezerowassuccessful,orAutozerofailedifitwasnot.

4.8Testortunethesystemusingsensorsimulation

•Allmassow,temperature,ordensityvaluesshownonthedisplayorreportedviaoutputs ordigitalcommunications

•Themasstotalandmassinventoryvalues

•Allvolumecalculationsanddata,includingreportedvalues,volumetotals,andvolumeinventories

•Allmass,temperature,density,orvolumevaluesloggedtoDataLogger

Sensorsimulationdoesnotaffectanydiagnosticvalues.

Unlikeactualmassowanddensityvalues,thesimulatedvaluesarenottemperature-compensated (adjustedfortheeffectoftemperatureonthesensor’sowtubes).

Important

Donotenablesensorsimulationunlessyourprocesscantoleratetheeffectsofthesimulatedprocess values.

Procedure

1.Navigatetothesensorsimulationmenu:ServiceTools→Simulate→SimulateSensor.

2.Enablesensorsimulation.

3.Formassow,setWaveFormasdesiredandentertherequiredvalues.

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OptionRequiredvalues

QuickstartwiththeFieldCommunicator

Fixed

Sawtooth

SimFixedValue

SimRampLowPoint

SimRampHighPoint

SimRampPeriod

Sine

SimRampLowPoint

SimRampHighPoint

SimRampPeriod

4.Fordensity,setWaveFormasdesiredandentertherequiredvalues.

OptionRequiredvalues

Fixedvalue

Triangularwave

SimFixedValue

SimRampLowPoint

SimRampHighPoint

SimRampPeriod

Sinewave

SimRampLowPoint

SimRampHighPoint

SimRampPeriod

5.Fortemperature,setWaveFormasdesiredandentertherequiredvalues.

OptionRequiredvalues

Fixedvalue

Triangularwave

SimFixedValue

SimRampLowPoint

SimRampHighPoint

SimRampPeriod

Sinewave

SimRampLowPoint

SimRampHighPoint

SimRampPeriod

6.Observethesystemresponsetothesimulatedvaluesandmakeanyappropriatechangesto thetransmittercongurationortothesystem.

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7.Modifythesimulatedvaluesandrepeat.

8.Whenyouhavenishedtestingortuning,disablesensorsimulation.

4.9Enable/disableHARTsecurity

Important

TheHARTsecurityswitchdoesnotaffectModbuscommunications.

Ifthetransmitterisinahazardousarea,donotremovethehousingcoverwhilepower isbeingsuppliedtotheunit.Removingthehousingcoverwhilepowerissuppliedto theunitcouldcauseanexplosion.ToaccesstheHARTsecurityswitchinahazardous environment,besuretoremovepowerfromthetransmitterbeforeremovingthehousing coverandsettingtheHARTsecurityswitch.

FieldCommunicatororProLinkII

Procedure

1.Removepowerfromthetransmitter.

2.Removethetransmitterhousingcover.

3.MovetheHARTsecurityswitchtothedesiredposition(seeFigure4-4).

Figure4-4HARTsecurityswitch(onblankdisplay)

AHARTsecurityswitch

BUnused

4.Replacethetransmitterhousingcover.

5.Restorepowertothetransmitter.

MicroMotion9739MVDTransmitters

Page 65

II II

Referenceinformationfor commissioning

Chapterscoveredinthispart:

♦Congureprocessmeasurement ♦Conguredeviceoptionsandpreferences ♦Integratethemeterwiththecontrolsystem

Page 66

Page 67

Chapter5

Configureprocessmeasurement

Topicscoveredinthischapter:

♦Characterizetheowmeter ♦Conguremassowmeasurement ♦Congurevolumeowmeasurementforliquidapplications ♦Conguregasstandardvolumeowmeasurement ♦CongureFlowDirection ♦Conguredensitymeasurement ♦Conguretemperaturemeasurement ♦Congurepressurecompensation ♦Congurethepetroleummeasurementapplication ♦Conguretheconcentrationmeasurementapplication

5.1Characterizetheflowmeter

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Characterize

ProLink→Conguration→DensityProLink→Conguration→Flow

Characterizingtheowmeteradjuststhetransmitter’smeasurementalgorithmstomatchtheunique traitsofthesensoritispairedwith.Thecharacterizationparameters(alsocalledcalibrationparameters) describethesensor’ssensitivitytoow,density,andtemperature.Dependingonyoursensortype, differentparametersarerequired.Valuesforyoursensorareprovidedby tagorthecalibrationcerticate.

Note

Ifyoursensorandtransmitterwereorderedtogether,thetransmitterhasalreadybeencharacterizedat thefactory.However,youshouldstillverifycharacterizationparameters.

ConfigurationandUseManual

MicroMotiononthesensor

Page 68

Configureprocessmeasurement

Procedure

1.SpecifySensorType.

•Straight-tube(T-Series)

•Curved-tube(allsensorsexceptT-Series)

2.Settheowcharacterizationparameters.Besuretoincludealldecimalpoints.

•Forstraight-tubesensors,setFCF(FlowCalorFlowCalibrationFactor),FTG,andFFQ.

•Forcurved-tubesensors,setFlowCal(FlowCalibrationFactor).

3.Setthedensitycharacterizationparameters.

•Forstraight-tubesensors,setD1,D2,DT,DTG,K1,K2,FD,DFQ1,andDFQ2.

•Forcurved-tubesensors,setD1,D2,TC,K1,K2,andFD.(TCissometimesshownasDT.)

5.1.1Sourcesandformatsforcharacterizationparameters

Differentsensortagsdisplaycharacterizationparametersdifferently,andoldersensorsmaynothaveall therequiredparametersonthetag.

Samplesensortags

Samplesensortagsareshowninthefollowingillustrations:

•Figure5-1:Oldercurved-tubesensors(allsensorsexceptT-Series)

•Figure5-2:Newercurved-tubesensors(allsensorsexceptT-Series)

•Figure5-3:Olderstraight-tubesensors(T-Series)

•Figure5-4:Newerstraight-tubesensors(T-Series)

Figure5-1Tagonoldercurved-tubesensors(allsensorsexceptT-Series)

62MicroMotion9739MVDTransmitters

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Figure5-2Tagonnewercurved-tubesensors(allsensorsexceptT-Series)

Figure5-3Tagonolderstraight-tubesensor(T-Series)

Configureprocessmeasurement

Figure5-4Tagonnewerstraight-tubesensor(T-Series)

ConfigurationandUseManual

Page 70

Configureprocessmeasurement

Densitycalibrationparameters(D1,D2,K1,K2,FD,DT,TC)

IfyoursensortagdoesnotshowaD1orD2value:

•ForD1,entertheDensAorD1valuefromthecalibrationcerticate.Thisvalueistheline-condition densityofthelow-densitycalibrationuid.MicroMotionusesair.IfyoucannotndaDensAor D1value,enter0.001g/cm

•ForD2,entertheDensBorD2valuefromthecalibrationcerticate.Thisvalueistheline-condition densityofthehigh-densitycalibrationuid. orD2value,enter0.998g/cm

IfyoursensortagdoesnotshowaK1orK2value:

•ForK1,entertherst5digitsofthedensitycalibrationfactor.InthesampletaginFigure5-1,this valueisshownas12500.

•ForK2,enterthesecond5digitsofthedensitycalibrationfactor.InthesampletaginFigure5-1, thisvalueisshownas14286.

MicroMotionuseswater.IfyoucannotndaDensB

IfyoursensordoesnotshowanFDvalue,contact

ow.support@emerson.com.

IfyoursensortagdoesnotshowaDTorTCvalue,enterthelast3digitsofthedensitycalibration factor.InthesampletaginFigure5-1,thisvalueisshownas4.44.

Flowcalibrationparameters(FCF,FT)

Twoseparatevaluesareusedtodescribeowcalibration:a6-characterFCFvalueanda4-character FTvalue.Bothvaluescontaindecimalpoints.Duringcharacterization,theseareenteredasasingle 10-characterstringthatincludestwodecimalpoints.ThisparameteriscalledeitherFlowcalorFCF.

IfyoursensortagshowstheFCFandtheFTvaluesseparately ,concatenatethetwovaluestoform thesingleparametervalue.

tExample:ConcatenatingFCFandFT

FCF=x.xxxx FT=y.yy Flowcalibrationparameter:x.xxxxy.yy

5.2Configuremassflowmeasurement

Display

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Flow

OFF-LINEMAINT→OFF-LINECONFG→UNITS→MASS

ProLink→Conguration→Flow

Themassowmeasurementparameterscontrolhowmassowismeasuredandreported.

Themassowmeasurementparametersinclude:

•MassFlowMeasurementUnit

•FlowDamping

•MassFlowCutoff

MicroMotion9739MVDTransmitters

Page 71

5.2.1ConfigureMassFlowMeasurementUnit

Configureprocessmeasurement

Display

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Flow→MassFlowUnit

OFF-LINEMAINT→OFF-LINECONFG→UNITS→MASS

ProLink→Conguration→Flow→MassFlowUnits

MassFlowMeasurementUnitspeciestheunitwillbeusedforthemassowrate.Theunitusedformass totalandmassinventoryisderivedfromthisunit.

Procedure

SetMassFlowMeasurementUnittothedesiredunit.

ThedefaultsettingforMassFlowMeasurementUnitisg/s(gramspersecond).

Tip

Ifthemeasurementunityouwanttouseisnotavailable,youcandeneaspecialmeasurementunit.

OptionsforMassFlowMeasurementUnit

ThetransmitterprovidesastandardsetofmeasurementunitsforMassFlowMeasurementUnit,plusone user-denedspecialmeasurementunit.Differentcommunicationstoolusedifferentlabelsfortheunits.

OptionsforMassFlowMeasurementUnitareshowninTable5-1.

Table5-1OptionsforMassFlowMeasurementUnit

Label

UnitdescriptionDisplayProLinkIIFieldCommunicator

GramspersecondG/Sg/sg/s

GramsperminuteG/MINg/ming/min

GramsperhourG/Hg/hrg/h

Kilogramspersecond

Kilogramsperminute

Kilogramsperhour

Kilogramsperday

Metrictonsperminute

Metrictonsperhour

Metrictonsperday

Poundspersecond

Poundsperminute

Poundsperhour

Poundsperday

Shorttons(2000pounds) perminute

KG/Skg/skg/s

KG/MINkg/minkg/min

KG/Hkg/hrkg/h

KG/Dkg/daykg/d

T/MINmTon/minMetT on/min

T/HmTon/hrMetT on/h

T/DmTon/dayMetT on/d

LB/Slbs/slb/s

LB/MINlbs/minlb/min

LB/Hlbs/hrlb/h

LB/Dlbs/daylb/d

ST/MINsT on/minSTon/min

ConfigurationandUseManual

Page 72

Configureprocessmeasurement

Table5-1OptionsforMassFlowMeasurementUnit

UnitdescriptionDisplayProLinkIIFieldCommunicator

Shorttons(2000pounds) perhour

Shorttons(2000pounds) perday

Longtons(2240pounds) perhour

Longtons(2240pounds) perday

SpecialunitSPECL

ST/HsT on/hrSTon/h

ST/DsT on/dayST on/d

LT/HlTon/hrLT on/h

LT/DlTon/dayLT on/d

continued

Label

special

Defineaspecialmeasurementunitformassflow

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→SpecialUnits→MassSpecialUnits

ProLink→Conguration→SpecialUnits

Spcl

Aspecialmeasurementunitallowsyoutoreportprocessdata,totalizerdata,andinventorydataina unitthatisnothard-codedinthetransmitter.Aspecialmeasurementunitiscalculatedfromanexisting measurementunitusingaconversionfactor.

Restriction

Althoughyoucannotdeneaspecialmeasurementunitusingthedisplay,youcanusethedisplayto selectanexistingspecialmeasurementunitandtoviewprocessdata.

Procedure

1.SpecifyBaseMassUnit.

BaseMassUnitistheexistingmassunitthatthespecialunitwillbebasedon.

2.SpecifyBaseTimeUnit.

BaseTimeUnitistheexistingtimeunitthatthespecialunitwillbebasedon.

3.CalculateMassFlowConversionFactorasfollows:

a.xbaseunits=yspecialunits

b.MassFlowConversionFactor=x/y

4.EnterMassFlowConversionFactor.

5.SetMassFlowLabeltothelabeltobeusedforthemassowunit.

6.SetMassTotalLabeltothelabeltobeusedforthemasstotalandmassinventoryunit.

Thespecialmeasurementunitisstoredinthetransmitter.Youcancongurethetransmittertousethe specialmeasurementunitatanytime.

MicroMotion9739MVDTransmitters

Page 73

tExample:Definingaspecialmeasurementunitformassflow

Youwanttomeasuremassowinouncespersecond.

1.SetBaseMassUnittoPounds(lb).

2.SetBaseTimeUnittoSeconds(sec).

3.CalculateMassFlowConversionFactor:

a.1lb/sec=16oz/sec

b.MassFlowConversionFactor=1/16=0.0625

4.SetMassFlowConversionFactorto0.0625.

5.SetMassFlowLabeltooz/sec.

6.SetMassT otalLabeltooz.

5.2.2ConfigureFlowDamping

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Flow→FlowDamping

ProLink→Conguration→Flow→FlowDamp

Configureprocessmeasurement

Dampingisusedtosmoothoutsmall,rapiductuationsinprocessmeasurement.TheDampingValue speciesthetimeperiod(inseconds)overwhichthetransmitterwillspreadchangesinthereported processvariable.Attheendoftheinterval,thereportedprocessvariablewillreect63%ofthechange intheactualmeasuredvalue.

Tips

•Ahighdampingvaluemakestheprocessvariableappearsmootherbecausethereportedvalue mustchangeslowly .

•Alowdampingvaluemakestheprocessvariableappearmoreerraticbecausethereported valuechangesmorequickly.

Procedure

SetFlowDampingtothedesiredvalue.

Thedefaultvalueis0.8seconds.Therangeis0to10.24seconds.WhenyouenteravalueforFlow

Damping,thetransmitterautomaticallyroundsitdowntothenearestvalidvalue.ThevalidvaluesforFlow Dampingare:0,0.04,0.08,0.16,...10.24.

Tips

Forgasapplications,MicroMotionrecommendssettingFlowDampingto2.56orhigher.

ConfigurationandUseManual

Page 74

Configureprocessmeasurement

EffectofFlowDampingonvolumemeasurement

FlowDampingeffectsvolumemeasurementforbothliquidvolumeandgasstandardvolume.Volumedata

iscalculatedfromthedampedmassowdataratherthanthemeasuredowvalue.

InteractionbetweenFlowDampingandAddedDamping

FlowDampingcontrolstherateofchangeinowprocessvariables.AddedDampingcontrolstherateof changereportedviathemAoutput.IfmAOutputProcessVariableissettoMassFlowRate,andbothFlow DampingandAddedDampingaresettonon-zerovalues,owdampingisappliedrst,andtheadded

dampingcalculationisappliedtotheresultoftherstcalculation.

5.2.3ConfigureMassFlowCutoff

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Flow→MassFlowCutoff

ProLink→Conguration→Flow→MassFlowCutoff

MassFlowCutoffspeciesthelowestmassowratethatwillreportedasmeasured.Allmassowrates belowthiscutoffwillbereportedas0.

Procedure

SetMassFlowCutofftothedesiredvalue.

ThedefaultvalueforMassFlowCutoffis0.0g/s.Therecommendedsettingis0.05%ofthesensor's ratedmaximumowrate.

EffectofMassFlowCutoffonvolumemeasurement

MassFlowCutoffdoesnotaffectvolumemeasurement.Volumedataiscalculatedfromtheactualmass

dataratherthanthereportedvalue.

InteractionbetweenMassFlowCutoffandAOCutoff

MassFlowCutoffaffectsallreportedvaluesandvaluesusedinothertransmitterbehavior(e.g.,events

denedonmassow).

AOCutoffaffectsonlymassowvaluesreportedviathemAoutput.

tExample:Cutoffinteraction

Conguration:

•mAOutputProcessVariablefortheprimarymAoutput:MassFlowRate

•FrequencyOutputProcessVariable:MassFlowRate

•AOCutofffortheprimarymAoutput:10grams/second

•MassFlowCutoff:15grams/second

Result:Ifthemassowratedropsbelow15grams/second,massowwillbereportedas0,and0 willbeusedinallinternalprocessing.

MicroMotion9739MVDTransmitters

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Configureprocessmeasurement

tExample:Cutoffinteraction

Conguration:

•mAOutputProcessVariablefortheprimarymAoutput:MassFlowRate

•FrequencyOutputProcessVariable:MassFlowRate

•AOCutofffortheprimarymAoutput:15grams/second

•MassFlowCutoff:10grams/second

Result:

•Ifthemassowratedropsbelow15grams/secondbutnotbelow10grams/second:

−TheprimarymAoutputwillreportzeroow.

−Thefrequencyoutputwillreporttheactualowrate,andtheactualowratewillbeused inallinternalprocessing.

•Ifthemassowratedropsbelow10grams/second,bothoutputswillreportzeroow,and0will beusedinallinternalprocessing.

5.3Configurevolumeflowmeasurementforliquid applications

Display

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Flow

Thevolumeowmeasurementparameterscontrolhowliquidvolumeowismeasuredandreported.

Thevolumeowmeasurementparametersinclude:

•VolumeFlowType

•VolumeFlowMeasurementUnit

•VolumeFlowCutoff

Restriction

Youcannotimplementbothliquidvolumeowandgasstandardvolumeow.Y oumustchooseoneor theother.

OFF-LINEMAINT→OFF-LINECONFG→UNITS→VOL

ProLink→Conguration→Flow

5.3.1ConfigureVolumeFlowTypeforliquidapplications

Display

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→GasStandardVolume→VolumeFlowType→Liquid

VolumeFlowTypecontrolswhetherliquidorgasstandardvolumeowmeasurementwillbeimplemented.

ConfigurationandUseManual

OFF-LINEMAINT→OFF-LINECONFG→VOL→VOLTYPELIQUID

ProLink→Conguration→Flow→VolFlowType→LiquidVolume

Page 76

Configureprocessmeasurement

Restriction

Ifyouareusingthepetroleummeasurementapplication,youmustsetVolumeFlowTypetoLiquid.Gas standardvolumemeasurementisincompatiblewiththepetroleummeasurementapplication.

Restriction

Ifyouareusingtheconcentrationmeasurementapplication,youmustsetVolumeFlowTypetoLiquid.Gas standardvolumemeasurementisincompatiblewiththeconcentrationmeasurementapplication.

Procedure

SetVolumeFlowTypetoLiquid.

5.3.2ConfigureVolumeFlowMeasurementUnitforliquidapplications

Display

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Flow→VolumeFlowUnit

VolumeFlowMeasurementUnitspeciestheunitwillbeusedforthevolumeowrate.Theunitusedfor thevolumetotalandthevolumeinventoryisderivedfromthisunit.

OFF-LINEMAINT→OFF-LINECONFG→UNITS→VOL

ProLink→Conguration→Flow→VolFlowUnits

Prerequisites

BeforeyoucongureVolumeFlowMeasurementUnit,besurethatVolumeFlowTypeissettoLiquid.

Procedure

SetVolumeFlowMeasurementUnittothedesiredunit.

ThedefaultsettingforVolumeFlowMeasurementUnitisL/s(literspersecond).

Tip

Ifthemeasurementunityouwanttouseisnotavailable,youcandeneaspecialmeasurementunit.

OptionsforVolumeFlowMeasurementUnitforliquidapplications

ThetransmitterprovidesastandardsetofmeasurementunitsforVolumeFlowMeasurementUnit,plusone user-denedspecialmeasurementunit.Differentcommunicationstoolusedifferentlabelsfortheunits.

OptionsforVolumeFlowMeasurementUnitareshowninT able5-2.

70MicroMotion9739MVDTransmitters

Page 77

Table5-2OptionsforVolumeFlowMeasurementUnitforliquidapplications

Label

UnitdescriptionDisplayProLinkIIFieldCommunicator

CubicfeetpersecondCUFT/Sft3/secCuft/s

CubicfeetperminuteCUF/MNft3/minCuft/min

CubicfeetperhourCUFT/Hft3/hrCuft/h

CubicfeetperdayCUFT/Dft3/dayCuft/d

CubicmeterspersecondM3/Sm3/secCum/s

CubicmetersperminuteM3/MINm3/minCum/min

CubicmetersperhourM3/Hm3/hrCum/h

CubicmetersperdayM3/Dm3/dayCum/d

U.S.gallonspersecondUSGPSUSgal/secgal/s

U.S.gallonsperminuteUSGPMUSgal/mingal/min

U.S.gallonsperhourUSGPHUSgal/hrgal/h

U.S.gallonsperdayUSGPDUSgal/dgal/d

MillionU.S.gallonsperdayMILG/DmilUSgal/dayMMgal/d

Literspersecond

Litersperminute

Litersperhour

Millionlitersperday

Imperialgallonsper second

Imperialgallonsperminute

Imperialgallonsperhour

Imperialgallonsperday

Barrelspersecond

Barrelsperminute

Barrelsperhour

Barrelsperday

Beerbarrelspersecond

Beerbarrelsperminute

Beerbarrelsperhour

Beerbarrelsperday

SpecialunitSPECL

L/Sl/secL/s

L/MINl/minL/min

L/Hl/hrL/h

MILL/Dmill/dayML/d

UKGPSImpgal/secImpgal/s

UKGPMImpgal/minImpgal/min

UKGPHImpgal/hrImpgal/h

UKGPDImpgal/dayImpgal/d

BBL/Sbarrels/secbbl/s

BBL/MNbarrels/minbbl/min

BBL/Hbarrels/hrbbl/h

BBL/Dbarrels/daybbl/d

BBBL/SBeerbarrels/secbbbl/s

BBBL/MNBeerbarrels/minbbbl/min

BBBL/HBeerbarrels/hrbbbl/h

BBBL/DBeerbarrels/daybbbl/d

special

Configureprocessmeasurement

Spcl

ConfigurationandUseManual

Page 78

Configureprocessmeasurement

Defineaspecialmeasurementunitforvolumeflow

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→SpecialUnits→VolumeSpecialUnits

Restriction

Althoughyoucannotdeneaspecialmeasurementunitusingthedisplay,youcanusethedisplayto selectanexistingspecialmeasurementunitandtoviewprocessdata.

Procedure

1.SpecifyBaseVolumeUnit.

ProLink→Conguration→SpecialUnits

BaseVolumeUnitistheexistingvolumeunitthatthespecialunitwillbebasedon.

2.SpecifyBaseTimeUnit.

BaseTimeUnitistheexistingtimeunitthatthespecialunitwillbebasedon.

3.CalculateVolumeFlowConversionFactorasfollows:

a.xbaseunits=yspecialunits

b.VolumeFlowConversionFactor=x/y

4.EntertheVolumeFlowConversionFactor.

5.SetVolumeFlowLabeltothelabeltobeusedforthevolumeowunit.

6.SetVolumeTotalLabeltothelabeltobeusedforthevolumetotalandvolumeinventoryunit.

Thespecialmeasurementunitisstoredinthetransmitter.Youcancongurethetransmittertousethe specialmeasurementunitatanytime.

tExample:Definingaspecialmeasurementunitforvolumeflow

Youwanttomeasurevolumeowinpintspersecond.

1.SetBaseVolumeUnittoGallons(gal).

2.SetBaseTimeUnittoSeconds(sec).

3.Calculatetheconversionfactor:

a.1gal/sec=8pints/sec

b.VolumeFlowConversionFactor=1/8=0.1250

4.SetVolumeFlowConversionFactorto0.1250.

5.SetVolumeFlowLabeltopints/sec.

6.SetVolumeTotalLabeltopints.

72MicroMotion9739MVDTransmitters

Page 79

Configureprocessmeasurement

5.3.3ConfigureVolumeFlowCutoff

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Flow→VolumeFlowCutoff

VolumeFlowCutoffspeciesthelowestvolumeowratethatwillreportedasmeasured.Allvolume owratesbelowthiscutoffwillbereportedas0.

Procedure

SetVolumeFlowCutofftothedesiredvalue.

ThedefaultvalueforVolumeFlowCutoffis0.0L/s.Thelowerlimitis0.Theupperlimitisthesensor’sow calibrationfactor,inunitsofL/s,multipliedby0.2.

InteractionbetweenVolumeFlowCutoffandAOCutoff

VolumeFlowCutoffdenesthelowestliquidvolumeowvaluethatthetransmitterwillreportasmeasured. AOCutoffdenesthelowestowratethatwillbereportedviathemAoutput.IfmAOutputProcessVariableis

settoVolumeFlowRate,thevolumeowratereportedviathemAoutputiscontrolledbythehigherof thetwocutoffvalues.

ProLink→Conguration→Flow→VolFlowCutoff

VolumeFlowCutoffaffectsbothvolumeowvaluesreportedviaoutputsandvolumeowvaluesusedin othertransmitterbehavior(e.g.,eventsdenedonvolumeow).

AOCutoffaffectsonlyowvaluesreportedviathemAoutput.

tExample:CutoffinteractionwithAOCutofflowerthanVolumeFlowCutoff

Conguration:

•mAOutputProcessVariablefortheprimarymAoutput:VolumeFlowRate

•FrequencyOutputProcessVariable:VolumeFlowRate

•AOCutofffortheprimarymAoutput:10liters/second

•VolumeFlowCutoff:15liters/second

Result:Ifthemassowratedropsbelow15liters/second,volumeowwillbereportedas0,and0 willbeusedinallinternalprocessing.

tExample:CutoffinteractionwithAOCutoffhigherthanVolumeFlowCutoff

Conguration:

•mAOutputProcessVariablefortheprimarymAoutput:VolumeFlowRate

•FrequencyOutputProcessVariable:VolumeFlowRate

•AOCutofffortheprimarymAoutput:15liters/second

•VolumeFlowCutoff:10liters/second

ConfigurationandUseManual

Page 80

Configureprocessmeasurement

Result:

•Ifthevolumeowratedropsbelow15liters/secondbutnotbelow10liters/second:

−TheprimarymAoutputwillreportzeroow.

−Thefrequencyoutputwillreporttheactualowrate,andtheactualowratewillbeused inallinternalprocessing.

•Ifthevolumeowratedropsbelow10liters/second,bothoutputswillreportzeroow,and0will beusedinallinternalprocessing.

5.4Configuregasstandardvolumeflowmeasurement

Display

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→GasStandardVolume

OFF-LINEMAINT→OFF-LINECONFG→VOL→VOLTYPEGAS

ProLink→Conguration→Flow→VolFlowType

Thegasstandardvolumeowmeasurementparameterscontrolhowgasstandardvolumeowis measuredandreported.

Thegasstandardvolumeowmeasurementparametersinclude:

•VolumeFlowType

•StandardGasDensity

•GasStandardVolumeFlowMeasurementUnit

•GasStandardVolumeFlowCutoff

Restriction

Youcannotimplementbothliquidvolumeowandgasstandardvolumeow.Y oumustchooseoneor theother.

5.4.1ConfigureVolumeFlowTypeforgasapplications

Display

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→GasStandardVolume→V olumeFlowType→GSV

OFF-LINEMAINT→OFF-LINECONFG→VOL→VOLTYPEGAS

ProLink→Conguration→Flow→VolFlowType→StdGasVolume

VolumeFlowTypecontrolswhetherliquidorgasstandardvolumeowmeasurementwillbeimplemented.

Restriction

Ifyouareusingthepetroleummeasurementapplication,youmustsetVolumeFlowTypetoLiquid.Gas standardvolumemeasurementisincompatiblewiththepetroleummeasurementapplication.

MicroMotion9739MVDTransmitters

Page 81

Configureprocessmeasurement

Restriction

Ifyouareusingtheconcentrationmeasurementapplication,youmustsetVolumeFlowTypetoLiquid.Gas standardvolumemeasurementisincompatiblewiththeconcentrationmeasurementapplication.

Procedure

SetVolumeFlowTypetoGasStandardVolume.

5.4.2ConfigureStandardGasDensity

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→GasStandardVolume→GasDensity

StandardGasDensityisusedtoconvertthemeasuredowdatatoreference(standard)values.

Prerequisites

ProLink→Conguration→Flow→StdGasDensity

EnsurethatDensityMeasurementUnitissettotheunitsyouwilluseforStandardGasDensity.

Procedure

EntertheappropriateStandardGasDensityvalueforthegasyouaremeasuring.

Tip

ProLinkIIprovidesaGasWizardthatyoucanusetocalculatethestandarddensityofyourgas,ifyou donotknowit.

5.4.3ConfigureGasStandardVolumeFlowMeasurementUnit

Display

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→GasStandardVolume→GasVolFlowUnit

GasStandardVolumeFlowMeasurementUnitspeciestheunitwillbeusedforthegasstandardvolume owrate.Theunitusedforthegasstandardvolumetotalandthegasstandardvolumeinventoryis derivedfromthisunit.

Prerequisites

OFF-LINEMAINT→OFF-LINECONFG→UNITS→VOL

ProLink→Conguration→Flow→StdGasVolFlowUnits

BeforeyoucongureGasStandardVolumeFlowMeasurementUnit,besurethatVolumeFlowTypeissettoGas StandardVolume.

Procedure

SetGasStandardVolumeFlowMeasurementUnittothedesiredunit.

ThedefaultsettingforGasStandardVolumeFlowMeasurementUnitisSCFM(standardcubicfeetperminute).

ConfigurationandUseManual

Page 82

Configureprocessmeasurement

Tip

Ifthemeasurementunityouwanttouseisnotavailable,youcandeneaspecialmeasurementunit.

OptionsforGasStandardVolumeFlowMeasurementUnit

ThetransmitterprovidesastandardsetofmeasurementunitsforGasStandardVolumeFlowMeasurement Unit,plusoneuser-denedspecialmeasurementunit.Differentcommunicationstoolusedifferent

labelsfortheunits.

OptionsforGasStandardVolumeFlowMeasurementUnitareshowninTable5-3.

Table5-3OptionsforGasStandardVolumeMeasurementUnit

Label

UnitdescriptionDisplayProLinkIIFieldCommunicator

Normalcubicmetersper second

Normalcubicmetersper minute

Normalcubicmetersper hour

Normalcubicmetersper day

Normalliterpersecond

NormalliterperminuteNLPMNLPMNotavailable

NormalliterperhourNLPHNLPHNotavailable

NormalliterperdayNLPDNLPDNotavailable

Standardcubicfeetper second

Standardcubicfeetper minute

Standardcubicfeetper hour

Standardcubicfeetper day

Standardcubicmetersper second

Standardcubicmetersper minute

Standardcubicmetersper hour

Standardcubicmetersper day

StandardliterpersecondSLPSSLPS

StandardliterperminuteSLPMSLPM

NM3/SNm3/sec

NM3/MNNm3/min

NM3/HNm3/hr

NM3/DNm3/day

NLPSNLPS

SCFSSCFS

SCFMSCFM

SCFHSCFH

SCFDSCFD

SM3/SSm3/S

SM3/MNSm3/min

SM3/HSm3/hr

SM3/DSm3/day

Notavailable

MicroMotion9739MVDTransmitters

Page 83

Configureprocessmeasurement

Table5-3OptionsforGasStandardVolumeMeasurementUnit

UnitdescriptionDisplayProLinkIIFieldCommunicator

StandardliterperhourSLPHSLPH

StandardliterperdaySLPDSLPD

SpecialmeasurementunitSPECL

continued

Label

Notavailable

special

Spcl

DefineaspecialmeasurementunitforGasStandardVolumeflow

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→SpecialUnits→VolumeSpecialUnits

Restriction

Althoughyoucannotdeneaspecialmeasurementunitusingthedisplay,youcanusethedisplayto selectanexistingspecialmeasurementunitandtoviewprocessdata.

ProLink→Conguration→SpecialUnits

Procedure

1.SpecifyBaseGasStandardVolumeUnit.

BaseGasStandardVolumeUnitistheexistingGasStandardVolumeunitthatthespecialunitwillbe

basedon.

2.SpecifyBaseTimeUnit.

BaseTimeUnitistheexistingtimeunitthatthespecialunitwillbebasedon.

3.CalculateGasStandardVolumeFlowConversionFactorasfollows:

a.xbaseunits=yspecialunits

b.GasStandardVolumeFlowConversionFactor=x/y

4.EntertheGasStandardVolumeFlowConversionFactor.

5.SetGasStandardVolumeFlowLabeltothelabeltobeusedfortheGasStandardVolumeowunit.

6.SetGasStandardVolumeTotalLabeltothelabeltobeusedfortheGasStandardVolumetotaland GasStandardVolumeinventoryunit.

Thespecialmeasurementunitisstoredinthetransmitter.Youcancongurethetransmittertousethe specialmeasurementunitatanytime.

tExample:DefiningaspecialmeasurementunitforGasStandardVolumeflow

YouwanttomeasureGasStandardVolumeowinthousandsofstandardcubicfeetperminute.

1.SettheBaseGasStandardVolumeUnittoSCFM.

ConfigurationandUseManual

Page 84

Configureprocessmeasurement

2.SettheBaseTimeUnittominutes(min).

3.Calculatetheconversionfactor:

a.1thousandsofstandardcubicfeetperminute=1000cubicfeetperminute

b.GasStandardVolumeFlowConversionFactor=1/1000=0.001

4.SetGasStandardVolumeFlowConversionFactorto0.001.

5.SetGasStandardVolumeFlowLabeltoKSCFM.

6.SetGasStandardVolumeTotalLabeltoKSCF.

5.4.4ConfigureGasStandardVolumeFlowCutoff

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→GasStandardVolume→GSVCutoff

ProLink→Conguration→Flow→StdGasVolFlowCutoff

GasStandardVolumeFlowCutoffspeciesthelowestvolumeowratethatwillreportedasmeasured.All volumeowratesbelowthiscutoffwillbereportedas0.

Procedure

SetVolumeFlowCutofftothedesiredvalue.

ThedefaultvalueforGasStandardVolumeFlowCutoffis0.0.Thelowerlimitis0.0.Thereisnoupperlimit.

InteractionbetweenGasStandardVolumeFlowCutoffandAOCutoff

GasStandardVolumeFlowCutoffdenesthelowestGasStandardVolumeowvaluethatthetransmitterwill reportasmeasured.AOCutoffdenesthelowestowratethatwillbereportedviathemAoutput.If mAOutputProcessV ariableissettoGasStandardVolumeFlowRate,thevolumeowratereportedviathemA

outputiscontrolledbythehigherofthetwocutoffvalues.

GasStandardVolumeFlowCutoffaffectsbothgasstandardvolumeowvaluesreportedviaoutputsand gasstandardvolumeowvaluesusedinothertransmitterbehavior(e.g.,eventsdenedongas standardvolumeow).

AOCutoffaffectsonlyowvaluesreportedviathemAoutput.

tExample:CutoffinteractionwithAOCutofflowerthanGasStandardVolumeFlowCutoff

Conguration:

•mAOutputProcessVariablefortheprimarymAoutput:GasStandardVolumeFlowRate

•FrequencyOutputProcessVariable:GasStandardVolumeFlowRate

•AOCutofffortheprimarymAoutput:10SLPM(standardlitersperminute)

•GasStandardVolumeFlowCutoff:15SLPM

Result:IftheGasStandardVolumeowratedropsbelow15SLPM,volumeowwillbereportedas 0,and0willbeusedinallinternalprocessing.

MicroMotion9739MVDTransmitters

Page 85

Configureprocessmeasurement

tExample:CutoffinteractionwithAOCutoffhigherthanGasStandardVolumeFlowCutoff

Conguration:

•mAOutputProcessVariablefortheprimarymAoutput:GasStandardVolumeFlowRate

•FrequencyOutputProcessVariable:GasStandardVolumeFlowRate

•AOCutofffortheprimarymAoutput:15SLPM(standardlitersperminute)

•GasStandardVolumeFlowCutoff:10SLPM

Result:

•IftheGasStandardVolumeowratedropsbelow15SLPMbutnotbelow10SLPM:

−TheprimarymAoutputwillreportzeroow.

−Thefrequencyoutputwillreporttheactualowrate,andtheactualowratewillbeused inallinternalprocessing.

•IftheGasStandardVolumeowratedropsbelow10SLPM,bothoutputswillreportzeroow, and0willbeusedinallinternalprocessing.

5.5ConfigureFlowDirection

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Flow→FlowDirection

FlowDirectioncontrolshowconditionsofforwardowandreverseowaffectowmeasurementand reporting.

FlowDirectionisdenedwithrespecttotheowarrowonthesensor:

•Forwardow(positiveow)movesinthedirectionoftheowarrowonthesensor.

•Reverseow(negativeow)movesinthedirectionoppositetotheowarrowonthesensor.

Procedure

SetFlowDirectionasdesired.

5.5.1OptionsforFlowDirection

FlowDirectioncontrolshowtheoutputsreportowandhowthetotalizersandinventoriesincrementtotals.

ProLink→Conguration→Flow→FlowDirection

ConfigurationandUseManual

Page 86

Configureprocessmeasurement

Table5-4OptionsforFlowDirection

FlowDirectionsetting

ProLinkIIFieldCommunicator

ForwardForward

ReverseReverse

AbsoluteValueAbsoluteValue

BidirectionalBidirectional

NegateForward

NegateBidirectional

Negate/ForwardOnly

Negate/Bi-directional

5.5.2EffectofFlowDirectionontransmitteroutputsandtotalizers

FlowDirectionandmAoutputs

mAoutputsareaffectedbyFlowDirectiononlyifmAOutputProcessVariableissettoaowvariable.

TheeffectofFlowDirectiononmAoutputsdependontheLowerRangeValueconguredforthemAoutput:

•IfLowerRangeValueissetto0,seeFigure5-5.

•IfLowerRangeValueissettoanegativevalue,seeFigure5-6.

Figure5-5EffectofFlowDirectiononthemAoutput:LowerRangeValue=0

Notes

•LowerRangeValue=0

•UpperRangeValue=x

80MicroMotion9739MVDTransmitters

Page 87

Figure5-6EffectofFlowDirectiononthemAoutput:LowerRangeValue<0

Notes

•LowerRangeValue=−x

•UpperRangeValue=x

Configureprocessmeasurement

tExample:FlowDirection=ForwardandLowerRangeValue=0

Conguration:

•FlowDirection=Forward

•LowerRangeValue=0g/s

•UpperRangeValue=100g/s

Result:

•Underconditionsofreverseoworzeroow,themAoutputis4mA.

•Underconditionsofforwardow,uptoaowrateof100g/s,themAoutputvariesbetween 4mAand20mAinproportiontotheowrate.

•Underconditionsofforwardow,iftheowrateequalsorexceeds100g/s,themAoutputwillbe proportionaltotheowrateupto20.5mA,andwillbelevelat20.5mAathigherowrates.

tExample:FlowDirection=ForwardandLowerRangeValue<0

Conguration:

•FlowDirection=Forward

•LowerRangeValue=−100g/s

•UpperRangeValue=+100g/s

ConfigurationandUseManual

Page 88

Configureprocessmeasurement

Result:

•Underconditionsofzeroow,themAoutputis12mA.

•Underconditionsofforwardow,forowratesbetween0and+100g/s,themAoutputvaries between12mAand20mAinproportionto(theabsolutevalueof)theowrate.

•Underconditionsofforwardow,if(theabsolutevalueof)theowrateequalsorexceeds100g/s, themAoutputisproportionaltotheowrateupto20.5mA,andwillbelevelat20.5mAathigher owrates.

•Underconditionsofreverseow,forowratesbetween0and−100g/s,themAoutputvaries between4mAand12mAininverseproportiontotheabsolutevalueoftheowrate.

•Underconditionsofreverseow,iftheabsolutevalueoftheowrateequalsorexceeds100 g/s,themAoutputisinverselyproportionaltotheowratedownto3.8mA,andwillbelevelat

3.8mAathigherabsolutevalues.

tExample:FlowDirection=Reverse

Conguration:

•FlowDirection=Reverse

•LowerRangeValue=0g/s

•UpperRangeValue=100g/s

Result:

•Underconditionsofforwardoworzeroow,themAoutputis4mA.

•Underconditionsofreverseow,forowratesbetween0and−100g/s,themAoutputlevelvaries between4mAand20mAinproportiontotheabsolutevalueoftheowrate.

•Underconditionsofreverseow,iftheabsolutevalueoftheowrateequalsorexceeds100g/s, themAoutputwillbeproportionaltotheabsolutevalueoftheowrateupto20.5mA,andwill belevelat20.5mAathigherabsolutevalues.

FlowDirectionandfrequencyoutputs

FrequencyoutputsareaffectedbyFlowDirectiononlyifFrequencyOutputProcessVariableissettoaow variable.FrequencyoutputlevelsfordifferentcombinationsofFlowDirectionandactualowdirection areshowninT able5-5.

Table5-5EffectoftheFlowDirectionparameterandactualflowdirectiononfrequencyoutputs

Actualflowdirection

FlowDirectionsettingForwardZeroflowReverse

ForwardHz>00Hz0Hz

Reverse0Hz0HzHz>0

BidirectionalHz>00HzHz>0

AbsoluteV alueHz>00HzHz>0

NegateForwardZero

NegateBidirectionalHz>00HzHz>0

(1)

0HzHz>0

(1)Refertothedigitalcommunicationsstatusbitsforanindicationofwhetherowispositiveornegative.

82MicroMotion9739MVDTransmitters

Page 89

Configureprocessmeasurement

FlowDirectionanddiscreteoutputs

DiscreteoutputsareaffectedbyFlowDirectiononlyifDiscreteOutputSourceissettoFlowDirection.Discrete outputstatesfordifferentcombinationsofFlowDirectionandactualowdirectionareshowninT able5-6.

Table5-6EffectoftheFlowDirectionparameterandactualflowdirectionondiscreteoutputs

Actualflowdirection

FlowDirectionsettingForwardZeroflowReverse

Forward

Reverse

Bidirectional

AbsoluteV alue

NegateForward

NegateBidirectional

OFFOFFON

OFFOFFOFF

ONOFFOFF

FlowDirectionanddigitalcommunications

DigitalcommunicationsvaluesfordifferentcombinationsofFlowDirectionandactualowdirectionare showninT able5-7.

Table5-7EffectoftheFlowDirectionparameterandactualflowdirectiononflowvaluesreported

viadigitalcommunications

Actualflowdirection

FlowDirectionsettingForwardZeroflowReverse

ForwardPositive0Negative

ReversePositive0Negative

BidirectionalPositive0Negative

AbsoluteV aluePositive0Positive

NegateForwardNegative0Positive

NegateBidirectionalNegative0Positive

FlowDirectionandflowtotals

TotalizerandinventorybehaviorsfordifferentcombinationsofFlowDirectionandactualowdirection areshowninT able5-8.

ConfigurationandUseManual

Page 90

Configureprocessmeasurement

Table5-8EffectoftheFlowDirectionparameterandactualflowdirectiononflowtotals

Actualflowdirection

FlowDirectionsettingForwardZeroflowReverse

ForwardTotalsincreaseTotalsdonotchangeTotalsdonotchange

ReverseTotalsdonotchangeTotalsdonotchangeT otalsincrease

BidirectionalTotalsincreaseTotalsdonotchangeT otalsdecrease

AbsoluteV alueTotalsincreaseTotalsdonotchangeT otalsincrease

NegateForwardTotalsdonotchangeTotalsdonotchangeT otalsincrease

NegateBidirectionalT otalsdecreaseTotalsdonotchangeT otalsincrease

5.6Configuredensitymeasurement

Display

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Density

OFF-LINEMAINT→OFF-LINECONFG→UNITS→DENS

ProLink→Conguration→Density

Thedensitymeasurementparameterscontrolhowdensityismeasuredandreported.

Thedensitymeasurementparametersinclude:

•DensityMeasurementUnit

•Theslugowparameters:

−SlugHighLimit

−SlugLowLimit

−SlugDuration

5.6.1ConfigureDensityMeasurementUnit

Display

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Density→DensityUnit

OFF-LINEMAINT→OFF-LINECONFG→UNITS→DENS

ProLink→Conguration→Density→DensityUnits

DensityMeasurementUnitspeciestheunitthatwillbeusedfordensitymeasurement.

Procedure

SetDensityMeasurementUnittothedesiredoption.

ThedefaultsettingforDensityMeasurementUnitisg/cm3(gramspercubiccentimeter).

OptionsforDensityMeasurementUnit

ThetransmitterprovidesastandardsetofunitsforDensityMeasurementUnit.Differentcommunications toolsusedifferentlabels.

OptionsforDensityMeasurementUnitareshowninTable5-9.

MicroMotion9739MVDTransmitters

Page 91

Table5-9OptionsforDensityMeasurementUnit

Label

UnitdescriptionDisplayProLinkIIFieldCommunicator

Specicgravityunit(not temperature-corrected)

Gramspercubic centimeter

GramsperliterG/Lg/lg/L

GramspermilliliterG/mLg/mlg/mL

Kilogramsperliter

Kilogramspercubicmeter

PoundsperU.S.gallonLB/GALlbs/Usgallb/gal

PoundspercubicfootLB/CUFlbs/ft3lb/Cuft

Poundspercubicinch

APIgravityDAPIdegAPIdegAPI

ShorttonpercubicyardST/CUYsT/yd3ST on/Cuyd

SGUSGUSGU

G/CM3g/cm3g/Cucm

KG/Lkg/lkg/L

KG/M3kg/m3kg/Cum

LB/CUIlbs/in3lb/CuIn

Configureprocessmeasurement

5.6.2Configureslugflowparameters

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Density→SlugLowLimit

Theslugowparameterscontrolhowthetransmitterdetectsandreportstwo-phaseow.

Procedure

1.SetSlugLowLimittothelowestdensityvaluethatisconsiderednormalinyourprocess.

Valuesbelowthiswillcausethetransmittertoperformtheconguredslugowaction.Typically, thisvalueisthelowestdensityvalueinthenormalrangeofyourprocess.

Tip

Gasentrainmentcancauseyourprocessdensitytodroptemporarily.T oreducetheoccurrence ofslugowalarmsthatarenotsignicanttoyourprocess,setSlugLowLimitslightlybelowyour expectedlowestprocessdensity.

ProLink→Conguration→Density→SlugHighLimit ProLink→Conguration→Density→SlugLowLimit ProLink→Conguration→Density→SlugDuration

Congure→ManualSetup→Measurements→Density→SlugHighLimit Congure→ManualSetup→Measurements→Density→SlugDuration

YoumustenterSlugLowLimiting/cm measurement.

ThedefaultvalueforSlugLowLimitis0.0g/cm

ConfigurationandUseManual

,evenifanotherunithasbeenconguredfordensity

.Therangeis0.0g/cm

to10.0g/cm

Page 92

Configureprocessmeasurement

2.SetSlugHighLimittothehighestdensityvaluethatisconsiderednormalinyourprocess.

Tip

Toreducetheoccurrenceofslugowalarmsthatarenotsignicanttoyourprocess,setSlugHigh Limitslightlyaboveyourexpectedhighestprocessdensity.

Valuesabovethiswillcausethetransmittertoperformtheconguredslugowaction.Typically , thisvalueisthehighestdensityvalueinthenormalrangeofyourprocess.

YoumustenterSlugHighLimiting/cm

,evenifanotherunithasbeenconguredfordensity

measurement.

ThedefaultvalueforSlugHighLimitis5.0g/cm

.Therangeis0.0g/cm

to10.0g/cm

3.SetSlugDurationtothenumberofsecondsthatthetransmitterwillwaitforaslugowconditionto clearbeforeperformingtheconguredslugowaction.

ThedefaultvalueforSlugDurationis0.0seconds.Therangeis0.0secondsto60.0seconds.

Slugflowdetectionandreporting

Slugowistypicallyusedasanindicatoroftwo-phaseow(gasinaliquidprocessorliquidinagas process).Two-phaseowcancauseavarietyofprocesscontrolissues.Byconguringtheslugow parametersappropriatelyforyourapplication,youcandetectprocessconditionsthatrequirecorrection.

Tip

Todecreasetheoccurrenceofslugowalarms,lowerSlugLowLimitorraiseSlugHighLimit.

AconditionofslugowoccurswheneverthemeasureddensitygoesbelowSlugLowLimitorabove SlugHighLimit.Ifthisoccurs:

•Aslugowalarmispostedtotheactivealarmlog.

•Alloutputsthatareconguredtorepresentowrateholdtheirlast“pre-slugow”valueforthe conguredSlugDuration.

IftheslugowconditionclearsbeforeSlugDurationexpires:

•Outputsthatrepresentowratereverttoreportingactualow.

•Theslugowalarmisdeactivated,butremainsintheactivealarmloguntilitisacknowledged.

IftheslugowconditiondoesnotclearbeforeSlugDurationexpires,outputsthatrepresentowrate reportaowrateof0.

IfSlugDurationissetto0.0seconds,outputsthatrepresentowratewillreportaowrateof0assoonas slugowisdetected.

MicroMotion9739MVDTransmitters

Page 93

Configureprocessmeasurement

5.6.3ConfigureDensityDamping

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Density→DensityDamping

Tips

•Ahighdampingvaluemakestheprocessvariableappearsmootherbecausethereportedvalue mustchangeslowly .

•Alowdampingvaluemakestheprocessvariableappearmoreerraticbecausethereported valuechangesmorequickly.

ProLink→Conguration→Density→DensityDamping

Procedure

SetDensityDampingtothedesiredvalue.

Thedefaultvalueis1.6seconds.Therangeis0to10.24seconds.WhenyouenteravalueforFlow

Damping,thetransmitterautomaticallyroundsitdowntothenearestvalidvalue.ThevalidvaluesforFlow Dampingare:0,0.04,0.08,0.16,...10.24.

EffectofDensityDampingonvolumemeasurement

DensityDampingaffectsliquidvolumemeasurement.DensityDampingdoesnotaffectgasstandardvolume

measurement.

InteractionbetweenDensityDampingandAddedDamping

DensityDampingcontrolstherateofchangeinthedensityprocessvariable.AddedDampingcontrolsthe rateofchangereportedviathemAoutput.IfmAOutputProcessVariableissettoDensity,andbothDensity DampingandAddedDampingaresettonon-zerovalues,densitydampingisappliedrst,andtheadded

dampingcalculationisappliedtotheresultoftherstcalculation.

5.6.4ConfigureDensityCutoff

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Density→DensityCutoff

ProLink→Conguration→Density→LowDensityCutoff

DensityCutoffspeciesthelowestdensityvaluethatwillreportedasmeasured.Alldensityvaluesbelow thiscutoffwillbereportedas0.

ConfigurationandUseManual

Page 94

Configureprocessmeasurement

Procedure

SetDensityCutofftothedesiredvalue.

ThedefaultvalueforDensityCutoffis0.2g/cm

.Therangeis0.0g/cm

to0.5g/cm

EffectofDensityCutoffonvolumemeasurement

DensityCutoffaffectsliquidvolumemeasurement.IfthedensityvaluegoesbelowDensityCutoff,thevolume

owrategoesto0.DensityCutoffdoesnotaffectgasstandardvolumemeasurement.Gasstandard volumevaluesarealwayscalculatedfromthemeasureddensityvalue.

5.7Configuretemperaturemeasurement

Display

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Temperature

OFF-LINEMAINT→OFF-LINECONFG→UNITS→TEMP

ProLink→Conguration→Density→LowDensityCutoff

Thetemperaturemeasurementparameterscontrolhowtemperaturedatafromthesensorisreported. Temperaturedataisusedtocompensateowmeasurementfortheeffectoftemperatureonthesensor tubes.

Thetemperaturemeasurementparametersinclude:

•TemperatureMeasurementUnit

•TemperatureDamping

5.7.1ConfigureTemperatureMeasurementUnit

Display

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Temperature→TemperatureUnit

TemperatureMeasurementUnitspeciestheunitthatwillbeusedfortemperaturemeasurement.

OFF-LINEMAINT→OFF-LINECONFG→UNITS→TEMP

ProLink→Conguration→Temperature→T empUnits

Procedure

SetTemperatureMeasurementUnittothedesiredoption.

ThedefaultsettingisDegreesCelsius.

Tip

IfyouareconguringthemAinputtoreceivetemperaturedatafromanexternalmeasurementdevice, youmustsetthemeasurementunittomatchthetemperaturemeasurementunitattheexternal measurementdevice.

OptionsforT emperatureMeasurementUnit

ThetransmitterprovidesastandardsetofunitsforTemperatureMeasurementUnit.Differentcommunications toolsusedifferentlabels.

MicroMotion9739MVDTransmitters

Page 95

OptionsforTemperatureMeasurementUnitareshowninT able5-10.

Table5-10OptionsforT emperatureMeasurementUnit

Label

DescriptionDisplayProLinkIIFieldCommunicator

DegreesCelsius°CdegCdegC

DegreesFahrenheit

DegreesRankine

Kelvin

°F

°R

°K

degFdegF

degRdegR

degKKelvin

5.7.2ConfigureTemperatureDamping

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→Temperature→TempDamping

ProLink→Conguration→Temperature→T empDamping

Configureprocessmeasurement

Tips

•Ahighdampingvaluemakestheprocessvariableappearsmootherbecausethereportedvalue mustchangeslowly .

•Alowdampingvaluemakestheprocessvariableappearmoreerraticbecausethereported valuechangesmorequickly.

Procedure

EnterthedesiredvalueforTemperatureDamping.

Thedefaultvalueis4.8seconds.Therangeis0.0secondsto38.4seconds.

WhenyouenteravalueforT emperatureDamping,thetransmitterautomaticallyroundsitdowntothe nearestvalidvalue.ValidvaluesforTemperatureDampingare0,0.6,1.2,2.4,4.8,…38.4.

EffectofTemperatureDamping

TemperatureDampingaffectstheresponsespeedfortemperaturecompensation.Temperature

compensationadjustsprocessmeasurementtocompensatefortheeffectoftemperatureonsensor tubestiffness.

ConfigurationandUseManual

Page 96

Configureprocessmeasurement

TemperatureDampingaffectspetroleummeasurementprocessvariablesonlyifthetransmitteriscongured tousetemperaturedatafromthesensor.Ifanexternaltemperaturevalueisusedforpetroleum measurement,TemperatureDampingdoesnotaffectpetroleummeasurementprocessvariables.

TemperatureDampingaffectsconcentrationmeasurementprocessvariablesonlyifthetransmitteris conguredtousetemperaturedatafromthesensor.Ifanexternaltemperaturevalueisusedfor concentrationmeasurement,TemperatureDampingdoesnotaffectconcentrationmeasurementprocess variables.

5.8Configurepressurecompensation

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→ExternalCompensation

Pressurecompensationadjustsprocessmeasurementtocompensateforthepressureeffectonthe sensor’sowtubes.Pressureeffectisdenedasthechangeinthesensor’ssensitivitytoowand densityassociatedwiththedifferencebetweencalibrationpressureandprocesspressure.

ProLink→Conguration→Pressure→PressureCompensation

Tip

Notallsensorsorapplicationsrequirepressurecompensation.Ifyouareuncertainaboutimplementing pressurecompensation,contact

ow.support@emerson.com.

Procedure

1.Enablepressurecompensation.

2.EnterFlowFactorforyoursensor.

FlowFactoristhepercentchangeintheowrateperPSI.FlowFactorforyoursensorisprovidedon thesensorproductdatasheet.Whenenteringthevalue,reversethesign.

Example:Iftheowfactoris0.000004%perPSI,enter−0.000004%perPSI.

3.EnterDensityFactorforyoursensor.

DensityFactoristhechangeinuiddensity,ing/cm thesensorproductdatasheet.Whenenteringthevalue,reversethesign.

Example:Ifthedensityfactoris0.000006g/cm

4.EnterCalibrationPressureforyoursensor.

/PSI.DensityFactorforyoursensorisprovidedon

/PSI,enter−0.000006g/cm3/PSI.

90MicroMotion9739MVDTransmitters

Page 97

Configureprocessmeasurement

CalibrationPressureisthepressureatwhichyoursensorwascalibrated,andthereforedenesthe pressureatwhichtherewillbenopressureeffect.CalibrationPressureforyoursensorisprovidedon thesensorcalibrationsheet.Ifthedataisunavailable,enter20PSI.

5.Decidehowpressuredatawillbeprovidedtothetransmitter,andperformtherequiredsetup.

•Ifyouwillpollanexternalpressuredevice,setuppollingforpressure.

•Ifyouwilluseastaticpressurevalue,setPressureUnitstotheunitsyouareusing,enter ExternalPressure,andensurethatpollingforpressureisdisabled.

•Ifyouwillusedigitalcommunicationsoradirectanalogcurrenttowritepressuredatatothe transmitter,setPressureUnitstotheunitstobeusedandensurethatpollingforpressure isdisabled.Thenensurethattheappropriatevalueiswrittentotransmittermemoryat appropriateintervals.

•Ifyouwilluseanexternalmeasurementdevice,congurethemAinputtoExternalPressure. YoumustalsoenableExternalPressureCompensationandsetthePressureUnitstotheunitssetat theexternalmeasurementdevice.

5.9Configurethepetroleummeasurementapplication

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→PetroleumMeasurement

Thepetroleummeasurementparameterscontrolthevaluesthatwillbeusedinthetransmitter’s petroleummeasurementapplication.

Thepetroleummeasurementparametersinclude:

•APITableType

•ThermalExpansionCoefcient(TEC)(ifrequiredbyAPITableType)

•ReferenceT emperature(ifrequiredbyAPITableType)

Restriction

Thepetroleummeasurementparametersareavailableonlyifthepetroleummeasurementapplicationhas beenpurchasedandisenabledonyourtransmitter.

ProLink→Conguration→APISetup

Procedure

1.SelectAPITableType.

2.IfyousetAPITableTypeto53A,53B,53D,or54C,setReferenceTemperaturetotheappropriatevaluefor yourapplication.Enterthevaluein°C.

3.IfyousetAPIT ableTypeto6C,24C,or54C,setThermalExpansionCoefcienttotheappropriatevalue foryourapplication.

4.(Optional)Setthetemperatureunitconguredonthetransmittertothetemperatureunitusedby yourAPIreferencetable.

ConfigurationandUseManual

Page 98

Configureprocessmeasurement

Tip

AlthoughconguringthetemperatureunittomatchthetemperatureunitsusedbyyourAPI referencetableisnotrequired,

MicroMotionrecommendsit.

5.(Optional)Ifyouwanttousetemperaturedatafromanexternaltemperaturesensor:

a.SetTemperatureSourcetoExternal.

b.Dependingonyourexternalsetup,dooneofthefollowing:

•Setuppollingfortemperature

•Usedigitalcommunicationstowritetemperaturedatatothesensoratappropriateintervals

•CongurethemAinputtoreceivetemperaturedatafromanexternalmeasurementdevice

Youcannowcongureyourtransmittertoreportandhandlepetroleummeasurementprocessvariables inthesamewaythatitreportsandhandlesotherprocessvariables.

5.9.1Petroleummeasurementapplication

ThepetroleummeasurementapplicationenablesCorrectionfortheeffectofTemperatureonvolumeof Liquids(CTL),bycalculatingandapplyingaVolumeCorrectionFactor(VCF)tovolumemeasurement. InternalcalculationsareperformedincompliancewithAmericanPetroleumMeasurement(API) standards.

APIreferencetablesareusedtocontrolhowCTLiscalculated.Y ourselectionofAPIT ableTypespecies thetypeofprocessuidthatthecalculationswillassume,andtheCTLsourcedata,thereference temperature,andthedensityunitthatthecalculationswilluse.DependingonyourselectionofAPIT able Type,youmayormaynotneedtospecifyReferenceT emperatureandThermalExpansionCoefcient.See Table5-11foralistingoftheAPIreferencetablesandrelatedinformation.

Table5-11APIreferencetables,associatedprocessfluids,andassociatedcalculationvalues

Reference

TablenameProcessfluidCTLsourcedata

5DLubricatingoils

Generalizedcrude andJP4

Generalized products

Liquidswitha constantdensity baseorknown thermalexpansion coefcient

Observeddensity andobserved temperature

User-supplied referencedensity(or thermalexpansion coefcient) andobserved temperature

temperatureDensityunit

60°F(noncongurable)

DegreesAPI

Range:0to100

DegreesAPI

Range:0to85

DegreesAPI

Range:−0to+40

DegreesAPI

92MicroMotion9739MVDTransmitters

Page 99

Configureprocessmeasurement

Table5-11APIreferencetables,associatedprocessfluids,andassociatedcalculationvalues

Reference

TablenameProcessfluidCTLsourcedata

23A

23B

23DLubricatingoils

24C

53A

53B

53DLubricatingoils

54C

Generalizedcrude andJP4

Generalized products

Liquidswitha constantdensity baseorknown thermalexpansion coefcient

Generalizedcrude andJP4

Generalized products

Liquidswitha constantdensity baseorknown thermalexpansion coefcient

Observeddensity andobserved temperature

User-supplied referencedensity(or thermalexpansion coefcient) andobserved temperature

Observeddensity andobserved temperature

User-supplied referencedensity(or thermalexpansion coefcient) andobserved temperature

temperatureDensityunit

60°F(noncongurable)

15°C(congurable)

continued

Relativedensity

Range:0.6110to

1.0760

Relativedensity

Range:0.6535to

1.0760

Relativedensity

Range:8520to

1.1640

Relativedensity

Basedensity

Range:610to1075

kg/m

Basedensity

Range:653to1075

kg/m

Basedensity

Range:825to1164

kg/m

Basedensityinkg/m

5.10Configuretheconcentrationmeasurementapplication

DisplayNotavailable

ProLinkII

FieldCommunicatorCongure→ManualSetup→Measurements→ConcentrationMeasurement

Theconcentrationmeasurementparameterscontrolhowthetransmittercalculatesconcentration fromtemperatureanddensitydata.

ConfigurationandUseManual

ProLink→Conguration→CMSetup

Page 100

Configureprocessmeasurement

Theconcentrationmeasurementparametersinclude:

•ActiveCurve

•DerivedVariable

Restriction

Theconcentrationmeasurementparametersareavailableonlyiftheconcentrationmeasurement applicationhasbeenpurchasedandisenabledonyourtransmitter.

Prerequisites

Beforeyoucancongureconcentrationmeasurement:

•Theconcentrationmeasurementapplicationmustbeenabledonyourtransmitter.

•Thecurveyouwanttousemustbeavailableonyourtransmitter.

Note

Curvescanbemadeavailableonyourtransmittereitherbyloadinganexistingcurveorbyconguring anewcurve.Uptosixcurvescanbeavailableonyourtransmitter,butonlyonecanbeused formeasurementatanygiventime.SeeMicroMotionEnhancedDensityApplication:Theory, Conguration,andUseManualforinformationonloadingorconguringacurve.

Procedure

1.Identifythecurveyouwanttouse.

2.SetDensityMeasurementUnittomatchthedensityunitusedbyyourcurve.

3.SetTemperatureMeasurementUnittomatchthetemperatureunitusedbyyourcurve.

4.SetDerivedVariabletooneofthederivedvariablesavailablewithyourcurve.

Tip

SelectaDerivedVariablethatwillprovidetheconcentrationmeasurementprocessvariablesthatyou wanttouse.Ifyouareusingoneofthestandardcurvesfrom MassConc(Dens).Ifyouareusingacustomcurve,seethereferenceinformationforyourcurve.

5.SetActiveCurvetothecurveyouidentiedinStep1.

6.(Optional)Ifyouwanttheconcentrationmeasurementapplicationtousetemperaturedatafroman externaltemperaturesensor:

a.SetTemperatureSourcetoExternal.

b.Setuppollingfortemperature,orcongurethemAinputtoreceivetemperaturedatafrom

anexternalmeasurementdevice.

Youcannowcongureyourtransmittertoreportandhandleconcentrationprocessvariablesinthe samewaythatitreportsandhandlesotherprocessvariables.

MicroMotion,setDerivedVariableto

MicroMotion9739MVDTransmitters

Emerson Micro Motion 9739 MVD Configuration And Use Manual

Specifications and Main Features

Frequently Asked Questions

User Manual

1.1Safetymessages

1.2Obtainversioninformation

1.3Availablecommunicationstools

1.4Additionaldocumentationandresources

1.59739MVDtransmitterconfigurationworksheet

2.1Applypower

2.2Configurationtipsandtricks

2.2.1AccesstoOFFLINEmenu

2.2.2Defaultvaluesandranges

2.4Performalooptest

2.5Zerotheflowmeter

2.5.1Restorefactoryzero

3.1Applypower

3.2ConnectwithProLinkII

3.2.1ProLinkIIconnectiontypes

3.2.2Makeaserviceportconnection

3.2.3MakeaHART/Bell202connection

3.2.4MakeaHART/RS-485connection

3.2.5MakeaModbus/RS-485connection

3.3Configurationtipsandtricks

3.3.1HARTsecurity

3.3.2Defaultvaluesandranges

3.3.3Restorethefactoryconfiguration

3.5Performalooptest

3.6TrimmAoutputs

3.7Zerotheflowmeter

3.8Testortunethesystemusingsensorsimulation

3.9Backuptransmitterconfiguration

3.10Enable/disableHARTsecurity

4.1Applypower

4.2ConnectwiththeFieldCommunicator

4.3Configurationtipsandtricks

4.3.1HARTsecurity

4.3.2Defaultvaluesandranges

4.5Performalooptest

4.6TrimmAoutputs

4.7Zerotheflowmeter

4.8Testortunethesystemusingsensorsimulation

4.9Enable/disableHARTsecurity

5.1Characterizetheflowmeter

5.1.1Sourcesandformatsforcharacterizationparameters

Samplesensortags

Densitycalibrationparameters(D1,D2,K1,K2,FD,DT,TC)

Flowcalibrationparameters(FCF,FT)

5.2Configuremassflowmeasurement

5.2.1ConfigureMassFlowMeasurementUnit

5.2.2ConfigureFlowDamping

5.2.3ConfigureMassFlowCutoff

5.3Configurevolumeflowmeasurementforliquid applications

5.3.1ConfigureVolumeFlowTypeforliquidapplications

5.3.3ConfigureVolumeFlowCutoff

5.4Configuregasstandardvolumeflowmeasurement

5.4.1ConfigureVolumeFlowTypeforgasapplications

5.4.2ConfigureStandardGasDensity

5.4.3ConfigureGasStandardVolumeFlowMeasurementUnit

5.4.4ConfigureGasStandardVolumeFlowCutoff

5.5ConfigureFlowDirection

5.5.1OptionsforFlowDirection

FlowDirectionandmAoutputs

FlowDirectionandfrequencyoutputs

FlowDirectionanddiscreteoutputs

FlowDirectionanddigitalcommunications

FlowDirectionandflowtotals

5.6Configuredensitymeasurement

5.6.1ConfigureDensityMeasurementUnit

5.6.2Configureslugflowparameters

5.6.3ConfigureDensityDamping

5.6.4ConfigureDensityCutoff

5.7Configuretemperaturemeasurement

5.7.1ConfigureTemperatureMeasurementUnit

5.7.2ConfigureTemperatureDamping

5.8Configurepressurecompensation

5.9Configurethepetroleummeasurementapplication

5.9.1Petroleummeasurementapplication

5.10Configuretheconcentrationmeasurementapplication