Emerson 9739 manuel d'utilisation

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Table des matières du manuel d’utilisation

  • Page 1

    Configuration and Use Manual MMI-20016855, Rev A C April 201 3 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 2

    Micro Motion customer service Email • Worldwide: flow.support@emerson.com • Asia-Pacific: APflow.support@emerson.com North and South America Europe and Middle East Asia Pacific United States 800-522-6277 U.K. 0870 240 1978 Australia 800 158 727 Canada +1 303-527-5200 The Netherlands +31 (0) 318 495 555 New Zealand 099 128 804 Mexico +41 (0) 41 [...]

  • Page 3

    Contents Part I Getting Started Chapter 1 Before you begin .............................................................................................................3 1.1 About this manual .........................................................................................................................3 1.2 Transmitter model code ........[...]

  • Page 4

    4.4 Configure Flow Direction ............................................................................................................. 37 4.4.1 Options for Flow Direction ............................................................................................ 38 4.5 Configure density measurement .............................................[...]

  • Page 5

    6.1 Configure the mA output ............................................................................................................ 83 6.1.1 Configure mA Output Process Variable ......................................................................... 84 6.1.2 Configure Lower Range Value (LRV) and Upper Range Value (URV) ......................[...]

  • Page 6

    8.5 Start and stop totalizers and inventories .................................................................................... 137 8.5.1 Start and stop totalizers and inventories using the display .......................................... 138 8.6 Reset totalizers .................................................................................[...]

  • Page 7

    10.25 Check for slug flow (two-phase flow) ......................................................................................... 185 10.26 Check the drive gain .................................................................................................................. 185 10.26.1 Collect drive gain data ...................................[...]

  • Page 8

    Contents vi Micro Motion ® 9739 MVD Transmitters[...]

  • Page 9

    Part I Getting Started Chapters covered in this part: • Before you begin • Quick start Getting Started Configuration and Use Manual 1[...]

  • Page 10

    Getting Started 2 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 11

    1 Before you begin Topics covered in this chapter: • About this manual • Transmitter model code • Communications tools and protocols • Additional documentation and resources 1.1 About this manual This manual provides information to help you configure, commission, use, maintain, and troubleshoot the Micro Motion 9739 MVD transmitter. Importa[...]

  • Page 12

    Communications tools, protocols, and related information (continued) Table 1-1: Communica- tions tool Supported protocols Scope In this manual For more information Field Commu- nicator HART/Bell 202 Complete configuration and commissioning Basic user information. See Appendix C . User manual on Micro Motion web site ( www.micromo- tion.com Tip You [...]

  • Page 13

    2 Quick start Topics covered in this chapter: • Power up the transmitter • Check flowmeter status • Make a startup connection to the transmitter • Characterize the flowmeter (if required) • Verify mass flow measurement • Verify the zero 2.1 Power up the transmitter The transmitter must be powered up for all configuration and commissioni[...]

  • Page 14

    1. Wait approximately 10 seconds for the power-up sequence to complete. Immediately after power-up, the transmitter runs through diagnostic routines and checks for error conditions. During the power-up sequence, Alarm A009 is active. This alarm should clear automatically when the power-up sequence is complete. 2. Check the status LED on the transmi[...]

  • Page 15

    Communications tool Connection type to use Instructions Field Communicator HART Appendix C Postrequisites (Optional) Change the communications parameters to site-specific values. To change the communications parameters using ProLink II: • To change the protocol, baud rate, parity, or stop bits, choose ProLink > Configuration > RS-485 . • [...]

  • Page 16

    2. Set the flow characterization parameters. Be sure to include all decimal points. • For straight-tube sensors, set FCF ( Flow Cal or Flow Calibration Factor ), FTG , and FFQ . • For curved-tube sensors, set Flow Cal ( Flow Calibration Factor ). 3. Set the density characterization parameters. • For straight-tube sensors, set D1 , D2 , DT , D[...]

  • Page 17

    Tag on older straight-tube sensor (T-Series) Figure 2-3: Tag on newer straight-tube sensor (T-Series) Figure 2-4: 2.4.2 Flow calibration parameters (FCF, FT) Two separate values are used to describe flow calibration: a 6-character FCF value and a 4- character FT value. They are provided on the sensor tag. Both values contain decimal points. During [...]

  • Page 18

    Example: Concatenating FCF and FT FCF = x.xxxx FT = y.yy Flow calibration parameter: x.xxxxy.yy Example: Splitting the concatenated Flowcal or FCF value Flow calibration parameter: x.xxxxy.yy FCF = x.xxxx FT = y.yy 2.4.3 Density calibration parameters (D1, D2, K1, K2, FD, DT, TC) Density calibration parameters are typically on the sensor tag and th[...]

  • Page 19

    Postrequisites If the reported mass flow rate is not accurate: • Check the characterization parameters. • Review the troubleshooting suggestions for flow measurement issues. See Section 10.3 . 2.6 Verify the zero Verifying the zero helps you determine if the stored zero value is appropriate to your installation, or if a field zero can improve m[...]

  • Page 20

    d. Verify that the sensor is blocked in, that flow has stopped, and that the sensor is completely full of process fluid. 2. Choose ProLink > Calibration > Zero Verification and Calibration > Verify Zero and wait until the procedure completes. 3. If the zero verification procedure fails: a. Confirm that the sensor is completely blocked in, [...]

  • Page 21

    Terminology used with zero verification and zero calibration (continued) Table 2-2: Term Definition Zero Verification A procedure used to evaluate the stored zero and determine whether or not a field zero can improve measurement accuracy. Quick start Configuration and Use Manual 13[...]

  • Page 22

    Quick start 14 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 23

    Part II Configuration and commissioning Chapters covered in this part: • Introduction to configuration and commissioning • Configure process measurement • Configure device options and preferences • Integrate the meter with the control system • Completing the configuration Configuration and commissioning Configuration and Use Manual 15[...]

  • Page 24

    Configuration and commissioning 16 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 25

    3 Introduction to configuration and commissioning Topics covered in this chapter: • Configuration flowchart • Default values and ranges • Enable access to the off-line menu of the display • Disable write-protection on the transmitter configuration • HART security • Restore the factory configuration 3.1 Configuration flowchart Use the fo[...]

  • Page 26

    Configuration flowchart Figure 3-1: Integrate device with control system Configure device options and preferences Configure process measurement Configure mass flow measurement Configure volume flow meaurement Configure flow direction Configure temperature measurement V olume flow type Liquid Gas Define gas properties Configure display parameters Co[...]

  • Page 27

    3.3 Enable access to the off-line menu of the display Display OFF-LINE MAINT > OFF-LINE CONFG > DISPLAY > OFFLN ProLink II ProLink > Configuration > Display > Display Options > Display Offline Menu Field Communicator Not available Overview By default, access to the off-line menu of the display is enabled. If it is disabled, you[...]

  • Page 28

    3.6 Restore the factory configuration Display Not available ProLink II ProLink > Configuration > Device > Restore Factory Configuration Field Communicator Not available Overview Restoring the factory configuration returns the transmitter to a known operational configuration. This may be useful if you experience problems during configuratio[...]

  • Page 29

    4 Configure process measurement Topics covered in this chapter: • Configure mass flow measurement • Configure volume flow measurement for liquid applications • Configure gas standard volume (GSV) flow measurement • Configure Flow Direction • Configure density measurement • Configure temperature measurement • Configure the petroleum me[...]

  • Page 30

    Tip If the measurement unit you want to use is not available, you can define a special measurement unit. Options for Mass Flow Measurement Unit The transmitter provides a standard set of measurement units for Mass Flow Measurement Unit , plus one user-defined special measurement unit. Different communications tools may use different labels for the [...]

  • Page 31

    Define a special measurement unit for mass flow Display Not available ProLink II ProLink > Configuration > Special Units Field Communicator Configure > Manual Setup > Measurements > Special Units > Mass Special Units Overview A special measurement unit is a user-defined unit of measure that allows you to report process data, total[...]

  • Page 32

    b. Mass Flow Conversion Factor = 1/16 = 0.0625 4. Set Mass Flow Conversion Factor to 0.0625 . 5. Set Mass Flow Label to oz/sec . 6. Set Mass Total Label to oz . 4.1.2 Configure Flow Damping Display Not available ProLink II ProLink > Configuration > Flow > Flow Damp Field Communicator Configure > Manual Setup > Measurements > Flow [...]

  • Page 33

    Interaction between Flow Damping and Added Damping In some circumstances, both Flow Damping and Added Damping are applied to the reported mass flow value. Flow Damping controls the rate of change in flow process variables. Added Damping controls the rate of change reported via the mA output. If mA Output Process Variable is set to Mass Flow Rate , [...]

  • Page 34

    Example: Cutoff interaction with AO Cutoff lower than Mass Flow Cutoff Configuration: • mA Output Process Variable : Mass Flow Rate • Frequency Output Process Variable : Mass Flow Rate • AO Cutoff : 10 g/sec • Mass Flow Cutoff : 15 g/sec Result: If the mass flow rate drops below 15 g/sec, mass flow will be reported as 0, and 0 will be used [...]

  • Page 35

    4.2.1 Configure Volume Flow Type for liquid applications Display OFF-LINE MAINT > OFF-LINE CONFG > VOL > VOL TYPE LIQUID ProLink II ProLink > Configuration > Flow > Vol Flow Type > Liquid Volume Field Communicator Configure > Manual Setup > Measurements > Gas Standard Volume > Volume Flow Type > Liquid Overview V[...]

  • Page 36

    The default setting for Volume Flow Measurement Unit is l/sec (liters per second). Tip If the measurement unit you want to use is not available, you can define a special measurement unit. Options for Volume Flow Measurement Unit for liquid applications The transmitter provides a standard set of measurement units for Volume Flow Measurement Unit , p[...]

  • Page 37

    Options for Volume Flow Measurement Unit for liquid applications (continued) Table 4-2: Unit description Label Display ProLink II ProLink III Field Communica- tor Barrels per minute (1) BBL/MN barrels/min barrels/min bbl/min Barrels per hour (1) BBL/H barrels/hr barrels/hr bbl/h Barrels per day (1) BBL/D barrels/day barrels/day bbl/d Beer barrels p[...]

  • Page 38

    a. x base units = y special units b. Volume Flow Conversion Factor = x/y 4. Enter Volume Flow Conversion Factor . 5. Set Volume Flow Label to the name you want to use for the volume flow unit. 6. Set Volume Total Label to the name you want to use for the volume total and volume inventory unit. The special measurement unit is stored in the transmitt[...]

  • Page 39

    Interaction between Volume Flow Cutoff and AO Cutoff Volume Flow Cutoff defines the lowest liquid volume flow value that the transmitter will report as measured. AO Cutoff defines the lowest flow rate that will be reported via the mA output. If mA Output Process Variable is set to Volume Flow Rate , the volume flow rate reported via the mA output i[...]

  • Page 40

    The GSV flow measurement parameters include: • Volume Flow Type • Standard Gas Density • Gas Standard Volume Flow Measurement Unit • Gas Standard Volume Flow Cutoff Restriction You cannot implement both liquid volume flow and gas standard volume flow at the same time. You must choose one or the other. 4.3.1 Configure Volume Flow Type for ga[...]

  • Page 41

    Note ProLink II and ProLink III provide a guided method that you can use to calculate the standard density of your gas, if you do not know it. 4.3.3 Configure Gas Standard Volume Flow Measurement Unit Display OFF-LINE MAINT > OFF-LINE CONFG > UNITS > VOL ProLink II ProLink > Configuration > Flow > Std Gas Vol Flow Units Field Comm[...]

  • Page 42

    Options for Gas Standard Volume Measurement Unit (continued) Table 4-3: Unit description Label Display ProLink II ProLink III Field Communica- tor Normal cubic meters per hour NM3/H Nm3/hr Nm3/hr Nm3/hr Normal cubic meters per day NM3/D Nm3/day Nm3/day Nm3/day Normal liter per second NLPS NLPS NLPS NLPS Normal liter per minute NLPM NLPM NLPM NLPM N[...]

  • Page 43

    Overview A special measurement unit is a user-defined unit of measure that allows you to report process data, totalizer data, and inventory data in a unit that is not available in the transmitter. A special measurement unit is calculated from an existing measurement unit using a conversion factor. Note Although you cannot define a special measureme[...]

  • Page 44

    4.3.4 Configure Gas Standard Volume Flow Cutoff Display Not available ProLink II ProLink > Configuration > Flow > Std Gas Vol Flow Cutoff Field Communicator Configure > Manual Setup > Measurements > Gas Standard Volume > GSV Cutoff Overview Gas Standard Volume Flow Cutoff specifies the lowest gas standard volume flow rate that [...]

  • Page 45

    Example: Cutoff interaction with AO Cutoff higher than Gas Standard Volume Flow Cutoff Configuration: • mA Output Process Variable for the primary mA output: Gas Standard Volume Flow Rate • Frequency Output Process Variable : Gas Standard Volume Flow Rate • AO Cutoff for the primary mA output: 15 SLPM (standard liters per minute) • Gas Stan[...]

  • Page 46

    4.4.1 Options for Flow Direction Options for Flow Direction Table 4-4: Flow Direction setting Relationship to Flow Direction ar- row on sensor ProLink II ProLink III Field Communicator Forward Forward Forward Appropriate when the Flow Direction arrow is in the same direction as the majority of flow. Reverse Reverse Reverse Appropriate when the Flow[...]

  • Page 47

    Effect of Flow Direction on the mA output: Lower Range Value = 0 Figure 4-1: Flow Direction = Forward mA output -x 0 x Reverse flow Forward flow 20 12 4 Flow Direction = Reverse, Negate Forward mA output -x 0 x Reverse flow Forward flow 20 12 4 Flow Direction = Absolute V alue, Bidirectional, Negate Bidirectional mA output -x 0 x Reverse flow Forwa[...]

  • Page 48

    • Under conditions of reverse flow or zero flow, the mA output is 4 mA. • Under conditions of forward flow, up to a flow rate of 100 g/sec, the mA output varies between 4 mA and 20 mA in proportion to the flow rate. • Under conditions of forward flow, if the flow rate equals or exceeds 100 g/sec, the mA output will be proportional to the flow[...]

  • Page 49

    Effect of Flow Direction on frequency outputs Flow Direction affects how the transmitter reports flow values via the frequency outputs. The frequency outputs are affected by Flow Direction only if Frequency Output Process Variable is set to a flow variable. Effect of the Flow Direction parameter and actual flow direction on frequency outputs Table [...]

  • Page 50

    Effect of the Flow Direction parameter and actual flow direction on flow values reported via digital communications Table 4-7: Flow Direction setting Actual flow direction Forward Zero flow Reverse Forward Positive 0 Negative Reverse Positive 0 Negative Bidirectional Positive 0 Negative Absolute Value Positive (3) 0 Positive Negate Forward Negative[...]

  • Page 51

    4.5.1 Configure Density Measurement Unit Display OFF-LINE MAINT > OFF-LINE CONFG > UNITS > DENS ProLink II ProLink > Configuration > Density > Density Units Field Communicator Configure > Manual Setup > Measurements > Density > Density Unit Overview Density Measurement Unit specifies the units of measure that will be d[...]

  • Page 52

    4.5.2 Configure slug flow parameters Display Not available ProLink II ProLink > Configuration > Density > Slug High Limit ProLink > Configuration > Density > Slug Low Limit ProLink > Configuration > Density > Slug Duration Field Communicator Configure > Manual Setup > Measurements > Density > Slug Low Limit Co[...]

  • Page 53

    The default value for Slug High Limit is 5.0 g/cm 3 . The range is 0.0 to 10.0 g/cm 3 . 3. Set Slug Duration to the number of seconds that the transmitter will wait for a slug flow condition to clear before performing the configured slug flow action. The default value for Slug Duration is 0.0 seconds. The range is 0.0 to 60.0 seconds. Slug flow det[...]

  • Page 54

    Procedure Set Density Damping to the value you want to use. The default value is 1.6 seconds. The range is 0 to 10.24 seconds. Tips • A high damping value makes the process variable appear smoother because the reported value changes slowly. • A low damping value makes the process variable appear more erratic because the reported value changes m[...]

  • Page 55

    Procedure Set Density Cutoff to the value you want to use. The default value for Density Cutoff is 0.2 g/cm 3 . The range is 0.0 g/cm 3 to 0.5 g/cm 3 . Effect of Density Cutoff on volume measurement Density Cutoff affects liquid volume measurement. If the density value goes below Density Cutoff , the volume flow rate is reported as 0. Density Cutof[...]

  • Page 56

    Options for Temperature Measurement Unit The transmitter provides a standard set of units for Temperature Measurement Unit . Different communications tools may use different labels for the units. Options for Temperature Measurement Unit Table 4-10: Unit description Label Display ProLink II ProLink III Field Commu- nicator Degrees Celsius °C degC ?[...]

  • Page 57

    The value you enter is automaticaly rounded down to the nearest valid value. Valid values for Temperature Damping are 0 , 0.6 , 1.2 , 2.4 , 4.8 , … 76.8 . Effect of Temperature Damping on process measurement Temperature Damping affects the response speed for temperature compensation with fluctuating temperatures. Temperature compensation adjusts [...]

  • Page 58

    Option Setup Temperature data from the sensor a. Choose View > Preferences . b. Disable Use External Temperature . A user-configured static temperature value a. Choose View > Preferences . b. Enable Use External Temperature . c. Choose ProLink > Configuration > Temperature . d. Set External Temperature to the value to be used. Polling f[...]

  • Page 59

    3. Determine how the transmitter will obtain temperature data for the petroleum measurement calculations, and perform the required setup. Option Setup Temperature data from the sensor a. Choose Online > Configure > Manual Setup > Measurements > External Pressure/Temperature > Temperature . b. Set External Temperature to Disabled . A [...]

  • Page 60

    API reference tables, associated process fluids, and associated calculation values (continued) Table 4-11: Table name Process fluid CTL source data Reference temperature Density unit 5B Generalized products Observed density and observed temperature 60 °F (non-configurable) Degrees API Range: 0 to 85 5D Lubricating oils Observed density and observe[...]

  • Page 61

    4.8 Configure the concentration measurement application The concentration measurement application calculates concentration data from process temperature and density. Micro Motion provides a set of concentration matrices that provide the reference data for several standard industry applications and process fluids. If desired, you can build a custom [...]

  • Page 62

    4. In Global Config, set Derived Variable to the derived variable that your matrix is designed for. Important • All concentration matrices on your transmitter must use the same derived variable. If you are using one of the standard matrices from Micro Motion, set Derived Variable to Mass Conc (Density) . If you are using a custom matrix, see the [...]

  • Page 63

    Option Setup A user-configured static temperature value a. Choose View > Preferences . b. Enable Use External Temperature . c. Choose ProLink > Configuration > Temperature . d. Set External Temperature to the value to be used. Polling for tempera- ture (6) a. Ensure that the primary mA output has been wired to support HART polling. b. Choo[...]

  • Page 64

    Prerequisites Before you can configure concentration measurement: • The concentration measurement application must be enabled on your transmitter. • You must know the derived variable that your matrix is designed for. • You must know the density unit used by your matrix. • You must know the temperature unit used by your matrix. • The conc[...]

  • Page 65

    Option Setup Temperature data from the sensor a. Choose Online > Configure > Manual Setup > Measurements > External Pressure/Temperature > Temperature . b. Disable External Temperature . A user-configured static temperature value a. Choose Online > Configure > Manual Setup > Measurements > External Pressure/Temperature &g[...]

  • Page 66

    See Table 4-12 for a list of the standard concentration matrices available from Micro Motion, along with the density and temperature measurement units used in calculation, and the unit used to report concentration data. Tip If the standard matrices are not appropriate for your application, you can build a custom matrix or purchase a custom matrix f[...]

  • Page 67

    Derived variables and calculated process variables Table 4-13: Derived Variable Description Calculated process variables Density at reference tempera- ture Standard volume flow rate Specific gravity Concen- tration Net mass flow rate Net vol- ume flow rate Density at reference temperature Mass/unit volume, cor- rected to a given refer- ence tempera[...]

  • Page 68

    Derived variables and calculated process variables (continued) Table 4-13: Derived Variable Description Calculated process variables Density at reference tempera- ture Standard volume flow rate Specific gravity Concen- tration Net mass flow rate Net vol- ume flow rate Concentration de- rived from specific gravity The mass, volume, weight, or number[...]

  • Page 69

    The flow factor is the percent change in the flow rate per PSI. When entering the value, reverse the sign. Example: If the flow factor is 0.000004 % per PSI, enter − 0.000004 % per PSI. 4. Enter Density Factor for your sensor. The density factor is the change in fluid density, in g/cm 3 /PSI. When entering the value, reverse the sign. Example: If[...]

  • Page 70

    Postrequisites If you are receiving pressure data over the mA input, ensure that the mA input is configured for your application. If you are using an external pressure value, verify the setup by choosing ProLink > Process Variables and checking the value displayed in External Pressure . 4.9.2 Configure pressure compensation using the Field Commu[...]

  • Page 71

    Option Setup A user-configured static pressure val- ue a. Set Pressure Unit to the desired unit. b. Set Compensation Pressure to the desired value. Polling for pres- sure (9) a. Ensure that the primary mA output has been wired to support HART polling. b. Choose Online > Configure > Manual Setup > Measurements > External Pressure/Tempera[...]

  • Page 72

    Options for Pressure Measurement Unit (continued) Table 4-14: Unit description Label Display ProLink II ProLink III Field Communica- tor Inches water @ 4 °C INW4C In Water @ 4°C In Water @ 4°C inH2O @4DegC Inches water @ 60 °F INW60 In Water @ 60°F In Water @ 60°F inH2O @60DegF Inches water @ 68 °F INH2O In Water @ 68°F In Water @ 68°F inH[...]

  • Page 73

    5 Configure device options and preferences Topics covered in this chapter: • Configure the transmitter display • Enable or disable operator actions from the display • Configure security for the display menus • Configure response time parameters • Configure alarm handling • Configure informational parameters 5.1 Configure the transmitter[...]

  • Page 74

    5.1.2 Configure the process variables shown on the display Display Not available ProLink II ProLink > Configuration > Display > Display Var X Field Communicator Configure > Manual Setup > Display > Display Variables Overview You can control the process variables shown on the display and the order in which they appear. The display [...]

  • Page 75

    Configure Display Variable 1 to track the primary mA output You can configure Display Variable 1 to track mA Output Process Variable for the primary mA output. When tracking is enabled, you can control Display Variable 1 from the display menu. Tip This feature is the only way to configure a display variable from the display menus, and it applies on[...]

  • Page 76

    5.1.4 Configure the refresh rate of data shown on the display Display OFF-LINE MAINT > OFF-LINE CONFG > DISPLAY > RATE ProLink II ProLink > Configuration > Display > Display Options > Update Period Field Communicator Configure > Manual Setup > Display > Update Period Overview You can set Update Period to control how fr[...]

  • Page 77

    Tip Scroll Rate may not be available until you apply Auto Scroll . 5.1.6 Enable or disable the display backlight Display OFF-LINE MAINT > OFF-LINE CONFG > DISPLAY > BKLT ProLink II ProLink > Configuration > Display > Display Options > Display Backlight On/Off Field Communicator Not available Overview You can enable or disable t[...]

  • Page 78

    • Totalizer Start/Stop • Totalizer Reset • Acknowledge All Alarms 5.2.1 Enable or disable Totalizer Start/Stop from the display Display OFF-LINE MAINT > OFF-LINE CONFG > DISPLAY > TOTALS STOP ProLink II ProLink > Configuration > Display > Display Options > Display Start/Stop Totalizers Field Communicator Not available Ove[...]

  • Page 79

    Overview You can configure whether or not the operator is able to reset totalizers from the display. Restrictions • This parameter does not apply to inventories. You cannot reset inventories from the display. • You cannot use the display to reset all totalizers as a group. You must reset totalizers individually. • If the petroleum measurement[...]

  • Page 80

    Option Description Enabled (default) Operators can use a single display command to acknowledge all alarms at once. Disabled Operators cannot acknowledge all alarms at once, they must be ac- knowledged individually. 5.3 Configure security for the display menus Display OFF-LINE MAINT > OFF-LINE CONFG > DISPLAY > OFFLN ProLink II ProLink >[...]

  • Page 81

    3. To require a password for access to the maintenance section of the off-line menu and the Smart Meter Verification menu, enable or disable Off-Line Password . Option Description Enabled Operator is prompted for the off-line password at entry to the Smart Meter Verification menu (if applicable) or entry to the maintenance section of the off-line m[...]

  • Page 82

    Overview Update Rate controls the rate at which process data is polled and process variables are calculated. Update Rate = Special produces faster and “noisier” response to changes in the process. Do not use Special mode unless required by your application. Prerequisites Before setting Update Rate to Special : • Check the effects of Special m[...]

  • Page 83

    Special mode and process variable updates Table 5-1: Always polled and updated Updated only when the petroleum measurement application is disa- bled Never updated • Mass flow • Volume flow • Gas standard volume flow • Density • Temperature • Drive gain • LPO amplitude • Status [contains Event 1 and Event 2 (basic events)] • Raw tu[...]

  • Page 84

    Restriction Fault Timeout is applied only to the following alarms (listed by Status Alarm Code): A003, A004, A005, A008, A016, A017, A033. For all other alarms, fault actions are performed as soon as the alarm is detected. Procedure Set Fault Timeout as desired. The default value is 0 seconds. The range is 0 to 60 seconds. If you set Fault Timeout [...]

  • Page 85

    Procedure 1. Select a status alarm. 2. For the selected status alarm, set Status Alarm Severity as desired. Option Description Fault Actions when fault is detected: • The alarm is posted to the Alert List. • Outputs go to the configured fault action (after Fault Timeout has expired, if applicable). • Digital communications go to the configure[...]

  • Page 86

    Status alarms and Status Alarm Severity (continued) Table 5-2: Alarm code Status message Default severity Notes Configurable? A011 Zero Calibration Failed: Low Fault Yes A012 Zero Calibration Failed: High Fault Yes A013 Zero Calibration Failed: Unstable Fault Yes A014 Transmitter Failure Fault No A016 Sensor RTD Failure Fault Yes A017 T-Series RTD [...]

  • Page 87

    5.6 Configure informational parameters The informational parameters can be used to identify or describe your flowmeter but they are not used in transmitter processing and are not required. The informational parameters include: • Device parameters - Descriptor - Message - Date • Sensor parameters - Sensor Serial Number - Sensor Material - Sensor[...]

  • Page 88

    Procedure Enter a short message for the transmitter. Your message can be up to 32 characters long. 5.6.3 Configure Date Display Not available ProLink II ProLink > Configuration > Device > Date Field Communicator Configure > Manual Setup > Info Parameters > Transmitter Info > Date Overview Date lets you store a static date (not [...]

  • Page 89

    5.6.5 Configure Sensor Material Display Not available ProLink II ProLink > Configuration > Sensor > Sensor Matl Field Communicator Configure > Manual Setup > Info Parameters > Sensor Information > Tube Wetted Material Overview Sensor Material lets you store the type of material used for your sensor’s wetted parts in transmitt[...]

  • Page 90

    Overview Sensor Flange Type lets you store your sensor’s flange type in transmitter memory. This parameter is not used in processing and is not required. Procedure 1. Obtain your sensor’s flange type from the documents shipped with your sensor, or from a code in the sensor model number. To interpret the model number, refer to the product data s[...]

  • Page 91

    6 Integrate the meter with the control system Topics covered in this chapter: • Configure the mA output • Configure the frequency output • Configure the discrete output • Configure the discrete input • Configure the mA input • Configure events • Configure digital communications • Set up polling for temperature • Set up polling for[...]

  • Page 92

    6.1.1 Configure mA Output Process Variable Display OFF-LINE MAINT > OFF-LINE CONFG > IO > AO 1 > SRC OFF-LINE MAINT > OFF-LINE CONFG > IO > AO 2 > SRC ProLink II ProLink > Configuration > Analog Output > Primary/Secondary Output > PV/SV Is Field Communicator Configure > Manual Setup > Inputs/Outputs > mA[...]

  • Page 93

    Options for mA Output Process Variable (continued) Table 6-1: Process variables Label Display ProLink II ProLink III Field Communicator Gas standard volume flow rate GSV F Gas Std Vol Flow Rate Gas Standard Volume Flow Rate Gas vol flo Temperature TEMP Temperature Temperature Temp Density DENS Density Density Dens External pressure EXT P External P[...]

  • Page 94

    6.1.2 Configure Lower Range Value (LRV) and Upper Range Value (URV) Display OFF-LINE MAINT > OFF-LINE CONFG > IO > AO 1/2 > 4 mA OFF-LINE MAINT > OFF-LINE CONFG > IO > AO 1/2 > 20 mA ProLink II ProLink > Configuration > Analog Output > Primary/Secondary Output > Lower Range Value ProLink > Configuration > A[...]

  • Page 95

    Note You can set URV below LRV . For example, you can set URV to 50 and LRV to 100 . The mA output uses a range of 4–20 mA or 0–20 mA to represent mA Output Process Variable . Between LRV and URV , the mA output is linear with the process variable. If the process variable drops below LRV or rises above URV , the transmitter posts an output satu[...]

  • Page 96

    Procedure Set AO Cutoff as desired. The default values for AO Cutoff are as follows: • Primary mA output: 0.0 g/sec • Secondary mA output: Not-A-Number Tip For most applications, the default value of AO Cutoff should be used. Contact Micro Motion customer service before changing AO Cutoff . Interaction between AO Cutoff and process variable cut[...]

  • Page 97

    6.1.4 Configure Added Damping Display Not available ProLink II ProLink > Configuration > Analog Output > Primary/Secondary Output > AO Added Damp Field Communicator Configure > Manual Setup > Inputs/Outputs > mA Output 1 > mA Output Settings > PV Added Damping Configure > Manual Setup > Inputs/Outputs > mA Output[...]

  • Page 98

    Example: Damping interaction Configuration: • Flow Damping = 1 second • mA Output Process Variable = Mass Flow Rate • Added Damping = 2 seconds Result: A change in the mass flow rate will be reflected in the mA output over a time period that is greater than 3 seconds. The exact time period is calculated by the transmitter according to interna[...]

  • Page 99

    Options for mA Output Fault Action and mA Output Fault Level Options for mA Output Fault Action and mA Output Fault Level Table 6-4: Option mA output behavior mA Output Fault Level Upscale Goes to the configured fault level Default: 22.0 mA Range: 21 to 24 mA Downscale (default) Goes to the configured fault level Default: 2.0 mA Range: 1.0 to 3.6 m[...]

  • Page 100

    Important Whenever you change a frequency output parameter, verify all other frequency output parameters before returning the flowmeter to service. In some situations, the transmitter automatically loads a set of stored values, and these values may not be appropriate for your application. 6.2.1 Configure Frequency Output Power Source Display OFF-LI[...]

  • Page 101

    Procedure Set Frequency Output Process Variable as desired. The default setting is Mass Flow Rate . Options for Frequency Output Process Variable The transmitter provides a basic set of options for Frequency Output Process Variable , plus several application-specific options. Different communications tools may use different labels for the options. [...]

  • Page 102

    6.2.4 Configure Frequency Output Scaling Method Display OFF-LINE MAINT > OFF-LINE CONFG > IO > FO > SCALE ProLink II ProLink > Configuration > Frequency > Scaling Method Field Communicator Configure > Manual Setup > Inputs/Outputs > Frequency Output > FO Scaling Overview Frequency Output Scaling Method defines the r[...]

  • Page 103

    The resulting Frequency Factor must be within the range of the frequency output (0 to 10,000 Hz): • If Frequency Factor is less than1 Hz,reconfigure the receiving device for a higher pulses/unit setting. • If Frequency Factor is greater than 10,000 Hz, reconfigure the receiving device for a lower pulses/unit setting. Tip If Frequency Output Sca[...]

  • Page 104

    Interaction of Frequency Output Maximum Pulse Width and Frequency Output Polarity Table 6-6: Polarity Pulse width Active High Active Low Procedure Set Frequency Output Maximum Pulse Width as desired. The default value is 277 milliseconds. You can set Frequency Output Maximum Pulse Width to 0 milliseconds or to a value between 0.5 milliseconds and 2[...]

  • Page 105

    Procedure 1. Set Frequency Output Fault Action as desired. The default value is Downscale (0 Hz). 2. If you set Frequency Output Fault Action to Upscale , set Frequency Fault Level to the desired value. The default value is 15000 Hz. The range is 10 to 15000 Hz. Options for Frequency Output Fault Action Options for Frequency Output Fault Action Tab[...]

  • Page 106

    Important Whenever you change a discrete output parameter, verify all other discrete output parameters before returning the flowmeter to service. In some situations, the transmitter automatically loads a set of stored values, and these values may not be appropriate for your application. 6.3.1 Configure Discrete Output Power Source Display OFF-LINE [...]

  • Page 107

    Options for Discrete Output Source Options for Discrete Output Source Table 6-8: Option Label Condition Discrete out- put voltage Display ProLink II ProLink III Field Commu- nicator Discrete Event 1– 5 (1) D EV x Discrete Event x Enhanced Event 1 Enhanced Event 2 Enhanced Event 3 Enhanced Event 4 Enhanced Event 5 Discrete Event x ON Site-specific[...]

  • Page 108

    Configure Flow Switch parameters Display OFF-LINE MAINT > OFF-LINE CONFG > IO > DO > CONFIG FL SW ProLink II ProLink > Configuration > Flow > Flow Switch Setpoint ProLink > Configuration > Flow > Flow Switch Variable ProLink > Configuration > Flow > Flow Switch Hysteresis Field Communicator Configure > Manu[...]

  • Page 109

    Overview Discrete outputs have two states: ON (active) and OFF (inactive). Two different voltage levels are used to represent these states. Discrete Output Polarity controls which voltage level represents which state. Procedure Set Discrete Output Polarity as desired. The default setting is Active High . Options for Discrete Output Polarity Options[...]

  • Page 110

    Illustration of discrete output circuit Typical discrete output circuit (internal power) Figure 6-1: A. 3.2 K Ω B. Out+ C. Out − 6.3.4 Configure Discrete Output Fault Action Display Not available ProLink II ProLink > Configuration > Discrete Output > Discrete Output > DO Fault Action Field Communicator Configure > Manual Setup &g[...]

  • Page 111

    Procedure Set Discrete Output Fault Action as desired. The default setting is None . Options for Discrete Output Fault Action Options for Discrete Output Fault Action Table 6-10: Label Discrete output behavior Polarity= Active High Polarity= Active Low Upscale • Fault: discrete output is ON (site-specific voltage) • No fault: discrete output is[...]

  • Page 112

    Important Whenever you change a discrete input parameter, verify all other discrete input parameters before returning the flowmeter to service. In some situations, the transmitter automatically loads a set of stored values, and these values may not be appropriate for your application. 6.4.1 Configure Discrete Input Action Display OFF-LINE MAINT >[...]

  • Page 113

    (continued) Table 6-11: Action Label Display ProLink II ProLink III Field Communicator Reset gas standard volume total RESET GSVT Reset Gas Std Volume Total Reset Gas Std Volume Total Reset gas standard vol- ume total Reset all totals RESET ALL Reset All Totals Reset All Totals Reset totals Petroleum measurement Reset temperature- corrected volume [...]

  • Page 114

    Options for Discrete Input Polarity Options for Discrete Input Polarity Table 6-12: Polarity Discrete input power supply Voltage Status of discrete in- put at transmitter Active High Internal Voltage across terminals is high ON Voltage across terminals is 0 VDC OFF External Voltage applied across terminals is 3–30 VDC ON Voltage applied across te[...]

  • Page 115

    6.5.1 Configure mA Input Process Variable Display OFF-LINE MAINT > OFF-LINE CONFG > IO > MAI > AI SRC ProLink II ProLink > Configuration > Milliamp Input > PV Field Communicator Configure > Manual Setup > Inputs/Outputs > Milliamp Input > mA Input Variable Assignment Overview mA Input Process Variable specifies the [...]

  • Page 116

    Overview The Lower Range Value (LRV) and Upper Range Value (URV) are used to scale the readings received from the external measurement device, i.e., to define the relationship between mA input Process Variable and the mA input level received. Between LRV and URV , the mA input is linear with the process variable. If the process variable drops below[...]

  • Page 117

    Overview A basic event is used to provide notification of process changes. A basic event occurs (is ON) if the real-time value of a user-specified process variable moves above (HI) or below (LO) a user-defined setpoint. You can define up to two basic events. Event status can be queried via digital communications, and a discrete output can be config[...]

  • Page 118

    Options Description HI x > A The event occurs when the value of the assigned process variable ( x ) is greater than the setpoint ( Setpoint A ), endpoint not included. LO x < A The event occurs when the value of the assigned process variable ( x ) is less than the setpoint ( Setpoint A ), endpoint not included. IN A ≤ x ≤ B The event occu[...]

  • Page 119

    (continued) Table 6-13: Action Label Display ProLink II ProLink III Field Communicator Reset gas standard volume total RESET GSVT Reset Gas Std Volume Total Reset Gas Std Volume Total Reset gas standard vol- ume total Reset all totals RESET ALL Reset All Totals Reset All Totals Reset totals Petroleum measurement Reset temperature- corrected volume [...]

  • Page 120

    Important The service port clips on the user interface of the transmitter are directly connected to the RS-485 terminals (26 and 27). If you wire the transmitter for RS-485 digital communications, you cannot use the service port clips for communication with the transmitter. 6.7.1 Configure HART/Bell 202 communications Display N/A ProLink II ProLink[...]

  • Page 121

    Important If you use ProLink II or ProLink III to set HART Address to 0 , the program automatically enables Loop Current Mode . If you use ProLink II or ProLink III to set HART Address to any other value, the program automatically disables Loop Current Mode . This is designed to make it easier to configure the transmitter for legacy behavior. Alway[...]

  • Page 122

    Label Description ProLink II ProLink III Field Communi- cator PV current & % of range Primary Variable (Percent Range/ Current) % range/current The transmitter sends the PV’s per- cent of range and the PV’s actual mA level in each burst (e.g., 25%, 11.0 mA). Dynamic vars & PV current Process Variables/ Current Process variables/ current[...]

  • Page 123

    Options for HART variables (continued) Table 6-14: Process variable Primary Varia- ble (PV) Secondary Variable (SV) Third Variable (TV) Fourth Varia- ble (QV ) Mass flow rate ✓ ✓ ✓ ✓ Line (Gross) Volume flow rate ✓ ✓ ✓ ✓ Temperature ✓ ✓ ✓ Density ✓ ✓ ✓ Drive gain ✓ ✓ ✓ Mass total ✓ Line (Gross) Volume total ✓ M[...]

  • Page 124

    Options for HART variables (continued) Table 6-14: Process variable Primary Varia- ble (PV) Secondary Variable (SV) Third Variable (TV) Fourth Varia- ble (QV ) CM net mass total ✓ CM net mass inventory ✓ CM net volume flow rate ✓ ✓ ✓ ✓ CM net volume total ✓ CM net volume inventory ✓ CM concentration ✓ ✓ ✓ CM Baume ✓ ✓ ✓ [...]

  • Page 125

    HART/RS-485 communication parameters include: • HART Address (Polling Address) Procedure 1. Set Protocol to HART RS-485 . 2. Set Baud Rate to match the baud rate that will be used by your HART master. 3. Set Parity to match the parity that will be used by your HART master. 4. Set Stop Bits to match the stop bits setting that will be used by your [...]

  • Page 126

    Restriction To configure Floating-Point Byte Order or Additional Communications Response Delay , you must use ProLink II. Procedure 1. Set Disable Modbus ASCII as desired. Support for Modbus ASCII limits the set of addresses that are available for the transmitter's Modbus address. Modbus ASCII support Available Modbus addresses Disabled 1–12[...]

  • Page 127

    5. (Optional) Set Additional Communications Response Delay in “delay units.” A delay unit is 2/3 of the time required to transmit one character, as calculated for the port currently in use and the character transmission parameters. Valid values range from 1 to 255. Additional Communications Response Delay is used to synchronize Modbus communica[...]

  • Page 128

    Options for Digital Communications Fault Action (continued) Table 6-17: Label Description ProLink II ProLink III Field Communicator Zero Zero IntZero-All 0 • Flow rate variables go to the value that represents a flow rate of 0 (zero). • Density is reported as 0 . • Temperature is reported as 0 °C , or the equivalent if other units are used ([...]

  • Page 129

    Overview The transmitter can poll an external temperature device for current temperature data. The external temperature value is used only by the petroleum measurement application or the concentration measurement application. If you do not have one of these applications, do not set up polling for temperature. Tip To obtain value from using an exter[...]

  • Page 130

    1. Verify the HART tag of the external device. 2. Verify that the external device is powered up and online. 3. Verify the HART/mA connection between the transmitter and the external measurement device. 6.9 Set up polling for pressure Display Not available ProLink II ProLink > Configuration > Polled Variables > External Pressure Field Commu[...]

  • Page 131

    3. (ProLink II only) Click Apply to enable the polling controls. 4. Enter the device tag of the external measurement device. 5. Set Process Variable to Pressure . Postrequisites Verify that the transmitter is receiving the external data. To do this: • Using ProLink II, click ProLink > Process Variables and check the External Pressure value. ?[...]

  • Page 132

    Integrate the meter with the control system 124 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 133

    7 Completing the configuration Topics covered in this chapter: • Back up transmitter configuration • Enable/disable HART security • Enable write-protection on the transmitter configuration 7.1 Back up transmitter configuration ProLink II and ProLink III provide a configuration upload/download function which allows you to save configuration se[...]

  • Page 134

    Important The HART security switch does not affect Modbus communications. CAUTION! If the transmitter is in a hazardous area, do not remove the housing cover while power is being supplied to the unit. Removing the housing cover while power is supplied to the unit could cause an explosion. To access the HART security switch in a hazardous environmen[...]

  • Page 135

    Overview If the transmitter is write-protected, the configuration is locked and nobody can change it until it is unlocked. This prevents accidental or unauthorized changes to the transmitter configuration parameters. Completing the configuration Configuration and Use Manual 127[...]

  • Page 136

    Completing the configuration 128 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 137

    Part III Operations, maintenance, and troubleshooting Chapters covered in this part: • Transmitter operation • Measurement support • Troubleshooting Operations, maintenance, and troubleshooting Configuration and Use Manual 129[...]

  • Page 138

    Operations, maintenance, and troubleshooting 130 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 139

    8 Transmitter operation Topics covered in this chapter: • Record the process variables • View transmitter status using the status LED • View and acknowledge status alarms • Read totalizer and inventory values • Start and stop totalizers and inventories • Reset totalizers • Reset inventories 8.1 Record the process variables Micro Motio[...]

  • Page 140

    • If your transmitter has a display, you can view the status LED with the transmitter housing cover in place. • If your transmitter does not have a display, you must remove the transmitter housing cover to view the status LED. CAUTION! If the transmitter is in a hazardous area, do not remove the housing cover while power is supplied to the unit[...]

  • Page 141

    Procedure See Figure 8-1 . Transmitter operation Configuration and Use Manual 133[...]

  • Page 142

    Using the display to view and acknowledge the status alarms Figure 8-1: SEE ALARM Y es Scroll and Select simultaneously for 4 seconds ACK ALL Y es EXIT Select No Alarm code Scroll ACK Y es Select No Active/ unacknowledged alarms? No Y es Select NO ALARM EXIT Scroll Scroll Select Scroll Scroll Select Is ACK ALL enabled? Y es No Transmitter operation[...]

  • Page 143

    Postrequisites • To clear the following alarms, you must correct the problem, acknowledge the alarm, then power-cycle the transmitter: A001, A002, A010, A011, A012, A013, A018, A019, A022, A023, A024, A025, A028, A029, A031. • For all other alarms: - If the alarm is inactive when it is acknowledged, it will be removed from the list. - If the al[...]

  • Page 144

    All active alarms or unacknowledged alarms are listed. Note Only Fault and Informational alarms are listed. The transmitter automatically filters out alarms with Status Alarm Severity set to Ignore . • To refresh the list of active or unacknowledged alarms, press Service Tools > Alerts > Refresh Alerts . 8.3.4 Alarm data in transmitter memo[...]

  • Page 145

    8.4 Read totalizer and inventory values Display To read a totalizer or inventory value from the display, it must be configured as a display variable. ProLink II ProLink > Totalizer Control Field Communicator Service Tools > Variables > Totalizer Control Overview Totalizers keep track of the total amount of mass or volume measured by the tr[...]

  • Page 146

    8.5.1 Start and stop totalizers and inventories using the display Prerequisites The Totalizer Start/Stop display function must be enabled. At least one totalizer must be configured as a display variable. Procedure • To start all totalizers and inventories using the display: 1. Scroll until the word TOTAL appears in the lower left corner of the di[...]

  • Page 147

    8.6 Reset totalizers Display See Section 8.6.1 . ProLink II ProLink > Totalizer Control > Reset Mass Total ProLink > Totalizer Control > Reset Volume Total ProLink > Totalizer Control > Reset Gas Volume Total ProLink > Totalizer Control > Reset Field Communicator Service Tools > Variables > Totalizer Control > Mass [...]

  • Page 148

    6. Scroll to EXIT . 7. Select . • To reset the volume totalizer: 1. Scroll until the volume totalizer value appears. 2. Select . 3. Scroll until RESET appears beneath the current totalizer value. 4. Select . 5. Select again to confirm. 6. Scroll to EXIT . 7. Select . • To reset the gas standard volume totalizer: 1. Scroll until the gas standard[...]

  • Page 149

    • To enable inventory reset in ProLink II: 1. Click View > Preferences . 2. Check the Enable Inventory Totals Reset checkbox. 3. Click Apply . • To enable inventory reset in ProLink III: 1. Choose Tools > Options . 2. Select Reset Inventories from ProLink III . Transmitter operation Configuration and Use Manual 141[...]

  • Page 150

    Transmitter operation 142 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 151

    9 Measurement support Topics covered in this chapter: • Options for measurement support • Zero the flowmeter • Validate the meter • Perform a (standard) D1 and D2 density calibration • Perform a D3 and D4 density calibration (T-Series sensors only) • Perform temperature calibration 9.1 Options for measurement support Micro Motion provid[...]

  • Page 152

    Prerequisites Before performing a field zero, execute the Zero Verification procedure to see whether or not a field zero can improve measurement accuracy. See Section 2.6 . Important Do not verify the zero or zero the flowmeter if a high-severity alarm is active. Correct the problem, then verify the zero or zero the flowmeter. You may verify the ze[...]

  • Page 153

    The display reports CAL PASS if the zero was successful, or CAL FAIL if it was not. Postrequisites Restore normal flow through the sensor by opening the valves. Need help? If the zero fails: • Ensure that there is no flow through the sensor, then retry. • Remove or reduce sources of electromechanical noise, then retry. • Set Zero Time to a lo[...]

  • Page 154

    Zero Time controls the amount of time the transmitter takes to determine its zero- flow reference point. The default Zero Time is 20 seconds. For most applications, the default Zero Time is appropriate. 5. Click Perform Auto Zero . The Calibration in Progress light will turn red during the zero procedure. At the end of the procedure: • If the zer[...]

  • Page 155

    e. Observe the drive gain, temperature, and density readings. If they are stable, check the Live Zero or Field Verification Zero value. If the average value is close to 0, you should not need to zero the flowmeter. 2. Press Service Tools > Maintenance > Zero Calibration > Perform Auto Zero . 3. Modify Zero Time , if desired. Zero Time cont[...]

  • Page 156

    Overview Meter validation compares flowmeter measurements reported by the transmitter to an external measurement standard. If the transmitter value for mass flow, volume flow, or density measurement is significantly different from the external measurement standard, you may want to adjust the corresponding meter factor. The flowmeter’s actual meas[...]

  • Page 157

    3. Configure the meter factor in the transmitter. Example: Calculating the meter factor for mass flow The flowmeter is installed and validated for the first time. The mass flow measurement from the transmitter is 250.27 lb. The mass flow measurement from the reference device is 250 lb. The mass flow meter factor is calculated as follows: MeterFacto[...]

  • Page 158

    3. Ensure that the calculated meter factor is between 0.8 and 1.2, inclusive. If the meter factor is outside these limits, contact Micro Motion customer service. 4. Configure the meter factor for volume flow in the transmitter. 9.4 Perform a (standard) D1 and D2 density calibration Density calibration establishes the relationship between the densit[...]

  • Page 159

    Procedure See Figure 9-1 . D1 and D2 density calibration using ProLink II Figure 9-1: Enter density of D1 fluid Calibration in Progress light turns green Calibration in Progress light turns red D1 calibration Close shutoff valve downstream from sensor Fill sensor with D1 fluid Fill sensor with D2 fluid Close Enter density of D2 fluid Calibration in[...]

  • Page 160

    • If LD Optimization is enabled on your meter, disable it. To do this, choose Configure > Manual Setup > Measurements > LD Optimization . LD Optimization is used only with large sensors in hydrocarbon applications. In some installations, only Micro Motion customer service has access to this parameter. If this is the case, contact Micro M[...]

  • Page 161

    D1 and D2 density calibration using the Field Communicator Figure 9-2: Enter density of D1 fluid Density Calibration Complete message Calibration in Progress message D1 calibration Close shutoff valve downstream from sensor Fill sensor with D1 fluid Fill sensor with D2 fluid D2 calibration OK Dens Pt 1 Calibration method executes OK Home Enter dens[...]

  • Page 162

    • Perform the D3 calibration if you have one calibrated fluid. • Perform both the D3 and D4 calibrations if you have two calibrated fluids (other than air and water). The calibrations must be performed without interruption, in the order shown. Make sure that you are prepared to complete the process without interruption. 9.5.1 Perform a D3 or D3[...]

  • Page 163

    D3 or D3 and D4 density calibration using ProLink II Figure 9-3: Enter density of D3 fluid Calibration in Progress light turns green Calibration in Progress light turns red D3 calibration Close shutoff valve downstream from sensor Fill sensor with D3 fluid Close Enter density of D4 fluid Calibration in Progress light turns green Calibration in Prog[...]

  • Page 164

    - Minimum difference of 0.1 g/cm 3 between the density of the D4 fluid and the density of the D3 fluid. The density of the D4 fluid must be greater than the density of the D3 fluid. - Minimum difference of 0.1 g/cm 3 between the density of the D4 fluid and the density of water. The density of the D4 fluid may be either greater or less than the dens[...]

  • Page 165

    9.6 Perform temperature calibration Temperature calibration establishes the relationship between the temperature of the calibration fluids and the signal produced by the sensor. 9.6.1 Perform temperature calibration using ProLink II Temperature calibration establishes the relationship between the temperature of the calibration fluids and the signal[...]

  • Page 166

    Temperature calibration using ProLink II Figure 9-5: Enter temperature of low- temperature fluid T emperature Offset calibration Do Cal W ait until sensor achieves thermal equilibrium Fill sensor with low- temperature fluid Calibration in Progress light turns green Calibration in Progress light turns red Close Enter temperature of high- temperature[...]

  • Page 167

    10 Troubleshooting Topics covered in this chapter: • Status LED states • Status alarms • Flow measurement problems • Density measurement problems • Temperature measurement problems • Milliamp output problems • Frequency output problems • Use sensor simulation for troubleshooting • Check power supply wiring • Check sensor-to-tran[...]

  • Page 168

    Status LED states Table 10-1: LED behavior Alarm condition Description Solid green No alarm Normal operation Flashing yellow No alarm Zero calibration procedure is in progress Solid yellow Low-severity alarm Alarm condition that will not cause measure- ment error (outputs continue to report proc- ess data) Solid red High-severity alarm Alarm condit[...]

  • Page 169

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Cause Recommended actions A005 Mass Flow Rate Over- range The measured flow has exceeded the maxi- mum flow rate of the sensor ( Δ T greater than 200 µs). • If other alarms are present, resolve those alarm conditions first. If the current alarm per- sists, cont[...]

  • Page 170

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Cause Recommended actions A011 Zero Calibration Failed: Low Many possible causes, such as too much flow – especially reverse flow – through the sen- sor during a calibration procedure. • Verify that there is no flow through the sensor, then retry the procedur[...]

  • Page 171

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Cause Recommended actions A022 Configuration Database Corrupt (Core Process- or) • Cycle power to the meter. • Contact Micro Motion. A026 Sensor/Transmitter Communications Fail- ure • The core processor may have been disconnec- ted or replaced. • Check the [...]

  • Page 172

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Cause Recommended actions A101 mA Output 1 Fixed Non-zero HART address configured, or the mA output is configured to send a constant value. • Check whether the output is in loop test mode. If it is, unfix the output. • Exit mA output trim, if applicable. • Ch[...]

  • Page 173

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Cause Recommended actions A113 mA Output 2 Saturated • Check process conditions. Actual conditions may be outside of the normal conditions for which the output is configured. • Verify process conditions, checking especially for air in the flow tubes, tubes not [...]

  • Page 174

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Cause Recommended actions A131 Meter Verification in Progress: Outputs to Last Measured Value Meter verification in progress, with outputs set to Last Measured Val- ue . • Allow the procedure to complete. A132 Sensor Simulation Ac- tive Simulation mode is en- abl[...]

  • Page 175

    Flow measurement problems and recommended actions (continued) Table 10-3: Problem Possible causes Recommended actions Erratic non-zero flow rate under no-flow conditions • Leaking valve or seal • Slug flow • Plugged or coated flow tube • Incorrect sensor orientation • Wiring problem • Vibration in pipeline at rate close to sen- sor tube[...]

  • Page 176

    Flow measurement problems and recommended actions (continued) Table 10-3: Problem Possible causes Recommended actions Inaccurate flow rate or batch total • Wiring problem • Inappropriate measurement unit • Incorrect flow calibration factor • Incorrect meter factor • Incorrect density calibration factors • Incorrect flowmeter grounding ?[...]

  • Page 177

    Density measurement problems and recommended actions (continued) Table 10-4: Problem Possible causes Recommended actions Unusually low density reading • Slug flow • Incorrect K2 value • In low frequency meters this can indi- cate erosion or corrosion • Check your process conditions against the values reported by the flowmeter. • Verify th[...]

  • Page 178

    10.6 Milliamp output problems Milliamp output problems and recommended actions Table 10-6: Problem Possible causes Recommended actions No mA output • Wiring problem • Circuit failure • Check the power supply and power supply wiring. See Section 10.9 . • Check the mA output wiring. • Check the Fault Action settings. See Section 10.18 . •[...]

  • Page 179

    Milliamp output problems and recommended actions (continued) Table 10-6: Problem Possible causes Recommended actions mA output consis- tently out of range • Incorrect process variable or units assigned to output • Fault condition if fault action is set to up- scale or downscale • LRV and URV are not set correctly • Verify the output variabl[...]

  • Page 180

    Frequency output problems and recommended actions Table 10-7: Problem Possible causes Recommended actions No frequency output • Stopped totalizer • Process condition below cutoff • Fault condition if fault action is set to in- ternal zero or downscale • Slug flow • Flow in reverse direction from config- ured flow direction parameter • B[...]

  • Page 181

    For more information on using sensor simulation, see #unique_253 . 10.9 Check power supply wiring If the power supply wiring is damaged or improperly connected, the transmitter may not receive enough power to operate properly. Prerequisites You will need the installation manual for your transmitter. The electronics module must be removed from the t[...]

  • Page 182

    10.10 Check sensor-to-transmitter wiring A number of power-supply and output problems may occur if the wiring between the sensor and the transmitter is improperly connected, or if the wiring becomes damaged. Prerequisites You will need the installation manual for your transmitter. Procedure 1. Before opening the wiring compartments, disconnect the [...]

  • Page 183

    10.12.1 Perform loop tests using the display A loop test is a way to verify that the transmitter and the remote device are communicating properly. A loop test also helps you know whether you need to trim mA outputs. Prerequisites Follow appropriate procedures to ensure that loop testing will not interfere with existing measurement and control loops[...]

  • Page 184

    a. Choose OFFLINE MAINT > SIM > DO SIM , and select SET ON . Dots traverse the display while the output is fixed. b. Verify the signal at the receiving device. c. At the transmitter, activate Select . d. Scroll to and select SET OFF . e. Verify the signal at the receiving device. f. At the transmitter, activate Select . 4. Test the discrete i[...]

  • Page 185

    Procedure 1. Test the mA output(s). a. Choose ProLink > Test > Fix Milliamp . b. Enter 0 mA or 4 mA in Set Output To . c. Click Fix mA . d. Read the mA current at the receiving device and compare it to the transmitter output. The readings do not need to match exactly. If the values are slightly different, you can correct the discrepancy by tr[...]

  • Page 186

    d. Set the remote input device to OFF. e. Choose ProLink > Test > Read Discrete Input . f. Verify the signal at the transmitter. 5. Test the mA input. a. Set the remote input device to generate a known fixed current. b. Choose ProLink > Test > Read MA Input . c. Return the remote input device to normal operation. Postrequisites • If t[...]

  • Page 187

    f. Read the mA current at the receiving device and compare it to the transmitter output. The readings do not need to match exactly. If the values are slightly different, you can correct the discrepancy by trimming the output. g. Press OK . h. Choose End . 2. Test the frequency output(s). Note If the Weights & Measures application is enabled on [...]

  • Page 188

    10.13.1 Trim mA outputs using ProLink II Trimming the mA output establishes a common measurement range between the transmitter and the device that receives the mA output. Important You must trim the output at both ends (0 mA or 4 mA, and 20 mA) to ensure that it is compensated accurately across the entire output range. Prerequisites Ensure that the[...]

  • Page 189

    Important The HART signal over the primary mA output affects the mA reading. Disconnect the wiring between the Field Communicator and the transmitter terminals when reading the primary mA output at the receiving device. Reconnect to continue the trim. 3. Choose Service Tools > Maintenance > Routine Maintenance > Trim mA output 2 . 4. Follo[...]

  • Page 190

    10.15 Check HART Address and Loop Current Mode If the transmitter is producing a fixed current from the mA output, the Loop Current Mode parameter may be disabled. When Loop Current Mode is disabled, the mA output produces a fixed value, and does not report process data or implement its fault action. When HART Address is changed, some configuration[...]

  • Page 191

    1. Check the status alarms for active fault conditons. 2. If there are active fault conditions, the transmitter is performing correctly. If you want to change its behavior, consider the following options: • Change the setting of mA Output Fault Action . • For the relevant status alarms, change the setting of Alarm Severity to Ignore . 3. If the[...]

  • Page 192

    2. If you changed the setting of Frequency Output Scaling Method , check the settings of all other frequency output parameters. 10.22 Check Frequency Output Fault Action The Frequency Output Fault Action controls the behavior of the frequency output if the transmitter encounters an internal fault condition. If the frequency output is reporting a co[...]

  • Page 193

    Tip For typical applications, Micro Motion recommends setting Mass Flow Cutoff to the zero stability value for your sensor, multiplied by 10. Zero stabiliy values can be found in the Product Data Sheet for your sensor. 10.25 Check for slug flow (two-phase flow) Slug flow (two-phase flow, entrained gas) can cause spikes in the drive gain. This may c[...]

  • Page 194

    Possible causes and recommended actions for excessive (saturated) drive gain (continued) Table 10-8: Possible cause Recommended actions Cavitation, flashing, or air en- trainment; settling of two- or three-phase fluids • Increase the inlet or back pressure at the sensor. • If a pump is located upstream from the sensor, increase the dis- tance b[...]

  • Page 195

    Overview Drive gain data can be used to diagnose a variety of process and equipment conditions. Collect drive gain data from a period of normal operation, and use this data as a baseline for troubleshooting. Procedure 1. Navigate to the drive gain data. 2. Observe and record drive gain data over an appropriate period of time, under a variety of pro[...]

  • Page 196

    10.27.1 Collect pickoff voltage data ProLink II ProLink > Diagnostic Information Field Communicator Service Tools > Maintenance > Diagnostic Variables Overview Pickoff voltage data can be used to diagnose a variety of process and equipment conditions. Collect pickoff voltage data from a period of normal operation, and use this data as a ba[...]

  • Page 197

    Procedure 1. Disconnect power to the transmitter. CAUTION! If the transmitter is in a hazardous area, wait 5 minutes before continuing. 2. Remove the transmitter housing cover. 3. Unplug the terminal blocks from the terminal board on the core processor. 4. Using a digital multimeter (DMM), check the pickoff coils by placing the DMM leads on the unp[...]

  • Page 198

    6. Test the resistance of junction box terminal pairs. a. Test the brown terminal against all other terminals except the red one. b. Test the red terminal against all other terminals except the brown one. c. Test the green terminal against all other terminals except the white one. d. Test the white terminal against all other terminals except the gr[...]

  • Page 199

    Appendix A Using the transmitter display Topics covered in this appendix: • Components of the transmitter interface • Use the optical switches • Access and use the display menu system • Display codes for process variables • Codes and abbreviations used in display menus • Menu maps for the transmitter display A.1 Components of the transm[...]

  • Page 200

    Transmitter interface with display Figure A-1: A B C E H G F I J K L M N D A. Display (LCD panel) B. Process variable C. HART security switch D. Unused E. Optical switch indicator for Scroll F. Scroll optical switch G. HART clips H. Unused I. Service port clips J. Select optical switch K. Optical switch indicator for Select L. Unit of measure M. St[...]

  • Page 201

    Transmitter interface without display Figure A-2: A B D E F C A. Zero button B. HART security switch C. Unused D. HART clips E. Service port clips F. Status LED A.2 Use the optical switches Use the optical switches on the transmitter interface to control the transmitter display. The transmitter has two optical switches: Scroll and Select . To activ[...]

  • Page 202

    A.3 Access and use the display menu system The display menu system is used to perform various configuration, administrative, and maintenance tasks. Tip The display menu system does not provide complete configuration, administrative, or maintenance functions. For complete transmitter management, you must use another communications tool. Prerequisite[...]

  • Page 203

    The display will prompt you through this sequence. The Scroll-Select-Scroll sequence is designed to guard against accidental activation of the off-line menu. It is not designed as a security measure. 5. To exit a display menu and return to a higher-level menu: • Activate Scroll until the EXIT option is displayed, then activate Select . • If the[...]

  • Page 204

    3. Repeat until all digits are set as desired. • To change the sign of the value: - If the current value is negative, activate Select until the minus sign is flashing, then activate Scroll until the space is blank. - If the current value is positive and there is a blank space at the left of the value, activate Select until the cursor is flashing [...]

  • Page 205

    Enter a floating-point value using exponential notation Exponential notation is used to enter values that are larger than 99999999 or smaller than − 9999999. Exponential values entered via the display must be in the following form: SX.XXXEYY . In this string: • S = Sign. A minus sign ( − ) indicates a negative number. A blank indicates a posi[...]

  • Page 206

    h. Activate Scroll until the desired character is displayed. 4. Enter the sign. a. Activate Select to move the cursor one digit to the left. b. Activate Scroll until the desired character is displayed. For positive numbers, select a blank space. 5. To save the displayed value to transmitter memory, activate Scroll and Select simultaneously and hold[...]

  • Page 207

    Display codes for process variables (continued) Table A-2: Code Definition Comment or reference NET M Net mass flow rate Concentration measurement applica- tion only NET V Net volume flow rate Concentration measurement applica- tion only NETMI Net mass inventory Concentration measurement applica- tion only NETVI Net volume inventory Concentration m[...]

  • Page 208

    Codes and abbreviations used in display menus (continued) Table A-3: Code or abbrevi- ation Definition Comment or reference ADDR Address AO 1 SRC Fixed to the process variable assigned to the primary out- put AO1 Analog output 1 (primary mA output) AO2 Analog output 2 (secondary mA output) AUTO SCRLL Auto Scroll BKLT B LIGHT Backlight CAL Calibrate[...]

  • Page 209

    Codes and abbreviations used in display menus (continued) Table A-3: Code or abbrevi- ation Definition Comment or reference ENABLE PASSW Enable password Enable or disable password protection for display functions ENABLE RESET Enable totalizer reset Enable or disable totalizer reset from display ENABLE START Enable totalizer start Enable or disable [...]

  • Page 210

    Codes and abbreviations used in display menus (continued) Table A-3: Code or abbrevi- ation Definition Comment or reference MSMT Measurement OFFLN Off-line OFF-LINE MAINT Off-line maintenance P/UNT Pulses/unit POLAR Polarity PRESS Pressure QUAD Quadrature r. Revision SCALE Scaling method SIM Simulation Used for loop testing, not simulation mode. Si[...]

  • Page 211

    Offline menu – version information Figure A-4: Using the transmitter display Configuration and Use Manual 203[...]

  • Page 212

    Offline menu – configuration: units and I/O Figure A-5: Using the transmitter display 204 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 213

    Offline menu – configuration: meter factors, volume Figure A-6: Using the transmitter display Configuration and Use Manual 205[...]

  • Page 214

    Offline menu – configuration: display Figure A-7: Using the transmitter display 206 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 215

    Offline menu – Simulation (loop testing) Figure A-8: Using the transmitter display Configuration and Use Manual 207[...]

  • Page 216

    Offline menu – Simulation: loop testing (continued) Figure A-9: Using the transmitter display 208 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 217

    Offline menu – Zero Figure A-10: Using the transmitter display Configuration and Use Manual 209[...]

  • Page 218

    Using the transmitter display 210 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 219

    Appendix B Using ProLink II with the transmitter Topics covered in this appendix: • Basic information about ProLink II • Menu maps for ProLink II B.1 Basic information about ProLink II ProLink II is a software tool available from Micro Motion. It runs on a Windows platform and provides complete access to transmitter functions and data. ProLink [...]

  • Page 220

    ProLink II messages As you use ProLink II with a Micro Motion transmitter, you will see a number of messages and notes. This manual does not document all of these messages and notes. Important The user is responsible for responding to messages and notes and complying with all safety messages. B.2 Menu maps for ProLink II Main menu Figure B-1: Using[...]

  • Page 221

    Configuration menu Figure B-2: Using ProLink II with the transmitter Configuration and Use Manual 213[...]

  • Page 222

    Configuration menu (continued) Figure B-3: Using ProLink II with the transmitter 214 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 223

    Configuration menu (continued) Figure B-4: Using ProLink II with the transmitter Configuration and Use Manual 215[...]

  • Page 224

    Using ProLink II with the transmitter 216 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 225

    Appendix C Using the Field Communicator with the transmitter Topics covered in this appendix: • Basic information about the Field Communicator • Menu maps for the Field Communicator C.1 Basic information about the Field Communicator The Field Communicator is a handheld configuration and management tool that can be used with a variety of devices[...]

  • Page 226

    If Micro Motion is not listed, or you do not see the required device description, use the Field Communicator Easy Upgrade Utility to install the device description, or contact Micro Motion. Field Communicator menus and messages Many of the menus in this manual start with the On-Line menu. Ensure that you are able to navigate to the On-Line menu. As[...]

  • Page 227

    Overview menu Figure C-2: Using the Field Communicator with the transmitter Configuration and Use Manual 219[...]

  • Page 228

    Configure menu: top level Figure C-3: Using the Field Communicator with the transmitter 220 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 229

    Configure menu: Manual Setup: Characterize Figure C-4: Using the Field Communicator with the transmitter Configuration and Use Manual 221[...]

  • Page 230

    Configure menu: Manual Setup: Measurements Figure C-5: Configure menu: Manual Setup: Display Figure C-6: Using the Field Communicator with the transmitter 222 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 231

    Configure menu: Manual Setup: Inputs/Outputs Figure C-7: Using the Field Communicator with the transmitter Configuration and Use Manual 223[...]

  • Page 232

    Configure menu: Manual Setup: Inputs/Outputs (continued) Figure C-8: Using the Field Communicator with the transmitter 224 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 233

    Configure menu: Alert Setup Figure C-9: Service Tools menu: top level Figure C-10: Using the Field Communicator with the transmitter Configuration and Use Manual 225[...]

  • Page 234

    Service Tools menu: Variables Figure C-11: Using the Field Communicator with the transmitter 226 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 235

    Service Tools menu: Maintenance Figure C-12: Service Tools menu: Simulate Figure C-13: Using the Field Communicator with the transmitter Configuration and Use Manual 227[...]

  • Page 236

    Using the Field Communicator with the transmitter 228 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 237

    Appendix D Default values and ranges D.1 Default values and ranges The default values and ranges represent the typical factory transmitter configuration. Depending on how the transmitter was ordered, certain values may have been configured at the factory and are not represented in the default values and ranges. Transmitter default values and ranges[...]

  • Page 238

    Transmitter default values and ranges (continued) Table D-1: Type Parameter Default Range Comments D2 1 g/cm 3 K1 1000 µsec 1000 – 50,000 µsec K2 50,000 µsec 1000 – 50,000 µsec FD 0 Temp Coefficient 4.44 Slug flow Slug flow low limit 0.0 g/cm 3 0.0 – 10.0 g/cm 3 Slug flow high limit 5.0 g/cm 3 0. 0 – 10.0 g/cm 3 Slug duration 0.0 sec 0.[...]

  • Page 239

    Transmitter default values and ranges (continued) Table D-1: Type Parameter Default Range Comments Variable map- ping Primary variable Mass flow Secondary variable Density Tertiary variable Mass flow Quaternary variable Volume flow mA output 1 Primary variable Mass flow LRV –200.00000 g/s URV 200.00000 g/s AO cutoff 0.00000 g/s AO added damping 0[...]

  • Page 240

    Transmitter default values and ranges (continued) Table D-1: Type Parameter Default Range Comments AO fault level – upscale 22 mA 21.0 – 24.0 mA Last measured value timeout 0.00 sec LRV Mass flow rate −200.000 g/s Volume flow rate −0.200 L/s Density 0.000 g/cm 3 Temperature − 240.000 °C Drive gain 0.000% Gas standard volume flow rate −[...]

  • Page 241

    Transmitter default values and ranges (continued) Table D-1: Type Parameter Default Range Comments Discrete input Actions None Polarity Active low mA input Process Variable (PV) None Display Backlight on/off On Backlight intensity 63 0 – 63 Refresh rate 200 millisec- onds 100 – 10,000 milliseconds Variable 1 Mass flow rate Variable 2 Mass total[...]

  • Page 242

    Default values and ranges 234 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 243

    Appendix E Transmitter components and installation wiring Topics covered in this appendix: • Transmitter components • Transmitter-to-sensor wiring • Power supply terminals • Input/output (I/O) terminals E.1 Transmitter components You may need to identify the transmitter components for certain operational or troubleshooting tasks. Transmitte[...]

  • Page 244

    Transmitter components Figure E-1: A G F B C E H D I A. Removable housing cover B. Electronics module C. Intrinsically safe sensor wiring terminals D. Non–intrinsically-safe output wiring terminals E. Conduit opening for sensor wiring F. Conduit opening for power supply wiring G. Conduit opening for output wiring H. Housing base I. User interface[...]

  • Page 245

    CAUTION! Refer to the Micro Motion 9739 MVD Transmitters: Installation Manual for all safety and detailed wiring information for the transmitter. You are responsible for following all safety and wiring instructions documented in the transmitter installation manual, plus any additional site requirements. You can wire the transmitter to the following[...]

  • Page 246

    Power supply terminals Figure E-2: E B C D A A. External ground terminal B. Power supply conduit opening C. L / L1 for AC; + for DC D. N / L2 for AC; – for DC E. Power ground terminal E.4 Input/output (I/O) terminals The I/O terminals are used to connect the transmitter to remote devices such as other transmitters or valves, or to hosts. CAUTION![...]

  • Page 247

    I/O terminals Figure E-3: I/O terminals and functions Table E-2: Terminal Function 14 Frequency output, DC supply voltage (+) 15 and 16 Frequency/pulse output (+) 16 Return 17 Primary variable (PV+) mA output 18 Primary variable (PV–) mA output 19 Secondary variable (SV+) mA output 20 Secondary variable (SV–) mA output 21 and 16 Discrete input [...]

  • Page 248

    Transmitter components and installation wiring 240 Micro Motion ® 9739 MVD Transmitters[...]

  • Page 249

    Index A Added Damping 89 Additional Communications Response Delay 117 address HART address 112, 116 Modbus address 117 air calibration , See calibration, density alarm menu , See display alarms alarm codes 160 configuring alarm handling 75 Status Alarm Severity configuring 76 options 77 transmitter response 136 troubleshooting 160 viewing and ackno[...]

  • Page 250

    connection startup connection 6 CTL 49 curve , See concentration measurement application customer service contacting ii cutoffs AO cutoff 87 density 46 interaction between AO Cutoff and process variable cutoffs 88 mass flow 25 troubleshooting 184 volume flow 30 D damping Added Damping 89 density damping 45 flow damping 24 interaction between Added [...]

  • Page 251

    configuring display behavior Auto Scroll 68 backlight 69 display language 65 display precision 67 display variables 66 LED Blinking 69 Update Period (refresh rate) 68 configuring security access to alarm menu 72 access to off-line menu 72 alarm password 72 off-line password 72 decimal notation 195 enabling or disabling operator actions acknowledgin[...]

  • Page 252

    scaling method configuring 94 Frequency = Flow 94 troubleshooting 171, 183, 184 G gas standard volume flow measurement configuring 31 cutoff configuring 36 interaction with AO cutoff 36 effect of flow damping on 24 effect of mass flow cutoff on 25 measurement units configuring 33 options 33 standard density 32 volume flow type 32 grounding troubles[...]

  • Page 253

    trimming using ProLink II 180 using the Field Communicator 180 troubleshooting 170, 182 mass flow measurement configuring 21 cutoff configuring 25 effect on volume measurement 25 interaction with AO cutoff 25 flow damping 24 measurement units configuring 21 options 22 meter factor 147 troubleshooting 166 matrix , See concentration measurement appli[...]

  • Page 254

    pressure compensation configuring using ProLink II 60 using the Field Communicator 62 configuring polling 122 overview 60 pressure measurement units options 63 primary variable (PV) 114 process measurement effect of Update Rate 73, 74 process variables See also density measurement See also gas standard volume flow measurement See also mass flow mea[...]

  • Page 255

    Thermal Expansion Coefficient (TEC) 49 totalizers resetting enabling display function 70 performing action 139 starting and stopping enabling display function 70 performing action 137, 138 transmitter communications protocols 3 model code 3 transmitter interface See also display components 191 trimming , See mA outputs, trimming troubleshooting ala[...]

  • Page 256

    *MMI-20016855* MMI-20016855 Rev A C 201 3 Micro Motion Inc. USA Worldwide Headquarters 7070 Winchester Circle Boulder, Colorado 80301 T +1 303-527-5200 T +1 800-522-6277 F +1 303-530-8459 www.micromotion.com Micro Motion Europe Emerson Process Management Neonstraat 1 6718 WX Ede The Netherlands T +31 (0) 318 495 555 F +31 (0) 318 495 556 www.microm[...]