Emerson Model 1700 Bedienungsanleitung

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Inhaltsverzeichnis der Gebrauchsanleitungen

  • Seite 1

    Configuration and Use Manual MMI-20021712, Rev A B April 201 3 Micro Motion ® Model 1700 Transmitters with Analog Outputs Includes the Chinese-Language Display Option[...]

  • Seite 2

    Safety messages Safety messages are provided throughout this manual to protect personnel and equipment. Read each safety message carefully before proceeding to the next step. 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 Pa[...]

  • Seite 3

    Contents Part I Getting Started Chapter 1 Before you begin ............................................................................................................ 2 1.1 About this manual ....................................................................................................................... 2 1.2 Transmitter model code .........[...]

  • Seite 4

    6.4 Configure the discrete output ................................................................................................... 93 6.5 Configure events ....................................................................................................................... 99 6.6 Configure digital communications ................................[...]

  • Seite 5

    10.22 Check Frequency Output Fault Action ............................................................................................. 206 10.23 Check Flow Direction .................................................................................................................. 206 10.24 Check the cutoffs ........................................[...]

  • Seite 6

    Contents iv Micro Motion ® Model 1700 Transmitters with Analog Outputs[...]

  • Seite 7

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

  • Seite 8

    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 transmitter. Important This m[...]

  • Seite 9

    Communications tools, protocols, and related information Table 1-1: Communica- tions tool Supported protocols Scope In this manual For more information Display (stand- ard) Not applicable Basic configuration and commissioning Complete user informa- tion. See Appendix A . Not applicable Chinese-lan- guage display Not applicable Basic configuration a[...]

  • Seite 10

    Additional documentation and resources Table 1-2: Topic Document Sensor Sensor documentation Transmitter installation Hazardous area installation See the approval documentation shipped with the transmitter, or download the appropriate documentation from the Micro Motion web site at www.micromotion.com . All documentation resources are available on [...]

  • Seite 11

    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[...]

  • Seite 12

    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[...]

  • Seite 13

    2.3 Make a startup connection to the transmitter For all configuration tools except the display, you must have an active connection to the transmitter to configure the transmitter. Follow this procedure to make your first connection to the transmitter. Identify the connection type to use, and follow the instructions for that connection type in the [...]

  • Seite 14

    2.4 Characterize the flowmeter (if required) Display (standard) Not available Chinese-language display Offline Maintain > Configuration > Calibrate Sensor ProLink II • ProLink > Configuration > Device > Sensor Type • ProLink > Configuration > Flow • ProLink > Configuration > Density • ProLink > Configuration &g[...]

  • Seite 15

    2.4.1 Sample sensor tags Tag on older curved-tube sensors (all sensors except T-Series) Figure 2-1: Tag on newer curved-tube sensors (all sensors except T-Series) Figure 2-2: Quick start Configuration and Use Manual 9[...]

  • Seite 16

    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. Duri[...]

  • Seite 17

    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 ta[...]

  • Seite 18

    • Connect to the transmitter with the Field Communicator and read the value for Mass Flow Rate in the Process Variables menu ( On-Line Menu > Overview > Primary Purpose Variables ). Postrequisites If the reported mass flow rate is not accurate: • Check the characterization parameters. • Review the troubleshooting suggestions for flow me[...]

  • Seite 19

    b. Run the process fluid through the sensor until the sensor temperature reaches the normal process operating temperature. c. Stop flow through the sensor by shutting the downstream valve, and then the upstream valve if available. d. Verify that the sensor is blocked in, that flow has stopped, and that the sensor is completely full of process fluid[...]

  • Seite 20

    b. Run the process fluid through the sensor until the sensor temperature reaches the normal process operating temperature. c. Stop flow through the sensor by shutting the downstream valve, and then the upstream valve if available. d. Verify that the sensor is blocked in, that flow has stopped, and that the sensor is completely full of process fluid[...]

  • Seite 21

    Terminology used with zero verification and zero calibration (continued) Table 2-2: Term Definition Zero Time The time period over which the Zero Calibration procedure is performed. Unit = seconds. Field Verification Zero A 3-minute running average of the Live Zero value, calculated by the transmitter. Unit = configured mass flow measurement unit. [...]

  • Seite 22

    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 16 Micro Motion ® Model 1700 Trans[...]

  • Seite 23

    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 • Restore the factory configuration 3.1 Configuration flowchart Use the following flowchart [...]

  • Seite 24

    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[...]

  • Seite 25

    3.2 Default values and ranges See Section F.1 to view the default values and ranges for the most commonly used parameters. 3.3 Enable access to the off-line menu of the display Display (standard) OFF-LINE MAINT > OFF-LINE CONFG > DISPLAY Chinese-language display Offline Maintain > Configuration > Display ProLink II ProLink > Configur[...]

  • Seite 26

    Tip Write-protecting the transmitter prevents accidental changes to configuration. It does not prevent normal operational use. You can always disable write-protection, perform any required configuration changes, then re-enable write-protection. 3.5 Restore the factory configuration Display (standard) Not available Chinese-language display Not avail[...]

  • Seite 27

    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 pressure compens[...]

  • Seite 28

    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 [...]

  • Seite 29

    Define a special measurement unit for mass flow Display (standard) Not available Chinese-language display Offline Maintain > Configuration > Units > Special Mass Flow ProLink II ProLink > Configuration > Special Units ProLink III Device Tools > Configuration > Process Measurement > Flow > Special Units Field Communicator [...]

  • Seite 30

    3. Calculate Mass Flow Conversion Factor : a. 1 lb/sec = 16 oz/sec 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 (standard) Not available Chinese-language display Offline Maintain > Configuration[...]

  • Seite 31

    • Whenever the damping value is non-zero, the reported measurement will lag the actual measurement because the reported value is being averaged over time. • In general, lower damping values are preferable because there is less chance of data loss, and less lag time between the actual measurement and the reported value. • For gas applications,[...]

  • Seite 32

    Overview Mass Flow Cutoff specifies the lowest mass flow rate that will be reported as measured. All mass flow rates below this cutoff will be reported as 0. Procedure Set Mass Flow Cutoff to the value you want to use. The default value for Mass Flow Cutoff is 0.0 g/sec or a sensor-specific value set at the factory. The recommended setting is 0.05%[...]

  • Seite 33

    • If the mass flow rate drops below 15 g/sec but not below 10 g/sec: - The mA output will report zero flow. - The frequency output will report the actual flow rate, and the actual flow rate will be used in all internal processing. • If the mass flow rate drops below 10 g/sec, both outputs will report zero flow, and 0 will be used in all interna[...]

  • Seite 34

    4.2.2 Configure Volume Flow Measurement Unit for liquid applications Display (standard) OFF-LINE MAINT > OFF-LINE CONFG > UNITS > VOL Chinese-language display Offline Maintain > Configuration > Units > Volume Flow Rate ProLink II ProLink > Configuration > Flow > Vol Flow Unit ProLink III Device Tools > Configuration &g[...]

  • Seite 35

    Options for Volume Flow Measurement Unit for liquid applications (continued) Table 4-3: Unit description Label Display (stand- ard) Chinese-lan- guage display ProLink II ProLink III Field Commu- nicator Cubic meters per second M3/S m3/sec m3/sec m3/sec Cum/s Cubic meters per minute M3/MIN m3/min m3/min m3/min Cum/min Cubic meters per hour M3/H m3/h[...]

  • Seite 36

    Define a special measurement unit for volume flow Display (standard) Not available Chinese-language display Not available ProLink II ProLink > Configuration > Special Units ProLink III Device Tools > Configuration > Process Measurement > Flow > Special Units Field Communicator Configure > Manual Setup > Measurements > Spe[...]

  • Seite 37

    3. Calculate the conversion factor: a. 1 gal/sec = 8 pints/sec b. Volume Flow Conversion Factor = 1/8 = 0.1250 4. Set Volume Flow Conversion Factor to 0.1250 . 5. Set Volume Flow Label to pints/sec . 6. Set Volume Total Label to pints . 4.2.3 Configure Volume Flow Cutoff Display (standard) Not available Chinese-language display Offline Maintain >[...]

  • Seite 38

    • AO Cutoff : 10 l/sec • Volume Flow Cutoff : 15 l/sec Result: If the volume flow rate drops below 15 l/sec, volume flow will be reported as 0, and 0 will be used in all internal processing. Example: Cutoff interaction with AO Cutoff higher than Volume Flow Cutoff Configuration: • mA Output Process Variable : Volume Flow Rate • Frequency Ou[...]

  • Seite 39

    4.3.1 Configure Volume Flow Type for gas applications Display (standard) Not available Chinese-language display Not available ProLink II ProLink > Configuration > Flow > Vol Flow Type ProLink III Device Tools > Configuration > Process Measurement > Flow Field Communicator Configure > Manual Setup > Measurements > GSV >[...]

  • Seite 40

    4.3.3 Configure Gas Standard Volume Flow Measurement Unit Display (standard) OFF-LINE MAINT > OFF-LINE CONFG > UNITS > GSV Chinese-language display Offline Maintain > Configuration > Units > Gas Std Volume Flow ProLink II ProLink > Configuration > Flow > Std Gas Vol Flow Unit ProLink III Device Tools > Configuration &g[...]

  • Seite 41

    Options for Gas Standard Volume Measurement Unit (continued) Table 4-4: Unit description Label Display (stand- ard) Chinese-lan- guage display ProLink II ProLink III Field Commu- nicator Normal cubic meters per day NM3/D Nm3/day Nm3/day Nm3/day Nm3/day Normal liter per second NLPS NLPS NLPS NLPS NLPS Normal liter per minute NLPM NLPM NLPM NLPM NLPM[...]

  • Seite 42

    Define a special measurement unit for gas standard volume flow Display (standard) Not available Chinese-language display Not available ProLink II ProLink > Configuration > Special Units ProLink III Device Tools > Configuration > Process Measurement > Flow > Special Units Field Communicator Configure > Manual Setup > Measurem[...]

  • Seite 43

    Example: Defining a special measurement unit for gas standard volume flow You want to measure gas standard volume flow in thousands of standard cubic feet per minute. 1. Set Base Gas Standard Volume Unit to SCFM . 2. Set Base Time Unit to minutes (min). 3. Calculate the conversion factor: a. 1 thousands of standard cubic feet per minute = 1000 cubi[...]

  • Seite 44

    Gas Standard Volume Flow Cutoff affects both the gas standard volume flow values reported via outputs and the gas standard volume flow values used in other transmitter behavior (e.g., events defined on gas standard volume flow). AO Cutoff affects only flow values reported via the mA output. Example: Cutoff interaction with AO Cutoff lower than Gas [...]

  • Seite 45

    Overview Flow Direction controls how forward flow and reverse flow affect flow measurement and reporting. Flow Direction is defined with respect to the flow arrow on the sensor: • Forward flow (positive flow) moves in the direction of the flow arrow on the sensor. • Reverse flow (negative flow) moves in the direction opposite to the flow arrow [...]

  • Seite 46

    Effect of Flow Direction on mA outputs Flow Direction affects how the transmitter reports flow values via the mA outputs. The mA outputs are affected by Flow Direction only if mA Output Process Variable is set to a flow variable. Flow Direction and mA outputs The effect of Flow Direction on the mA outputs depend on Lower Range Value configured for [...]

  • Seite 47

    Effect of Flow Direction on the mA output: Lower Range Value < 0 Figure 4-2: 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 Fo[...]

  • Seite 48

    • Under conditions of forward flow, if (the absolute value of) the flow rate equals or exceeds 100 g/sec, the mA output is proportional to the flow rate up to 20.5 mA, and will be level at 20.5 mA at higher flow rates. • Under conditions of reverse flow, for flow rates between 0 and − 100 g/sec, the mA output varies between 4 mA and 12 mA in [...]

  • Seite 49

    Effect of Flow Direction on discrete outputs The Flow Direction parameter affects the discrete output behavior only if Discrete Output Source is set to Flow Direction . Effect of the Flow Direction parameter and actual flow direction on discrete outputs Table 4-7: Flow Direction setting Actual flow direction Forward Zero flow Reverse Forward OFF OF[...]

  • Seite 50

    Effect of the Flow Direction parameter and actual flow direction on flow totals and inventories Table 4-9: Flow Direction setting Actual flow direction Forward Zero flow Reverse Forward Totals increase Totals do not change Totals do not change Reverse Totals do not change Totals do not change Totals increase Bidirectional Totals increase Totals do [...]

  • Seite 51

    The default setting for Density Measurement Unit is g/cm3 (grams per cubic centimeter). Options for Density Measurement Unit The transmitter provides a standard set of measurement units for Density Measurement Unit . Different communications tools may use different labels. Options for Density Measurement Unit Table 4-10: Unit description Label Disp[...]

  • Seite 52

    Overview The slug flow parameters control how the transmitter detects and reports two-phase flow (gas in a liquid process or liquid in a gas process). Procedure 1. Set Slug Low Limit to the lowest density value that is considered normal in your process. Values below this will cause the transmitter to perform the configured slug flow action. Typical[...]

  • Seite 53

    Tip To decrease the occurrence of slug flow alarms, lower Slug Low Limit or raise Slug High Limit . A slug flow condition occurs whenever the measured density goes below Slug Low Limit or above Slug High Limit . If this occurs: • A slug flow alarm is posted to the active alarm log. • All outputs that are configured to represent flow rate hold t[...]

  • Seite 54

    Core processor type Update Rate setting Density Damping range Enhanced Not applicable 0 to 40.96 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 more quickly. • Whene[...]

  • Seite 55

    4.5.4 Configure Density Cutoff Display (standard) Not available Chinese-language display Offline Maintain > Configuration > Low Flow Cutoff > Density Cutoff ProLink II ProLink > Configuration > Density > Low Density Cutoff ProLink III Device Tools > Configuration > Process Measurement > Density Field Communicator Configur[...]

  • Seite 56

    4.6.1 Configure Temperature Measurement Unit Display (standard) OFF-LINE MAINT > OFF-LINE CONFG > UNITS > TEMP Chinese-language display Offline Maintain > Configuration > Units > Temperature ProLink II ProLink > Configuration > Temperature > Temp Unit ProLink III Device Tools > Configuration > Process Measurement &g[...]

  • Seite 57

    4.6.2 Configure Temperature Damping Display (standard) Not available Chinese-language display Offline Maintain > Configuration > Damping > Temperature Damping ProLink II ProLink > Configuration > Temperature > Temp Damping ProLink III Device Tools > Configuration > Temperature Field Communicator Configure > Manual Setup &[...]

  • Seite 58

    4.7 Configure pressure compensation Pressure compensation adjusts process measurement to compensate for the pressure effect on the sensor. The pressure effect is the change in the sensor’s sensitivity to flow and density caused by the difference between the calibration pressure and the process pressure. Tip Not all sensors or applications require[...]

  • Seite 59

    6. Determine how the transmitter will obtain pressure data, and perform the required setup. Option Setup A user-configured static pressure val- ue a. Set Pressure Units to the desired unit. b. Set External Pressure to the desired value. Polling for pres- sure (4) a. Ensure that the primary mA output has been wired to support HART polling. b. Choose[...]

  • Seite 60

    The calibration pressure is the pressure at which your sensor was calibrated, and defines the pressure at which there is no pressure effect. If the data is unavailable, enter 20 PSI. 4. Enter Flow Factor for your sensor. The flow factor is the percent change in the flow rate per PSI. When entering the value, reverse the sign. Example: If the flow f[...]

  • Seite 61

    b. Set Static or Current Pressure to the value to use, and click Apply 9. If you want to use digital communications, click Apply , then perform the necessary host programming and communications setup to write pressure data to the transmitter at appropriate intervals. Postrequisites If you are using an external pressure value, verify the setup by ch[...]

  • Seite 62

    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 (6) a. Ensure that the primary mA output has been wired to support HART polling. b. Choose Online > Configure > Manual Setup > Measurements > External Pressure/Tempera[...]

  • Seite 63

    Options for Pressure Measurement Unit (continued) Table 4-13: Unit description Label Display (stand- ard) Chinese-lan- guage display ProLink II ProLink III Field Commu- nicator Millimeters water @ 4 °C mmW4C mm Water @ 4°C mm Water @ 4°C mm Water @ 4°C mmH2O @4DegC Millimeters water @ 68 °F mmH2O mm Water @ 68°F mm Water @ 68°F mm Water @ 68[...]

  • Seite 64

    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[...]

  • Seite 65

    Procedure Select the language you want to use. Tip For devices with the Chinese-language display, you can use a shortcut key, or an optical switch combination, to change the language without having to access the display menu. The optical switch combination is shown on the front of the display. The languages available depend on your transmitter mode[...]

  • Seite 66

    Example: Default display variable configuration Display variable Process variable assignment Display Variable 1 Mass flow Display Variable 2 Mass total Display Variable 3 Volume flow Display Variable 4 Volume total Display Variable 5 Density Display Variable 6 Temperature Display Variable 7 External pressure Display Variable 8 Mass flow Display Var[...]

  • Seite 67

    Display Variable 1 will automatically be set to match mA Output Process Variable for the primary mA output. If you change the configuration of mA Output Process Variable , Display Variable 1 will be updated automatically. 5.1.3 Configure the precision of variables shown on the display Display (standard) Not available Chinese-language display Offlin[...]

  • Seite 68

    Overview You can set Update Period to control how frequently data is refreshed on the display. Procedure Set Update Period to the desired value. The default value is 200 milliseconds. The range is 100 milliseconds to 10,000 milliseconds (10 seconds). 5.1.5 Enable or disable automatic scrolling through the display variables Display (standard) OFF-LI[...]

  • Seite 69

    5.1.6 Enable or disable the display backlight Display (standard) OFF-LINE MAINT > OFF-LINE CONFG > DISPLAY > BKLT Chinese-language display Offline Maintain > Configuration > Display > Backlight ProLink II ProLink > Configuration > Display > Display Options > Display Backlight On/Off ProLink III Device Tools > Config[...]

  • Seite 70

    5.2 Enable or disable operator actions from the display You can configure the transmitter to let the operator perform specific actions using the display. You can configure the following: • Totalizer Start/Stop • Totalizer Reset • Acknowledge All Alarms 5.2.1 Enable or disable Totalizer Start/Stop from the display Display (standard) OFF-LINE M[...]

  • Seite 71

    Option Description Disabled (default) Operators cannot start and stop totalizers and inventories from the dis- play. 5.2.2 Enable or disable Totalizer Reset from the display Display (standard) OFF-LINE MAINT > OFF-LINE CONFG > DISPLAY > TOTALS RESET Chinese-language display Offline Maintain > Configuration > Display > Reset Total [...]

  • Seite 72

    5.2.3 Enable or disable the Acknowledge All Alarms display command Display (standard) OFF-LINE MAINT > OFF-LINE CONFG > DISPLAY > ALARM Chinese-language display Offline Maintain > Configuration > Display > Acknowledge All ProLink II ProLink > Configuration > Display > Display Options > Display Ack All Alarms ProLink II[...]

  • Seite 73

    Overview You can control operator access to different sections of the display off-line menu. You can also configure a password to control access. Procedure 1. To control operator access to the maintenance section of the off-line menu, enable or disable Off-Line Menu . Option Description Enabled (de- fault) Operator can access the maintenance sectio[...]

  • Seite 74

    If both Off-Line Password and Alarm Password are enabled, the operator is prompted for the off-line password to access the off-line menu, but is not prompted thereafter. 5. (Optional) Set Off-Line Password to the desired value. The same value is used for both the off-line password and the alarm password. The default value is 1234. The range is 0000[...]

  • Seite 75

    • Contact Micro Motion. Procedure 1. Set Update Rate as desired. Option Description Normal All process data is polled at the rate of 20 times per second (20 Hz). All process variables are calculated at 20 Hz. This option is appropriate for most applications. Special A single, user-specified process variable is polled at the rate of 100 times per [...]

  • Seite 76

    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[...]

  • Seite 77

    Option Description Normal Transmitter calculates process variables at the standard speed. Special Transmitter calculates process variables at a faster speed. 5.5 Configure alarm handling The alarm handling parameters control the transmitter’s response to process and device conditions. Alarm handling parameters include: • Fault Timeout • Statu[...]

  • Seite 78

    If the fault timeout period expires while the alarm is still active, the fault actions are performed. If the alarm condition clears before the fault timeout expires, no fault actions are performed. Tip ProLink II allows you to set Fault Timeout in two locations. However, there is only one parameter, and the same setting is applied to all outputs. 5[...]

  • Seite 79

    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 configured fault action (after Fault Timeout has expired, if applicable). • The status LED (if available) changes t[...]

  • Seite 80

    Status alarms and Status Alarm Severity (continued) Table 5-2: Alarm code Status message Default severity Notes Configurable? A014 Transmitter Failure Fault No A016 Sensor RTD Failure Fault Yes A017 T-Series RTD Failure Fault Yes A018 EEPROM Error (Transmit- ter) Fault No A019 RAM Error (Transmitter) Fault No A020 No Flow Cal Value Fault Yes A021 I[...]

  • Seite 81

    Status alarms and Status Alarm Severity (continued) Table 5-2: Alarm code Status message Default severity Notes Configurable? A103 Data Loss Possible (Totals and Inventories) Informational Applies only to flowmeters with the standard core processor. Can be set to either Informational or Ignore , but cannot be set to Fault . Yes A104 Calibration in [...]

  • Seite 82

    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[...]

  • Seite 83

    5.6.2 Configure Message Display (standard) Not available Chinese-language display Not available ProLink II ProLink > Configuration > Device > Message ProLink III Device Tools > Configuration > Informational Parameters > Transmitter Field Communicator Configure > Manual Setup > Info Parameters > Transmitter Info > Messa[...]

  • Seite 84

    5.6.4 Configure Sensor Serial Number Display (standard) Not available Chinese-language display Not available ProLink II ProLink > Configuration > Sensor > Sensor S/N ProLink III Device Tools > Configuration > Informational Parameters > Sensor Field Communicator Configure > Manual Setup > Info Parameters > Sensor Informati[...]

  • Seite 85

    5.6.6 Configure Sensor Liner Material Display (standard) Not available Chinese-language display Not available ProLink II ProLink > Configuration > Sensor > Liner Matl ProLink III Device Tools > Configuration > Informational Parameters > Sensor Field Communicator Configure > Manual Setup > Info Parameters > Sensor Informat[...]

  • Seite 86

    6 Integrate the meter with the control system Topics covered in this chapter: • Configure the transmitter channels • Configure the mA output • Configure the frequency output • Configure the discrete output • Configure events • Configure digital communications 6.1 Configure the transmitter channels Display (standard) OFF-LINE MAINT > [...]

  • Seite 87

    Postrequisites For each channel that you configured, perform or verify the corresponding input or output configuration. When the configuration of a channel is changed, the channel’s behavior will be controlled by the configuration that is stored for the selected input or output type, and the stored configuration may not be appropriate for your pr[...]

  • Seite 88

    • If you are using the HART variables, be aware that changing the configuration of mA Output Process Variable will change the configuration of the HART Primary Variable (PV) and the HART Tertiary Variable (TV). • If you have configured Display Variable 1 to track mA Output Process Variable , be aware that changing the configuration of mA Output[...]

  • Seite 89

    Overview The Lower Range Value (LRV) and Upper Range Value (URV) are used to scale the mA output, that is, to define the relationship between mA Output Process Variable and the mA output level. Note For transmitter software v5.0 and later, if you change LRV and URV from the factory default values, and you later change mA Output Process Variable , L[...]

  • Seite 90

    Default values for Lower Range Value (LRV) and Upper Range Value (URV) Table 6-2: Process variable LRV URV All mass flow variables –200.000 g/sec 200.000 g/sec All liquid volume flow variables –0.200 l/sec 0.200 l/sec Gas standard volume flow –423.78 SCFM 423.78 SCFM 6.2.3 Configure AO Cutoff Display (standard) Not available Chinese-language [...]

  • Seite 91

    Example: Cutoff interaction 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, all outputs representing mass flow will report zero flow. Example: Cutoff interaction Configura[...]

  • Seite 92

    Note Added Damping is not applied if the mA output is fixed (for example, during loop testing) or if the mA output is reporting a fault. Added Damping is applied while sensor simulation is active. Procedure Set Added Damping to the desired value. The default value is 0.0 seconds. When you specify a value for Added Damping , the transmitter automati[...]

  • Seite 93

    6.2.5 Configure mA Output Fault Action and mA Output Fault Level Display (standard) Not available Chinese-language display Not available ProLink II • ProLink > Configuration > Analog Output > Primary Output > AO Fault Action • ProLink > Configuration > Analog Output > Primary Output > AO Fault Level ProLink III Device To[...]

  • Seite 94

    CAUTION! If you set mA Output Fault Action or Frequency Output Fault Action to None , be sure to set Digital Communications Fault Action to None . If you do not, the output will not report actual process data, and this may result in measurement errors or unintended consequences for your process. Restriction If you set Digital Communications Fault A[...]

  • Seite 95

    Overview Frequency Output Polarity controls how the output indicates the ON (active) state. The default value, Active High , is appropriate for most applications. Active Low may be required by applications that use low-frequency signals. Procedure Set Frequency Output Polarity as desired. The default setting is Active High . Options for Frequency O[...]

  • Seite 96

    Option Description Pulses/Unit A user-specified number of pulses represents one flow unit Units/Pulse A pulse represents a user-specified number of flow units 2. Set additional required parameters. • If you set Frequency Output Scaling Method to Frequency=Flow , set Rate Factor and Frequency Factor . • If you set Frequency Output Scaling Method[...]

  • Seite 97

    FrequencyFactor = x 10 2000 60 333.33 FrequencyFactor = FrequencyFactor = x N RateFactor T Set parameters as follows: • Rate Factor : 2000 • Frequency Factor : 333.33 6.3.3 Configure Frequency Output Maximum Pulse Width Display (standard) Not available Chinese-language display Offline Maintain > Configuration > Input/Output > Channel B[...]

  • Seite 98

    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 277.5 milliseconds. The transmitter automatically adjusts the value to the nearest valid value. Tip Micro Motion recommends leaving Frequency Output Maximum Pulse Width at the default value. Contact Mi[...]

  • Seite 99

    Options for Frequency Output Fault Action Options for Frequency Output Fault Action Table 6-7: Label Frequency output behavior Upscale Goes to configured Upscale value: • Range: 10 Hz to 15000 Hz • Default: 15000 Hz Downscale 0 Hz Internal Zero 0 Hz None (default) Tracks data for the assigned process variable; no fault action CAUTION! If you se[...]

  • Seite 100

    6.4.1 Configure Discrete Output Source Display (standard) OFF-LINE MAINT > OFF-LINE CONFG > IO > CH B > SET DO > DO SRC Chinese-language display Offline Maintain > Configuration > Input/Output > Channel B Setup > Discrete Output > DO Source ProLink II ProLink > Configuration > Frequency/Discrete Output > Discr[...]

  • Seite 101

    Options for Discrete Output Source (continued) Table 6-8: Option Label Condition Discrete output volt- age Display (standard) Chinese-lan- guage dis- play ProLink II ProLink III Field Com- municator Flow Switch FL SW Flow Rate Switch Flow Switch Indication Flow Switch In- dicator Flow Switch ON Site-specific Forward/Re- verse Indica- tion 0 V Flow [...]

  • Seite 102

    3. Set Flow Switch Setpoint to the value at which the flow switch will be triggered (after Hysteresis is applied). • If the flow rate is below this value, the discrete output is ON. • If the flow rate is above this value, the discrete output is OFF. 4. Set Hysteresis to the percentage of variation above and below the setpoint that will operate [...]

  • Seite 103

    Options for Discrete Output Polarity Options for Discrete Output Polarity Table 6-9: Polarity Description Active High • When asserted (condition tied to DO is true), the circuit provides a pull-up to 24 V. • When not asserted (condition tied to DO is false), the circuit provides 0 V. Active Low • When asserted (condition tied to DO is true), [...]

  • Seite 104

    6.4.3 Configure Discrete Output Fault Action Display (standard) Not available Chinese-language display Not available ProLink II ProLink > Configuration > Frequency/Discrete Output > Discrete Output > DO Fault Action ProLink III Device Tools > Configuration > Fault Processing Field Communicator Configure > Manual Setup > Inpu[...]

  • Seite 105

    Options for Discrete Output Fault Action (continued) Table 6-10: Label Discrete output behavior Polarity= Active High Polarity= Active Low None (default) Discrete output is controlled by its assignment Fault indication with the discrete output To indicate faults via the discrete output, set parameters as follows: • Discrete Output Source = Fault [...]

  • Seite 106

    Procedure 1. Select the event that you want to configure. 2. Specify Event Type . 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 t[...]

  • Seite 107

    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[...]

  • Seite 108

    Options for Enhanced Event Action (continued) Table 6-11: Action Label Display (stand- ard) Chinese-lan- guage display ProLink II ProLink III Field Communi- cator Reset mass total RESET MASS Reset Mass Total Reset Mass Total Reset Mass Total Reset mass total Reset volume to- tal RESET VOL Reset Volume Total Reset Volume Total Reset Volume Total Res[...]

  • Seite 109

    Overview HART/Bell 202 communications parameters support HART communication with the transmitter's primary mA terminals over a HART/Bell 202 network. The HART/Bell 202 communications parameters include: • HART Address ( Polling Address ) • Loop Current Mode (Chinese-language display and ProLink II) or mA Output Action (ProLink III) • Bur[...]

  • Seite 110

    Configure burst parameters Display (standard) Not available Chinese-language display Not available ProLink II ProLink > Configuration > Device > Burst Setup ProLink III Device Tools > Configuration > Communications > Communications (HART) Field Communicator Configure > Manual Setup > Inputs/Outputs > Communications > S[...]

  • Seite 111

    Label Description ProLink II ProLink III Field Communi- cator Transmitter vars Transmitter varia- bles Fld dev var The transmitter sends four user- specified process variables in each burst. 3. Ensure that the burst output variables are set appropriately. • If you set Burst Mode Output to send four user-specified variables, set the four process v[...]

  • Seite 112

    Options for HART variables (continued) Table 6-12: Process variable Primary Varia- ble (PV) Secondary Variable (SV) Third Variable (TV) Fourth Varia- ble (QV ) Mass inventory ✓ Line (Gross) Volume inventory ✓ Gas standard volume flow rate ✓ ✓ ✓ ✓ Gas standard volume total ✓ Gas standard volume inventory ✓ Interaction of HART variabl[...]

  • Seite 113

    Overview HART/RS-485 communications parameters support HART communication with the transmitter's RS-485 terminals. HART/RS-485 communication parameters include: • Protocol • HART Address (Polling Address) • Parity , Stop Bits , and Baud Rate Restriction Devices with the Chinese-language display do not support HART/RS-485 communications. [...]

  • Seite 114

    Overview Modbus/RS-485 communications parameters control Modbus communication with the transmitter's RS-485 terminals. Modbus/RS-485 communications parameters include: • Disable Modbus ASCII • Protocol • Modbus Address ( Slave Address ) • Parity , Stop Bits , and Baud Rate • Floating-Point Byte Order • Additional Communications Res[...]

  • Seite 115

    Code Byte order 3 4–3 2–1 See Table 6-14 for the bit structure of bytes 1, 2, 3, and 4. Bit structure of floating-point bytes Table 6-14: Byte Bits Definition 1 SEEEEEEE S=Sign E=Exponent 2 EMMMMMMM E=Exponent M=Mantissa 3 MMMMMMMM M=Mantissa 4 MMMMMMMM M=Mantissa 6. (Optional) Set Additional Communications Response Delay in “delay units.” [...]

  • Seite 116

    Procedure Set Digital Communications Fault Action as desired. The default setting is None . Options for Digital Communications Fault Action Options for Digital Communications Fault Action Table 6-15: Label Description ProLink II ProLink III Field Communicator Upscale Upscale Upscale • Process variable values indicate that the value is greater tha[...]

  • Seite 117

    Restriction If you set Digital Communications Fault Action to NAN , you cannot set mA Output Fault Action or Frequency Output Fault Action to None . If you try to do this, the transmitter will not accept the configuration. Integrate the meter with the control system Configuration and Use Manual 111[...]

  • Seite 118

    7 Completing the configuration Topics covered in this chapter: • Test or tune the system using sensor simulation • Back up transmitter configuration • Enable write-protection on the transmitter configuration 7.1 Test or tune the system using sensor simulation Use sensor simulation to test the system's response to a variety of process con[...]

  • Seite 119

    Option Required values Sawtooth Period Minimum Maximum Sine Period Minimum Maximum 4. For density, set Wave Form as desired and enter the required values. Option Required values Fixed Fixed Value Sawtooth Period Minimum Maximum Sine Period Minimum Maximum 5. For temperature, set Wave Form as desired and enter the required values. Option Required va[...]

  • Seite 120

    When sensor simulation is enabled, the simulated values are stored in the same memory locations used for process data from the sensor. The simulated values are then used throughout transmitter functioning. For example, sensor simulation will affect: • All mass flow rate, temperature, and density values shown on the display or reported via outputs[...]

  • Seite 121

    The backup file is saved to the specified name and location. It is saved as a text file and can be read using any text editor. 7.3 Enable write-protection on the transmitter configuration Display (standard) OFF-LINE MAINT > CONFIG > LOCK Chinese-language display Offline Maintain > Configuration > Lock ProLink II ProLink > Configurati[...]

  • Seite 122

    Part III Operations, maintenance, and troubleshooting Chapters covered in this part: • Transmitter operation • Measurement support • Troubleshooting Operations, maintenance, and troubleshooting 116 Micro Motion ® Model 1700 Transmitters with Analog Outputs[...]

  • Seite 123

    8 Transmitter operation Topics covered in this chapter: • Record the process variables • View 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 pr[...]

  • Seite 124

    8.2 View process variables Display (standard) Scroll to the desired process variable. If AutoScroll is enabled, you can wait until the proc- ess variable is displayed. See Section 8.2.1 for more information. Chinese-language display Scroll to the desired process variable. If AutoScroll is enabled, you can wait until the proc- ess variable is displa[...]

  • Seite 125

    Transmitter display features Figure 8-1: A B C D E F G H A. Status LED B. Display (LCD panel) C. Process variable D. Scroll optical switch E. Optical switch indicator: turns red when either Scroll or Select is activated F. Select optical switch G. Unit of measure for process variable H. Current value of process variable 8.2.2 View process variables[...]

  • Seite 126

    Chinese-language display features Figure 8-2: A C D E F G B A. Process variable B. Current value of the process variable C. Scroll up optical switch D. Scroll down optical switch E. Select optical switch F. Unit of measure for process variable G. Display (LCD panel) 8.2.3 View process variables using ProLink III When you connect to a device, the pr[...]

  • Seite 127

    • If your transmitter does not have a display, it does not have a status LED. This option is not available. To interpret the status LED, see the following table. Restriction If LED Blinking is disabled, the status LED will flash only during calibration. It will not flash to indicate an unacknowledged alarm. Status LED states Table 8-1: LED behavi[...]

  • Seite 128

    Procedure See Figure 8-3 . Transmitter operation 122 Micro Motion ® Model 1700 Transmitters with Analog Outputs[...]

  • Seite 129

    Using the display to view and acknowledge the status alarms Figure 8-3: 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[...]

  • Seite 130

    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[...]

  • Seite 131

    Using the Chinese-language display to view and acknowledge the status alarms Figure 8-4: Acknowledge All* Y es Exit Select No Down Select *This screen is displayed only if the Acknowledge All function is enabled and there are unacknowledged alarms. Process variable display Select Alarm code Acknowledge Y es Select No Active/ unacknowledged alarms? [...]

  • Seite 132

    - If the alarm is inactive when it is acknowledged, it will be removed from the list. - If the alarm is active when it is acknowledged, it will be removed from the list when the alarm condition clears. 8.4.3 View and acknowledge alarms using ProLink II You can view a list containing all alarms that are active, or inactive but unacknowledged. From t[...]

  • Seite 133

    Category Description Failed: Fix Now A meter failure has occurred and must be addressed immediately. Maintenance: Fix Soon A condition has occurred that can be fixed at a later time. Advisory: Informational A condition has occurred, but requires no maintenance from you. Notes • All fault alerts are displayed in the Failed: Fix Now category. • A[...]

  • Seite 134

    • Recent Alerts Alarm data in transmitter memory Table 8-2: Alarm data structure Transmitter action if condition occurs Contents Clearing Alert List As determined by the alarm status bits, a list of: • All currently active alarms • All previously active alarms that have not been acknowledged Cleared and regenerated with every transmit- ter po[...]

  • Seite 135

    8.6 Start and stop totalizers and inventories Display (standard) See Section 8.6.1 . Chinese-language display Offline Maintain > Totalizer Mgmt > Start Totals Offline Maintain > Totalizer Mgmt > Stop Totals ProLink II ProLink > Totalizer Control > Start ProLink > Totalizer Control > Stop ProLink III Device Tools > Totaliz[...]

  • Seite 136

    4. Select . 5. Select again to confirm. 6. Scroll to EXIT . • To stop all totalizers and inventories using the display: 1. Scroll until the word TOTAL appears in the lower left corner of the display. Important Because all totalizers are started or stopped together, it does not matter which total you use. 2. Select . 3. Scroll until STOP appears b[...]

  • Seite 137

    Tip When you reset a single totalizer, the values of other totalizers are not reset. Inventory values are not reset. 8.7.1 Reset totalizers using the display (standard option) Prerequisites The Totalizer Reset display function must be enabled. The totalizer that you want to reset must be configured as a display variable. For example: • If you wan[...]

  • Seite 138

    6. Scroll to EXIT . 7. Select . 8.8 Reset inventories ProLink II ProLink > Totalizer Control > Reset Inventories ProLink > Totalizer Control > Reset Mass Inventory ProLink > Totalizer Control > Reset Volume Inventory ProLink > Totalizer Control > Reset Gas Volume Inventory ProLink III Device Tools > Totalizer Control >[...]

  • Seite 139

    9 Measurement support Topics covered in this chapter: • Options for measurement support • Use Smart Meter Verification • 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 measur[...]

  • Seite 140

    9.2.1 Smart Meter Verification requirements To use Smart Meter Verification, the transmitter must be paired with an enhanced core processor, and the Smart Meter Verification option must be ordered for the transmitter. See Table 9-1 for the minimum version of the transmitter, enhanced core processor, and communication tool needed to support Smart Me[...]

  • Seite 141

    Smart Meter Verification has an output mode called Continuous Measurement that allows the transmitter to keep measuring while the test is in progress. If you choose to run the test in Last Measured Value or Fault modes instead, the transmitter outputs will be held constant for the two minute duration of the test. If control loops depend on transmit[...]

  • Seite 142

    Option Description Last Value During the test, all outputs will go to their configured fault action. The test will run for approximately 140 seconds. While the test is in progress, dots traverse the display and test progress is shown. Postrequisites View the test results and take any appropriate actions. Measurement support 136 Micro Motion ® Mode[...]

  • Seite 143

    Smart Meter Verification flowchart: Running a test using the display Running a Smart Meter Verification test using the display Figure 9-2: OUTPUTS ARE YOU SURE/YES? . . . . . . . . . . . . . . . x % P ASS VERFY ABORTED VERFY CAUTION VERFY Fail Abort RERUN/YES? Y es No Correct condition RUN VERFY CONTINUE MEASR F AUL T LAST V ALUE Select Scroll Scro[...]

  • Seite 144

    Smart Meter Verification – Top-level menu Figure 9-3: Run V erify Read Results Schedule V erify Exit Down Down Down Down Select Select Select Select *This option is displayed only if the transmitter is connected to an enhanced core processor (V3.6 or higher) and the meter verification software is installed on the transmitter. Online V erify* Sele[...]

  • Seite 145

    Smart Meter Verification flowchart: Running a test using the Chinese-language display Running a Smart Meter Verification test using the Chinese-language display Figure 9-4: Stop?/Y es . . . . . . . . . . . . . . . x % Pass V erify Abort V erify Caution V erify Fail Abort Sensor Rerun? Y es No Correct condition Run V erify Continue Measure Last V al[...]

  • Seite 146

    Option Description Outputs Continue Measuring During the test, all outputs will continue to report their assigned proc- ess variable. The test will run for approximately 90 seconds. Outputs Held at Last Value During the test, all outputs will report the last measured value of their assigned process variable. The test will run for approximately 140 [...]

  • Seite 147

    • Overview > Shortcuts > Meter Verification • Service Tools > Maintenance > Routine Maintenance > Meter Verification 2. Choose Manual Verification . 3. Choose Start . 4. Set output behavior as desired, and press OK if prompted. Option Description Continue Measuring During the test, all outputs will continue to report their assign[...]

  • Seite 148

    If you use ProLink II or ProLink III to run a test, a test result chart and a test report are displayed at the completion of the test. On-screen directions are provided to manipulate the test data or export the data to a CSV file for offline analysis. View test result data using the display (standard option) 1. If you have just run a test, results [...]

  • Seite 149

    Smart Meter Verification flowchart: Viewing test results using the display (standard option) Viewing Smart Meter Verification test results using the display (standard option) Figure 9-6: RESUL TS READ Select xx L STF% RUNCOUNT x Select xx HOURS Select P ASS Select xx R STF% Select RESUL TS MORE? Select Scroll T o Run V erfy Pass Select Scroll Resul[...]

  • Seite 150

    View test result data using the Chinese-language display 1. If you have just run a test, results are displayed automatically at the end of the test. 2. If you want to view results from previous tests: a. Navigate to the Smart Meter Verification menu. Smart Meter Verification – Top-level menu Figure 9-7: Run V erify Read Results Schedule V erify E[...]

  • Seite 151

    Smart Meter Verification flowchart: Viewing test results using the Chinese- language display Viewing Smart Meter Verification test results using the Chinese-language display Figure 9-8: Read Results Select xx L STF% Run Count x Select Hours Left xx Select Pass V erify Up xx R STF% Up Select Down Pass Result type Fail Abort Hours Left xx Select Caut[...]

  • Seite 152

    View test result data using ProLink III 1. Choose Device Tools > Diagnostics > Meter Verification and click Previous Test Results . The chart shows test results for all tests stored in the ProLink III database. 2. (Optional) Click Next to view and print a test report. 3. (Optional) Click Export Data to CSV File to save the data to a file on y[...]

  • Seite 153

    Abort A problem occurred with the meter verification test (e.g., process instability) or you stopped the test manually. See Table 9-3 for a list of abort codes, a descript of each code, and possible actions you can take in response. Smart Meter Verification abort codes Table 9-3: Code Description Recommended actions 1 User-initiated abort None requ[...]

  • Seite 154

    Smart Meter Verification – Top-level menu Figure 9-9: Scroll and Select simultaneously for 4 seconds ENTER METER VERFY Scroll RUN VERFY RESUL TS READ SCHEDULE VERFY Select EXIT Scroll Scroll Scroll Scroll Select Select Select Select 2. Scroll to Schedule Verfy and press Select . 3. To schedule a single test or the first test in recurring executio[...]

  • Seite 155

    Smart Meter Verification flowchart: Scheduling test execution using the display (standard option) Scheduling Smart Meter Verification test execution using the display (standard option) Figure 9-10: SCHEDULE VERFY Select SA VE/YES? TURN OFF SCHED/YES? SET NEXT Select Select Schedule set? Y es Schedule deleted Scroll HOURS LEFT Select Scroll xx HOURS[...]

  • Seite 156

    Smart Meter Verification – Top-level menu Figure 9-11: Run V erify Read Results Schedule V erify Exit Down Down Down Down Select Select Select Select *This option is displayed only if the transmitter is connected to an enhanced core processor (V3.6 or higher) and the meter verification software is installed on the transmitter. Online V erify* Sel[...]

  • Seite 157

    Smart Meter Verification flowchart: Scheduling test execution using the Chinese- language display Scheduling Smart Meter Verification test execution using the Chinese-language display Figure 9-12: Schedule V erify Select Save?/Y es T urn Off Schedule?/Yes Set Next Select Select Schedule set? Y es Schedule deleted Up Hours Left Select Down Hours Lef[...]

  • Seite 158

    3. To schedule recurring execution, specify a value for Hours Between Recurring Runs . 4. To disable scheduled execution: • To disable execution of a single scheduled test, set Hours Until Next Run to 0. • To disable recurring execution, set Hours Between Recurring Runs to 0. • To disable all scheduled execution, click Disable Scheduled Execu[...]

  • Seite 159

    9.3.1 Zero the flowmeter using the display (standard option) Zeroing the flowmeter establishes a baseline for process measurement by analyzing the sensor's output when there is no flow through the sensor tubes. Restriction You cannot change the Zero Time setting from the display. The current setting of Zero Time will be applied to the zero pro[...]

  • Seite 160

    • Set Zero Time to a lower value, then retry. • If the zero continues to fail, contact Micro Motion. • If you want to return the flowmeter to operation using a previous zero value: - To restore the zero value set at the factory: OFFLINE MAINT > ZERO > RESTORE ZERO > RESTORE/YES? . This function requires the enhanced core processor. R[...]

  • Seite 161

    • 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 lower value, then retry. • If the zero continues to fail, contact Micro Motion. • If you want to return the flowmeter to operation using a previous zero value: - To restore the zero value s[...]

  • Seite 162

    • If the zero procedure was successful, the Calibration in Progress light returns to green and a new zero value is displayed. • If the zero procedure failed, the Calibration Failure light turns red. Postrequisites Restore normal flow through the sensor by opening the valves. Need help? If the zero fails: • Ensure that there is no flow through[...]

  • Seite 163

    2. Choose Device Tools > Calibration > Zero Verification and Calibration . 3. Click Calibrate Zero . 4. Modify Zero Time , if desired. 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. Cli[...]

  • Seite 164

    d. Verify that the sensor is blocked in, that flow has stopped, and that the sensor is completely full of process fluid. 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 Servi[...]

  • Seite 165

    9.4 Validate the meter Display (standard) OFF-LINE MAINT > CONFG > UNITS > MTR F Chinese-language display Offline Maintain > Configuration > Meter Factor ProLink II ProLink > Configuration > Flow ProLink III Device Tools > Configuration > Process Measurement > Flow Device Tools > Configuration > Process Measureme[...]

  • Seite 166

    Important For good results, the reference device must be highly accurate. Procedure 1. Determine the meter factor as follows: a. Use the flowmeter to take a sample measurement. b. Measure the same sample using the reference device. c. Calculate the meter factor using the following formula: NewMeterFactor ConfiguredMeterFactor ReferenceMeasurement F[...]

  • Seite 167

    Procedure 1. Calculate the meter factor for density, using the standard method (see Section 9.4 ). 2. Calculate the meter factor for volume flow from the meter factor for density: MeterFactor V olume 1 MeterFactor Density = Note The following equation is mathematically equivalent to the first equation. You may use whichever version you prefer. Mete[...]

  • Seite 168

    • If LD Optimization is enabled on your meter, disable it. To do this, choose ProLink > Configuration > Sensor and ensure that the checkbox is not checked. LD Optimizatio n 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,[...]

  • Seite 169

    Postrequisites If you disabled LD Optimization before the calibration procedure, re-enable it. 9.5.2 Perform a D1 and D2 density calibration using ProLink III Prerequisites • During density calibration, the sensor must be completely filled with the calibration fluid, and flow through the sensor must be at the lowest rate allowed by your applicati[...]

  • Seite 170

    D1 and D2 density calibration using ProLink III Figure 9-14: Enter density of D1 fluid D1 calibration Close shutoff valve downstream from sensor Fill sensor with D1 fluid Done Device T ools > Calibration > Density Calibration > Density Calibration – Point 1 (Air) Close Start Calibration Enter density of D2 fluid D2 calibration Fill senso[...]

  • Seite 171

    • Before performing the calibration, record your current calibration parameters. If the calibration fails, restore the known values. Restriction For T-Series sensors, the D1 calibration must be performed on air and the D2 calibration must be performed on water. Procedure See #unique_242/D1AndD2DensityCalibration-6656AA2B . D1 and D2 density calib[...]

  • Seite 172

    9.6 Perform a D3 and D4 density calibration (T- Series sensors only) For T-Series sensors, the optional D3 and D4 calibration could improve the accuracy of the density measurement if the density of your process fluid is less than 0.8 g/cm 3 or greater than 1.2 g/cm 3 . If you perform the D3 and D4 calibration, note the following: • Do not perform[...]

  • Seite 173

    D3 or D3 and D4 density calibration using ProLink II Figure 9-16: 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 Pro[...]

  • Seite 174

    - 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[...]

  • Seite 175

    • For D3 density calibration, the D3 fluid must meet the following requirements: - Minimum density of 0.6 g/cm 3 - Minimum difference of 0.1 g/cm 3 between the density of the D3 fluid and the density of water. The density of the D3 fluid may be either greater or less than the density of water. • For D4 density calibration, the D4 fluid must mee[...]

  • Seite 176

    D3 or D3 and D4 density calibration using the Field Communicator Figure 9-18: Enter density of D3 fluid Density Calibration Complete message Calibration in Progress message D3 calibration Close shutoff valve downstream from sensor Fill sensor with D3 fluid Fill sensor with D4 fluid D4 calibration OK Dens Pt 3 T -Series Calibration method executes O[...]

  • Seite 177

    Prerequisites The temperature calibration is a two-part procedure: temperature offset calibration and temperature slope calibration. The two parts must be performed without interruption, in the order shown. Ensure that you are prepared to complete the process without interruption. Important Consult Micro Motion before performing a temperature calib[...]

  • Seite 178

    Prerequisites The temperature calibration is a two-part procedure: temperature offset calibration and temperature slope calibration. The two parts must be performed without interruption, in the order shown. Ensure that you are prepared to complete the process without interruption. Important Consult Micro Motion before performing a temperature calib[...]

  • Seite 179

    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[...]

  • Seite 180

    10.1 Status LED states The status LED on the transmitter indicates whether or not alarms are active. If alarms are active, view the alarm list to identify the alarms, then take appropriate action to correct the alarm condition. Your transmitter has a status LED only if it has a display. If the transmitter has a display and LED Blinking is disabled,[...]

  • Seite 181

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Recommended actions A003 No Sensor Response The transmitter is not receiving one or more basic electrical sig- nals from the sensor. This could mean that the wiring between the sensor and the transmitter has been damaged, or that the sensor requires factory service[...]

  • Seite 182

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Recommended actions A005 Mass Flow Rate Overrange The sensor is signaling a flow rate that is out of range for the sen- sor. 1. If other alarms are present, resolve those alarm conditions first. If the current alarm persists, continue with the recom- mended actions[...]

  • Seite 183

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Recommended actions A008 Density Overrange The sensor is signaling a density reading below 0 g/cm 3 or above 10 g/cm 3 . Common causes for this alarm include partially filled flow tubes, excessive gas entrainment or flashing, tube fouling (foreign material stuck in[...]

  • Seite 184

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Recommended actions A010 Calibration Failure This alarm is typically caused by flow through the sensor during the zero, or by a zero offset result that is out of range. Power to the transmitter must be cycled to clear this alarm. 1. Cycle power to the meter. 2. Mak[...]

  • Seite 185

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Recommended actions A016 Sensor RTD Failure The sensor RTD is signaling a resistance that is out of range for the sensor. 1. Check the wiring between the sensor and the transmitter. a. Using the installation manual for your transmitter, verify that the transmitter [...]

  • Seite 186

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Recommended actions A019 RAM Error (Transmitter) Power to the transmitter must be cycled to clear this alarm. 1. Check that all wiring compartment covers are installed prop- erly. 2. Check that the wiring connected to the transmitter meets specifications and that s[...]

  • Seite 187

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Recommended actions A026 Sensor/Transmitter Communi- cations Failure The transmitter has lost communication with the core processor on the sensor. This alarm can be an indication of a problem with the core or the transmitter requiring the replacement of one or both[...]

  • Seite 188

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Recommended actions A031 Low Power The core processor on the sensor is not receiving sufficient pow- er. Check the wiring between the transmitter and the sensor. Power to the transmitter must be cycled to clear this alarm. 1. Using the installation manual for your [...]

  • Seite 189

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Recommended actions A100 mA Output 1 Saturated The calculated mA output value is outside of the meter's config- ured range. 1. Check the Upper Range Value and Lower Range Value parame- ters. Are they set correctly? 2. Check your process conditions against the [...]

  • Seite 190

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Recommended actions A110 Frequency Output Saturated The calculated frequency output is outside the configured range. 1. Check the Frequency Output Scaling Method parameter. 2. Check your process conditions against the values reported by the flowmeter. 3. Verify pro[...]

  • Seite 191

    Status alarms and recommended actions (continued) Table 10-2: Alarm code Description Recommended actions A117 Density Overrange (Petrole- um) 1. Check your process conditions against the values reported by the flowmeter. 2. Verify the configuration of the petroleum measurement ta- ble type and density. A118 Discrete Output 1 Fixed The discrete outp[...]

  • Seite 192

    10.3 Flow measurement problems Flow measurement problems and recommended actions Table 10-3: Problem Possible causes Recommended actions Flow indication at no flow conditions or zero offset • Misaligned piping (especially in new in- stallations) • Open or leaking valve • Incorrect sensor zero • Verify that all of the characterization parame[...]

  • Seite 193

    Flow measurement problems and recommended actions (continued) Table 10-3: Problem Possible causes Recommended actions Erratic non-zero flow rate when flow is steady • Slug flow • Damping value too low • Plugged or coated flow tube • Output wiring problem • Problem with receiving device • Wiring problem • Verify that the sensor orienta[...]

  • Seite 194

    10.4 Density measurement problems Density measurement problems and recommended actions Table 10-4: Problem Possible causes Recommended actions Inaccurate density reading • Problem with process fluid • Incorrect density calibration factors • Wiring problem • Incorrect flowmeter grounding • Slug flow • Plugged or coated flow tube • Inco[...]

  • Seite 195

    10.5 Temperature measurement problems Temperature measurement problems and recommended actions Table 10-5: Problem Possible causes Recommended actions Temperature reading significantly different from process temper- ature • RTD failure • Wiring problem • Check junction box for moisture or verdi- gris. • Perform RTD resistance checks and che[...]

  • Seite 196

    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 • Channel not configured for desired output • Check the power supply and power supply wiring. See Section 10.9 . • Check the mA output wiring. • Check the [...]

  • Seite 197

    Milliamp output problems and recommended actions (continued) Table 10-6: Problem Possible causes Recommended actions Consistently incorrect mA measurement • Loop problem • Output not trimmed correctly • Incorrect flow measurement unit config- ured • Incorrect process variable configured • LRV and URV are not set correctly • Check the mA[...]

  • Seite 198

    10.8 Use sensor simulation for troubleshooting When sensor simulation is enabled, the transmitter reports user-specified values for mass flow, temperature, and density. This allows you to reproduce various process conditions or to test the system. You can use sensor simulation to help distinguish between legitimate process noise and externally caus[...]

  • Seite 199

    6. Reapply power to the transmitter. CAUTION! If the transmitter is in a hazardous area, do not reapply power to the transmitter with the housing cover removed. Reapplying power to the transmitter while the housing cover is removed could cause an explosion. 7. Use a voltmeter to test the voltage at the transmitter’s power supply terminals. The vo[...]

  • Seite 200

    Procedure Refer to the sensor and transmitter installation manuals for grounding requirements and instructions. 10.12 Perform loop tests 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. 10.12.1 Perform loop tests using the displ[...]

  • Seite 201

    2. Test the frequency output(s). a. Choose OFFLINE MAINT > SIM > FO SIM , and select the frequency output value. The frequency output can be set to 1, 10, or 15 kHz. Note If the Weights & Measures application is enabled on the transmitter, it is not possible to perform a loop test of the frequency output, even when the transmitter is unse[...]

  • Seite 202

    Procedure 1. Test the mA output(s). a. Choose Offline Maintain > Simulation > Milliamp Output and select a low value, e.g., 4 mA. Dots traverse the display while the output is fixed. b. 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 di[...]

  • Seite 203

    c. At the transmitter, activate Select . d. Scroll to and select Off . e. Verify the signal at the receiving device. f. At the transmitter, activate Select . Postrequisites • If the mA output reading at the receiving device was slightly inaccurate, you can correct this discrepancy by trimming the output. • If the mA output reading at the receiv[...]

  • Seite 204

    The readings do not need to match exactly. If the values are slightly different, you can correct the discrepancy by trimming the output. i. Click UnFix mA . 2. Test the frequency output(s). a. Choose ProLink > Test > Fix Freq Out . b. Enter the frequency output value in Set Output To . c. Click Fix Frequency . d. Read the frequency signal at [...]

  • Seite 205

    Procedure 1. Test the mA output(s). a. Choose Device Tools > Diagnostics > Testing > mA Output 1 Test or Device Tools > Diagnostics > Testing > mA Output 2 Test . b. Enter 4 in Fix 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 exac[...]

  • Seite 206

    • If the mA output reading at the receiving device was significantly inaccurate, or if at any step the reading was faulty, verify the wiring between the transmitter and the remote device, and try again. • If the discrete output reading is reversed, check the setting of Discrete Output Polarity . 10.12.5 Perform loop tests using the Field Commun[...]

  • Seite 207

    b. Read the frequency signal at the receiving device and compare it to the transmitter output. c. Choose End . 3. Test the discrete output(s). a. Press Service Tools > Simulate > Simulate Outputs > Discrete Output Test . b. Choose Off . c. Verify the signal at the receiving device. d. Press OK . e. Choose On . f. Verify the signal at the r[...]

  • Seite 208

    2. Follow the instructions in the guided method. Important If you are using a HART/Bell 202 connection, the HART signal over the primary mA output affects the mA reading. Disconnect the wiring between ProLink II and the transmitter terminals when reading the primary mA output at the receiving device. Reconnect to continue the trim. 3. Check the tri[...]

  • Seite 209

    Prerequisites Ensure that the mA output is wired to the receiving device that will be used in production. Procedure 1. Choose . 2. Follow the instructions in the guided method. 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 [...]

  • Seite 210

    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[...]

  • Seite 211

    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 there are no active fault conditions, continue troubleshoo[...]

  • Seite 212

    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 constant value, the transmitter may be in a fault condition. 1. Check the status alarms for active fault conditons. 2. If there ar[...]

  • Seite 213

    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 cause the transmitter to report zero flow, or to post several different alarms. 1. Check for slug flow alarms. If the transmitter is not generating slug flow alarms, slug flow is not the source of your problem. 2. Check [...]

  • Seite 214

    Possible causes and recommended actions for excessive (saturated) drive gain (continued) Table 10-8: Possible cause Recommended actions Bent flow tube Check the pickoff voltages (see Section 10.27 ). If either of them are close to zero (but neither is zero), the flow tubes may be bent. The sensor will need to be replaced. Cracked flow tube Replace [...]

  • Seite 215

    To know whether your pickoff voltage is unusually low, you must collect pickoff voltage data during the problem condition and compare it to pickoff voltage data from a period of normal operation. Possible causes and recommended actions for low pickoff voltage Table 10-10: Possible cause Recommended actions Air entrainment • Increase the inlet or [...]

  • Seite 216

    Possible causes and recommended actions for electrical shorts Table 10-11: Possible cause Recommended action Moisture inside the junction box Ensure that the junction box is dry and no corrosion is present. Liquid or moisture inside the sensor case Contact Micro Motion. Internally shorted feedthrough Contact Micro Motion. Faulty cable Replace the c[...]

  • Seite 217

    Coils and test terminal pairs (continued) Table 10-12: Coil Sensor model Terminal colors Composite RTD T-Series Yellow to orange Fixed resistor (see note) CMF400 Yellow to orange Note The CMF400 fixed resistor applies only to certain specific CMF400 releases. Contact Micro Motion for more information. There should be no open circuits, that is, no i[...]

  • Seite 218

    1. Plug the terminal blocks into the terminal board. 2. Replace the end-cap on the core processor housing. 3. Replace the lid on the sensor junction box. Important When reassembling the meter components, be sure to grease all O-rings. 10.29 Check the core processor LED The core processor has an LED that indicates different meter conditions. 1. Main[...]

  • Seite 219

    4. If you have a 9-wire remote installation: a. Remove the end-cap. 9-wire remote installation components Figure 10-2: Transmitter Core processor 4 x cap screws (4 mm) End-cap b. Inside the core processor housing, loosen the three screws that hold the core processor mounting plate in place. Do not remove the screws. c. Rotate the mounting plate so [...]

  • Seite 220

    • For a 9-wire remote installation: 1. Without pinching or stressing the wires, slide the mounting plate into place. 2. Rotate the mounting plate so that the screws are in the locked position. 3. Tighten the screws, torquing to 6 to 8 in-lbs (0.7 to 0.9 N-m). 4. Replace the end-cap. Important When reassembling the meter components, be sure to gre[...]

  • Seite 221

    Enhanced core processor LED states Table 10-14: LED state Description Recommended action Solid green Normal operation No action required. Flashing yellow Zero in progress No action required. Solid yellow Low-severity alarm Check alarm status. Solid red High-severity alarm Check alarm status. Flashing red (80% on, 20% off) Tubes not full • If alar[...]

  • Seite 222

    Integral installation components Figure 10-3: Base 4 x cap screws (4 mm) Transition ring Transmitter Core processor b. Rotate the transmitter counter-clockwise so that the cap screws are in the unlocked position. c. Gently lift the transmitter straight up, disengaging it from the cap screws. 4. If you have a 9-wire remote installation: a. Remove th[...]

  • Seite 223

    5. At the core processor, disconnect the 4-wire cable between the core processor and the transmitter. 6. Measure the resistance between core processor terminal pairs 3–4, 2–3, and 2–4. Terminal pair Function Expected resistance 3–4 RS-485/A and RS-485/B 40 k Ω to 50 k Ω 2–3 VDC– and RS-485/A 20 k Ω to 25 k Ω 2–4 VDC– and RS-485/[...]

  • Seite 224

    Appendix A Using the standard 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 t[...]

  • Seite 225

    Transmitter interface Figure A-1: A B C D E F G H A. Status LED B. Display (LCD panel) C. Process variable D. Scroll optical switch E. Optical switch indicator F. Select optical switch G. Unit of measure for process variable H. Current value of process variable A.2 Use the optical switches Use the optical switches on the transmitter interface to co[...]

  • Seite 226

    Optical switch indicator and optical switch states Table A-1: Optical switch indicator State of optical switches Solid red One optical switch is activated. Flashing red Both optical switches are activated. A.3 Access and use the display menu system The display menu system is used to perform various configuration, administrative, and maintenance tas[...]

  • Seite 227

    Tip If you do not know the correct value for Off-Line Password , wait 30 seconds. The password screen will time out automatically and you will be returned to the previous screen. 4. If Scroll flashes on the display, activate the Scroll optical switch, then the Select optical switch, and then the Scroll optical switch again. The display will prompt [...]

  • Seite 228

    1. Activate Select until the digit you want to change is active (flashing). Select moves the cursor one position to the left. From the leftmost position, Select moves the cursor to the rightmost digit. 2. Activate Scroll to change the value of the active digit. 3. Repeat until all digits are set as desired. • To change the sign of the value: - If[...]

  • Seite 229

    - If the displayed value is not the same as the value in transmitter memory, SAVE/ YES? flashes on the display. Activate Scroll . 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 fo[...]

  • Seite 230

    f. Activate Scroll until the desired character is displayed. g. Activate Select to move the cursor one digit to the left. 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, sele[...]

  • Seite 231

    Display codes for process variables (continued) Table A-2: Code Definition Comment or reference MTR_T Case temperature (T-Series sensors only) 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 [...]

  • Seite 232

    Codes and abbreviations used in display menus (continued) Table A-3: Code or abbrevi- ation Definition Comment or reference ACT Action 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 CA[...]

  • Seite 233

    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 [...]

  • Seite 234

    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[...]

  • Seite 235

    A.6 Menu maps for the transmitter display Offline menu – top level Figure A-2: Scroll and Select simultaneously for 4 seconds SWREV OFF-LINE MAINT Select SEE ALARM Scroll Scroll Scroll EXIT CONFG Scroll SIM Scroll ZERO ENTER METER VERFY (1) EXIT (1) This option is displayed only if the transmitter is connected to an enhanced cor e processor and t[...]

  • Seite 236

    Offline menu – version information Figure A-3: Scroll and Select simultaneously for 4 seconds SWREV Y es Version info* Scroll Select Y es ETO info* Scroll Scroll SENSOR VERFY* Scroll EXIT OFF-LINE MAINT Select Scroll * Displayed only if the corresponding ET O or application is installed on the transmitter. Using the standard transmitter display 2[...]

  • Seite 237

    Offline menu – configuration: units and I/O Figure A-4: OFF-LINE MAINT Scroll and Select simultaneously for 4 seconds Scroll Select Select Scroll CONFG MASS UNITS VOL/GSV DENS TEMP Select Scroll Scroll Scroll AO 1 SRC AO 1 4 MA AO 120 MA Scroll Scroll EXIT Scroll Scroll PRESS FO FO SRC FO FREQ Select Scroll Scroll Scroll FO RA TE Scroll FO POLAR [...]

  • Seite 238

    Offline menu – configuration: meter factor, display, and digital communications Figure A-5: OFF-LINE MAINT Scroll and Select simultaneously for 4 seconds Scroll Select Select Scroll CONFG UNITS MASS MTR F VOL Select Scroll Scroll DENS EXIT Scroll Scroll Scroll TOT ALS RESET DISPLA Y TOT ALS STOP DISPLA Y OFFLN* Select Scroll Scroll Scroll DISPLA [...]

  • Seite 239

    Offline menu – alarms Figure A-6: SEE ALARM 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 *This screen is displayed only if the ACK ALL function s enabled and there are unacknowle[...]

  • Seite 240

    Offline menu – meter verification: top level Figure A-7: Scroll and Select simultaneously for 4 seconds ENTER METER VERFY Scroll RUN VERFY RESUL TS READ SCHEDULE VERFY Select EXIT Scroll Scroll Scroll Scroll Select Select Select Select Offline menu – meter verification schedule Figure A-8: SCHEDULE VERFY Select SA VE/YES? TURN OFF SCHED/YES? SE[...]

  • Seite 241

    Offline menu – meter verification test Figure A-9: OUTPUTS ARE YOU SURE/YES? . . . . . . . . . . . . . . . x % P ASS VERFY ABORTED VERFY CAUTION VERFY Fail Abort RERUN/YES? Y es No Correct condition RUN VERFY CONTINUE MEASR F AUL T LAST V ALUE Select Scroll Scroll Scroll Select Scroll RESUL TS VIEW/YES? Select Scroll Scroll Select Select Select S[...]

  • Seite 242

    Offline menu – meter verification results Figure A-10: RESUL TS READ Select xx L STF% RUNCOUNT x Select xx HOURS Select P ASS Select xx R STF% Select RESUL TS MORE? Select Scroll Pass Select Scroll Result type Fail Abort xx HOURS Select CAUTION xx L STF% xx R STF% Select Select xx HOURS Abort T ype T o Runcount x -1 Select Select Select T o Run V[...]

  • Seite 243

    Offline menu – totalizers and inventories Figure A-11: RESET (3) Select Scroll STOP/ST ART (2) RESET YES? Process variable display STOP/ST ART YES? Scroll Mass total V olume total Scroll Select Y es No Select Scroll EXIT Select Y es No Select Scroll Scroll E1--SP (1) E2--SP (1) Scroll Scroll Scroll (1) The Event Setpoint screens can be used to de[...]

  • Seite 244

    Offline menu – Simulation (loop testing) Figure A-12: Scroll and Select simultaneously for 4 seconds Y es Scroll Select AO SIM FO SIM DO SIM Scroll Select SET x MA* Y es Select** SET y KHZ**** Select SET OFF SET ON Select EXIT Scroll Scroll Select*** . . . . . . . . . . . . . . . . EXIT Y es Select** Scroll Select*** . . . . . . . . . . . . . . .[...]

  • Seite 245

    Offline menu – Zero Figure A-13: …………………. OFF-LINE MAINT Scroll and Select simultaneously for 4 seconds Scroll Select Select CAL ZERO Troubleshoot ZERO/YES? CAL P ASS CAL F AIL RESTORE ZERO RESTORE ZERO/YES? Current zero display Factory zero display Select Select Y es No EXIT Scroll Select Scroll Scroll Scroll Y es Select No Scroll [...]

  • Seite 246

    Appendix B Using the Chinese-language display Topics covered in this appendix: • Components of the transmitter interface • Use the optical switches • Access and use the display menu system • Menu maps for the transmitter display B.1 Components of the transmitter interface The Chinese-language display interface includes the status LED, the d[...]

  • Seite 247

    Display feature shortcut keys Figure B-2: A B C D E A. Returns to the process variable view B. Change the language display: English or Chinese C. Access to show or hide the Offline menu D. Unlock or lock the display E. Activate the optical switches in the shown combinations to perform the specific task B.2 Use the optical switches Use the optical s[...]

  • Seite 248

    Optical switch indicator and optical switch states Table B-1: Optical switch indicator State of optical switches Solid red One optical switch is activated. Flashing red More than one optical switch is activated. B.3 Access and use the display menu system The display menu system is used to perform various configuration, administrative, and maintenan[...]

  • Seite 249

    b. Repeat this process for the second, third, and fourth digits. Tip If you do not know the correct value for Offline Password , wait 30 seconds. The password screen will time out automatically and you will be returned to the previous screen. 5. If Up flashes on the display, activate the Up optical switch, then the Down optical switch, and then the[...]

  • Seite 250

    Procedure • To change the value: 1. Activate Select until the digit you want to change is active (flashing). Select moves the cursor one position to the left. From the leftmost position, Select moves the cursor to the rightmost digit. 2. Activate Up/Down to change the value of the active digit. 3. Repeat until all digits are set as desired. • T[...]

  • Seite 251

    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 positive number. • X.XXX = The 4-digit mantissa. • E = The exponent indicator. • YY = The 2-digit exponent. Procedure 1. Switch from decimal notation to expon[...]

  • Seite 252

    b. Activate Up/Down until the desired character is displayed. For positive numbers, select a blank space. 5. To save the displayed value to transmitter memory, activate Down and Select simultaneously and hold until the display changes. • If the displayed value is the same as the value in transmitter memory, you will be returned to the previous sc[...]

  • Seite 253

    B.4 Menu maps for the transmitter display Offline menu – top level Figure B-3: Software V ersion Offline Maintain Select Alarm Down Down Exit Configuration Down Simulation T otalizer Mgmt Down Down Down Sensor Zero * Process variable display Select Down Meter V erify** Down Exit * Shown only when connected to a 700 or 800 core processor that has [...]

  • Seite 254

    Offline menu – version information Figure B-4: Software V ersion Transmitter and Core V ersion Information (Read Only) Select Y es ETO (CEQ) info* Down Y es Meter V erify** Down Down Exit Offline Maintain Up Down *The option is displayed only if the corresponding CEQ/ETO or application is installed on the transmitter. **This option is displayed o[...]

  • Seite 255

    Offline menu – configuration: units and I/O Figure B-5: Offline Maintain Select Select Down Select Configuration Mass Flow Rate Units V olume Flow Rate* Density T emperature Select Down Down Down mAO Source V ariable at 4 mA V ariable at 20 mA Down Down Exit Down Down Pressure Frequency Output*** FO Source Select Down Down Down Flow Rate Factor D[...]

  • Seite 256

    Offline menu – configuration: meter factor and display Figure B-6: …(continued) Mass Flow Rate Meter Factor V olume Flow Rate Select Down Down LD Optimization Exit Down Down Down Reset T otals Display Start/Stop T otals Offline Menu* Select Down Down Down Alarm Menu Num of Decimals Down Acknowledge All Down Auto Down** Down Offline Password*** [...]

  • Seite 257

    Offline menu – configuration: sensor calibration, low flow cutoff, and damping Figure B-7: …(continued) Down Calibrate Sensor Select Flow Cal Factor Density Cal Factor T emperature Cal Factor Exit Down Down Down Offline Maintain Select Select Down Select Configuration Process variable display Up Select Down Low Flow Cutoff Select Mass Flow Cuto[...]

  • Seite 258

    Offline menu – alarms Figure B-8: Acknowledge All* Y es Exit Select No Down Select *This screen is displayed only if the Acknowledge All function is enabled and there are unacknowledged alarms. Process variable display Select Alarm code Acknowledge Y es Select No Active/ unacknowledged alarms? No Y es No Alarm Exit Down Down Down Select Alarm Sel[...]

  • Seite 259

    Offline menu – meter verification: top level Figure B-9: Run V erify Read Results Schedule Verify Exit Down Down Down Down Select Select Select Select *This option is displayed only if the transmitter is connected to an enhanced core processor (V3.6 or higher) and the meter verification software is installed on the transmitter. Online V erify* Se[...]

  • Seite 260

    Offline menu – meter verification test Figure B-11: Stop?/Y es . . . . . . . . . . . . . . . x % Pass V erify Abort V erify Caution V erify Fail Abort Sensor Rerun? Y es No Correct condition Run V erify Continue Measure Last V alue Select Down Down Up Select Down Results View/Y es? Down Down Select Select Select Select Select Sensor Abort?/Y es S[...]

  • Seite 261

    Offline menu – meter verification results Figure B-12: Read Results Select xx L STF% Run Count x Select Hours Left xx Select Pass V erify Up xx R STF% Up Select Down Pass Result type Fail Abort Hours Left xx Select Caution V erify xx L STF% Up Hours Left xx Abort T ype T o Runcount x -1 Select Up Select Select xx R STF% Using the Chinese-language[...]

  • Seite 262

    Offline menu – totalizers and inventories Figure B-13: Offline Maintain Select Select Down Select T otalizer Mgmt Event 2 T otal* Event 1 T otal* Start T otals** Reset T otal Down Down Down Down Exit Process variable display Up Select Stop T otals** Down *This option displays only when Event X is enabled. **The Stop T otals option displays when y[...]

  • Seite 263

    Offline menu – Simulation (loop testing) Figure B-14: Y es Select Milliamp Output Frequency Output* Discrete Output* Down Select x mA (1) Y es y KHZ (4) Select Off On Select Exit Down Down Select (3) . . . . . . . . . . . . . . . . Exit Y es Down . . . . . . . . . . . . . . . . Y es Exit Down . . . . . . . . . . . . . . . . Y es Select (2) Down .[...]

  • Seite 264

    Offline menu – Zero Figure B-15: …………………. Select Calibration Zero Troubleshoot Zero? Calibration Result Pass Calibration Result Fail Zero Result Current Zero Standard Deviation* Select Exit Select Down Down Y es Select No Up Down Offline Maintain Select Down Select Process variable display Up Select Exit Down Factory Zero** Down Res[...]

  • Seite 265

    Appendix C Using ProLink II with the transmitter Topics covered in this appendix: • Basic information about ProLink II • Connect with ProLink II • Menu maps for ProLink II C.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 [...]

  • Seite 266

    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. C.2 Connect with ProLink II A connection from ProLink II[...]

  • Seite 267

    C.2.2 Make a service port connection CAUTION! If the transmitter is in a hazardous area, do not use a service port connection. Service port connections require opening the wiring compartment, and opening the wiring compartment while the transmitter is powered up could cause an explosion. To connect to the transmitter in a hazardous environment, use[...]

  • Seite 268

    Connection to service port Figure C-1: A C D E B A. PC B. Signal converter C. Service port terminal 7 (RS-485/A) D. Service port terminal 8 (RS-485/B) E. Transmitter, with wiring compartment and power supply compartment opened Note This figure shows a serial port connection. USB connections are also supported. 4. Start ProLink II. 5. Choose Connect[...]

  • Seite 269

    CAUTION! If the transmitter is in a hazardous area, do not connect directly to the transmitter terminals. Connecting directly to the transmitter terminals requires opening the wiring compartment, and opening the wiring compartment while the transmitter is powered up could cause an explosion. To connect to the transmitter in a hazardous environment,[...]

  • Seite 270

    Connection to transmitter terminals Figure C-2: A C D B A. PC B. Signal converter C. 250–600 Ω resistance D. Transmitter, with wiring compartment and power supply compartment opened Note This figure shows a serial port connection. USB connections are also supported. 3. To connect from a point in the local HART loop: a. Attach the leads from the[...]

  • Seite 271

    Connection over local loop Figure C-3: A C D E R1 R3 R2 B A. PC B. Signal converter C. Any combination of resistors R1, R2, and R3 as necessary to meet HART communication resistance requirements D. DCS or PLC E. Transmitter, with wiring compartment and power supply compartment opened Note This figure shows a serial port connection. USB connections [...]

  • Seite 272

    Connection over multidrop network Figure C-4: B A C D A. Signal converter B. 250–600 Ω resistance C. Devices on the network D. Master device 5. Start ProLink II. 6. Choose Connection > Connect to Device . 7. Set Protocol to HART Bell 202 . Tip HART/Bell 202 connections use standard connection parameters. You do not need to configure them her[...]

  • Seite 273

    Option Description Primary Use this setting if no other host is on the network. The Field Communicator is not a host. 12. Click Connect . Need help? If an error message appears: • Verify the HART address of the transmitter. • Ensure that you have specified the correct COM port. • Check the physical connection between the PC and the transmitte[...]

  • Seite 274

    Tip HART connections are not polarity-sensitive. It does not matter which lead you attach to which terminal. Connection to transmitter terminals Figure C-5: A C B A. PC B. Signal converter C. Transmitter, with wiring compartment and power supply compartment opened Note This figure shows a serial port connection. USB connections are also supported. [...]

  • Seite 275

    Connection over network Figure C-6: A C E D B A. PC B. Signal converter C. 120- Ω , 1/2-watt resistors at both ends of the segment, if necessary D. DCS or PLC E. Transmitter, with wiring compartment and power supply compartment opened Note This figure shows a serial port connection. USB connections are also supported. 4. Start ProLink II. 5. Choo[...]

  • Seite 276

    Option Description Secondary Use this setting if another HART host such as a DCS is on the network. Primary Use this setting if no other host is on the network. The Field Communicator is not a host. 9. Click Connect . Need help? If an error message appears: • Verify the HART address of the transmitter. • Ensure that you have specified the corre[...]

  • Seite 277

    Tip Usually, but not always, the black lead is RS-485/A and the red lead is RS-485/B. Connection to transmitter terminals Figure C-7: A C B A. PC B. Signal converter C. Transmitter, with wiring compartment and power supply compartment opened Note This figure shows a serial port connection. USB connections are also supported. 3. To connect over the [...]

  • Seite 278

    Connection over network Figure C-8: A C E D B A. PC B. Signal converter C. 120- Ω , 1/2-watt resistors at both ends of the segment, if necessary D. DCS or PLC E. Transmitter, with wiring compartment and power supply compartment opened Note This figure shows a serial port connection. USB connections are also supported. 4. Start ProLink II. 5. Choo[...]

  • Seite 279

    Need help? If an error message appears: • Verify the Modbus address of the transmitter. • Ensure that you have specified the correct COM port. • Check the physical connection between the PC and the transmitter. • Increase or decrease resistance. • For long-distance communication, or if noise from an external source interferes with the sig[...]

  • Seite 280

    Main menu (continued) Figure C-10: Data Logging* Enable/Disable Custody T ransfer Gas Unit Configurator Meter V erification Entrained Gas Analyzer Commissioning Wizard Proving Wizard Marine Bunker T ransfer Options T ools Plug-ins ProLink Configuration Output Levels Process V ariables Status Alarm Log Diagnostic Information Calibration T est API T [...]

  • Seite 281

    Configuration menu Figure C-11: Flow • Flow Direction • Flow Damp • Flow Cal • Mass Flow Cutoff • Mass Flow units • Mass Factor • Dens Factor • V ol Factor • Flow Switch V ariable • Flow Switch Setpoint • Flow Switch Hysteresis • V ol Flow Cutoff • V ol Flow Units • V ol Flow T ype • Std Gas V ol Flow Cutoff • Std Ga[...]

  • Seite 282

    Configuration menu (continued) Figure C-12: T emperature • T emp Units • T emp Cal Factor • T emp Damping • External T emperature • External RTD Frequency/Discrete Output • Frequency • T ertiary V ariable • Freq Factor • Rate Factor • Freq Pulse Width • Last Measured V alue Timeout • Scaling Method • Pulses Per lbs • lbs[...]

  • Seite 283

    Configuration menu (continued) Figure C-13: ProLink > Configuration Device • Model • Manufacturer • Hardware Rev • Distributor • Software Rev • ETO • CP Software Rev • CP ETO • Option Board • Firmware Checksum • CP Firmware Checksum • T ag • Date • Descriptor • Message • Sensor type • Transmitter Serial • Floa[...]

  • Seite 284

    Configuration menu (continued) Figure C-14: ProLink > Configuration Polled V ariables Polled V ariable 1/2 • Polling Control • External T ag • V ariable T ype • Current V alue Discrete Events • Event Name • Event T ype • Process V ariable • Low Setpoint (A) • High Setpoint (B) Alarm • Alarm • Severity Events Event 1/2 • V[...]

  • Seite 285

    Configuration menu (continued) Figure C-15: ProLink > Configuration Special Units • Base Mass Unit • Base Mass Time • Mass Flow Conv Fact • Mass Flow T ext • Mass T otal T ext • Base V ol Unit • Base V ol T ime • V ol Flow Conv Fact • V ol Flow T ext • V ol T otal T ext Additional configuration options Display • mA1 • V a[...]

  • Seite 286

    Configuration menu (continued) Figure C-16: ProLink > Configuration Sensor Simulation • Enable/disable • Mass flow • Wave form • Fixed value • Period • Minimum • Maximum • Density • Wave form • Fixed value • Period • Minimum • Maximum • T emperature • Wave form • Fixed value • Period • Minimum • Maximum Sens[...]

  • Seite 287

    Appendix D Using ProLink III with the transmitter Topics covered in this appendix: • Basic information about ProLink III • Connect with ProLink III • Menu maps for ProLink III D.1 Basic information about ProLink III ProLink III is a configuration and service tool available from Micro Motion. It runs on a Windows platform and provides complete[...]

  • Seite 288

    ProLink III messages As you use ProLink III 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. D.2 Connect with ProLink III A connection from ProLink[...]

  • Seite 289

    D.2.2 Make a service port connection CAUTION! If the transmitter is in a hazardous area, do not use a service port connection. Service port connections require opening the wiring compartment, and opening the wiring compartment while the transmitter is powered up could cause an explosion. To connect to the transmitter in a hazardous environment, use[...]

  • Seite 290

    Connection to service port Figure D-1: A C D E B A. PC B. Signal converter C. Service port terminal 7 (RS-485/A) D. Service port terminal 8 (RS-485/B) E. Transmitter, with wiring compartment and power supply compartment opened Note This figure shows a serial port connection. USB connections are also supported. 4. Start ProLink III. 5. Choose Connec[...]

  • Seite 291

    CAUTION! If the transmitter is in a hazardous area, do not connect directly to the transmitter terminals. Connecting directly to the transmitter terminals requires opening the wiring compartment, and opening the wiring compartment while the transmitter is powered up could cause an explosion. To connect to the transmitter in a hazardous environment,[...]

  • Seite 292

    Connection to transmitter terminals Figure D-2: A C D B A. PC B. Signal converter C. 250–600 Ω resistance D. Transmitter, with wiring compartment and power supply compartment opened Note This figure shows a serial port connection. USB connections are also supported. 3. To connect from a point in the local HART loop: a. Attach the leads from the[...]

  • Seite 293

    Connection over local loop Figure D-3: A C D E R1 R3 R2 B A. PC B. Signal converter C. Any combination of resistors R1, R2, and R3 as necessary to meet HART communication resistance requirements D. DCS or PLC E. Transmitter, with wiring compartment and power supply compartment opened Note This figure shows a serial port connection. USB connections [...]

  • Seite 294

    Connection over multidrop network Figure D-4: B A C D A. Signal converter B. 250–600 Ω resistance C. Devices on the network D. Master device 5. Start ProLink III. 6. Choose Connect to Physical Device . 7. Set Protocol to HART Bell 202 . Tip HART/Bell 202 connections use standard connection parameters. You do not need to configure them here. 8. [...]

  • Seite 295

    Option Description Primary Use this setting if no other host is on the network. The Field Communicator is not a host. 12. Click Connect . Need help? If an error message appears: • Verify the HART address of the transmitter. • Ensure that you have specified the correct COM port. • Check the physical connection between the PC and the transmitte[...]

  • Seite 296

    Tip HART connections are not polarity-sensitive. It does not matter which lead you attach to which terminal. Connection to transmitter terminals Figure D-5: A C B A. PC B. Signal converter C. Transmitter, with wiring compartment and power supply compartment opened Note This figure shows a serial port connection. USB connections are also supported. [...]

  • Seite 297

    Connection over network Figure D-6: A C E D B A. PC B. Adapter, if necessary C. Signal converter D. 120- Ω , 1/2-watt resistors at both ends of the segment, if necessary E. DCS or PLC F. Transmitter, with wiring compartment and power supply compartment opened Note This figure shows a serial port connection. USB connections are also supported. 4. [...]

  • Seite 298

    8. Set Master as appropriate. Option Description Secondary Use this setting if another HART host such as a DCS is on the network. Primary Use this setting if no other host is on the network. The Field Communicator is not a host. 9. Click Connect . Need help? If an error message appears: • Verify the HART address of the transmitter. • Ensure tha[...]

  • Seite 299

    b. Connect the leads from the signal converter to terminals 5 (RS-485/A) and 6 (RS-485/B). Tip Usually, but not always, the black lead is RS-485/A and the red lead is RS-485/B. Connection to transmitter terminals Figure D-7: A C B A. PC B. Signal converter C. Transmitter, with wiring compartment and power supply compartment opened Note This figure [...]

  • Seite 300

    Connection over network Figure D-8: A C E D B A. PC B. Signal converter C. 120- Ω , 1/2-watt resistors at both ends of the segment, if necessary D. DCS or PLC E. Transmitter, with wiring compartment and power supply compartment opened Note This figure shows a serial port connection. USB connections are also supported. 4. Start ProLink III. 5. Cho[...]

  • Seite 301

    Need help? If an error message appears: • Verify the Modbus address of the transmitter. • Ensure that you have specified the correct COM port. • Check the physical connection between the PC and the transmitter. • Increase or decrease resistance. • For long-distance communication, or if noise from an external source interferes with the sig[...]

  • Seite 302

    Configuration: Process Measurement Figure D-10: Configuration: I/O Figure D-11: Using ProLink III with the transmitter 296 Micro Motion ® Model 1700 Transmitters with Analog Outputs[...]

  • Seite 303

    Configuration: Events Figure D-12: Configuration: Communications Figure D-13: Using ProLink III with the transmitter Configuration and Use Manual 297[...]

  • Seite 304

    Configuration: Informational Parameters Figure D-14: Device Tools: Calibration Figure D-15: Using ProLink III with the transmitter 298 Micro Motion ® Model 1700 Transmitters with Analog Outputs[...]

  • Seite 305

    Calibration: Density Calibration Figure D-16: Calibration: Temperature Calibration Figure D-17: Using ProLink III with the transmitter Configuration and Use Manual 299[...]

  • Seite 306

    Device Tools: Configuration Transfer Figure D-18: Diagnostics: Testing Figure D-19: Using ProLink III with the transmitter 300 Micro Motion ® Model 1700 Transmitters with Analog Outputs[...]

  • Seite 307

    Diagnostics: Meter Verification Figure D-20: Device Tools: Trending Figure D-21: Using ProLink III with the transmitter Configuration and Use Manual 301[...]

  • Seite 308

    Appendix E Using the Field Communicator with the transmitter Topics covered in this appendix: • Basic information about the Field Communicator • Connect with the Field Communicator • Menu maps for the Field Communicator E.1 Basic information about the Field Communicator The Field Communicator is a handheld configuration and management tool th[...]

  • Seite 309

    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[...]

  • Seite 310

    Field Communicator connection to transmitter terminals Figure E-1: A B C A. Field Communicator B. 250–600 Ω resistance C. Transmitter, with wiring compartment and power supply compartment opened 2. To connect to a point in the local HART loop, attach the leads from the Field Communicator to any point in the loop and add resistance as necessary.[...]

  • Seite 311

    Field Communicator connection to multidrop network Figure E-3: A B C D A. Field Communicator B. 250–600 Ω resistance C. Devices on the network D. Master device 4. Turn on the Field Communicator and wait until the main menu is displayed. 5. If you are connecting across a multidrop network: a. Set the Field Communicator to poll. The device return[...]

  • Seite 312

    E.3 Menu maps for the Field Communicator On-Line menu Figure E-4: Configure 1 Manual Setup 2 Alert Setup Service T ools 1 Alerts 2 V ariables 3 T rends 4 Maintenance 5 Simulate 2 3 Overview 1 Check Status 2 Primary Purpose V ariables 3 Shortcuts 1 On-Line Menu Using the Field Communicator with the transmitter 306 Micro Motion ® Model 1700 Transmit[...]

  • Seite 313

    Overview menu Figure E-5: Identification 1 T ag 2 Model 3 Xmtr Serial Num 4 Sensor Serial Num 5 Date 6 Descriptor 7 Message 1 Revisions 1 Universal 2 Field Device 3 DD Revision 4 T ransmitter Software 5 CP Software 6 ETO Number Mat. of Construction 1 T ube Wetted Mat. 2 T ube Lining 3 Sensor Flange Check Status 1 Refresh Alerts 2 Dev Status: 3 Comm[...]

  • Seite 314

    Configure menu Figure E-6: Manual Setup 1 Characterize 2 Measurements 3 Display 4 Inputs/Outputs 5 Info Parameters 2 1 Alert Setup 1 I/O Fault Actions 2 Alert Severity 3 Discrete Events On-Line Menu > 1 Configure Using the Field Communicator with the transmitter 308 Micro Motion ® Model 1700 Transmitters with Analog Outputs[...]

  • Seite 315

    Manual Setup menu Figure E-7: Characterize 1 Sensor T ype 2 Sensor T ag Parameters Measurements 1 Flow 2 Density 3 T emperature 4 Update Rate 5 LD Optimization 6 Special Units 7 External Pressure/T emperature 8 GSV 1 2 Inputs/Outputs 1 Channels 2 mA Output 3 Frequency Output 4 Discrete Output 5 Communications 6 V ariable Mapping 3 Info Parameters 1[...]

  • Seite 316

    Manual Setup menu: Characterize Figure E-8: On-Line Menu > 2 Configure > 1 Manual Setup > 1 Characterize 2 1 2 1 Sensor T ype Straight T ube Curved T ube Density Parameters 1 D1 2 D2 3 DT 4 DTG 5 K1 6 K2 7 FD 8 DFQ1 9 DFQ2 Flow Parameters 1 Flow FCF 2 FTG 3 FFQ Sensor T ag Parameters 1 Flow Parameters 2 Density Parameters Sensor T ag Param[...]

  • Seite 317

    Manual Setup menu: Measurements Figure E-9: * Displayed only if V olume Flow T ype = Liquid. Menu numbers are adjusted as required. On-Line Menu > 2 Configure > 1 Manual Setup > 2 Measurements Flow 1 Flow Direction 2 Flow Damping 3 Mass Flow Unit 4 Mass Flow Cutoff 5 V olume Flow Unit * 6 V olume Flow Cutoff * 7 Mass Factor 8 V olume Facto[...]

  • Seite 318

    Manual Setup menu: Display Figure E-10: On-Line Menu > 2 Configure > 1 Manual Setup > 3 Display Language English German French Spanish Display V ariable Menu Features 1 T otalizer Reset 2 Start/Stop T otals 3 Auto Scroll 4 Scroll T ime * 5 Refresh Rate 6 Status LED Blinking Offline V ariable Menu Features 1 Offline Menu 2 Alert Menu 3 Ackn[...]

  • Seite 319

    Manual Setup menu: I/O Figure E-11: On-Line Menu > 2 Configure > 1 Manual Setup > 4 Inputs/Outputs mA Output 1 Primary V ariable 2 mA Output Settings 3 mA Fault Settings Frequency Output 1 FO Settings 2 FO Fault Parameters 3 FO Scaling 2 3 mA Fault Settings 1 mAO Fault Action 2 mAO Fault Level mA Output Settings 1 PV LRV 2 PV URV 3 PV Min [...]

  • Seite 320

    Manual Setup menu: I/O (continued) Figure E-12: Discrete Output 1 DO Assignment 2 DO Polarity 3 DO Fault Action 4 Flow Switch Source 5 Flow Switch Setpoint 6 Hysteresis (0.1-10.0) 4 6 V ariable Mapping 1 Primary V ariable 2 Secondary V ariable 3 Third V ariable 4 Fourth V ariable 5 Communications 1 HART Address 2 T ag 3 Device Identification 4 Dev [...]

  • Seite 321

    Alert Setup menu Figure E-13: On-Line Menu > 2 Configure > 2 Alert Setup I/O Fault Actions 1 mAO Fault Action 2 mAO Fault Level 3 FO Fault Action 4 FO Fault Level 5 Comm Fault Action Alert Severity 1 Fault T imeout 2 Set Alert Severity 3 View Alert Severity Discrete Events 1 Discrete Event 1 2 Discrete Event 2 3 Discrete Event 3 4 Discrete Ev[...]

  • Seite 322

    Service Tools menu Figure E-14: On-Line Menu > 3 Service T ools Alerts 1 Refresh Alerts Alert Name Additional Information for Above V ariables 1 V ariable Summary 2 Process V ariables 3 Mapped V ariables 4 External V ariables 5 T otalizer Control 6 Outputs 1 2 T rends 1 Process V ariables 2 Diagnostic V ariables 3 Maintenance 1 Routine Maintenan[...]

  • Seite 323

    Service Tools menu: Variables Figure E-15: * If V olume Flow T ype = GSV , GSV variables are displayed. On-Line Menu > 3 Service T ools > 2 V ariables Process V ariables 1 Mass Flow Rate 2 V olume Flow Rate * 3 Density 4 T emperature Mapped V ariables 1 PV Mass Flow Rate 2 SV Mass Flow Rate 3 TV Mass Flow Rate 4 QV Mass Flow Rate 1 3 5 T otal[...]

  • Seite 324

    Service Tools menu: Maintenance Figure E-16: On-Line Menu > 3 Service T ools > 4 Maintenance Routine Maintenance 1 T rim mA Output 2 Meter V erification * 1 Zero Calibration 1 Mass Flow Rate 2 V olume Flow Rate 3 Zero T ime 4 Zero V alue 5 Standard Deviation 6 Perform Auto Zero 7 Restore Factory Zero Density Calibration 1 Mass Flow Rate 2 Den[...]

  • Seite 325

    Service Tools menu: Simulate Figure E-17: On-Line Menu > 3 Service T ools > 5 Simulate 1 Simulate Outputs 1 mA Output Loop T est 2 Frequency Output T est/ Discrete Output T est * * Options vary depending on Channel settings. Simulate Sensor 1 Simulate Primary Purpose V ariables 2 Mass Flow Rate 3 Density 4 T emperature 2 Using the Field Commu[...]

  • Seite 326

    Appendix F Default values and ranges F.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[...]

  • Seite 327

    Transmitter default values and ranges (continued) Table F-1: Type Parameter Default Range Comments Density units g/cm 3 Density cutoff 0.2 g/cm 3 0.0 – 0.5 g/cm 3 D1 0 g/cm 3 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[...]

  • Seite 328

    Transmitter default values and ranges (continued) Table F-1: Type Parameter Default Range Comments Base volume time sec Volume flow conversion factor 1 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 2[...]

  • Seite 329

    Transmitter default values and ranges (continued) Table F-1: Type Parameter Default Range Comments Fault action Downscale AO fault level – downscale 2.0 mA 1.0 – 3.6 mA 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 Tem[...]

  • Seite 330

    Transmitter default values and ranges (continued) Table F-1: Type Parameter Default Range Comments Polarity Active low 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 Variable 3 Volume flow rate Variable 4 Volume total Variable 5 [...]

  • Seite 331

    Appendix G Transmitter components and installation wiring Topics covered in this appendix: • Installation types • Power supply terminals and ground • Input/output (I/O) wiring terminals G.1 Installation types Model 1700 and Model 2700 transmitters can be installed five different ways, only one of which applies to your specific installation. ?[...]

  • Seite 332

    High-temperature flexible conduit installation Figure G-2: High-temperature flexible conduit installations use the same installation instructions as 4-wire remote installations, except that the distance between the sensor and the electronics is limited by the length of the flexible conduit. • 4-wire remote – The transmitter is installed remotel[...]

  • Seite 333

    4-wire remote installation – stainless steel housing Figure G-4: Sensor Core processor Transmitter 4-wire cable • 9-wire remote – The transmitter and core processor are combined in a single unit that is installed remotely from the sensor. You need to mount the transmitter/core processor assembly separately from the sensor, connect a 9-wire ca[...]

  • Seite 334

    9-wire remote installation type Figure G-5: Transmitter Junction box Sensor 9-wire cable • Remote core processor with remote sensor – A remote core process with remote sensor installation separates all three components – transmitter, core processor, and sensor – all of which are installed separately. A 4-wire cable connects the transmitter [...]

  • Seite 335

    Remote core processor with remote sensor installation type Figure G-6: Core processor Transmitter 4-wire cable 9-wire cable Sensor Junction box G.2 Power supply terminals and ground Power supply wiring terminals Figure G-7: A B C A. Warning flap B. Equipment ground C. Power supply wiring terminals (9 and 10) Transmitter components and installation [...]

  • Seite 336

    G.3 Input/output (I/O) wiring terminals I/O wiring terminals Figure G-8: A B C A. mA/HART B. Frequency output or discrete output C. RS-485 Transmitter components and installation wiring 330 Micro Motion ® Model 1700 Transmitters with Analog Outputs[...]

  • Seite 337

    Appendix H NE 53 history H.1 NE 53 history Date Version Type Change Operating in- struction 08/2000 1.x Expansion Added writing of the device tag using Modbus 3600204 A Adjustment Improved communication handling with the HART Tri-Loop product Feature Indication of outputs option board type appears on display at power-up 05/2001 2.x Expansion Added [...]

  • Seite 338

    Date Version Type Change Operating in- struction The display start/stop totalizers function can be enabled or disabled Petroleum measurement application improve- ments Live zero available as display variable Increased options for fault output settings New cryogenic application temperature algo- rithms Adjustment Improved frequency output stability [...]

  • Seite 339

    Date Version Type Change Operating in- struction 09/2006 5.x Expansion Discrete output assignable as a flow switch 20001715 B Discrete output fault indication configurability Discrete input support for multiple action as- signments Added support for querying the display LED sta- tus via Modbus Additional HART and Modbus commands Process comparator [...]

  • Seite 340

    Date Version Type Change Operating in- struction Adjustment The following combinations are not allowed: • mA Output Fault Action = None and Digital Communications Fault Action = NAN • Frequency Output Fault Action = None and Digital Communications Fault Action = NAN Display variables set to a volume process varia- ble automatically switch betwe[...]

  • Seite 341

    Date Version Type Change Operating in- struction Pressing and holding the Up or Down optical switch allows continuous scrolling of the current screen in the Chinese-language display Auto-detection of the RS-485 address is availa- ble with the Chinese-language display NE 53 history Configuration and Use Manual 335[...]

  • Seite 342

    Index A Added Damping 85 Additional Communications Response Delay 107 address HART address 102, 106 Modbus address 107 air calibration , See calibration, density alarm menu , See display alarms alarm codes 174 configuring alarm handling 71 Status Alarm Severity configuring 72 options 73 transmitter response 127 troubleshooting 174 viewing and ackno[...]

  • Seite 343

    customer service contacting ii cutoffs AO cutoff 84 density 49 interaction between AO Cutoff and process variable cutoffs 84 mass flow 25 troubleshooting 206 volume flow 31 D damping Added Damping 85 density damping 47 flow damping 24 interaction between Added Damping and process variable damping 86 on mA outputs 85 temperature damping 51 Date 77 D[...]

  • Seite 344

    alarm password 66 off-line password 66 decimal notation 221 enabling or disabling operator actions acknowledging all alarms 66 resetting totalizers 65 starting and stopping totalizers 64 exponential notation 221 floating-point values 221 menu codes 225 menu maps 229 optical switches 219 process variable codes 224 status LED states 174 display, Chin[...]

  • Seite 345

    measurement units configuring 34 options 34 standard density 33 volume flow type 33 ground 329 grounding troubleshooting 193 GSV , See gas standard volume flow measurement H HART address 102, 106, 204 burst mode 104, 204 device description (DD) 302 HART/Bell 202 configuring 102 Field Communicator connections 303 HART/RS-485 configuring 106 loop 203[...]

  • Seite 346

    measurement units density configuring 44, 47 options 45 gas standard volume flow rate configuring 34 options 34 special unit 36 mass flow rate configuring 21 options 22 special unit 23 pressure , See pressure compensation temperature configuring 50 options 50 volume flow rate configuring 28 options 28 special unit 30 menu maps display 229 display, [...]

  • Seite 347

    ProLink III connecting HART/Bell 202 284 HART/RS-485 289 Modbus/RS-485 292 service port 283 startup connection 7 connection types 282 connnecting to the transmitter 282 menu maps 295 overview 281, 282 requirements 281, 282 protocols 2 proving , See meter validation pulse width 91 Q quaternary variable (QV) 105 R radio frequency interference (RFI) t[...]

  • Seite 348

    measurement units configuring 50 options 50 troubleshooting 189 tertiary variable (TV) 105 testing loop testing using ProLink II 197 using ProLink III 198 using the display 194, 195 using the Field Communicator 200 system testing 112 totalizers resetting enabling display function 65 performing action 130, 131 starting and stopping enabling display [...]

  • Seite 349

    Z zero procedure using ProLink II 155 using ProLink III 156 using the Field Communicator 157 restore factory zero using ProLink II 155 using ProLink III 156 using the Field Communicator 157 restore prior zero using ProLink II 155 using ProLink III 156 verification using ProLink II 12 using ProLink III 13 Index Configuration and Use Manual 343[...]

  • Seite 350

    *MMI-20021712* MMI-20021712 Rev A B 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[...]