Kimray OPC Items

 Table Of Contents

Standard Items

See Device Standard Items.

Protocol Items

ItemData TypeDescription
ABSOLUTE.VISCOSITYR4Absolute Viscosity.
ACUI4
ACCUM.UNITS.DO0R4
ACCUM.UNITS.DO1R4
ACCUMULATOR.ADDRESSUI1If the Input Type is 1, this field contains the address of the CIM to be used to obtain the data. If the Input Type is 3, this field contains the Modbus address of the device.
ACCUMULATOR.ALARM.VALUER4The value over which an alarm condition occurs.
ACCUMULATOR.CURREN_VALUER4The current accumulated value.
ACCUMULATOR.DAILY_RESETUI1Flag to set the accumulated value back to zero each day.
ACCUMULATOR.DESCRIPTIONSTRINGText describing the accumulator record.
ACCUMULATOR.DO_RECORD_NUMBERUI2Digital Output record number.
ACCUMULATOR.HARDWARE.CHANNELUI1External Input ID. Channel Number, depends on Input type below.
ACCUMULATOR.INITUI1Initialize to initial value. Write only, read returns 0.
ACCUMULATOR.INIT_VALUEUI4

New value of the accumulator. The RTU sets the value of the accumulator to the value in this field if several conditions are met.

These conditions are:

  • Scaling Factor is not equal to zero.
  • "Initialize to initial value" flag is set to one.
  • If the Input Type = 0 (On-Board accumulator), the record has not been initialized.

This field is only available in the update message

ACCUMULATOR.INPUT_TYPEUI1

0 = On-Board Accumulator

1 = I/O CIM

2 = Digital Input Tripped Time Function (added 2:7.8 changed to tripped 3:1.0)

3 = Modbus (added 3:0.4)

4 = Analog Input Alarm Time Function (added 3:1.0)

5 = Analog Input Modbus last Communication Time (added 3:1.0)

ACCUMULATOR.MODBUS_REGISTERUI2Modbus register to be used to obtain the data.
ACCUMULATOR.MODBUS_TIMEUI2Modbus communication frequency.
ACCUMULATOR.MONTHLY_RESETUI1Flag to set the accumulated value back to zero each month. 0 = No, 1 = Yes
ACCUMULATOR.PSDUI2Permanent Shutdown(PSD)
ACCUMULATOR.REPORT_TO_DISPLAYUI1Flag that indicates if the accumulator value is to be displayed on the RTU's two line display. 0 = No, 1 = Yes
ACCUMULATOR.SCALING.FACTORR4Value of an accumulator increment, in engineering units.
ACCUMULATOR.TIME_OFFUI2The time in seconds the digital output is unlatched when the accumulator is in the alarm state if the alarm type is 4, Pulse.
ACCUMULATOR.TIME_ONUI2Time (milliseconds) the digital output is latched when the accumulator is in the alarm state if the alarm type is 4, Pulse.
ACCUMULATOR.UNITSSTRINGText describing the value of the accumulator.
AGA7.PRESSURE.CALCULATEDUI1Flag indicating if the AGA7 pressure factor is calculated. 1 is calculated, 0 is not calculated and a value has been entered.
AGA7.PRESSUE.VALUER4Current value of the AGA7 pressure factor.
AGA7.TEMP.CALCULATEDUI1Flag indicating if the AGA7 temperature factor is calculated. 1 is calculated, 0 is not calculated and a value has been entered.
AGA7.TEMP.VALUER4Current value of the AGA7 temperature factor.
AGA8.METHODUI1
AIUI2
ANALOG.AI.ALARM.DELAYUI2AI Alarm delay – in seconds

ANALOG.ANALOG_OUTPUT_FLAG

UI1

Analog Output. Flag indicating this record is associated with an analog output.

ANALOG.AO_CHANNEL

UI2

AO Channel. The number of the analog output record.

ANALOG.AO_OFFSET

R4

AO offset. The offset of the analog output record.

ANALOG.AO_RANGE

R4

AO range. The range of the analog output record.

ANALOG.AO_SCALE

R4

AO scale. Used as follows for the AO: (Value * scale – offset)/range *100.

ANALOG.AVERAGE.STATION.NUMBER

UI2


ANALOG.AVERAGE.TYPE

UI2


ANALOG.DEADBAND

R4

Alarm deadband. The amount the analog value must change in order to come out of an alarm condition. For the "Low Alarm Limit", the value of the analog must be above the sum of the "Alarm Deadband" and "Low

Alarm Limit". For the "High Alarm Limit", the value of the analog must be below the "High Alarm Limit" less the "Alarm Deadband".

ANALOG.DESCRIPTION

STRING

Description.

ANALOG.DEVIATION.FLAG

UI1

Deviation Value used.  0 = No; 1 = Yes

ANALOG.DEVIATION.VALUE

R4

Deviation Amount

ANALOG.ESD_TSD_OVERRANGE

UI2

ESD/TSD overrange.

The ESD/TSD underrange and overrange indicate what types of actions is taken if an alarm condition exists. The types of actions are:

0  = No alarm

1  = PSD - The RTU shuts down production until manually reset. 2 = TSD - The RTU shuts down production until the condition clears.

3 = Digital Output - The RTU activates a Digital Output. 4 = Pulses - The RTU activates and deactivates a Digital Output based upon times provided in this message.

5 = Inverted Digital Output - The RTU deactivates the Digital Output.

ANALOG.ESD_TSD_UNDERRANGE

UI2

ESD/TSD underrange.

The ESD/TSD underrange and overrange indicate what types of actions is taken if an alarm condition exists. The types of actions are:

  • 0  = No alarm
  • 1  = PSD - The RTU shuts down production until manually reset.
  • 2 = TSD - The RTU shuts down production until the condition clears.
  • 3 = Digital Output - The RTU activates a Digital Output.
  • 4 = Pulses - The RTU activates and deactivates a Digital Output based upon times provided in this message.
  • 5 = Inverted Digital Output - The RTU deactivates the Digital Output.

ANALOG.FLOWRATE.CHANNEL

UI2


ANALOG.FLOWRATE.FUDGE.FACTOR

R4


ANALOG.FLOWRATE.SETPOINT.OFFSET

R4


ANALOG.FLOWRATE.SETPOINT.RANGE

R4


ANALOG.HARDWARE.CHANNEL

UI1


ANALOG.HIGH.LIMIT

R4

High alarm limit.  The analog value above which an alarm condition exists.

ANALOG.IGNORE_HI_FAIL

UI1

Ignore High Fail. Flag to ignore the High Failure condition of this analog

0 = No, 1 = Yes

ANALOG.IGNORE_LO_FAIL

UI1

Ignore Low Fail. Flag to ignore the Low Failure condition of this analog.

0 = No, 1 = Yes

ANALOG.INPUT.TYPE.FLAG

UI2

Input Type.

  • 0 = LIVE AI Channel Number
  • 1 = MANUAL
  • 2 = FLOW RATE Flow Computer Number
  • 3 = CIM MV SP CIM Address
  • 4 = CIM MV DP CIM Address
  • 5 = CIM MV TEMP CIM Address
  • 6 = PPT-R PPT-R Address
  • 7 = CIM IO AI0 CIM Address
  • 8 = CIM IO AI1 CIM Address
  • 9 = CIM VALVE FEEDBACK (EPVP) CIM Address
  • 10 = TANK LEVEL 1 Tank Probe Address
  • 11 = TANK LEVEL 2 Tank Probe Address
  • 12 = TANK TEMP Tank Probe Address
  • 13 = BAKER COM2 PRES
  • 14 = BAKER COM2 TEMP
  • 15 = BAKER LOCAL PRES
  • 16 = BAKER LOCAL TEMP
  • 17 = ENTRONIC FLOAT Entronic Float Offset (Not implemented)
  • 18 Modbus holding reg.
  • 19 D5000 D5000 address

  • 20 Add Analog Records 1st AI record no. 


  • 21 Subtract Analog Records 1st AI record no. 
  • 22 = Multiply Analog Records 1st AI record no.
  • 23 = Divide Analog Records 1st AI record no.
  • 24 = Modbus input reg.
  • 25 = Modbus Rocklink Input no.
  • 26 = Modbus Float Register
  • 27 = Modbus Float Register using 2 16-bit registers
  • 28 = Flow Time Flow Computer Number
  • 29 = Flow volume Flow Computer
  • 30 Energy volume Flow Computer Number 

ANALOG.LOW.LIMIT

R4

Low alarm limit. The analog value below which an alarm condition exists.

ANALOG.MANUAL.FLAG

UI1

Input Type

ANALOG.MANUAL.VALUE

R4

Current/Manual Value. 

Write: field is manual value if the Input Type is MANUAL. For other types, field is ignored.

Read: field is the current value of the AI record in engineering units.

ANALOG.MODBUS_ADDRESS

UI1

Modbus address. Address of the modbus device.

ANALOG.MODBUS.CYCLE.TIME

UI2

Modbus communication cycle time (in seconds).

ANALOG.MODBUS.FLAG

UI1

Send to Modbus.  Flag that indicates if the value of the analog input record is to be sent to a Modbus device.

ANALOG.MODBUS.FUNCTION.FIELD

UI1

Modbus function field.

If Send to Modbus is Yes:

0  - Read register before writing.

1  - Always write

2- Float Register (Always write)

6-Float Register with 2 16-bit registers

ANALOG.MODBUS.OFFSET

R4

Modbus offset. See Modbus scaling

ANALOG.MODBUS.REGISTER

UI2

Modbus register

ANALOG.MODBUS.SCALING

R4

Modbus scaling. 

Send: (value * scaling) + offset.

Get: (value – offset) / scaling

ANALOG.OFFSET

R4

Offset from zero.

ANALOG.OUTPUT.USED

UI1

Flag indicating this record is associated with an analog output.

ANALOG.RANGE

R4

Range of analog.

ANALOG.RELAY_NUMBER

UI2

The number of the Digital

Output record used for alarming when the ESD/TSD Underrange or Overrange fields have values of 3, 4, or 5.

ANALOG.REPORT_TO_DISPLAY

UI1

Report to display.  0 = No, 1 = Yes

ANALOG.SCALING_FACTOR

R4

Scaling Factor.  The value of an increment of the analog input record.

ANALOG.SECONDARY.AI.RECORD.NUMBER

UI1

2nd AI record no. (For Input

Types requiring 2nd input)

ANALOG.TIME_OFF_SEC

UI2

Time Off.  The time, in seconds, the Digital Output is deactivated. This field only has meaning when the value of "ESD/TSD Underrange" or "ESD/TSD Overrange" is set to 3, 4, or 5.

ANALOG.TIME_ON_MSEC

UI2

Time On.  The time, in milliseconds, the Digital Output is activated. This field only has meaning when the value of ESD/TSD Underrange or

Overrange is set to 3, 4, or 5.

ANALOG.UNITS

STRING

Units

ANALOG.WEIGHTED.AVERAGE.FLAG

UI1

Flag that indicates if the average analog value is weighted by the flow from an associated flow computer.

ANALOGCALIBATION.HIGH.RTU.VALUE

R4

High calibration point RTU value: The raw value read by the RTU for this calibration point.

ANALOGCALIBATION.HIGH.USER.ENTER.VALUE

R4

High calibration point user entered value: The value entered by the user for this calibration point. 

ANALOGCALIBATION.LOW.RTU.VALUE

R4

Low calibration point RTU value: The raw value read by the RTU for this calibration point.

ANALOGCALIBATION.LOW.USER.ENTER.VALUE

R4

Low calibration point user entered value: The value entered by the user for this calibration point.

ANALOGCALIBATION.MID.RTU.VALUE

R4

Mid calibration point RTU value: The raw value read by the RTU for this calibration point.

ANALOGCALIBATION.MID.USER.ENTER.VALUE

R4

Mid calibration point user entered value: The value entered by the user for this calibration point.

ANALOGCALIBATION.OFFSET

R4

The low value of the sensor.

ANALOGCALIBATION.RANGE

R4

The difference between the high value and low value of the sensor.

ANALOGCALIBATION.SENSOR.TYPE

UI1

0  = Misc.

1  = Low DP if 2 DP’s

2  = High DP if 2 DP’s

3  = DP if 1 DP

4  = Static Pressure

5  = Flowing Temp

ANALOGCALIBATION.AGA.SENSOR

UI1

Set to 1 if the sensor is used in AGA calculations, 0 if not.

ANALOGCALIBATION.FLOW.COMPUTER

UI1

If the value of AGA Sensor is 1, this is the number of the flow computer that uses the AGA sensor.

ANALOGCALIBATION.TYPE

UI1

0 = Range/Offset (DACC1000 not calibrated)

2  = 2 point

3  = 3 point

ANALOGOUTPUT.AOCOUNT

UI1

Count of analog outputs in message, always 1; in older version this field is always 0.

ANALOGOUTPUT.AOOFFSET

R4

The offset of the analog output record.

ANALOGOUTPUT.AORANGE

R4

The range of the analog output record.

ANALOGOUTPUT.AORECORD

UI1

AO record number, was HW AO #

ANALOGOUTPUT.AOSCALE

R4

Used as follows for the AO: (Value * scale – offset)/range *100.

ANALOGOUTPUT.AOTYPE

UI1

0 = LIVE

1 = MANUAL

2 = FLOW RATE

3 = CIM MV SP

4 = CIM MV DP 

5 = CIM MV TEMP 

6  = PPT-R 

7  =  CIM IO AI0 

8 = CIM IO AI1 

9 = CIM VALVE FEEDBACK (EPVP) 

10 = TANK LEVEL 1 

11 = TANK LEVEL 2 

12 = TANK TEMP 

13 = BAKER COM2 PRES 

14 = BAKER COM2 TEMP 

15 = BAKER LOCAL PRES 

16 = BAKER LOCAL TEMP  17 ENTRONIC FLOAT 

18 = Modbus holding reg.

19  = D5000 

20 = Add Analog Records 

21 = Subtract Analog Records 

22 = Multiply Analog Records  23 Divide Analog Records  24 Modbus input reg. 

25 = Modbus Rocklink 

26 = Modbus Float Register 

27 = Modbus Float Register using 2 16-bit registers

28 = Flow Time 

29 = Flow volume 

30 = Energy volume 

ANALOGOUTPUT.CHANNEL.NUMBER

UI2

Number identifying the associated hardware device.

ANALOGOUTPUT.CURRENT.VALUE

R4

Current value of the record.

ANALOGOUTPUT.DESCRIPTION

STRING

Text describing the analog.

ANALOGOUTPUT.FLOWRATEAOFLAG

UI1

Flag indicating it this module is to be used.

ANALOGOUTPUT.MODBUS.ADDRESS

UI1

Modbus Address

ANALOGOUTPUT.MODBUS.CYCLE.TIME

UI2

In seconds (added 3:0.4)

ANALOGOUTPUT.MODBUE.FUNCTION.FIELD

UI1

If Send to Modbus is Yes:

0  - Read register before writing.

1  - Always write

2- Float Register (Always write)

6-Float Register with 2 16-bit registers

ANALOGOUTPUT.MODBUS.REGISTER

UI2

Modbus register

ANALOGOUTPUT.REPORT.TO.DISPLAY

UI1

Flag to display this analog value on the RTU's two-line display.

ANALOGOUTPUT.SOURCE

UI2

0=RTU, 1=I/O CIM, 2=modbus

AO

UI2

Analog Output Flag indicating this record is associated with an analog output.

ATMOSPHERIC.PRESSURE

R4

Atmospheric pressure.

AUTOTUNE.INTERMIT.OFFTIME.INCREMENT

UI2

OFF time increment: Minutes

AUTOTUNE.INTERMIT.OFFTIME.MAX

UI2

OFF time Maximum: Minutes

AUTOTUNE.INTERMIT.OFFTIME.MIN

UI2

OFF time Minimum: Minutes

AUTOTUNE.INTERMIT.ONTIME.INCREMENT

UI2

ON time increment: Minutes

AUTOTUNE.INTERMIT.ONTIME.MAX

UI2

ON time Maximum: Minutes

AUTOTUNE.INTERMIT.ONTIME.MIN

UI2

ON time Minimum: Minutes

AUTOTUNE.LIFT.ARRIVALTIME.DEADBAND

UI2

Lift arrival time deadband : Seconds

AUTOTUNE.LIFT.ARRIVALTIME.SETPOINT

UI2

Lift arrival time setpoint :

Seconds

AUTOTUNE.LIFT.AUTOTUNEFLAG

UI1

 Lift Autotune 1 = ON 0 = OFF

AUTOTUNE.LIFT.CRYOUT

UI1

Lift Cryout : bitmap of flags

AUTOTUNE.OPTIMIZECLOSE.FAILEDTRIP

UI2

Optimize Close Pressure increment failed trip. The amount to adjust the pressure after the plunger failed to arrive within the given time. This value is usually larger than the increment for the normal trip in order to more quickly bring the parameters back into a normal operating range.

AUTOTUNE.OPTIMIZECLOSE.MAXPRESSURE

UI2

Optimize Close Maximum pressure allowed. 

AUTOTUNE.OPTIMIZECLOSE.MINPRESSURE

UI2

Optimize Close Minimum pressure allowed. 

AUTOTUNE.OPTIMIZECLOSE.NORMALTRIP

UI2

Optimize Close Pressure increment normal trip. The amount to adjust the pressure after a successful plunger trip.

AUTOTUNE.OPTIMIZECLOSE.SELECTION

UI1

Optimize Close Autotune condition selection

1 = casing, 2 = tubing, 3 = line, 4 = casing-tubing, 5 = tubingline 6 = casing-line, 7 = differential pressure, 8 = flow rate

AUTOTUNE.OPTIMIZECLOSE.VENTVALVE

UI2

Optimize Close Pressure increment vent valve operated. The amount to adjust the pressure after a trip caused the vent valve to open. This value is usually larger than the increment for the normal trip in order to more quickly bring the parameters back into a normal operating range.

AUTOTUNE.OPTIMIZEOPEN.FAILEDTRIP

UI2

Optimize Open Pressure increment failed trip. The amount to adjust the pressure after the plunger failed to arrive within the given time. This value is usually larger than the increment for the normal trip in order to more quickly bring the parameters back into a normal operating range.

AUTOTUNE.OPTIMIZEOPEN.MAXPRESSURE

UI2

Optimize Close Maximum pressure allowed.

AUTOTUNE.OPTIMIZEOPEN.MINPRESSURE

UI2

Optimize Close Minimum pressure allowed. 

AUTOTUNE.OPTIMIZEOPEN.NORMALTRIP

UI2

Optimize Open Pressure increment normal trip. The amount to adjust the pressure after a successful plunger trip.

AUTOTUNE.OPTIMIZEOPEN.SELECTION

UI1

Optimize Open  Autotune Condition selection: 

1 = casing, 2 = tubing, 3 = line, 4 = casing-tubing, 5 = tubingline, 6 = casing-line, 

AUTOTUNE.OPTIMIZEOPEN.VENTVALVE

UI2

Optimize Open Pressure increment vent valve operated. The amount to adjust the pressure after a trip caused the vent valve to open. This value is usually larger than the increment for the normal trip in order to more quickly bring the parameters back into a normal operating range.

BasePoll.AnalogTime

STRING

Analog Time

BasePoll.EnergyProdLastHour/FlowComputerNumber Ex. BasePoll.EnergyProdLastHour/1

UI4

This accumulator contains the total amount of energy produced in the last hour.

BasePoll.EnergyProdToday/FlowComputerNumber Ex: BasePoll.EnergyProdToday/2

UI4

This accumulator contains the total amount of energy produced since the beginning of the contract day.

BasePoll.EnergyProdTotal/FlowComputerNumber Ex: BasePoll.EnergyProdTotal/1

UI4

This accumulator contains the amount of energy produced from the beginning of the month up through the previous contract day.

BasePoll.EnergyProdYest/FlowComputerNumber Ex: BasePoll.EnergyProdYest/2

UI4

This accumulator contains the total amount of energy produced in the previous contract day.

BasePoll.EnergyRate/FlowComputerNumber Ex: BasePoll.EnergyRate/1

R4

Energy rate for each flow computer.

BasePoll.FlowComputerStatus

UI1


BasePoll.FlowControlStatus

UI1


BasePoll.FlowProdLastHour/FlowComputerNumber Ex: BasePoll.FlowProdLastHour/2

UI4

This accumulator contains the total production for the previous hour.

BasePoll.FlowProdToday/FlowComputerNumber Ex: BasePoll.FlowProdToday/1

UI4

This accumulator contains the total amount produced since the beginning of the contract day.

BasePoll.FlowProdTotal/FlowComputerNumber Ex: BasePoll.FlowProdTotal//2

UI4

This accumulator contains the total production from the beginning of the month through the end of the previous contract day.

BasePoll.FlowProdYest/FlowComputerNumber Ex: BasePoll.FlowProdYest/1

UI4

This accumulator contains the total amount produced for the previous contract day.

BasePoll.FlowRate/FlowComputerNumber Ex: BasePoll.FlowRate/2

R4

Flow rate for each flow computer.

BasePoll.FlowTimeLastHour/FlowComputerNumber Ex: BasePoll.FlowTimeLastHour/1

UI4

This accumulator contains the total time in minutes that the well was producing in the previous hour.

BasePoll.FlowTimeToday/FlowComputerNumber Ex: BasePoll.FlowTimeToday/2

UI4

This accumulator contains the total time in minutes that the well was producing since the beginning of the contract day.

BasePoll.FlowTimeTotal/FlowComputerNumber Ex: BasePoll.FlowTimeTotal/1

UI4

This accumulator contains the total time in minutes that the well was producing since the beginning of the month.

BasePoll.FlowTimeYest

UI4

This accumulator contains the total time in minutes that the well was producing in the previous contract day.

BasePoll.HardwareAccu

UI4


BasePoll.HardwareAccuExp

UI4


BasePoll.HardwareAO

UI2


BasePoll.HardwareAOExp

UI2


BasePoll.HardwareDI

UI1


BasePoll.HardwareDIExp

UI1


BasePoll.HardwareDO

UI1


BasePoll.HardwareDOExp

UI1


BasePoll.HardwareExtAI

UI2


BasePoll.HardwareExtExp

UI2


BasePoll.HardwareExtRTDAI

UI2


BasePoll.HardwareExtRTDAIExp

UI2


BasePoll.HardwareIntAI

UI2


BasePoll.LiftFailureToday/FlowComputerNumber Ex. BasePoll.LiftFailureToday/1

UI1

This accumulator contains the total number of Lift fails since the beginning of the contract day.

BasePoll.LiftFailureYest/FlowComputerNumber Ex:  BasePoll.LiftFailureYest/2

UI1

This accumulator contains the total number of Lift fails in the previous contract day.

BasePoll.ListStartToday/FlowComputerNumber Ex: BasePoll.ListStartToday/1

UI1

This accumulator contains the total number of Lift starts since the beginning of the contract day.

BasePoll.OverrideSetpoint

R4


BasePoll.PrimarySetpoint

R4


BasePoll.RTUStatus

UI1


BasePoll.SoftwareAccu

R4


BasePoll.SoftwareAI

UI2


BasePoll.SoftwareAIFloats

R4


BasePoll.SoftwareAO

UI2


BasePoll.SoftwareDI

UI1


BasePoll.SoftwareDO

UI1


BasePoll.WaterMadeMonthToYest/TankNumber Ex: BasePoll.WaterMadeMonthToYest/1

UI4

This accumulator contains the total volume of water made since the beginning of the month.

BasePoll.WaterMadeToday/TankNumber Ex:  BasePoll.WaterMadeToday/2

UI4

This accumulator contains the total volume of water made since the beginning of the contract day.

BasePoll.WaterMadeYest/TankNumber Ex: BasePoll.WaterMadeYest/1

UI4

This accumulator contains the total volume of water made the previous contract day.

BTU.CONTENT.ANALOG

UI2

The British Thermal Units generated by a cubic foot of gas.

ChangeAIManual

R4

Change AI manual

ChangeOrificePlate

R4

Change orifice plate

ChangePassword

String

Change password

ChangeProductionControl

UI1

Change production control

ChangeProductionValve

UI1

Change production valve

ChangeProductionValveFlag

UI1

Change production valve flag

CommandAO

UI2


COMMPORT.COMM1_BAUDRATE

UI2

The baud rate used for the port.

COMMPORT.COMM1_CTSFLAG

UI1

Informs the RTU if it is to use the Clear-To-Send (CTS) signal on the serial port. 0 = no, 1 = yes, 2 = bidirectional

COMMPORT.COMM1_FORMAT

UI1

Defines the parity, bit count and stop bits:

0  = N81

1  = E71

2  = O71

3  = N71

4  = E81

COMMPORT.COMM1_SELECT

UI1

Defines the port selection:

0     = not used

1     = CIM

2     = tank

3     = PLC

4     = display

5     = Bristol

6     = Baker

7     = RTU Modbus

8     = ASCII Modbus

9     = communications

10  = store and forward

DACC500: 9

DACC1000: 9

DACC2000: 0,9

DACC3000: 0,9

COMMPORT.COMM1_TURNAROUND

UI2

The amount of time, in milliseconds, the RTU waits before sending a response to a message.

COMMPORT.COMM1_WARMDOWN

UI2

The time, in milliseconds, from when the RTU stops sending bytes to when it lowers Request-To-Send.

COMMPORT.COMM1_WARMUP

UI2

The time, in milliseconds, from when the RTU raises the Request-To-Send (RTS) signal to the time it sends the data.

COMMPORT.COMM2_CTSFLAG

UI1

Informs the RTU if it is to use the Clear-To-Send (CTS) signal on the serial port. 0 = no, 1 = yes

COMMPORT.COMM2_FORMAT

UI1

Defines the parity, bit count and stop bits:

0  = N81

1  = E71

2  = O71

3  = N71

4  = E81

COMMPORT.COMM2_SELECT

UI1

Defines the port selection:

0  = not used

1  = CIM

2  = tank

3  = PLC

4  = display

5  = Bristol

6  = Baker

7  = RTU Modbus

8  = ASCII Modbus

9 = communications

10 = store and forward

DACC500: 1

DACC1000: 0,1,2,7,8

DACC2000: 0,1,2,7,8,9,10

DACC3000: 0,1,2,7,8,9,10

COMMPORT.COMM2_WARMDOWN

UI2

The time, in milliseconds, from when the RTU stops sending bytes to when it lowers Request-To-Send.

COMMPORT.COMM2_WARMUP

UI2

The time, in milliseconds, from when the RTU raises the Request-To-Send (RTS) signal to the time it sends the data.

COMMPORT.COMM_TYPE

UI1

Defines the type of communications being used:

0              = Wire Line

1              = Trunked Radio

2              = Conventional Radio 3 = Auto Dial/Auto-Answer modem

4 = Conventional Radio with

Sleep Mode

COMMPORT.LOCAL_BAUDRATE

UI2

The baud rate used for the port.

COMMPORT.LOCAL_FORMAT

UI1

Defines the parity, bit count and stop bits:

0  = N81

1  = E71

2  = O71

3  = N71

4  = E81

COMMPORT.LOCAL_SELECT

UI1

Defines the port selection:

0 = not used

1 = CIM

2 = tank

3 = PLC

4 = display

5 = Bristol

6 = Baker

7 = RTU Modbus

8 = ASCII Modbus

9 = communications

10 = store and forward

DACC500: 0

DACC1000: 0

DACC2000: 0,1,2,7,8

DACC3000: 0,1,2,4,7,8

COMMPORT.RTU_ADDRESS

UI1

The address of the RTU. Note: The value of the RTU address can be changed with the update message. If the address is changed, all future messages must use the new address.

COMMPORT.RTU_GROUP

UI1

The group ID of the RTU. If the value of the group ID is zero, the group ID is not used. If the group ID is not zero, the value becomes part of the RTU address. The group ID and the way it changes the message address is discussed in the introduction of this manual. Note: The value of the RTU group ID can be changed with the update message. If the group is changed, all future messages must use the new group ID. 0 = Not used, non-0 = contains group number

COMMPORT_COMM2_BAUDRATE

UI2

The baud rate used for the port.

CONFIGURATION.ACCOFF

I2

The number of bytes from the beginning of the poll response to the start of the Accumulator section. The accumulator values are 3 byte BCD and 1 byte BCD.

CONFIGURATION.ACCUMULATORS

UI1

Number of Software Accumulator record values returned in the poll response.

CONFIGURATION.ANALOG_INPUT

UI1

Number of Software Analog Input record values returned in the poll response.

CONFIGURATION.ANALOG_OUTPUT

UI1

Number of Software Analog Output record values returned in the poll response.

CONFIGURATION.ANALOG_OUTPUT_REC

UI1

Number of Software Analog Output records available at the RTU.

CONFIGURATION.ANALOGOFF

I2

The number of bytes from the beginning of the poll response to the start of the Analog section. The analog values are 2 byte BCD.

CONFIGURATION.CRC1

I2

The number of bytes from the beginning of the poll response to the start of the CRC.

CONFIGURATION.DIGITAL_INPUT

UI1

Number of Software Digital

Input record values returned in the poll response. 

CONFIGURATION.DIGITAL_OUTPUT

UI1

Number of Software Digital Output record values returned in the poll response.

CONFIGURATION.DIGITAL_OUTPUT_REC

UI1

Number of Software Digital Output records available at the RTU.

CONFIGURATION.ENABLE_ENERGY_VALUES

UI1

Flag indicating if energy values are returned in the poll response.

1 = yes, 0 = no, Unused before 2:2.x

CONFIGURATION.ENABLE_FLOWPROD_LAST

UI1

Flag indicating if the production last hour values are in the poll response.

1 = yes, 0 = no, Unused before 2:2.x

CONFIGURATION.ENABLE_FLOWPROD_TODAY

UI1

Flag indicating if the production today values are in the poll response.

1 = yes, 0 = no, Unused before 2:2.x

CONFIGURATION.ENABLE_FLOWPROD_TOTAL

UI1

Flag indicating if the production total values are in the poll response.

1 = yes, 0 = no, Unused before 2:2.x

CONFIGURATION.ENABLE_FLOWPROD_YEST

UI1

Flag indicating if the production yesterday values are in the poll response.

1 = yes, 0 = no, Unused before

2:2.x

CONFIGURATION.ENABLE_FLOWTIME

UI1

Flag indicating if the flow time values are in the poll response. 

1 = yes, 0 = no, Unused before 2:2.x

CONFIGURATION.ENABLE_LIFTCOUNTERS

UI1

Flag indicating if the lift counter accumulators are in the poll response. 

1 = yes, 0 = no, Unused before 2:2.x

CONFIGURATION.ENABLE_SETPOINTS

UI1

Flag indicating if the setpoint values (analog output values) are in the poll response.  1 = yes, 0 = no, Unused before 2:2.x

CONFIGURATION.ENABLE_TIME

UI1

Flag indicating if the RTU time of day is in the poll response. 

1 = yes, 0 = no, Unused before 2:2.x

CONFIGURATION.FIRMWARE_DAY

UI1

Day the version of firmware was released. Read Only.

CONFIGURATION.FIRMWARE_MONTH

UI1

Month the version of firmware was released. Read Only.

CONFIGURATION.FIRMWARE_YEAR

UI1

Year the version of firmware was released. Read Only.

CONFIGURATION.FLOATOFF

I2

The number of bytes from the beginning of the poll response to the start of the Float section. The float values are 4 byte DEC float format

CONFIGURATION.INIT_FC

UI1

The number of flow computers that have been initialized at the RTU. 

Read Only, Unused before 2:2.x

CONFIGURATION.MESSAGE_VERSION

UI1

Number indicating the version of the message returned.

CONFIGURATION.NUM_ACC

UI1

The number of hardware accumulator values returned in the poll response.

CONFIGURATION.NUM_AO

UI1

The number of hardware analog outputs returned in the poll response.

CONFIGURATION.NUM_DI

UI1

The number of hardware digital input values returned in the poll response.

CONFIGURATION.NUM_DO

UI1

The number of hardware digital output values returned in the poll response.

CONFIGURATION.NUM_EXT_AI

UI1

The number of external hardware analog input values returned in the poll response.

CONFIGURATION.NUM_FC

UI1

The maximum number of flow computers available at the RTU.

CONFIGURATION.NUM_FLOATS

UI1

The number of floating point values returned in the poll response.

CONFIGURATION.NUM_INT_AI

UI1

The number of internal analog inputs (Battery charger, board temperature, etc.) that are returned in the poll response.

CONFIGURATION.NUM_RTD

UI1

The number of RTD's returned in the poll response.

CONFIGURATION.NUM_TANKS

UI1

The maximum number of tanks available at the RTU.

CONFIGURATION.TOTAL_EXPANSIONS

I2

The number of expansion cards attached to the main board of the RTU.

CONFIGURATION.TOTAL_FC

UI1

The number of flow computers in the poll response.

CONFIGURATION.TOTAL_SWACC

UI1

The total number of software accumulator records available at the RTU.

CONFIGURATION.TOTAL_SWANALOGS

UI1

The total number of software analog records available at the RTU.

CONFIGURATION.TOTAL_SWDIGITALS

UI1

The total number of software digital inputs records available at the RTU.

CONFIGURATION.TOTAL_TANKS

UI1

The total number of tank records returned in the poll response.

CONFIGURATION.VERSION_A

UI1

Major firmware version number.

CONFIGURATION.VERSION_B

UI1

Minor firmware version number.

CONFIGURATION.VERSION_C

UI1

Firmware Revision number.

CONFIGURATION.VERSION_D

UI1

System ID.

CONTRACT.PRESSURE

R4

Contract Pressure

CONTRACT.TEMPERATURE

R4

Contract Temperature

DateTime.Contract_Hour

UI1

Contract Hour

DateTime.Contract_Minute

UI1

Contract Minute

DateTime.Day

UI1

 Day

DateTime.Hour

UI1

Hour

DateTime.Minute

UI1

Minute

DateTime.Month

UI1

Month

DateTime.Second

UI1

Second

DateTime.Week_Day

UI1

Weekday

DateTime.Year

UI1

Year

DI

UI1


DIGITALINPUT.ALARM.TYPE

UI2

Defines when the digital input goes into an alarm state:

0  - No alarm.

1  - Tripped to normal.

2  - Normal to tripped.

3  - Any change.

DIGITALINPUT.BIT

UI2


DIGITALINPUT.CLOSE.MSG

STRING

Text displayed when the digital input is closed. This may be either the tripped or the normal state.

DIGITALINPUT.CURRENT.VALUE

UI1

The current digital input tripped state (tripped = 1, normal = 0).

DIGITALINPUT.DELAY.TIME

UI2

The amount of time, in seconds, the RTU waits after the digital input has gone into an alarm state before performing the alarm actions. If the digital input goes from an alarm state to an normal state before the delay time is up, no alarm action is taken.

DIGITALINPUT.DESCRIPTION

STRING

Text describing the digital input

DIGITALINPUT.HARDWARE.CHANNEL

UI2

If the input type for this record is an on-board digital input, this is the channel number for the input. If the input type is an I/O CIM, this is the channel at the CIM to access. If the input type is Modbus, this field is not used.

DIGITALINPUT.MODBUS.ADDRESS

UI1

If the Input type is 1, this is the channel on the I/O CIM. If the Input type is 2, this is the address of the modbus device.

DIGITALINPUT.MODBUS.CYCLE.TIME

UI2

Delay in seconds in firmware version 3:0.4 and later, previously not used.

DIGITALINPUT.MODBUS.FUNCTION.FIELD

UI1

Currently always set to 0.

DIGITALINPUT.MODBUS.REGISTER

UI2

Register in the Modbus device that contains the input value for the digital input.

DIGITALINPUT.OPEN.MSG

STRING

Text displayed when the digital input is open. This may be either the tripped or the normal state.

DIGITALINPUT.OUTPUT.ALARM.TYPE

UI2

The action taken by the RTU with the digital input goes into alarm.

The actions that can be taken are:

0              - No action.

1              - Permanent Shutdown (PSD). The RTU must be manually reset.

2              - Temporary Shutdown (TSD). The RTU resumes operations automatically when the alarm condition clears.

3              - Digital Output - The RTU energizes a digital output (latch).

4              - Pulse - The RTU periodically opens and closed a digital output.

5              - Inverted Digital Output - The RTU de-energizes a digital output (unlatch).

DIGITALINPUT.RELAY.NUMBER

UI2


DIGITALINPUT.REPORT.TO.DISPLAY

UI1

Flag indicating if the digital input information is displayed on the RTU's two-line display.

DIGITALINPUT.SENSE

UI1


DIGITALINPUT.TIME.OFF.MSEC

UI2

Time, in seconds, the digital output is unlatched when the digital input is in an alarm state. This value is valid when the

Output Alarm Type is Pulse (4).

DIGITALINPUT.TIME.ON.MSEC

UI2

The time, in milliseconds, the digital output is latched when the digital input is in an alarm state. This value is valid when the Output Alarm Type is Pulse

(4).

DIGITALOUTPUT.CHANNEL.NUMBER

Ui2

The number that identifies which bit of the value to read.

DIGITALOUTPUT.CLOSE.MESSAGE

STRING

Text displayed when the digital output is in a closed, or latched, state.

DIGITALOUTPUT.CURRENT.VALUE

UI1

Value of the digital output.

DIGITALOUTPUT.DESCRIPTION

STRING

Text describing this record.

DIGITALOUTPUT.DO0COUNTERTYPE

UI2

Type of counter used. The choices are:

0 - Flow from the associated flow computer

1 - Energy from the associated flow computer

2 - Flow from all flow computers

3 - Energy from all flow computers

DIGITALOUTPUT.DO0FLOWENERGY

R4

The amount of production for each pulse of the DO.

DIGITALOUTPUT.DO0RELAYNUMBER

UI2

Record number of the DO to be pulsed.

DIGITALOUTPUT.DO0TIMEDURATION

UI2

Time, in milliseconds, the DO is to be energized.

DIGITALOUTPUT.DO1COUNTERTYPE

UI2

Type of counter used. The choices are:

0              - Flow from the associated flow computer

1              - Energy from the associated flow computer

2              - Flow from all flow computers

3              - Energy from all flow computers

DIGITALOUTPUT.DO1FLOWENERGY

R4

The amount of production for each pulse of the DO.

DIGITALOUTPUT.DO1RELAYNUMBER

UI2

Record number of the DO to be pulsed.

DIGITALOUTPUT.DO1TIMEDURATION

UI2

Time, in milliseconds, the DO is to be energized.

DIGITALOUTPUT.MODBUS.ADDRESS

UI1

If the Source is 1, this is the channel number on the I/O CIM

to use. If the Source is 2, this is the address of the Modbus device.

DIGITALOUTPUT.MODBUS.CYCLE.TIME

UI2


DIGITALOUTPUT.MODBUS.FUNCTION.FIELD

UI1

Flag controlling the RTU handling of messages to a Modbus device. If 0, the RTU reads the value from the

Modbus device first. If the value read is different from the value to be sent, the RTU sends the value to the device. When 1, the RTU does not read the value first, it always sends the value.

DIGITALOUTPUT.MODBUS.REGISTER

UI2

Register in the Modbus device that is updated by this record.

DIGITALOUTPUT.MODULE

UI1


DIGITALOUTPUT.NUMOFDO

UI1


DIGITALOUTPUT.OPEN.MESSAGE

STRING

Text displayed when the digital output is in an open, or unlatched, state.

DIGITALOUTPUT.REPORT.TO.DISPLAY

UI1

Flag indicating if information about this record is to be displayed on the RTU's two-line display. Not currently used.

DIGITALOUTPUT.SOURCE

UI2

The type of input to this record.

0              - Output is to a relay on the RTU.

1              - Output is to an I/O CIM.

2              - Output is to a Modbus device.

DO

UI1


ENERGY.ACCUMULATION.EU

STRING

Text field describing the units used for energy produced.

ENERGY.ACCUMULATION.SCALE

R4

Conversion factor used to determine the energy produced.

ENERGY.RATE.SCALE

R4

Conversion factor used to determine the rate energy is being produced. The energy rate is calculated as follows:

EnergyRate =

VolumetricFlowRate x

HeatingValue x

RateScaleFactor

FL

R4


FLOW.ACCUMULATION.EU

STRING

Text field describing the units used to measure the amount of fluid produced, e.g. MCF, MMCF, etc.

FLOW.ACCUMULATION.SCALE

R4

Conversion factor used to determine the amount of fluid produced.

FLOW.OR.ENERGY.DO0

UI2


FLOW.OR.ENERGY.DO1

UI2


FLOW.RATE.EU

STRING

Text field describing the units used for the flow rate, e. g.

MCF/Day, MCF/Hour, etc.

FLOW.RATE.SCALE

R4

Conversion factor used to convert the flow rate from engineering units per hour to the desired rate.

FLOWCONTROL.ANALOG1.CHANNEL

UI2


FLOWCONTROL.ANALOG2.CHANNEL

UI2


FLOWCONTROL.CONTROL.TYPE

UI2

The value that determines what method of flow control is to be used. The following methods are available:

0  - Flow Rate Control

1  - Differential Pressure

2  - Pressure Reducing

3  - Back Pressure

4  - Pressure Differential

FLOWCONTROL.CONTROL_DEADBAND

UI2

The amount above or below the setpoint the control value is allowed to deviate and be considered within range.

FLOWCONTROL.INIT_FLAG

UI1

Read, indicates if the record has been edited.

Write: In 2:3.0 and on, the field is ignored and the “init” flag is set to 1 in the RTU. Earlier versions the value in this field is set into the “init” flag.

FLOWCONTROL.MODULE_STATUS

UI1

Set of flags that show the status of all Production Control Modules, as described earlier.

The flags for Flow/Override Control and Production Control can be set on or off with the update message, the other bits are read only.

FLOWCONTROL.OVERRIDE.ANALOG1.CHANNEL

UI2


FLOWCONTROL.OVERRIDE.ANALOG2.CHANNEL

UI2


FLOWCONTROL.OVERRIDE.DEADBAND

UI2

The amount above or below the setpoint the control value is allowed to deviate and be considered within range.

FLOWCONTROL.OVERRIDE.FLAG

UI2

Flag indicating that Override Control is to be used.

FLOWCONTROL.OVERRIDE.SETPOINT

R4

Desired value for the Flow Control routine to maintain.

FLOWCONTROL.OVERRIDE.TYPE

UI2

The value that determines what method of flow control is to be used. The following methods are available:

0  - Flow Rate Control

1  - Differential Pressure

2  - Pressure Reducing

3  - Back Pressure

4  - Pressure Differential

FLOWCONTROL.OVERRIDE.VALVE.FREQUENCY

UI2

The time, in seconds, between valve adjustments.

FLOWCONTROL.OVERRIDE.VALVE.TIME

UI2

For Production Valves that use DOs to control opening and closing, supplies the time, in milliseconds, that the DO is energized to open or close the valve. For Production Valves that use an AO, contains the percentage adjustment.

FLOWCONTROL.SETPOINT

UI4

Desired value for the Flow Control routine to maintain.

FLOWCONTROL.VALVE.FREQUENCY

UI2

The time, in seconds, between valve adjustments.

FLOWCONTROL.VALVE.TIME

UI2

For Production Valves that use DOs to control opening and closing, supplies the time, in milliseconds, that the DO is energized to open or close the valve. For Production Valves that use an AO, contains the percentage adjustment.

FLOWING.TEMPERATURE_ANALOG

I2

Software AI record providing the flowing temperature of the gas. If no software AI record is used, this value is -1 (The default value).

GASANALYSIS.ARGON

R4

Argon

GASANALYSIS.BTU.CONTENT

R4

BTU content

GASANALYSIS.CO

R4

Carbon Monoxide

GASANALYSIS.CO2

R4

Carbon Dioxide

GASANALYSIS.DECANE

R4

Decane

GASANALYSIS.ETHANE

R4

Ethane

GASANALYSIS.H2S

R4

Hydrogen Sulfide

GASANALYSIS.HELIUM

R4

Helium

GASANALYSIS.HEPTANE

R4

Heptane

GASANALYSIS.HEXANE

R4

Hexane

GASANALYSIS.HYDROGEN

R4

Hydrogen

GASANALYSIS.ISO.BUTANE

R4

ISO Butane

GASANALYSIS.ISO.PENTANE

R4

ISO Pentane

GASANALYSIS.METHAN

R4

Methane

GASANALYSIS.N.BUTANE

R4

nButane

GASANALYSIS.N.PENTANE

R4

nPentane

GASANALYSIS.N2

R4

Nitrogen

GASANALYSIS.NONANE

R4

Nonane

GASANALYSIS.OCTANE

R4

Octane

GASANALYSIS.OXYGEN

R4

Oxygen

GASANALYSIS.PROPANE

R4

Propane

GASANALYSIS.SPEC.GRAV

R4

Specific Gravity

GASANALYSIS.WATER

R4

Water

ID.NAME

STRING

ID Name

ID.NUMBER

STRING

ID Number

IDS_ITEM_ENERGY_RATE_EU

STRING

Text field describing the units used to measure the rate of energy being produced, e. g.

MMBTU/Day, BTU/Hour, etc.

INITIALIZED

UI1

Flag indicating the flow computer has been initialized.  1 = yes, 0 = no

Latch/FlowComputerNumber

Ex: Latch/1

UI1

Latch DO

LIFT.ARRIVAL.ACCUNUM

UI2

Record number of the

Accumulator used to record the plunger arrival.

LIFT.ARRIVAL.SWITCHTIME

UI2


LIFT.BYPASS.VALVEDONUM

UI2

Number of the DO record that controls the Bypass Valve.

LIFT.BYPASS.VALVEFLAG

UI2

Flag indicating the presence of a bypass valve.

LIFT.CRYOUT

UI1

A byte that controls the RTU cryout on alarms and which alarms trigger a cryout. 

LIFT.EARLYARRIVALTIME

UI2

The time, in seconds, that determines if the plunger arrived earlier than expected. If the plunger arrives in fewer seconds than this time it is considered an early arrival. In version 3:1.0, arrivals earlier than this time are ignored.

LIFT.INITFLAG

UI1

Read: indicates if the record has been edited.

Write: In 2:3.0 and on, the field is ignored and the “init” flag is set to 1 in the RTU. Earlier versions the value in this field is set into the “init” flag.

LIFT.MAXLIFTTIME

UI2

Maximum amount of time, in seconds, allowed for the plunger to arrive.

LIFT.MODULESTATUS

UI1

Set of flags showing the status of all Production Control Modules, as described earlier.

The flags for Lift Control and Production Control can be set on or off with the update message, the other bits are read only.

LIFT.PLUNGER.FALLTIME

UI2

Time, in seconds, allowed for the plunger to fall before beginning the time allowed for

lifting. . This option is in firmware versions 2:2.10 and greater.

LIFT.PLUNGER.RELEASEACTIVATIONTIME

UI2

Time, in milliseconds, the digital output is energized in order to release the plunger.

LIFT.PLUNGER.RELEASEDONUM

UI2

Record number of the Digital Output that controls the plunger release.

LIFT.PLUNGER.RELEASEFLAG

UI2

Flag indicating the presence of a plunger release digital output.

LIFT.SECONDARYLIST.ARRIVALTIME

UI2

Time, in seconds, allowed for the plunger to arrive after the maximum lift time has completed and the plunger has not arrived. If the plunger does not arrive before this time is up, the bypass valve opens.

LIFT.SETPOINT

UI4

This is the setpoint used by the Flow Control module during lift. This value is only used if the field "Use Flow Control During Lift" is set to a value of 2.

LIFT.USEFLOWCONTROL

UI1

This field was not used prior to version 2:3.6. It indicates if flow control is used during lift and the type of control setpoint that is used. It can take on the following values:

0              - Flow Control is not used during lift.

1              - Flow Control is used, using the Flow Control module setpoint.

2              - Flow Control is used, using the setpoint specified in the “setpoint during lift” field. This option was added in version 3:0.0

LIFT.VALVEOPENPERCENT

UI2

Amount to open the valve when the conditions to open are met. This option was not available in firmware prior to 2:2.10.

MAX.TUBES

UI2

Always 1

METER.ABSOLUTE.STATIC.PRESSURE.SENSOR

UI1

1 = absolute, 0 = gauge

METER.ACC.ANALOG.INPUT

UI1

For turbine meters only: This is the number of the software record that provides the input from the turbine.

METER.AGATYPE

UI1

Defines the type of meter used with this flow computer.

METER.ALLOW.FLOW.RATE.AI

UI1

For turbine meters only: This flag indicates whether the flow rate comes from an analog input or from an accumulator input.

METER.B1.CORRETION.FACTOR

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B1.FLOW.RATE

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B10.CORRECTION.FACTOR

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B10.FLOW.RATE

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B2.CORRECTION.FACTOR

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor. 

METER.B2.FLOW.RATE

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B3.CORRECTION.FACTOR

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B3.FLOW.RATE

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B4.CORRECTION.FACTOR

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B4.FLOW.RATE

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B5.CORRECTION.FACTOR

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B5.FLOW.RATE

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B6.CORRECTION.FACTOR

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B6.FLOW.RATE

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B7.CORRECTION.FACTOR

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B7.FLOW.RATE

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor. 

METER.B8.CORRECTION.FACTOR

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B8.FLOW.RATE

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B9.CORRECTION.FACTOR

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.B9.FLOW.RATE

R4

For turbine meters only: calibration curve supplied by the meter manufacturer. The defaults for all entries are 0.0 for the flow rate and 1.0 for the correction factor.

METER.EXP.CONST.FOR.PIPE

R4

For orifice meters only: This value tells how much the size of the pipe changes as the temperature changes. This value is only used in the AGA 3 - 1992 equations.

METER.EXPANSION.FACTOR.CALCULATED

UI1

These factors are only settable if the AGA 3 - 1985 equations are used. For the AGA 3 - 1992 and VCONE equations, these values are always calculated. The flags should all be set to 1. When the meter message is requested from the RTU, the values returned in these fields are for information only. 

METER.EXPANSION.FACTOR.VALUE

R4

These factors are only settable if the AGA 3 - 1985 equations are used. For the AGA 3 - 1992 and VCONE equations, these values are always calculated. The flags should all be set to 1. When the meter message is requested from the RTU, the values returned in these fields are for information only.

METER.FLANGE.TAPS

UI1

1 = flange taps, 0 = pipe taps

METER.HIGH.DP.ANALOG

UI2

Used only if the number of DP Cells is 2.

METER.HIGHTOLOW.RATE

R4

Transfer rate from high to low

DP.  Used only if the number of DP Cells is 2. DP value below which the low DP cell is used.

METER.INITIALIZED

UI1

1 = yes, 0 = no

METER.LOW.DP.ANALOG

UI2

Software AI record number for low DP sensor if the number of cells in the DP stack is 2. If only DP cell is used, this is the analog record of the DP sensor.

METER.LOW.DP.CUTOFF

R4

below which the flow computer sets the flow rate to zero. Turbine meter: the rate, in engineering units per hour, below which the flow computer sets the flow rate to zero.

METER.LOWTOHIGH.RATE

R4

Transfer rate from low to high

DP. Used only if the number of DP Cells is 2. DP value above which the high DP cell is used.

METER.METER.FACTOR

R4

Used for turbine meters only. Supplied by the meter manufacturer.

METER.NUMBER.BREAKPOINT.PAIRS

UI1

Always 10

METER.NUMBER.STACKED.DPS

UI2

Orifice meter only; 1 or 2

METER.ORIFICE.DIAMETER

R4

The diameter of the orifice, in inches. If VCONE is used, this is the VCONE diameter.

METER.ORIFICE.EXPANSION.CONSTANT.NEW

R4


METER.ORIFICE.EXPANSION.CONSTANT.OLD

R4


METER.ORIFICE.FLOW.FACTOR.CALCULATED

UI1

These factors are only settable if the AGA 3 - 1985 equations are used. For the AGA 3 - 1992 and VCONE equations, these values are always calculated. The flags should all be set to 1. When the meter message is requested from the RTU, the values returned in these fields are for information only.

METER.ORIFICE.FLOW.FACTOR.VALUE

R4

These factors are only settable if the AGA 3 - 1985 equations are used. For the AGA 3 - 1992 and VCONE equations, these values are always calculated. The flags should all be set to 1. When the meter message is requested from the RTU, the values returned in these fields are for information only.

METER.ORIFICE.THERMALEXP.FACTOR.CALC

UI1

These factors are only settable if the AGA 3 - 1985 equations are used. For the AGA 3 - 1992 and VCONE equations, these values are always calculated. The flags should all be set to 1. When the meter message is requested from the RTU, the values returned in these fields are for information only.

METER.ORIFICE.THERMALEXP.FACTOR.VALUE

R4

These factors are only settable if the AGA 3 - 1985 equations are used. For the AGA 3 - 1992 and VCONE equations, these values are always calculated. The flags should all be set to 1. When the meter message is requested from the RTU, the values returned in these fields are for information only.

METER.ORIFICE.PIPE.ID

R4


METER.ORIFICE.PULSE.SCALE.FACTOR

R4

Used for turbine meters only.

Used to scale the meter factor. Pulses are multiplied by meter factor / scaling factor, then converted to rate per hour for the break pair table lookup. These 2 factors aren't used on the analog input flow rate 

METER.ORIFICE.RATIO.SPECIFIC.HEAT

R4

Isotropic exponent, Ki. Refer to the AGA 3 manuals for a more complete definition. The default is 1.3.

METER.ORIFICE.REYNOLDS.NUMBER.FACTOR.C ALCU

UI1

These factors are only settable if the AGA 3 - 1985 equations are used. For the AGA 3 - 1992 and VCONE equations, these values are always calculated. The flags should all be set to 1. When the meter message is requested from the RTU, the values returned in these fields are for information only.

METER.ORIFICE.REYNOLDS.NUMBER.FACTOR.V ALUE

R4

These factors are only settable if the AGA 3 - 1985 equations are used. For the AGA 3 - 1992 and VCONE equations, these values are always calculated. The flags should all be set to 1. When the meter message is requested from the RTU, the values returned in these fields are for information only.

METER.UPSTREAM.TAPS

UI1

Indicates whether taps for the pressure sensor are upstream or downstream of the meter.

1 = upstream taps, 

0 = downstream taps

METER.VCONE

UI1

1 = yes; 0 = no

METER.WATER.VAPOR.FACTOR

R4

AGA7: Orifice meter correction factor 

AGA3 or VCONE: meter factor.

METER.WATER.VAPOR.FACTOR.CALCULATE

UI1

1 = yes, 0 = no

METER.WATER.VAPOR.FACTOR.VALUE

R4


MISCSETUP.AI.HIGH.FAIL

UI2

The value, in terms of raw analog counts, above which the analog input is considered to have failed.

MISCSETUP.AI.LOW.FAIL

UI2

The value, in terms of raw analog counts, below which the analog input is considered to have failed. The AI High Fail and AI Low Fail are given in raw analog counts, and must be converted to the mA values in order to correspond to what is entered in the RTU.

The formula below converts the analog counts returned in the message to a milliamp value, as entered at the RTU:

counts = (((mA - 4) / 4) + 1) * 4000

This formula converts from the milliamp value to analog counts:

mA = (((counts / 4000) - 1) * 4) + 4

MISCSETUP.CRYOUT.DIAL.TIMEOUT

UI2

Time, in seconds, the RTU waits for the modem to synchronize itself with the remote modem after dialing the number.

MISCSETUP.CRYOUT.FLAG

UI1

Configures the RTU cryout feature. Set to 1 if cryout is to be enabled, 0 if cryout is disabled.

MISCSETUP.CRYOUT.MODEM.LISTEN.TIME

UI2

Time, in seconds, the RTU waits for the modem to make a connection after answering.

MISCSETUP.CRYOUT.ON.ACC.ALARM

UI1

Configures RTU cryout on an accumulator alarm. Set to 1 to enable, 0 to disable.

MISCSETUP.CRYOUT.ON.AI.ALARM

UI1

Configures RTU cryout on an analog alarm. Set to 1 to enable, 0 to disable.

MISCSETUP.CRYOUT.ON.DI.ALARM

UI1

Configures RTU cryout on an digital alarm. Set to 1 to enable, 0 to disable.

MISCSETUP.CRYOUT.RADIO.TIMEOUT

UI2

Time, in seconds, the RTU waits for the conventional radio system to become available to send data.

MISCSETUP.CRYOUT.RETRY.TIME

UI2

Time, in seconds, the RTU waits for a response from a device after sending it a message. If no response is received within this time, the message is sent again.

MISCSETUP.CRYOUT.TELEPHONE.NO

STRING

Telephone number the RTU dials.

MISCSETUP.CRYOUT.TRUNK.TIMEOUT

UI2

Time, in seconds, the RTU waits for the trunked radio system to become available to send data.

MISCSETUP.CUTOFF.VOLTAGE

R4

Radio communications are discontinued below this voltage.

MISCSETUP.DEFAULT.RELAY.TIME

UI4

When no other time is available, this is the time, in milliseconds, that a relay remains closed when it is pulsed.

MISCSETUP.DISPLAY.SCROLL.TIME

UI2

The time, in seconds, the RTU waits before displaying new data on the two-line display.

MISCSETUP.EFM.HISTORY.FORMAT

UI1

If flag is 1 the field contains the contract day. If 0 the field contains the calendar day. Refer to section 4.2, starting at offset 6.

MISCSETUP.EVENT.SEQUENCE.NUMBER

UI4

The current EFM Event Sequence Number.

MISCSETUP.PORT2.COMM.READ.ONLY

UI1

If the flag is set port 2 comm. is read only.

MISCSETUP.RECONNECT.VOLTAGE

R4

Radio communications are enabled above this voltage. The Reconnect Voltage must be greater than or equal to the Cutoff voltage.

MISCSETUP.STOREFORWARDRTU.ADDRESS1

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS10

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS11

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS12

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS13

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS14

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS15

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS16

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS17

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS18

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS19

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS2

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS20

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS3

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS4

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS5

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS6

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS7

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS8

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.ADDRESS9

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP1

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP10

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP11

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP12

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP13

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP14

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP15

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP16

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP17

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP18

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP19

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP2

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP20

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP3

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP4

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP5

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP6

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP7

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP8

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.STOREFORWARDRTU.GROUP9

UI1

An array of up to twenty RTU addresses for this RTU to forward messages. Both the RTU Address and Group Id are required to be set. If two-byte addressing is not enabled, set the Group Id to zero. For addresses that are not used, set these to zero.

MISCSETUP.UNUSED

UI2

Always 0 (was flow computer sequence number prior to 2:5.0)

MISCSETUP.USE.LOW.VOLTAGE.CUTOFF

UI1

Flag indicating the RTU no longer communicates over the radio if the main battery voltage falls below a given value.

MODULESTATUS.PRODUCTION_CONTROL/

UI1

Request/Change production

FlowComputerNumber/BIT

Ex:

MODULESTATUS.PRODUCTION_CONTROL/1/3

BIT = 0 - 7


control module status

MOLE.CO2.ANALOG

UI2

Software AI record providing Carbon Dioxide present in the gas. If no software AI record is used, this value is -1 (The default value)

MOLE.N2.ANALOG

UI2

Software AI record providing the Nitrogen present in the gas. If no software AI record is used, this value is -1.

NOT.USED1

R4


NOT.USED2

R4


NOT.USED3

R4


NOT.USED4

R4


NOT.USED5

R4


NOT.USED6

R4


NOT.USED7

R4


NOT.USED8

UI2


NUMBER.OF.DIGITAL.OUTPUT

UI2


NX19.CALCULATED

UI1


NX19.DELTA.SECONDS

UI2


NX19.VALUE

R4


OPTIMIZE.CASING.PRESSUE.CHANNEL.NUM

UI2

Request/Change Optimize <ItemName>

X = Flow Computer Name

In all of the following Optimize tags.

OPTIMIZE.CASING.PRESSURE.SENSOR.AVAIL

UI2

Flag indicating if this input is to be used. 0 = no, 1 = yes

OPTIMIZE.CASING_LINE_VALUE

UI2


OPTIMIZE.CASING_PRESSURE_VALUE

UI2


OPTIMIZE.CASING_TUBING_VALUE

UI2


OPTIMIZE.CHECK_ON_CASING_LINE

UI2


OPTIMIZE.CHECK_ON_CASING_PRESSURE

UI2


OPTIMIZE.CHECK_ON_CASING_TUBING

UI2


OPTIMIZE.CHECK_ON_DP

UI2


OPTIMIZE.CHECK_ON_FLOW_RATE

UI2


OPTIMIZE.CHECK_ON_LINE_PRESSURE

UI2


OPTIMIZE.CHECK_ON_SWITCH

UI2


OPTIMIZE.CHECK_ON_TUBING_LINE

UI2


OPTIMIZE.CHECK_ON_TUBING_PRESSURE

UI2


OPTIMIZE.CLOSE.CASING-LINE.PRESSURE.FLOW

       UI2


OPTIMIZE.CLOSE.CASING-LINE.PRESSURE.VA

UI2


OPTIMIZE.CLOSE.CASING-TUBING.PRESSURE…

UI2


OPTIMIZE.CLOSE.CASING-TUBING.PRESSURE…

UI2


OPTIMIZE.CLOSE.CASING.PRESSURE.FLAG

UI2


OPTIMIZE.CLOSE.CASING.PRESSURE.VALUE

UI2


OPTIMIZE.CLOSE.DP.PRESSURE.FLAG

UI2


OPTIMIZE.CLOSE.DP.PRESSURE.VALUE

UI2


OPTIMIZE.CLOSE.STATUS.CHANNEL.NUMBER

UI2


OPTIMIZE.CLOSE.STATUS.FLAG

UI2


OPTIMIZE.CLOSE.STATUS.NORMALLY.OPEN

UI2


OPTIMIZE.CLOSE.TUBING-LINE.PRESSURE.FL…

UI2


OPTIMIZE.CLOSE.TUBING-LINE.PRESSURE.VA…

UI2


OPTIMIZE.CLOSE_FLOW_RATE_DELAY

UI2


OPTIMIZE.CLOSE_FLOW_RATE_VALUE

UI2


OPTIMIZE.CLOSE_LINE_PRESSURE_VALUE

UI2


OPTIMIZE.CLOSE_ON_FLOW_RATE

UI2


OPTIMIZE.CLOSE_ON_LINE_PRESSURE

UI2


OPTIMIZE.CLOSE_ON_TUBING_PRESSURE

UI2


OPTIMIZE.DP_CLOSE_DELAY

UI2


OPTIMIZE.DP_DELAY

UI2


OPTIMIZE.DP_VALUE

UI2


OPTIMIZE.FLOW_RATE_DELAY

UI2


OPTIMIZE.DP_VALUE

UI2


OPTIMIZE.FLOW_RATE_DELAY

UI2


OPTIMIZE.FLOW_RATE_VALUE

UI2


OPTIMIZE.INTERMIT.TIME.OFF

UI2

The amount of time, in minutes, the valve is to be closed.

OPTIMIZE.INTERMIT.TIME.ON

UI2

The amount of time, in minutes, the valve is to be open.

OPTIMIZE.INTERMITTER_INIT_FLAG

UI1

Read: indicates if the record has been edited previously.

Write: In 2:3.0 and on, the field is ignored and the “init” flag is set to 1 in the RTU. Earlier versions the value in this field is set into the “init” flag.

OPTIMIZE.INTERMITTER_OFF_FLAG

UI2

Read: non-0 if the OFF cycle is in progress. 

Write: if OFF cycle is in progress and “on flag” is non-0, the value in the “off time left” field is used.

OPTIMIZE.INTERMITTER_OFF_TIME_LEFT

UI2

Meaningful if “off flag” is non-0. Read: time remaining, in minutes, in the OFF cycle. Write: Value is new time remaining. 

OPTIMIZE.INTERMITTER_ON_FLAG

UI1

Read: non-0 if the ON cycle is in progress.

Write: if ON cycle is in progress and “on flag” is non-0, the value in the “on time left” field is used.

OPTIMIZE.INTERMITTER_ON_TIME_LEFT

UI2

Meaningful if “on flag” is non-0. Read: time remaining, in minutes, in the ON cycle. Write:

Value is new time remaining.

OPTIMIZE.LIFT_OPTIMIZE_NORMALLY_OPEN

UI2


OPTIMIZE.LINE.PRESSURE.CHANNEL.NUMBER

UI2


OPTIMIZE.LINE.PRESSURE.SENSOR.AVAILABLE

UI2

Flag indicating if this input is to be used. 0 = no, 1 = yes

OPTIMIZE.LINE.PRESSURE_VALUE

UI2


OPTIMIZE.MODULE_STATUS

UI1


OPTIMIZE.OPEN.CASING-LINE.PRESSURE.FLAG

UI2


OPTIMIZE.OPEN.CASING-LINE.PRESSURE.VA…

UI2


OPTIMIZE.OPEN.CASING-TUBING.PRESSURE…

UI2


OPTIMIZE.OPEN.CASING-TUBING.PRESSURE…

UI2


OPTIMIZE.OPEN.CASING.PRESSURE.FLAG

UI2


OPTIMIZE.OPEN.CASING.PRESSURE.VALUE

UI2


OPTIMIZE.OPEN.STATUS.CHANNEL.NUMBER

UI2


OPTIMIZE.OPEN.STATUS.FLAG

UI2


OPTIMIZE.OPEN.STATS.NORMMALLY.OPEN

UI2


OPTIMIZE.OPEN.TUBING-LINE.PRESSURE.FLAG

UI2


OPTIMIZE.OPEN.TUBING-LINE.PRESSURE.VA….

UI2


OPTIMIZE.OPEN_LINE_PRESSURE_VALUE

UI2


OPTIMIZE.OPEN_ON_LINE_PRESSURE

UI2


OPTIMIZE.OPEN_ON_TUBING_PRESSURE

UI2


OPTIMIZE.OPTIMIZER_INIT_FLAG

UI1

Read: indicates if the record has been edited previously.

Write: In 2:3.0 and on, the field is ignored and the “init” flag is set to 1 in the RTU. Earlier versions the value in this field is set into the “init” flag.

OPTIMIZE.ORIFICE.DP.CHANNEL,NUMBER

UI2


OPTIMIZE.ORIFICE.DP.SENSOR_AVAILABLE

UI2

Flag indicating if this input is to be used. 0 = no, 1 = yes

OPTIMIZE.SWITCH_CHANNEL_NUMBER

UI2


OPTIMIZE.TUBING.PRESSURE.CHANNEL.NU..

UI2


OPTIMIZE.TUBING.PRESSURE.SENSOR.AVAIL…

UI2

Flag indicating if this input is to be used. 0 = no, 1 = yes 

OPTIMIZE.TUBING_LINE_VALUE

UI2


OPTIMIZE.TUBING_PRESSURE_VALUE

UI2


OPTIMIZE.TUBING_PRESSURE_VALUE_FOR_C…

UI2


OPTIMIZE.TUBING_PRESSRUE_VALUE_FOR_O…

UI2


OPTIMIZE.FLOWING.TEMPERATURE.CALCULA…

UI1


OPTIMIZE.FLOWING.TERMPERATURE.VALUE

R4


PRESSURE.BASE.CALCULATED

UI1


PRESSURE.BASE.VALUE

R4


PRODUCTIONVALVE.ANALOG_FEEDBACK

UI1

Flag indicating that an AI record is used to indicate the position of the primary valve

PRODUCTIONVALVE.FEEDBACK_CHANNEL

UI2

AI record number to be used for the Analog Feedback.

PRODUCTIONVALVE.INIT_FLAG

UI1

Read: indicates if the valve has been initialized.

Write: In 2:3.0. and on, the field is ignored, and the “init” flag is set to 1 in the RTU. Earlier versions the value in this field is set into the “init” flag.

PRODUCTIONVALVE.MODULE_STATUS

UI1

Bitmap indicating which modules in Production Control are currently operating, as described earlier. The value for the Production Control bit may be modified, the other bits are read only. Also if the valve data are sent to the RTU to initialize the valve, the Production Valve initialized flag is set to 1. 

PRODUCTIONVALVE.PRIMARY.CLOSE.LIMIT

UI2


PRODUCTIONVALVE.PRIMARY.CLOSE.RELAY…

UI2


PRODUCTIONVALVE.PRIMARY.CLOSE.RELAY..

UI2


PRODUCTIONVALVE.PRIMARY.LOCAL.RESET..

UI2


PRODUCTIONVALVE.PRIMARY.LOCAL.RESET..

UI2


PRODUCTIONVALVE.PRIMARY.NUMBER.LIMIT

UI1

Number of DIs used to detect when the production valve is in a fully open or fully closed state.

PRODUCTIONVALVE.PRIMARY.OPEN.LIMIT.S..

UI2


PRODUCTIONVALVE.PRIMARY.OPEN.RELAY…

UI2


PRODUCTIONVALVE.PRIMARY.OPEN.RELAY..

UI2


PRODUCTIONVALVE.PRIMARY.POWER.OPTI..

UI2


PRODUCTIONVALVE.PRIMARY.RELAY.OPTI…

UI2


PRODUCTIONVALVE.PRIMARY.VALVE.NORM..

UI2


PRODUCTIONVALVE.SECONDARY.OPEN.REL…

UI2


PRODUCTIONVALVE.SECONDARY.VALVE.FLAG

UI2

Flag indicating if there is a secondary valve.  

0= no, 1= yes

PRODUCTIONVALVE.VALVE_TYPE

UI1

Indicates the type of primary valve being used.

0  - Pulse Relay

1  – Latch

2  - Analog Output

3  - Inverted Analog Output

PRODUCTIONVOLUME.ACCUMULATION

R4

Read only. Amount produced on the current cycle.

PRODUCTIONVOLUME.AUTO_RESET

UI1

Tells the Production Volume Control module if the cycle is to be reset automatically, where 0 = no reset, 1 = daily reset, 2 = monthly reset.

PRODUCTIONVOLUME.CYCLE

UI1

Read: YES if the Production Volume Control cycle is in progress and has not reached the limit.

Write: YES to reset the Production Volume Control cycle.

PRODUCTIONVOLUME.DELAY_TIME

UI1

Amount of time, in minutes, the Production Volume Control module waits after the end of the day or month, before starting the next cycle.

PRODUCTIONVOLUME.INIT_FLAG

R4

Read: indicates if the record has been edited previously.

Write: In 2:3.0 and later, the field is ignored and the “init” flag is set to 1 in the RTU. Earlier versions the value in this field is set into the “init” flag.

PRODUCTIONVOLUME.MODULE_STATUS

UI1

Set of flags that show the status of all Production Control Modules, as described earlier.

The flags for Production Volume Control and Production Control can be set on or off with the update message, the other bits are read only.

PRODUCTIONVOLUME.NEXT_LIMIT_TO_USE

UI2


PRODUCTIONVOLUME.SETPOINT

UI4


PSDTSD.EDITFLAG

UI1

Read: indicates if the record has been edited previously.

Write: In 2:3.1 and on, the field is ignored and the “edited” flag is set to 1 in the RTU. In 2:3.0 the field is ignored and the “edited” flag is unchanged. Earlier versions the value in this field is set into the “edited” flag.

PSDTSD.ESDFLAG

UI1

Read, a value of 1 indicates an ESD has occurred.

Write, a value of 1 resets the ESD.

PSDTSD.ESDVALVE

UI1

Flag indicating if this is an

Emergency Shutdown (ESD)

valve. Set to 1 if this is an ESD Valve, 0 otherwise.

PSDTSD.MODULESTATUS

UI1

Bitmap indicating which modules in Production Control are currently operating. The values for the Production Control bit and the PSD/TSD bit may be modified, the other bits are read only. 

PSDTSD.RESETDORECORD

UI2

DO record that opens the ESD valve.

PSDTSD.RESETTIME

UI2

Time, in milliseconds, to pulse the DO that opens the ESD valve.

PSDTSD.TRIPDORECORD

UI2

DO record that closes the ESD valve.

PSDTSD.TRIPTIME

UI2

Time, in milliseconds, to pulse the DO to close the ESD valve.

Pulse/FlowComputerNumber

Ex: Pulse/2

UI1

Pulse DO

Pulse2/FlowComputerNumber

Ex: Pulse2/1

UI2

Pulse DO with time period  (0 – 65535 ms)

Pulse4/FlowComputerNumber

EX:  Pulse4/1

UI4

Pulse DO with time period  (0 – 4294967295 ms)

ReInitializeDeviceConfig

UI2


RELAY.NUMBER.FOR.DO0

UI2


RELAY.NUMBER.FOR_DO1

UI2


REPORT.TO.DISPLAY

UI1


SHUTIN.ACTIVE

UI2


SHUTIN.ARMED

UI2


SHUTIN.DI_RECORD_NUMBER

UI2


SHUTIN.DO_RECORD_NUMBER

UI2


SHUTIN.SPARE1

UI2


SHUTIN.SPARE2

UI1


SHUTIN.TIMEOUT

UI4


SPECIFIC.GRAVITY.ANALOG

UI2


SPECIFIC.GRAVITY.CALCULATED

UI1


SPECIFIC.GRAVITY.VALUE

R4


STATIC.PRESSURE.ANALOG

UI2


TEMPERATURE.BASE.CALCULATED

UI1


TEMPERATURE.BASE.VALUE

R4


TIME.VALUE.FOR.DO0

UI2


TIME.VALUE.FOR.DO1

UI2


Time Sync

I4

This item syncs the time with the host computer. It can be performed with interval or by poking values. For details of the poking value and time sync rules, see ACM User Guide for details.

TOTALIZER.ACCUMULATOR_RECORD_NUM

I1


TOTALIZER.AI_RECORD_NUMBER

I1


TOTALIZER.DESCRIPTION

STRING


TOTALIZER.REPORT_TO_DISPLAY

UI1


TOTALIZER.STRAPPING_FACTOR

R4


TOTALIZER.UNITS

STRING


TURBINE.FACTOR.REQUIRED

UI1


Unlatch/FlowComputerNumber

Ex: Unlatch/1

UI1

Unlatch DO


Upload_Analog/AnalogRecordNumber Ex: Upload_Analog/8

I2

This item retrieves analog records only when it is being poked. Poking x > 0 number to this item will upload x number of days since current if there are that many available in the RTU. If successful, it will return 0 in the value, otherwise it will be 3 indicating no response or that an error occurred during the communication.  The uploaded file will be stored in the prespecified location with the name also pre-specified. For details on how to configure history, se the ACM User Guide.

Upload_CTD/FlowComputer/MessageOption


Ex: Upload_CTD/1/3


Message Option:

  • Return Sum of Extension: bit 0
  • Return Only Closed Days: bit 1

I2

This item retrieves CTD history and CTD events only when it is being poked. Poking x > 0 number to this item will upload x number of days since current time if there are that many available in the RTU.  If successful, it will return a 0 in the value, otherwise it will return 3, indicating no response or that an error occurred during the communication. The uploaded file will be stored in the prespecified location with the name also pre-specified. For details on how to configure history, see the ACM User Guide. 

Upload_Production/FlowComputerNumber


Ex: Upload_Production/1


I2

This item retrieves production events only when it is being poked. Poking x > 0 number to this item will upload x number of days since current time if there are that many available in the RTU. If successful, it will return 0, otherwise it will return 3 indicating no response or that an error occurred during the communication. The uploaded file will be stored in the prespecified location with the name also pre-specified. For details on how to configure history, see the ACM User Guide.

Upload_TrendDaily/TrendNumber



Ex: Upload_TrendDaily/0



I2

This item retrieves daily trends only when it is being poked.  Poking x > 0 number to this item will upload x number of days since current time if there are than many available in the RTU. If successful, it will be 0 in the value, otherwise it will return a 3 to indicate no response or that an error occurred during the communication. Uploaded file will be stored in the prespecified location with the name also pre-specified. For details on how to configure history, see the ACM User Guide. 

Upload_TrendHourly/TrendNumber


Ex: Upload_TrendHourly/0

I2

This item retrieves hourly trends only when it is being poked. Poking x > 0 number to this item will upload x number of hours since current time if there are that many available in the RTU. If successful, a 0 will be returned, otherwise it will be 3 to indicate no response or that errors occurred during the communication.  The uploaded file will be stored in the prespecified location with the name also pre-specified. For detail on how to configure history, see the ACM User Guide.

ZeroAccumulator

UI1


Extended Items

ItemData TypeDescription

GCWrite/Txn

VAR


LastAnalogRecord/1

Date


LastDailyRecord/1

Date


LastHourlyrecord/1

Date


LastProductionRecord/1

Date


LastTimeSync

Date


LastTimeSyncResult

I4


LastTrendDailyRecord/1

Date


LastTrendHourlyRecord/1

Date


For assistance, please submit a ticket via our Support Portal, email autosol.support@autosoln.com or call 281.286.6017 to speak to a support team member.