Emerson IP258 manual Hand Held Communicator Registers

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HAND HELD COMMUNICATOR REGISTERS

D9.0 SAFE, WORKING, OFFLINE, DEFAULT, Registers

Introduction to Registers

From the FUNCTION screen, whilst interrogating an MSM400 control unit, there is a selection titled “BACKUP”. This allows the data now stored in the WORKING register (i.e. the MSM400 control unit data) to be transferred to a separate secure memory, to either retain it while making changes to the MSM400 control unit (i.e. as a “revert to the original program” insurance data store) or to save it in memory so that it can be copied or consulted back in the office. The registers available are

WORKING REGISTER

This is literally the work sheet where all work is done – all changes made to the parameters on the SMART Communicator keyboard are made to the data in the WORKING Register. While the Communicator is attached across the 4-20mA loop, the WORKING register is exactly the same as the MSM400 control unit memory, so all changes made to the WORKING register are also made to the control unit itself. The MSM400 control unit memory and the WORKING register in the SMART Communicator are identical. If communication between the two units fails, then changes attempted in the WORKING register will be rejected.

Note : The SMART Communicator can be unaware of changes to the MSM400 control unit memory made by (a) a Primary Master (such as Mobrey H-View) also attached to this control unit loop, and (b) the local zero and span on the MSM400.

The data existing in the WORKING register is overwritten (and therefore lost) when new data is loaded from another register, or when the SMART communicator is reconnected to an MSM400 loop, because the start up routine will load this new MSM400 memory into the WORKING register. To save any data that has been entered in an “Off-loop” state (i.e. back in the office) the data must be held in the OFFLINE register (see below).

It is recommended that the data in the WORKING register is transferred OFFLINE before disconnection of the SMART communicator from the loop, if it is likely to be needed for reference back in the office. However, the data in the WORKING register is retained in the Psion memory after this disconnection, and can still be interrogated until overwritten by new data.

SAFE REGISTER

The SAFE Register is literally a register where the current MSM400 calibration data can be stored and kept SAFE, while changes are made on the WORKING register and the SMART Communicator is attached to the loop. If these WORKING register changes then prove ineffective or not required, the SAFE register data can be recalled into the WORKING register (and therefore to the MSM400 control unit) to reset all the MSM400 parameters to their original values – i.e. the values in the control unit when the last “Backup” operation transferring the data to the SAFE register was carried out. The data in the SAFE register can only be loaded into the WORKING REGISTER when the communicator is attached to the same MSM400 control unit that was the source of the data – i.e. the control unit with the same unique identifier (D08). It is not possible to transfer programmes between instruments using the SAFE register.

The SAFE register is retained even when the Communicator is disconnected from the loop, powered down, and then reconnected to another loop, collecting new data in the WORKING register. It is not accessible until the correct control unit loop is interrogated, so that the check on the D08 Unique Identifier has been satisfied.

OFF-LINE REGISTER

This is the register used for transfer of programmes between one unit and the next, or from a programme developed on the SMART Communicator at the office desk, stored OFF-LINE and then down loaded into an MSM400 control unit on the plant later. Such data transfer is achieved by connecting the SMART Communicator across the relevant MSM400 loop, loading the WORKING register with the current MSM400 program (see below) then transferring the OFF-LINE stored data into the WORKING register – this overwrites the previous programme in the MSM400 (both the control unit memory and the WORKING Register).

IP258

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Contents Mobrey Contents Safety Precautions Sensor Connection IVE Neutral Earth Mains DisplayENT Product Description Product Introduction MSM400 Slurry Monitoring SystemUltrasonic Attenuation versus Suspended solids Slurry CharacteristicsMobrey Pipe Section Sensors Suspended Sensor Type MSM433Sensor Type Numbering System Control Unit MSM400 Displays and KeypadKeypad Operation SPECIFICATIONS--MSM400 HartEMC Pipe Section Installation Suspended Sensor InstallationPreliminary Checks Control Unit Sensor CablesTerminal Label Function Current Output Hart Connections and Jumper SettingsSensor Connections RelaysSafety Precautions Initial Power UPMains Supply Toggle RUN Calibration Setup Monitor Main Menu Toggle RUN Calibration SetupToggle RUN Diagnostic Parameters EX-FACTORY System FeaturesZero Setting Initial Zero Rechecking Zero Calibration Methods Auto CAL Auto CAL Zero Setting ProcedureClear Liquor Press ENT To set 23.1dB 26.2dB Autocal Span Setting ProcedureAuto CAL LAB Values Sample Press ENT to set 33.6dB 44.2dBCalibration Method 1-SLURRY Type Zero Setting ProcedureMaximum % Solids Span CALIBRATION/GRADIENT MethodsAttenuation VALUE-METHOD Duty Mode Desludge Mode No. of operation Set Default value Max value Hrs & minsStart on Stop on Stop if Do not start if INPUT↓ Output Start Time #1 hm 730 P254 Relay Operation Outputs Current OutputDisplay option parameter number Description AlarmMiddle Display ←−−−−−−− Lower DisplaySettings Engineering Frequency SETSystem Test Current Output Sensors Hart Smart CommunicationsAppendix A1 Main Menu SUB Menu Parameter DescriptionPar No Engineering Alarm ReportDiagnostics LoggingParameter Description Min Max Default ValueMSM400 Monit Parameter Description Min Max Default ValueFrom list 3.6/21mA/hold last reading Min Max Default Value Ex-Factory Manufacturer’s Code Hart Considerations Appendix A3 Hart and Psion Operating InstructionsSmart Communication with the Mobrey MSM400 Calibration adjustments at operating conditionsFurther customisation using the Smart HHC Handheld Communicator Mobrey CK Hand Held Communicator Assembly InstructionsFig DII. Loop diagram Fig D1 MOBREY-CK* HHC assembly How to connect the Smart Communicator Hand Held Communicator Operation How to drive a Psion based Smart Communicator Mobrey Find Save Diary Calc Time Notes World AlarmTAG Tank D7.0 Introduction and Function menu HelpD7.2 Program Parameters P D7.1 Monitor/Display Parameters DSafe Register Default RegisterMode KEY Working RegisterHand Held Communicator Registers Select Data Source Display of Parameter Data 10.0ERROR Messages on the HHC10.1Alarm and Error Messages Printout or PC transfer of MSM400 programme data10.2Invalid Data Entry Invalid Action not the Same Instrument Password not OpenInstrument in Multidrop Mode 10.3Communication ErrorsD0 D8 11.0Current Loop Checks and Trimming Current Output ** Set current Trim-maximum Trim-maximum12.0Unknown Instrument Current and USE ↑ & ↓ To Trim the Output13.3Use of multiple Smart Communicators D13.0 Smart Interfaces Compatibility D13.1 IntroductionEmerson Process Management Rosemount Measurement

IP258 specifications

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