National Centre for Nuclear Research, Poland

National Centre for Nuclear Research, Poland
Cluster-Jet Target Slow Control FAIR GmbH-JU-NCBJ Contract Technical Solutions DCS Session of LVII PANDA Meeting Arkadiusz Chlopik 1 June 8, 2016, GSI

Agenda 1. Concept of the Cluster-Jet Target Slow Control System 1.1. Interface between target’s devices and Slow Control CompactRIO System 1.2. PLCs and CompactRIO functions 2. What is to be monitored and what controlled 3. Schemes of Slow Control of the cluster-jet source and the beam-dump 4. Description of the Slow Control system (source and beam-dump sub- systems, Laval nozzle temperature and pressure control and gas-flow measurement) 5. EPICS supervisory system in the Cluster-Jet Target Slow Control Arkadiusz Chlopik 2 June 8, 2016, GSI

Cluster-Jet Target Slow Control System Concept Arkadiusz Chlopik 3 June 8, 2016, GSI

Cluster-Jet Target Slow Control System Concept cont. Two separate PLCs – Main PLC – Transfer Point PLC Main PLC’s functions: – collect data from target sensors and devices – perform measuring loop – send data received from sensors to Transfer Point PLC via Profibus – control the target devices with commands received from Transfer Point PLC Transfer Point PLC’s functions: – receive data from the Main PLC and send them to the CompactRIO – receive data or commands from the CompactRIO and send them to the Main PLC – perform measuring loops Arkadiusz Chlopik 4 June 8, 2016, GSI

Cluster-Jet Target Slow Control System Concept cont. CompactRIO’s functions: – receive data from the Transfer Point PLC and send them to a PANDA DCS supervisory computer – perform measuring loops and send the resulting data to the Transfer Point PLC and DCS – receive commands from DCS and translate them to the proper actions of the Slow Control devices Arkadiusz Chlopik 5 June 8, 2016, GSI

VACUUM GAUGE CONTROLLERS1
National Centre for Nuclear Research, Poland Monitored and controlled devices MONITORED CONTROLLED PUMP CONTROLLERS VACUUM SENSORS VALVES SLOW CONTROL VACUUM GAUGE CONTROLLERS1 GAS MASS FLOW2 MASS FLOW METER3 TEMPERATURE SENSORS PRESSURE CONTROLLER4 TEMP. CONTROLLER5 1CENTER THREE 2BROOKS 0254 3BROOKS SLA5860S 4BROOKS SLA5810A 5LAKESHORE 336 Arkadiusz Chlopik 6 June 8, 2016, GSI

Source vacuum subsystem of the Cluster-Jet Target Arkadiusz Chlopik 7 June 8, 2016, GSI

Beam-dump vacuum subsystem of the Cluster-Jet Target Arkadiusz Chlopik 8 June 8, 2016, GSI

Cluster-Jet Target Slow Control System design requirements Use of standard industrial solutions as much as possible Based on National Instruments products (TDR recommendation): – hardware: CompactRIO – software: LabVIEW RS-485 chosen as a common control bus for transferring commands/data to/from devices – in the case of devices with RS-232 interface only it is necessary to use RS232-RS485 converters – use of a cRIO module with four RS-485 ports to distinguish between different data transfer rates Direct monitoring and control using Digital Input and Digital Output C- modules Arkadiusz Chlopik 9 June 8, 2016, GSI

Cluster-Jet Target Slow Control System design requirements cont. Use of finite state machines The programs have to be scalable Must have the ability to exchange data with PANDA supervisory system Arkadiusz Chlopik 10 June 8, 2016, GSI

Hardware serving the control of cluster-jet source vacuum system Arkadiusz Chlopik 11 June 8, 2016, GSI

Hardware serving the control of cluster-jet beam-dump vacuum system Arkadiusz Chlopik 12 June 8, 2016, GSI

Laval nozzle temperature and pressure control and gas-flow measurement Two-stage („warm” and „cold”) cold-head COOLPOWER 10MD in conjunction with the helium compressor COOLPAK 6000MD produces working temperatures in the range K The motor speed of COOLPAK is controlled with CompactRIO via an RS232-RS485 converter The nozzle temperature is controlled with a pair of calibrated Si-diode sensors and the LakeShore 336 PID temperature controller The hydrogen pressure at the nozzle input is controlled with precision pressure sensor SLA5810A (1-30 bar) and the pressure metering and PID control program running in channel #2 of the Brooks instrument; the Brooks 5860S and the program running in channel #1 of Brooks 0254 monitors the hydrogen mass flow Arkadiusz Chlopik 13 June 8, 2016, GSI

Hardware serving Laval nozzle temperature and pressure control and gas-flow measurement Arkadiusz Chlopik 14 June 8, 2016, GSI

Data exchange with the PANDA DCS system Router – the third LAN3 from the hydrogen gas purifier Arkadiusz Chlopik 15 June 8, 2016, GSI

Thank you very much! Arkadiusz Chlopik 16 June 8, 2016, GSI

Estimated costs Device Type Source Beam-dump Unit price [€] Total [€] NI cRIO-9039 w/ power supply, panel mount kit and 10m cables 1 pcs 6 930,50 13 831,00 NI 9205 (Analog Input) 1 050,00 2 100,00 NI 9476 (Digital Output) 2 pcs 374,40 1 497,60 NI 9425 (Digital Input) NI 9871 (4-port RS-485) 919,30 1838,60 NI PS-16 (Power Supply) 270,60 541,20 PC Computer and laptop ~ 2 000,00 ~4 000,00 RS232-RS485 Converter 12 pcs 5 pcs 111,00 1 887,00 Arkadiusz Chlopik 17 June 8, 2016, GSI

Estimated costs cont. Software Type Quantity Unit price [€] Total [€] LabVIEW Embedded Control and Monitoring Suite 1 pcs 11 521,00 LabVIEW DSC Module, Windows 3 062,00 LabVIEW Datalogging and Supervisory Control Module 2 pcs 960,10 1 920,20 All prices are netto Detailed hardware and software costs are presented in tables 3, 3.A and 4 in Annex 3 „Technical Specifications” Total netto costs about ,00 € Arkadiusz Chlopik 18 June 8, 2016, GSI

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