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Cooling System(s) for the Roman Pots of TOTEM experiment 1 V. Vacek AGENDA: 1.Scope of the Research activities (TFP and DAQ group at the Dept. of Applied.

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Presentation on theme: "Cooling System(s) for the Roman Pots of TOTEM experiment 1 V. Vacek AGENDA: 1.Scope of the Research activities (TFP and DAQ group at the Dept. of Applied."— Presentation transcript:

1 Cooling System(s) for the Roman Pots of TOTEM experiment 1 V. Vacek AGENDA: 1.Scope of the Research activities (TFP and DAQ group at the Dept. of Applied Physics – F. of Mechanical Engineering, CTU in Prague) 2.TOTEM Roman POT cooling system development 3.Application of the efficient heat exchangers 4.Commissioning matters (ATLAS, TOTEM RP or any other system) 5.What we have learned so far LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

2 Scope of the Research activities over the last 10 years Main research program : Cooling system design for electronics application: ATLAS Inner Detector cooling circuit Pixel and SCT structures testing (with CPPM Marseille) Design, assembly and commissioning of the cooling system realized at CERN in SR1 facility Commissioning measurements in the PIT (ATLAS cavern) TOTEM Cooling system for the Roman POTs Overall design, prototype development and verification of the Roman POT thermal mockup Commissioning measurements of the 24 RP, prior to the installation in the LHC tunnel; final system commissioning 2 LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

3 Scope of the Research activities over the last 10 years Associated research program: Fluid property research: Thermophysical properties of fluoroinert fluids we studied, both theoretically (simulations – MD and MC methods) and experimentally Databases, individual thermophysical property fitting functions and engineering diagrams were prepared at the CTU for the most of the fluoroinert DAQ systems and various type of the sensors Mobile DAQ systems (based on ELMB and PVSS use) development and their implementation was completed Calibration and verification of the great variety of sensors was done Most of the commissioning measurements for ATLAS and TOTEM cooling systems were performed with our DAQ systems Heat transfer modeling for the heat exchangers design Two phase flow studies (capillary flow modeling) Cold box with controlled atmosphere for the AIRFLY project was developed and used during measurements (Frascati, It; Chicago, USA) 3 LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

4 TOTEM Cooling system for the Roman POTs 4 Roman Pots The inner structure of the Roman Pot consists of 10 silicon detectors, each of them is positioned in an electronic board called the “hybrid” with four embedded readout chips. Operation of the detectors requires temperatures below –10 °C. The dissipated heat from the chips reaches ~ up to 3 W per plane. TOTEM Experiment - its main goal is to measure the total cross section, elastic scattering and diffractive processes at the LHC on both sides of the CMS detector. The diffractive processes are detected by two types of tracking telescopes (T1 and T2). To measure the cross section and the elastic and quasielastic interactions a special instrument had to be introduced: The Roman Pot (RP). 24 Roman Pots located in 8 positions around the beam pipes are capable of detecting particles diverted by extremely low angles LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

5 TOTEM Cooling system for the Roman POTs 5 We have been asked to develop CS for TOTEM RP in MAY 2006, once the system based upon the heat pipes and pulse tube refrigerator has been ruled out since the changes in specs and strategy Our task was extremely difficult since we have inherited some fixed baselines, time for development was extremely short and nearly no resources were available at the beginning of the work A new system has been developed by the team of the CTU Prague and the final system for the PIT was designed and installed by TS/CV of CERN Close cooperation of the CTU and CERN - TS/CV resulted in successful commissioning of the whole system and it is still going on LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

6 TOTEM Cooling system for the Roman POTs 6 An evaporative cooling system circulating fluorocarbon C 3 F 8 in 4 main closed loop has been chosen and designed to guarantee a total cooling capacity of 1.2 kW and supply a global mass flow rate of 40 g/s to be uniformly shared between the 24 TOTEM Roman Pots. Basic phases of the development: Evaluation of the principle (2006-2007) Thermal mock-up development and testing (2007) Small commissioning CS design and assembly for individual RP testing at H8 facility at CERN was successfully finished in 2007/08 and is being used. IN PARALLEL: Final CS has been designed by TS/CV (2007-2008) RP TOTEM CS is installed and being commissioned right now LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

7 TOTEM Cooling system for the Roman POTs 7 Evaluation of the principle (2006-2007) Thermal mock-up development and testing (2007) LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

8 Cooling Circuit in Building 887/H8 - CERN 8 The cooling has been designed, assembled and adjusted by the team from the Department of Applied Physics of the CTU in Prague in 2007 and 2008. It consists of two oil-free compressors, a set of chilled water heat exchangers, a pump and a condenser with PID controlled temperature. The circuit is filled with fluorinert refrigerant R218. The circuit is presently prepared to cool down up to three Roman Pots simultaneously. Several tuning and control devices implemented within the circuit enable to vary a large scale of operational parameters. LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

9 Schematics of the Cooling Circuit with single POT 9 LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague DATE HEX

10 Performance of the Cooling Circuit with single POT 10 CTU Prague LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

11 Success with elimination of the insulation = DATE-HEX provided to TOTEM and to us by TS/CV DATE-HEX is compact heat exchanger capable due to the enhanced heat transfer between liquid on one side and vapor on the other side. The device provide possibility to increase vapor temperature over the short distance and still keep pressure drop of vapor at relatively small values It could possibly, after modification and some more testing, replace „problematic“ heating elements- heaters in several applications elsewhere since the device does not require too complex control system and it can be considered as the self-tuning device 11 LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

12 Implementation of the HEX into the cooling circuit 12 Instrumentation around the HEX, P, T and flow sensors Arrangement for the nominal refrigerant mass flow up to 5 g/s; water flow measured standard with use of float device, while vapor flow was monitored via SWISS-FLOW meters (frequency principle) calibrated prior to measurements The Date–Hex prototype installed into the circuit with installed pipelines LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

13 Performance of the HEX 13 LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

14 Performance of the HEX (other applications?) 14 LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

15 15 What is needed for smooth commissioning ? Reliable and robust DAQ system – it is a „must“ for the commissioning Simple version of the mobile DAQ system for commissioning: 64 channels (but expandable; low cost per channel) Type of the sensors: PT 100, PT1000, NTC Pressure sensors (voltage signals) Humidity sensors (capacitance principle+voltage converter) Enhanced accuracy due to the „internal and „external ELMB calibration and proper sensor handling LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

16 DAQ system and PVSS project – well tested 16 Type of sensors: NTC (kapton coated, pearl type); pressure sensors Huba and Sensortechnics (both HP and LP); mass flow meter Bronkhorst for the gas phase; 3 out of 6 available ELMB´s were used. All parts of the DAQ were verified and calibrated before the measurements. ATLAS ID Cooling system commissioning LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

17 17 TOTEM Cooling system commissioning Main problems in the case of TOTEM: very often – some delays (both in hardware and software for the final system deliveries) What had to be prepared in addition: For the H8 use Multichannel DAQ and DCS system For the PIT use Several dummy loads – due to the final RP shifted delivery Mini DAQ and DCS system for the PIT commissioning LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

18 18 Modifying and tuning Prevessin CS for commissioning purposes CTU Prague Cooling System at H8/in Building 887 prepared was prepared DAQ and control system was verified and handed to TOTEM Patch panel with valves has been added to the system to separate the rack for the Roman POT installed for eventual commissioning Patch panel will allow: 1. an individual manipulation of the RP, 2. its leak checking 3. pumping down the separated part of the cooling lines and when ready, it can be connected to the CS circulation just through 2 valves LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

19 19 LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague Prevessin CS – commissioning results of the RP No. 2

20 20 Commissioning set up for single POT at H8: Three POTs already commissioned Fluid INLET (liquid) and OUTLET (vapor) available Patch panel for an easy handling Environmental protection of the upper part solved Once upper part is connected (two tubes with refrigerant, electrical services and DAQ wires), RP is leak checked and pumped down, we can proceed with fast runs at H8 installation Two major valves LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

21 21 Production of the dummy loads for the PIT and their verification at Prevessin LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

22 22 Production of the dummy loads for the PIT and their verification at Prevessin 1.Pressure drop verified 2.Leak tested 3.Electrical connection tested 4.Prepared for insulation 5.Installed within the final cooling plant Verified during the refrigerant circulation in the closed loops LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

23 Commissioning in the PIT: Sensors are monitored independently by the PLC and by the ELMB based mini DAQ system Roman Pot station in the LHC tunnel with one RP and two Dummy loads Sumary of the last results from the PIT 23

24 SUMMARY Overall scope of the research activities was outlined – covering last few years Activity within the ATLAS ID cooling system development were mentioned TOTEM Roman POT cooling system was described and relevant experience from CS design, running and commissioning were presented Heat exchanger use for the efficient vapor warm up was described and experimental results were introduced General comments related to CS of the RP detector applications were introduced 24 LHC cooling forum, CERN, October 30, 2008 V. Vacek, CTU Prague

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