An On-Line Acoustic Fluorocarbon Coolant Mixture Analyzer for the ATLAS Silicon Tracker

An On-Line Acoustic Fluorocarbon Coolant Mixture Analyzer for the ATLAS Silicon Tracker

The ATLAS silicon tracker community foresees an upgrade from the present octafluoropropane (C 3 F 8 ) evaporative cooling fluid to a composite fluid with a probable 10-20% admixture of hexafluoroethane (C 2 F 6 ). Such a fluid will allow a lower evaporation temperature and will afford the tracker si...

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Veröffentlicht in:IEEE transactions on nuclear science 2012-10, Vol.59 (5), p.2367-2374
Hauptverfasser: Bates, R., Battistin, M., Berry, S., Bitadze, A., Bonneau, P., Bousson, N., Boyd, G., Botelho-Direito, J., DiGirolamo, B., Doubek, M., Egorov, K., Godlewski, J., Hallewell, G., Katunin, S., Mathieu, M., McMahon, S., Nagai, K., Perez-Rodriguez, E., Rozanov, A., Vacek, V., Vitek, M.
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Sprache:eng
Schlagworte:
Acoustics
Evaporative cooling
fluorocarbons
gas composition detector
signal processing
Silicon
Software
speed of sound measurements
Temperature distribution
Temperature measurement
Temperature sensors
thermodynamics
ultrasonic transducers
Ultrasonic variables measurement
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container_end_page 2374
container_issue 5
container_start_page 2367
container_title IEEE transactions on nuclear science
container_volume 59
creator Bates, R.
Battistin, M.
Berry, S.
Bitadze, A.
Bonneau, P.
Bousson, N.
Boyd, G.
Botelho-Direito, J.
DiGirolamo, B.
Doubek, M.
Egorov, K.
Godlewski, J.
Hallewell, G.
Katunin, S.
Mathieu, M.
McMahon, S.
Nagai, K.
Perez-Rodriguez, E.
Rozanov, A.
Vacek, V.
Vitek, M.
description The ATLAS silicon tracker community foresees an upgrade from the present octafluoropropane (C 3 F 8 ) evaporative cooling fluid to a composite fluid with a probable 10-20% admixture of hexafluoroethane (C 2 F 6 ). Such a fluid will allow a lower evaporation temperature and will afford the tracker silicon substrates a better safety margin against leakage current-induced thermal runaway caused by cumulative radiation damage as the luminosity profile at the CERN Large Hadron Collider increases. Central to the use of this new fluid is a new custom-developed speed-of-sound instrument for continuous real-time measurement of the C 3 F 8 /C 2 F 6 mixture ratio and flow. An acoustic vapour mixture analyzer/flow meter with new custom electronics allowing ultrasonic frequency transmission through gas mixtures has been developed for this application. Synchronous with the emission of an ultrasound `chirp' from an acoustic transmitter, a fast readout clock (40 MHz) is started. The clock is stopped on receipt of an above threshold sound pulse at the receiver. Sound is alternately transmitted parallel and anti-parallel with the vapour flow for volume flow measurement from transducers that can serve as acoustic transmitters or receivers. In the development version, continuous real-time measurement of C 3 F 8 /C 2 F 6 flow and calculation of the mixture ratio is performed within a graphical user interface developed in PVSS-II, the Supervisory, Control and Data Acquisition standard chosen for LHC and its experiments at CERN. The described instrument has numerous potential applications - including refrigerant leak detection, the analysis of hydrocarbons, vapour mixtures for semi-conductor manufacture and anesthetic gas mixtures.
doi_str_mv 10.1109/TNS.2012.2209895
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Such a fluid will allow a lower evaporation temperature and will afford the tracker silicon substrates a better safety margin against leakage current-induced thermal runaway caused by cumulative radiation damage as the luminosity profile at the CERN Large Hadron Collider increases. Central to the use of this new fluid is a new custom-developed speed-of-sound instrument for continuous real-time measurement of the C 3 F 8 /C 2 F 6 mixture ratio and flow. An acoustic vapour mixture analyzer/flow meter with new custom electronics allowing ultrasonic frequency transmission through gas mixtures has been developed for this application. Synchronous with the emission of an ultrasound `chirp' from an acoustic transmitter, a fast readout clock (40 MHz) is started. The clock is stopped on receipt of an above threshold sound pulse at the receiver. Sound is alternately transmitted parallel and anti-parallel with the vapour flow for volume flow measurement from transducers that can serve as acoustic transmitters or receivers. In the development version, continuous real-time measurement of C 3 F 8 /C 2 F 6 flow and calculation of the mixture ratio is performed within a graphical user interface developed in PVSS-II, the Supervisory, Control and Data Acquisition standard chosen for LHC and its experiments at CERN. The described instrument has numerous potential applications - including refrigerant leak detection, the analysis of hydrocarbons, vapour mixtures for semi-conductor manufacture and anesthetic gas mixtures.</abstract><pub>IEEE</pub><doi>10.1109/TNS.2012.2209895</doi><tpages>8</tpages></addata></record>
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subjects Acoustics
Evaporative cooling
fluorocarbons
gas composition detector
signal processing
Silicon
Software
speed of sound measurements
Temperature distribution
Temperature measurement
Temperature sensors
thermodynamics
ultrasonic transducers
Ultrasonic variables measurement
title An On-Line Acoustic Fluorocarbon Coolant Mixture Analyzer for the ATLAS Silicon Tracker
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