COCO22 Cooling for High-Energy Physics Experiments Cooling for High-Energy Physics Experiments

EU-FP7 Project CRISP Cooling Method

CO2 Cooling

Prototype Systems

Dr. Johann M. Heuser**GSI Helmholtz Center for Heavy Ion Research GmbH, Darmstadt, Germany

CRISP - Cluster of Research Infrastructures for Synergies in Physics

www.crisp-fp7.eu

CRISP is a partnership that builds collaborations and creates long-term synergies between research infrastructures on the ESFRI (European Strategy Forum on Research Infrastructure) Roadmap in the field of physics, astronomy and analytical facilities to facilitate their implementation and enhance their efficiency and attractiveness.

Activities from 16 european physics research centers are covered spanning the topics “industry synergies”, “accelerators”, “detectors & data acquisition”, “instruments & experiments”, and “IT & data management”.

Objective:

An efficient and lightweight cooling system is a component of paramount importance for advanced particle detectors, notably detector systems for charged-particle track reconstruction requiring low-temperature operation.

CO2 has excellent thermo-dynamical properties and is likely to be the technological choice for most future particle tracking detectors, as well as for the refrigeration industry in general, while fluorocarbon fluids will be progressively banned by increasingly stringent environmental regulations.

CO2 two-phase cooling has been chosen as baseline for the upgrade of the silicon tracking systems of the LHC detectors at CERN where extended expertise on its application has been acquired. It is also suitable for silicon imaging and tracking detectors in experiments under design at the international accelerator facility FAIR (GSI), at EuroFEL (DESY), and at XFEL.

A spread of knowledge and the deployment of a generic prototype cooling system shall be achieved through the CRISP project.

Two-phase accumulator controlled loop

A-B-C-D – A pump transports sub-cooled CO2 to the evaporator in the detector.

E-F – On its way to the detector the CO2 is heated up to the right evaporation temperature by a thermal contact with the returning CO2 vapour.

C-D – At the detector the CO2 is distributed to the parallel evaporators by capillaries.

D-E – In the evaporators the heat is absorbed from the detector.

F-A – The returned CO2 liquid/vapour mixture is liquified and sub-cooled by a heat exchanger with a

primary cooling machine that is running at a temperature below the operating temperature of the CO2 two-phase accumulator controlled loop.

G – The “accumulator” is the key element for the control of the evaporation temperature. It is a

pressure regulated vessel filled with two-phase CO2 that is in direct contact with the inlet of the condenser. The CO2 pressure in the accumulator therefore directly determines the evaporation pressure, and hence the CO2 temperature in the detector.

https://espace.cern.ch/CO2cool4PHYS

• CO2 cooling for CMS

• CO2 cooling working space

• CORA (CO2 testing unit)

http://www.ohio.edu/mechanical/thermo/property_tables/CO2/ph_CO2.html

Operation regimes:

Participating institutes in CRISP work package 13 “CO2 cooling“: CERN (activity leader), DESY, FAIR, XFEL

Standardized compact unit MARCO for CO2 cooling from 0.1-1 kW in the temp. range -40 ÷ + 20 °C.

Prototype in the CERN Cryo Lab.

• TRACI (100 W CO2 cooling unit)

• MARCO (1 kW CO2 cooling unit)

→ objective for CRISP

Developments at CERN: