Current research projects

Image Micro heat exchangers in refrigeration
Image Software for technical building equipment
Image Cold meter
Image Laseroptical measurement
Image Filter Tests
Image Cryogenic liquid piston pumps for cold liquefied gases like LIN, LOX, LHe, LH2, LNG, LAr
Image Optimizing HVAC operation with machine learning
Image Non- invasive flow measurements
Image Certifiable connection types in cryogenics
Image Reduction of primary noise sources of fans
Image Ionocaloric cooling
Image Development of a Cryogenic Magnetic Air Separation Unit
Image Software for test rigs
Image Air-water heat pumps
Image Ice Slurry Generation
Image Innovative Manufacturing Technologies for Cryosorption Systems

You are here:  Home /  Research and Development


Cryostats, Non-Metallic and Metallic

Industry, R&D

Gregor Trommler

+49-351-4081-5132

position indenpendent, highest endurance, tiltable for liquid helium and liquid nitrogen

Cryostats for the cooling of cryo electric components

Custom-designed cryostats made of metal and non metallic materials (e.g. glass-reinforced plastics (GRP) or carbon fiber) have been developed for cooling of sensors with liquid nitrogen or liquid helium. These cryostats have many applications and can be adapted to customer wishes. A particular achievement was the development of GRP cryostats with special properties for the cooling of iSFCLs (Inductive Shielded Superconducting Fault Current Limiter) and SQUIDs (highly sensitive magnetic field sensors). These cryostat also available as pressure vessels. Long years of experience in the designing of cryostats and the know-how necessary for their manufacture and testing are available.

product range ILK cryostats

Special features of the ILK cryostats made of GRP or metal are:

  • Working temperature 4 K and 350 K, with a very high temperature stability (e.g. 3 mK by metal cryostats for the cooling of optical sensors).
  • Design as pressure vessel possible (also in GRP)
  • Liquid charge 250 ml up to 300 liter (in custom design up to 700 liter)
  • Cooling capacity 10 to 1300 Wh (35 to 4400 BTU)
  • Automatic filling and reliquefaction with sensors for monitoring.
  • Low evaporation losses (Nitrogen evaporation rate < 6 % of the liquid volume per day)
  • Long vacuum durability
  • The leackgae rate for GRP cryostats is typical 9×10-10 mbar l / s
  • HF-noise < 1  % in the range between 10 Hz and 2 MHz
  • Magnetic noise < 4 fT / Hz 

For non-destructive material testing position-independent GRP-Cryostats with an adjustable cold-warm distance (z-axis) can be manufactured. In the case of the measurement of lowest magnetic fields (heart and brain diagnostics) a displaceable x-y-position for the sensor is feasible. GRP-Cryostats, e.g. for geological surveys, can be delivered with solid insulation as well.  For the laser based gas analysis with laser diode metal cryostats are needed which have a highly temperature stability of 3 mK at the sensor location.

Examples

  • First position independent helium cryostat (e.g. for sensor cooling) made of GRP, with exhaust gas cooled radiation shield instead of a LN2 reservoir. 0.1 W standby heat load corresponds to 3 liter helium a day.
  • First LN2 bath cryostat made of GRP for sensor cooling with a special plug instead of a neck pipe, content 35 liter – a standby vaporisation of 0.9 liter per day corrosponds to a operating time of 35 days.
  • For ring cryostates made of GRP, designed as a pressure vessel without insulation on the top, a heat load less than 6 W / m² (depending on the design) is achievable. Such cryostats are suitable for the cooling of HTS componentes.
  • The leackgae rate for GRP cryostats is typical 9×10-10 mbar l / s

Your Request

Further Projects - Research and Development

Image

Air-water heat pumps

Test according DIN EN 14511 and 14825

Image

High temperature heat pump

Using waste heat from industrial processes

Image

Micro heat exchangers in refrigeration

3D-printing of micro heat exchangers

Image

Electrochemical decontamination of electrically conducting surfaces „EDeKo II“

Improvement of sanitary prevention by electrochemical decontamination