Headquarters:
Stirling Cryogenics B.V.
Science Park Eindhoven 5003
5692 EB Son, The Netherlands
T +31 40 26 77 300
info@stirlingcryogenics.com


USA Office:New
Stirling Cryogenics Inc.
421 Fayetteville Street, Suite 1100
Raleigh NC, 27601 USA
T +1 610 714 9801
info@stirlingcryogenics.com
www.stirlingcryogenics.com

Headquarters:
Stirling Cryogenics B.V.
Science Park Eindhoven 5003
5692 EB Son, The Netherlands
T +31 40 26 77 300
info@stirlingcryogenics.com



USA Office:New
Stirling Cryogenics Inc.
421 Fayetteville Street, Suite 1100
Raleigh NC, 27601 USA
T +1 610 714 9801
info@stirlingcryogenics.com
www.stirlingcryogenics.com

 

Cryogenic pumps

Cryopump optimized impeller and volute geometry to pump a sub-cooled LN<sub>2</sub> flow in closed loop cooling systems

The Stirling Cryopump has an optimized impeller and volute geometry to pump a sub-cooled LN2 flow in closed loop cooling systems.

Similar to the Stirling CryoFan the, Stirling CryoPump is used to circulate a liquid gas in order to transport cooling power from a cold source into and through an application. Examples are superconducting cables and thermal shields in vacuum chambers or other (large) devices. The required cooling power usually comes from a cryogenic system using a cooling machine or cryogenic storage vessel . In either of these cases there is a limited budget of cooling power which makes the efficiency of the pump of the utmost importance. The efficiency of Stirling Cryogenics’ liquid gas pumps ranges from 30 to more than 50%, depending on the set-up of the closed loop system. Important factors are the required flow versus the pressure drop over the system. By balancing these at the system design phase, the total set-up can be optimized.

Design concept of the liquid gas pumps

The liquid gas pumps are based on the generic design concept of Stirling Cryogenics’ successful CryoFans. Like all centrifugal pumps, the main parts are the impeller and the volute. Their dimensional shape determines the functionality and efficiency of the pump. The impeller is driven by a high rpm air-cooled electric motor to create the flow. All of the components are integrated into a single housing with the motor installed inside the pressurized gas volume. This solution does not require a rotating seal so there is no possibility of leakage.

Cryopump optimized impeller and volute geometry to pump a sub-cooled LN<sub>2</sub> flow in closed loop cooling systemsIn order to create a thermal barrier between the motor at ambient temperature and the cold impeller, the latter is mounted on a long thin stainless steel shaft. This cantilever set-up with a high-precision balanced shaft and impeller, is used to avoid the necessity of a cold bearing. This set-up ensures a Mean Time Between Maintenance of over 20.000 hours.

 

The design concept of the Stirling Cryogenics liquid pumps is such that they can also be used as a gas circulator. When they are used as a gas circulator, the motor is set at a higher velocity to achieve sufficient gas flow. This feature is of interest during the cooling down phase of a system. Instead of pumping cold liquid into the application, causing thermal shock, cold gas is circulated to cool down the application gradually, avoiding a too fast cool down that could disrupt the application.

Once a sufficiently low temperature has been reached, the system can be switched to liquid mode and the pump will be set to run slower for use with liquid. The motor of the pump is driven using a VFD so its pumping capacity can be regulated as required.

The liquid pump concept is easy to integrate into a system cryostat. Only a central bore with a flange pattern is required. This pattern can be machined in the cryostat flange or in an ISO-K or CF blind flange. Then the pressure housing with pump volute is mounted inside the cryostat and the circuit lines are connected. The motor with shaft and impeller can now be mounted from the outside. This means that the complete impeller unit can be removed without breaking the vacuum of the application.


Product specifications

Liquid Gas Pump

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Research applications in Physics
Aerospace

 
 
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