Current research projects

Image Low temperature – test facilities
Image Thermostatic Expansion Valves
Image Behavior of multiphase cryogenic fluids
Image Cryostats, Non-Metallic and Metallic
Image Micro heat exchangers in refrigeration
Image Modular storage system for solar cooling
Image Overall System Optimization of Refrigeration Plant Systems for Energy Transition and Climate Protection
Image Cryogenic liquid piston pumps for cold liquefied gases like LIN, LOX, LHe, LH2, LNG, LAr
Image Electrical components in refrigeration circuits
Image Optimizing HVAC operation with machine learning
Image Measurement of insulated packaging
Image Combined building and system simulation
Image Brine (water)-water heat pump
Image Performance tests of refrigerant compressors
Image Verification of storage suitability of cryo tubes
Image Development of a Cryogenic Magnetic Air Separation Unit

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Innovative Manufacturing Technologies for Cryosorption Systems

Euronorm, R&D

Sandra Tippmann

+49-351-4081-5131

Vacuum Pumps for UHV and XHV

A cryosorption system is defined as a vacuum pump that captures gas on cryogenic surfaces (gas-binding vacuum pump). Thus pressures lower than 5-12 mbar are obtainable (realisation of UHV - ultrahigh vacuum and XHV - extremely high vacuum). Cryosorption systems rely on very good heat transfer performance. This is currently being achieved with a complex, cost-intensive and risky manufacturing process. Therefore the aim of this project is to develop a new manufacturing technology that does not have this disadvantage.

 

For this purpose, thermodynamically important variables, such as sorption heat and heat transfer resistance were determined mathematically. A test sample was developed and constructed based on these results.

After completion of the design the test sample will be produced.

In the further course of the R&D project a test stand will be set up on which the test sample can be measured. These measurements will be checked and validated in a CFD simulation. With the help of the CFD model, various simulations for future cryosorption systems can be carried out. For example cooling times for different activated carbon masses or the thermal performance under different conditions for the cooling medium can be determined using this method.

Finally the sample production (functional sample) of a cryosorption system made of stainless steel with a precisely defined heat transfer behaviour takes place. The functional model is measured in relation to the cooling performance and pressure loss of the cooling medium and the results obtained will be included into the creation of a process instruction for manufacturing future cryosorption systems.


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