Current research projects

Image Intelligent innovative power supply for superconducting coils
Image Development of test methods and test rigs for stationary integrated refrigeration units
Image Optimizing HVAC operation with machine learning
Image Modular storage system for solar cooling
Image Computational fluid dynamics CFD
Image Certification of efficient air conditioning and ventilation systems through the new "indoor air quality seal" for non-residential buildings
Image Calibration of Low Temperature Sensors
Image Investigation according to DIN EN ISO 14903
Image Low Temperature Measuring Service
Image In-situ investigation concerning the swelling behaviour of polymer materials under elevated pressures and temperatures
Image Preformance measurements of heat exchangers
Image Innovative Manufacturing Technologies for Cryosorption Systems
Image Pulse-Tube-Refrigerator with sealed compressor
Image Behavior of multiphase cryogenic fluids
Image In-Situ-Swelling Behaviour of Polymer Materials in Flammable Fluids
Image Micro heat exchangers in refrigeration

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Innovative Parahydrogen Generator Based on Magnets

Euronorm GmbH

Erik Neuber

+49-351-4081-5122

Magnetic Gas Separation of the Hydrogen Isomers

Molecular hydrogen occurs in two isomeric forms which differ in their configuration of the nuclear spin: orthohydrogen and parahydrogen, whereas the latter accounts for only 25% of the whole gas at room temperature. Contrary to this, parahydrogen in its concentrated form is utilised especially for hyperpolarisation (so-called PHIP – Parahydrogen Induced Polarisation), which is a widespread method in the fields of medicine and chemistry to enhance the contrast of MRI and NMR apparatus.
However, all procedures for the production of this spin isomer are based upon cryogenic methods, which have comparatively high expenses for energy and maintenance. Because of this, there exists the demand for a cheap and efficient method to enrich parahydrogen for direct use in successive applications.

Project Goals

  • Development of an innovative ortho–para converter, which works at room temperature by using the principle of magnetic gas separation;
  • Measurement of the separation ability of the chosen principle at room temperature and optimisation of the resulting effect and
  • Enrichment up to 99% of parahydrogen at a variable volume flow (pursued are at least 4 standard litres per minute).

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Further Projects - Research and Development

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Characterisation of Superconductors in Hydrogen Atmosphere

Are superconductors really compatible with hydrogen?

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Corrosion inhibitor for ammonia absorption systems

An alternative to chromium(VI) compounds

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Development of a Cryogenic Magnetic Air Separation Unit

Oxygen Enrichment by Applied Cryogenic Magnetohydrodynamics

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Brine (water)-water heat pump

Test according DIN EN 14511 and 14825