Abstract
Today almost all refrigeration systems are based on compressors, which often require harmful refrigerants and typically reach 50% of the Carnot efficiency. Caloric cooling systems do not need any detrimental fluids and are expected to reach 60–70% of the Carnot limit. Current caloric systems utilise the active magnetocaloric regeneration principle and are quite cost-intensive, as it is challenging to achieve large cycle frequencies and thus high specific cooling powers with this principle. In this work, we present an alternative solution where the heat transfer from the heat exchangers to the caloric material is predicated on condensation and evaporation of a heat transfer fluid. Using thermal diodes, a directed heat flow is generated. Thereby we were able to build a cooling unit achieving a specific cooling power of 12.5 W g−1 at a cycle frequency of 20 Hz, which is one order of magnitude larger than the state-of-the-art.
Highlights
Today almost all refrigeration systems are based on compressors, which often require harmful refrigerants and typically reach 50% of the Carnot efficiency
A magnetocaloric cooling system utilises cyclical magnetisation and demagnetisation of the magnetocaloric materials (MCMs): while the MCM is exposed to a magnetic field, thermal energy of the MCM is transferred to a heat sink
This results in the major advantage of AMR systems: temperature spans between the heat exchangers can be achieved that are significantly higher than the adiabatic temperature change of the MCM
Summary
Today almost all refrigeration systems are based on compressors, which often require harmful refrigerants and typically reach 50% of the Carnot efficiency. Thereby, the cooling power of magnetocaloric cooling systems is proportional to the amount of MCM and to the cycle frequency.
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