Concept of a Magnetocaloric Generator with Latent Heat Transfer for the Conversion of Heat into Electricity

Second‐order and first‐order magnetocaloric materials (MCMs) not experiencing hysteresis are characterized by a reversible temperature change when exposed to an applied magnetic field. Due to this property described by the magnetocaloric effect, MCMs are used in magnetic cooling applications. Conver...

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Veröffentlicht in:	Energy technology (Weinheim, Germany) Germany), 2022-03, Vol.10 (3), p.n/a
Hauptverfasser:	Baliozian, Puzant, Corhan, Patrick, Hess, Tobias, Bartholomé, Kilian, Wöllenstein, Jürgen
Format:	Artikel
Sprache:	eng
Schlagworte:	Cooling Curie temperature Cycles Electricity Evaporation Heat Heat transfer High vacuum Induced voltage La(Fe,Si) Latent heat latent heat transfer low-grade heat Magnetic cooling Magnetic fields Magnetic materials Magnetic permeability Magnetic properties Magnetism magnetocaloric generators magnetocaloric materials Temperature gradients thermomagnetic generators Water pollution effects
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creator	Baliozian, Puzant Corhan, Patrick Hess, Tobias Bartholomé, Kilian Wöllenstein, Jürgen
description	Second‐order and first‐order magnetocaloric materials (MCMs) not experiencing hysteresis are characterized by a reversible temperature change when exposed to an applied magnetic field. Due to this property described by the magnetocaloric effect, MCMs are used in magnetic cooling applications. Conversely, a rapid variation of the MCM's temperature around its specific Curie temperature causes a fast change in its magnetic permeability. Cycling the MCM's temperature within a magnetic field allows the possibility of inducing voltage, which would be higher for rapid cycling rates. Herein, latent heat transfer is introduced as an approach to obtain higher heating/cooling cycle frequency in a magnetocaloric generator that converts heat to electricity. In practice, rapid condensation/evaporation cycles of the water on a first‐order magnetocaloric La(Fe,Si) alloy are observed in a high vacuum system. This leads to the fast change of magnetization in an applied magnetic field from which an induced voltage is picked up. With the constructed set‐up, a peak induced voltage 2.75 mVp is obtained from low‐grade heat having reservoir temperature differences of △T = 56 °C. At higher temperature differences, a peak‐to‐peak voltage of around 3.5 mVpp at a cycle frequency of 2 Hz is achieved. The thermomagnetic generator, herein, makes use of latent heat transfer from the working fluid to heat up and cool down a magnetocaloric material (MCM) around its Curie temperature. High temperature cycling frequencies that result in the more rapid change of magnetization lead to an induced peak‐to‐peak voltage of 3.5 mVpp at a cycle frequency of 2 Hz.
doi_str_mv	10.1002/ente.202100891
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At higher temperature differences, a peak‐to‐peak voltage of around 3.5 mVpp at a cycle frequency of 2 Hz is achieved. The thermomagnetic generator, herein, makes use of latent heat transfer from the working fluid to heat up and cool down a magnetocaloric material (MCM) around its Curie temperature. 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High temperature cycling frequencies that result in the more rapid change of magnetization lead to an induced peak‐to‐peak voltage of 3.5 mVpp at a cycle frequency of 2 Hz.</description><subject>Cooling</subject><subject>Curie temperature</subject><subject>Cycles</subject><subject>Electricity</subject><subject>Evaporation</subject><subject>Heat</subject><subject>Heat transfer</subject><subject>High vacuum</subject><subject>Induced voltage</subject><subject>La(Fe,Si)</subject><subject>Latent heat</subject><subject>latent heat transfer</subject><subject>low-grade heat</subject><subject>Magnetic cooling</subject><subject>Magnetic fields</subject><subject>Magnetic materials</subject><subject>Magnetic permeability</subject><subject>Magnetic properties</subject><subject>Magnetism</subject><subject>magnetocaloric generators</subject><subject>magnetocaloric materials</subject><subject>Temperature gradients</subject><subject>thermomagnetic generators</subject><subject>Water pollution effects</subject><issn>2194-4288</issn><issn>2194-4296</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2022</creationdate><recordtype>article</recordtype><sourceid>24P</sourceid><recordid>eNqFkM1PAjEQxRujiQS5em7iebEf2-72aAiCCeoFz023TGVxbbFbJfz3FjF49DQzmfd-L3kIXVMypoSwW_AJxoywfNSKnqEBo6osSqbk-Wmv60s06vsNIYQSwQXhA_Q2Cd7CNuHgsMGP5tVDCtZ0IbYWz8BDNClEvGvTGi9MyjF4DibhZTS-dxCxy9-0Bpw5XxD7NvgD6kfT-hTwtAObMqxN-yt04UzXw-h3DtHL_XQ5mReL59nD5G5RWC4qWkihGF0pK6kjFlhVVYo2jSNcGt4AZ7KhrFJClGUpV0qQklWyFitmqFOCupIP0c2Ru43h4xP6pDfhM_ocqZnkgnOqKpFV46PKxtD3EZzexvbdxL2mRB861YdO9anTbFBHw67tYP-PWk-fltM_7zfNP3na</recordid><startdate>202203</startdate><enddate>202203</enddate><creator>Baliozian, Puzant</creator><creator>Corhan, Patrick</creator><creator>Hess, Tobias</creator><creator>Bartholomé, Kilian</creator><creator>Wöllenstein, Jürgen</creator><general>Wiley Subscription Services, Inc</general><scope>24P</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7TB</scope><scope>8FD</scope><scope>FR3</scope><scope>H8D</scope><scope>KR7</scope><scope>L7M</scope><orcidid>https://orcid.org/0000-0002-6679-1330</orcidid></search><sort><creationdate>202203</creationdate><title>Concept of a Magnetocaloric Generator with Latent Heat Transfer for the Conversion of Heat into Electricity</title><author>Baliozian, Puzant ; 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subjects	Cooling Curie temperature Cycles Electricity Evaporation Heat Heat transfer High vacuum Induced voltage La(Fe,Si) Latent heat latent heat transfer low-grade heat Magnetic cooling Magnetic fields Magnetic materials Magnetic permeability Magnetic properties Magnetism magnetocaloric generators magnetocaloric materials Temperature gradients thermomagnetic generators Water pollution effects
title	Concept of a Magnetocaloric Generator with Latent Heat Transfer for the Conversion of Heat into Electricity
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