TY - GEN
T1 - The operating principle of a fully solid state active magnetic regenerator
AU - Zhang, Mingkan
AU - Momen, Ayyoub Mehdizadeh
AU - Abdelaziz, Omar
N1 - Publisher Copyright:
© 2016, International Institute of Refrigeration. All rights reserved.
PY - 2016
Y1 - 2016
N2 - As an alternative refrigeration technology, magnetocaloric refrigeration has the potential to be safer, quieter, more efficient, and more environmentally friendly than the conventional vapor compression refrigeration technology. Most of the reported active magnetic regenerator (AMR) systems that operate based on the magnetocaloric effect use heat transfer fluid to exchange heat, which results in complicated mechanical subsystems and components such as rotating valves and hydraulic pumps. This paper presents an operating principle of a fully solid state AMR, in which an alternative mechanism for heat transfer between the AMR and the heat source/sink is proposed. The operating principle of the fully solid state AMR is based on moving rods/sheets (e.g. copper, brass, iron or aluminum), which are employed to replace the heat transfer fluid. Such fully solid state AMR would provide a significantly higher heat transfer rate than a conventional AMR because the conductivity of moving solid rods/plates is high and it enables the increase in the machine operating frequency hence the cooling capacity. The details of operating principle are presented and discussed here. One of the key enabling features for this technology is the contact between the moving rods/sheets and magnetocaloric material, and heat exchange mechanism at the heat source/sink. This paper provides an overview of the design for a fully solid state magnetocaloric refrigeration system along with guidelines for their optimal design.
AB - As an alternative refrigeration technology, magnetocaloric refrigeration has the potential to be safer, quieter, more efficient, and more environmentally friendly than the conventional vapor compression refrigeration technology. Most of the reported active magnetic regenerator (AMR) systems that operate based on the magnetocaloric effect use heat transfer fluid to exchange heat, which results in complicated mechanical subsystems and components such as rotating valves and hydraulic pumps. This paper presents an operating principle of a fully solid state AMR, in which an alternative mechanism for heat transfer between the AMR and the heat source/sink is proposed. The operating principle of the fully solid state AMR is based on moving rods/sheets (e.g. copper, brass, iron or aluminum), which are employed to replace the heat transfer fluid. Such fully solid state AMR would provide a significantly higher heat transfer rate than a conventional AMR because the conductivity of moving solid rods/plates is high and it enables the increase in the machine operating frequency hence the cooling capacity. The details of operating principle are presented and discussed here. One of the key enabling features for this technology is the contact between the moving rods/sheets and magnetocaloric material, and heat exchange mechanism at the heat source/sink. This paper provides an overview of the design for a fully solid state magnetocaloric refrigeration system along with guidelines for their optimal design.
KW - Active Magnetic Regenerator
KW - Operating Principle
KW - Solid State
UR - https://www.scopus.com/pages/publications/85017627143
U2 - 10.18462/iir.thermag.2016.0088
DO - 10.18462/iir.thermag.2016.0088
M3 - Conference contribution
AN - SCOPUS:85017627143
T3 - Refrigeration Science and Technology
SP - 59
EP - 62
BT - 7th International Conference on Magnetic Refrigeration at Room Temperature, THERMAG 2016
A2 - Barbosa, Jader
A2 - Bruck, Ekkes
A2 - LoBue, Martino
A2 - Kedous-Lebouc, Afef
A2 - Rowe, Andrew
A2 - Sandeman, Karl
PB - International Institute of Refrigeration
T2 - 7th International Conference on Magnetic Refrigeration at Room Temperature, THERMAG 2016
Y2 - 11 September 2016 through 14 September 2016
ER -