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Progress of room temperature magnetic refrigeration technology

Li Zhen-Xing Li Ke Shen Jun Dai Wei Gao Xin-Qiang Guo Xiao-Hui Gong Mao-Qiong

Citation:

Progress of room temperature magnetic refrigeration technology

Li Zhen-Xing, Li Ke, Shen Jun, Dai Wei, Gao Xin-Qiang, Guo Xiao-Hui, Gong Mao-Qiong
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  • refrigeration technology. It has been considered as one of promising alternatives to traditional vapor compression refrigeration technology. Magnetic refrigeration, in which solid magnetic materials instead of gaseous refrigerants are used, is based on the magnetocaloric effect. When magnetocaloric material moves in or out of magnetic field, it releases heat due to magnetization or absorbs heat due to demagnetization, respectively. In this paper, magnetocaloric effects (MCEs) and basic thermodynamic cycles are briefly described at first. Some typical magnetic refrigeration cycles are introduced from the viewpoint of thermodynamics, which include hybrid cycle, cycle based on the active magnetic regenerator and cycle based on the active magnetic regenerator coupled with gas regenerative refrigeration. Specifically, magnetic refrigeration cycle based on the active magnetic regenerator (AMR) coupled with gas regenerative refrigeration is a novel idea that combines the magnetocaloric effect with the regenerative gas expansion refrigeration. And it has been under the way to try to achieve greater refrigeration performance of the coupled refrigerator in the research institutions. Thereafter, the paper reviews the existing different numerical models of AMR refrigerator. Analyzing and optimizing an AMR magnetic refrigerator are typical complicated multi-physics problems, which include heat transfer, fluid dynamics and magnetics. The majority of models published are based on one-dimensional simplification, which requires shorter computation time and lower computation resources. Because a one-dimensional model idealizes many factors important for the system performance, two- or three- dimensional numerical models have been setup. Besides, some key items for the model are described in detail, such as magnetocaloric effect, thermal conduction, thermal losses, demagnetizing effect and magnetic hysteresis. Considering the accuracy, convergence and computation time, it is quite vital for numerical models to choose some influential factors reasonably. Then, the recent typical room magnetic refrigeration systems are listed and grouped into four types, i.e., reciprocating-magnet type, reciprocating-regenerator type, rotary-magnet type, and rotaryregenerators type. Different characteristics of these four types are compared. Reciprocating magnetic refrigerators have the advantages of simple construction and max magnetic field intensity difference. Rotary magnetic refrigerator due to compact construction, higher operational frequency and better performance is deemed as a more promising type, in the progress of magnetic refrigeration technology. Meanwhile there are still some key challenges in the practical implementation of magnetic refrigeration technology, such as the development and preparation technologies of high-performance MCE materials, powerful magnetic circuit system and flowing condition. Finally, possible applications are discussed and the tendency of future development is given.
      Corresponding author: Shen Jun, jshen@mail.ipc.ac.cn;cryodw@mail.ipc.ac.cn ; Dai Wei, jshen@mail.ipc.ac.cn;cryodw@mail.ipc.ac.cn
    • Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 51322605, 51676198).
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    Brown J S, Domanski P A 2014 Appl. Therm. Eng. 64 252

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    Sari O, Balli M 2013 Int. J. Refrig. 37 8

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    Qian S, Alabdulkarem A, Ling J, Muehlbauer J, Hwang Y, Radermacher R, Takeuchib I 2015 Int. J. Refrig. 57 62

    [4]

    Kitanovski A, Tušek J, Tomc U, Plaznik U, Ožbolt M, Poredoš A 2015 Magnetocaloric Energy Conversion (vol. preface) (Switzerland: Springer International Publishing Switzerland) pviii

    [5]

    Aprea C, Greco A, Maiorino A, Masselli C 2015 J. Phys.: Conf. Ser. 655 012026

    [6]

    Yu B, Liu M, Egolf P W, Kitanovski A 2010 Int. J. Refrig. 33 1029

    [7]

    Warburg E 1881 Ann. Phys. 13 141

    [8]

    Giauque W F 1927 J. Am. Cher. Soc. 49 1864

    [9]

    Brown G V 1976 J. Appl. Phys. 47 3673

    [10]

    Steyert W A 1978 J. Appl. Phys. 49 1216

    [11]

    Barclay J A, Steyert W A U.S. Patent 4 332 135 [1982-06-01]

    [12]

    You Y, Guo Y, Xiao S, Yu S, Ji H, Luo X 2016 J. Magn. Magn. Mater. 405 231

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    Trevizoli P V, Lozano J A, Peixer G F, Barbosa J R 2015 J. Magn. Magn. Mater. 395 109

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    Pecharsky V K, Gschneidner Jr K A 1997 Phys. Rev. Lett. 78 4494

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    Hu F X, Shen B G, Sun J R, Cheng Z H, Rao G H, Zhang X X 2001 Appl. Phys. Lett. 78 3675

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    Brck E, Tegus O, Li X W, de Boer F R, Buschow K H J 2003 Physica B 327 431

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    Lei T, Nielsen K K, Engelbrecht K, Bahl C R H, Bez H N, Veje C T 2015 J. Appl. Phys. 118 014903

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    Monfared B, Palm B 2015 Int. J. Refrig. 57 103

    [19]

    Scarpa F, Tagliafico G, Tagliafico L A 2012 Int. J. Refrig. 35 453

    [20]

    Scarpa F, Tagliafico G, Tagliafico L A 2015 Renew. Sust. Energ. Rev. 50 497

    [21]

    Bisio G, Rubatto G, Schiapparelli P 1999 Energ. Convers. Manage. 40 1267

    [22]

    Pecharsky V K, Gschneeidner Jr K A 1999 J. Magn. Magn. Mater. 200 44

    [23]

    Lin G, Tegus O, Zhang L, Brck E 2004 Physica B 344 147

    [24]

    Sasso C P, Basso V, Lobue M, Bertotti G 2006 Physica B 372 9

    [25]

    Xu Z, Guo J, Lin G, Chen J 2016 J. Magn. Magn. Mater. 409 71

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    Plaznik U, Tušek J, Kitanovski A, Poredoš A 2013 Appl. Therm. Eng. 59 52

    [27]

    Kitanovski A, Plaznik U, Tušek J, Poredoš A 2014 Int. J. Refrig. 37 28

    [28]

    Kirol L D, Dacus M W 1988 Rotary Recuperative Magnetic Heat Pump (Vol. 33) (New York: Springer US) p757

    [29]

    Kitanovski A, Egolf P W 2006 Int. J. Refrig. 29 3

    [30]

    Gómez J R, Garcia R F, Catoira A D M, Gómez M R 2013 Renew. Sust. Energ. Rev. 17 74

    [31]

    Wu J F, Shen J, Dai W, Gong M Q, Shen B G 2013 China Patent ZL 201010622884.6 [2010-12-29]

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    [33]

    He X N, Gong M Q, Zhang H, Dai W, Shen J, Wu J F 2013 Int. J. Refrig. 36 1465

    [34]

    He X N, Gong M Q, Zhang H, Dai W, Shen J, Wu J F 2013 The 5th International Conference on Cyogenics and Refrigeration Hangzhou, China, April 6-9, 2013

    [35]

    Nielsen K K, Tusek J, Engelbrecht K, Schopfer S, Kitanovski A, Bahl C R H, Smith A, Pryds N, Poredos A 2011 Int. J. Refrig. 34 603

    [36]

    Trevizoli P V, Nakashima A T, Barbosa J R 2016 Int. J. Refrig. 72 206

    [37]

    Nielsen K K, Engelbrecht K 2012 J. Phys. D: Appl. Phys. 45 145001

    [38]

    Roudaut J, Kedous-Lebouc A, Yonnet J P, Muller C 2011 Int. J. Refrig. 34 1797

    [39]

    Engelbrecht K, Tušek J, Nielsen K K, Kitanovski A, Bahl C R H, Poredoš A 2013 J. Phys. D: Appl. Phys. 46 255002

    [40]

    Vuarnoz D, Kawanmi T 2012 Fifth ⅡF-ⅡR International Conference on Magnetic Refrigeration at Room Temperature, Thermag V Grenoble, France, September 17-20, 2012 p493

    [41]

    Tagliafico G, Scarpa F, Tagliafico L A 2012 Stroj. Vestnj. Mech. E 58 9

    [42]

    Dikeos J, Rowe A 2013 Int. J. Refrig. 36 921

    [43]

    Lei T, Nielsen K K, Engelbrecht K 2014 12th Biennial Conference on Engineering Systems Design and Analysis AMES, US, June 25-27, 2014 pV003T12A007

    [44]

    Yu B F, Gao Q, Zhang B, Meng X Z, Chen Z 2003 Int. J. Refrig. 26 622

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    Gschneidner Jr K A, Pecharsky V K 2008 Int. J. Refrig. 31 945

    [46]

    Gómez J R, Garcia R F, Carril J C, Gómez M 2013 Renew. Sust. Energ. Rev. 2 1

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    Yayama H, Hatta Y, Makimoto Y, Tomokiyo A 2000 Jpn. J. Appl. Phys. 39 4220

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    Nellis G F 1997 Ph. D. Dissipation (Massachusetts: Massachusetts Institute of Technology)

    [49]

    Kim Y, Park I, Jeong S 2013 Cryogenics 57 113

    [50]

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Publishing process
  • Received Date:  20 January 2017
  • Accepted Date:  05 April 2017
  • Published Online:  05 June 2017

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