CN211233524U - Refrigerator, refrigerating system and magnetic regenerator - Google Patents

Abstract

The utility model relates to a refrigerator, refrigerating system and magnetism regenerator, magnetism regenerator include magnetocaloric element and radiating piece. The heat exchange part of the heat dissipation part is arranged on the magneto-thermal part. During refrigeration, a refrigerant is introduced into the first heat exchange channel of the magnetocaloric element, and demagnetization is performed to ensure that the magnetocaloric element absorbs heat. The refrigerant in the first heat exchange channel exchanges heat with the magnetic heat piece to realize the cooling of the refrigeration piece, and the refrigeration effect is realized through the cold end heat exchanger. Excitation makes the magnetism hot component release heat, stops letting in the refrigerant in the first heat transfer passageway. The heat of the magneto-thermal element is transferred to the heat exchanging part, and the heat transferred to the heat exchanging part is further transferred to the heat radiating part connected with the heat exchanging part. Because the heat dissipation part is located one side that the magnetism heating element was kept away from to heat transfer portion, the heat of avoiding the heat dissipation part further transmits the magnetism heating element, makes things convenient for scattering and disappearing of the heat on the heat dissipation part, avoids influencing the refrigeration effect of demagnetization process magnetism heating element, and then guarantees refrigerating system's refrigeration efficiency, guarantees the cold-stored effect of refrigerator.

Description

Refrigerator, refrigerating system and magnetic regenerator

Technical Field

The utility model relates to a refrigeration structure technical field especially relates to a refrigerator, refrigerating system and magnetism regenerator.

Background

The magnetic refrigeration device utilizes the magnetocaloric effect of the magnetic material to realize the refrigeration process, and the magnetic material generates heat when magnetized and refrigerates when demagnetized. In a conventional magnetic refrigeration device, a magnetic material is demagnetized, and refrigeration of a refrigerant is realized by heat exchange with the refrigerant. When the magnetic material is magnetized, the circulation of the refrigerant is stopped, and the refrigeration effect is further ensured. But the heat dissipation efficiency of the magnetic material is low, and the refrigeration efficiency of the magnetic material in the next demagnetization process is influenced.

SUMMERY OF THE UTILITY MODEL

In view of the above, it is necessary to provide a refrigerator, a refrigeration system and a magnetic regenerator capable of effectively ensuring heat dissipation and refrigeration efficiency of a magnetic material.

A magnetic regenerator comprising:

the magneto-thermal piece is provided with a first heat exchange channel; and

the heat dissipation part comprises a heat dissipation part and a heat exchange part, the heat exchange part is arranged on the magnetocaloric component, and the heat dissipation part is connected to the heat exchange part and is positioned on one side, far away from the magnetocaloric component, of the heat exchange part.

When the magnetic regenerator is used, the heat exchange part of the heat dissipation part is arranged on the magnetocaloric element. When refrigeration is needed, a refrigerant is introduced into the first heat exchange channel of the magnetocaloric piece to demagnetize the magnetocaloric piece, so that the magnetic moment in the magnetocaloric piece is disordered along the magnetic field direction, and the magnetocaloric piece absorbs heat at the moment. The refrigerant in the first heat exchange channel can exchange heat with the magnetic heat piece, so that the cooling of the refrigeration piece is realized, and the refrigeration effect is further realized. In the process of exciting the magnetic heat piece, the magnetic moments of the magnetic heat piece are orderly from disorder to order along the direction of a magnetic field, at the moment, the magnetic heat piece releases heat outwards, and the refrigerant is stopped to be introduced into the first heat exchange channel. The heat of the magnetic heating part can be effectively transmitted to the heat exchanging part, and the heat transmitted to the heat exchanging part can be further transmitted to the heat radiating part connected with the heat exchanging part. Because the heat dissipation part is located the heat transfer portion and keeps away from the one side of magnetism heat piece, the heat of having avoided the heat dissipation part further transmits the magnetism heat piece, makes things convenient for scattering and disappearing of the heat on the heat dissipation part, avoids influencing the refrigeration effect of demagnetization process.

The technical solution is further explained below:

in one embodiment, a plurality of heat dissipation fins are arranged on the outer wall of the heat dissipation part at intervals.

In one embodiment, a second heat exchange channel is formed in the heat exchanging part, a heat exchange medium is filled in the second heat exchange channel, and a heat dissipation channel is formed in the heat dissipation part and is communicated with the second heat exchange channel, so that the heat exchange medium can flow into the heat dissipation channel from the second heat exchange channel.

In one embodiment, the height of the heat exchange medium in the second heat exchange channel is greater than or equal to the height of the magnetocaloric component.

In one embodiment, the heat dissipation part is arranged at a higher height than the heat exchange part, and the heat exchange medium is a heated volatile medium.

In one embodiment, the heat dissipation part is a tubular structure, and the heat dissipation part is folded away from the part of the magnetocaloric element.

In one embodiment, the heat dissipation member further includes a backflow portion, the backflow portion is disposed between the heat dissipation portion and the heat exchanging portion, a backflow channel is formed in the backflow portion, one end of the backflow channel is communicated with the heat dissipation channel, the other end of the backflow channel is communicated with the second heat exchanging channel, and the backflow channel, the heat dissipation channel and the second heat exchanging channel are communicated to form a heat dissipation circulation loop.

In one embodiment, the size of the cross section of the return channel tends to decrease toward the heat exchanging part.

In one embodiment, the heat dissipation element further includes an installation portion, the installation portion is disposed on the heat exchanging portion, a mounting hole is formed in the installation portion, and the magnetic thermal element is disposed in the mounting hole in a penetrating manner.

In one embodiment, the number of the heat dissipation members is at least two, at least two heat dissipation members are arranged around the periphery of the magnetocaloric element at intervals, and the heat exchanging part of each heat dissipation member is arranged on the magnetocaloric element.

In one embodiment, the magnetic regenerator further comprises a heat exchange tube, the heat exchange tube being in communication with the first heat exchange channel.

In one embodiment, the magnetocaloric element is disposed inside the heat exchange tube, and the heat exchange portion is disposed on the heat exchange tube.

A refrigeration system comprising:

the magnetic regenerator as described above; and

and the cold end heat exchanger is communicated with the first heat exchange channel of the magnetocaloric element.

A refrigerator comprising a refrigeration system as described above.

When the refrigerator is used, the heat exchange part of the heat dissipation part is arranged on the magneto-thermal part. When refrigeration is needed, a refrigerant is introduced into the first heat exchange channel of the magnetocaloric piece to demagnetize the magnetocaloric piece, so that the magnetic moment in the magnetocaloric piece is disordered along the magnetic field direction, and the magnetocaloric piece absorbs heat at the moment. The refrigerant in the first heat exchange channel can exchange heat with the magnetic heat piece to realize the cooling of the refrigeration piece, and the refrigerant enters the cold end heat exchanger to realize the refrigeration effect through the cold end heat exchanger. In the process of exciting the magnetic heat piece, the magnetic moments of the magnetic heat piece are orderly from disorder to order along the direction of a magnetic field, at the moment, the magnetic heat piece releases heat outwards, and the refrigerant is stopped to be introduced into the first heat exchange channel. The heat of the magnetic heating part can be effectively transmitted to the heat exchanging part, and the heat transmitted to the heat exchanging part can be further transmitted to the heat radiating part connected with the heat exchanging part. Because the heat dissipation part is located the heat transfer portion and keeps away from the one side of magnetism heat piece, the heat of having avoided the heat dissipation part further transmits the magnetism heat piece, makes things convenient for scattering and disappearing of the heat on the heat dissipation part, avoids influencing the refrigeration effect of demagnetization process. The magnetic regenerator can effectively ensure the refrigeration effect on the refrigerant in the demagnetization process, further ensure the refrigeration efficiency of a refrigeration system and ensure the refrigeration effect of a refrigerator.

In one embodiment, the refrigerator is an in-vehicle refrigerator.

Drawings

Fig. 1 is a schematic structural view of a magnetic regenerator in an embodiment;

fig. 2 is a cross-sectional view taken along line a-a of fig. 1.

Description of reference numerals:

10. the magnetic regenerator comprises a magnetic regenerator 100, magnetic heat elements 110, a first heat exchange channel 200, a heat dissipation element 210, a heat dissipation part 212, a heat dissipation channel 214, a heat dissipation fin 220, a heat exchange part 222, a second heat exchange channel 230, a heat exchange medium 240, a backflow part 242, a backflow channel 250, a mounting part 252, a mounting hole 300 and a heat exchange tube.

Detailed Description

In order to make the above objects, features and advantages of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The present invention can be embodied in many different forms other than those specifically described herein, and it will be apparent to those skilled in the art that similar modifications can be made without departing from the spirit and scope of the invention, and it is therefore not to be limited to the specific embodiments disclosed below.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

Referring to fig. 1 and 2, in an embodiment, a refrigeration system includes a magnetic regenerator 10 and a cold-end heat exchanger, and refrigeration is performed by the magnetic regenerator 10 and heat exchange is performed by the cold-end heat exchanger.

Specifically, the magnetic regenerator 10 includes a magnetocaloric element 100 and a heat sink 200, and a first heat exchange channel 110 is formed in the magnetocaloric element 100. Wherein the cold side heat exchanger is in communication with the first heat exchange channel 110 of the magnetocaloric element 100. The heat sink 200 includes a heat sink portion 210 and a heat exchanging portion 220, the heat exchanging portion 220 is disposed on the magnetocaloric component 100, the heat sink portion 210 is connected to the heat exchanging portion 220, and is located on a side of the heat exchanging portion 220 away from the magnetocaloric component 100.

When the refrigeration system is used, the heat exchanging portion 220 of the heat sink 200 is disposed on the magnetocaloric device 100. When refrigeration is needed, a refrigerant is introduced into the first heat exchange channel 110 of the magnetocaloric element 100, and in the process of demagnetizing the magnetocaloric element 100, the magnetic moments in the magnetocaloric element 100 change from ordered to disordered along the magnetic field direction, and at this time, the magnetocaloric element 100 absorbs heat. The refrigerant in the first heat exchange channel 110 can exchange heat with the magnetocaloric element 100, so as to cool the refrigeration element. The refrigerant enters the cold end heat exchanger, and the refrigeration effect is realized through the cold end heat exchanger. In the process of exciting the magnetocaloric element 100, the magnetic moments of the magnetocaloric element 100 change from disorder to order along the magnetic field direction, at this time, the magnetocaloric element 100 releases heat outwards, and the refrigerant stops flowing into the first heat exchange channel 110. The heat of the magnetocaloric component 100 can be effectively transferred to the heat exchanging portion 220, and the heat transferred to the heat exchanging portion 220 can be further transferred to the heat radiating portion 210 connected to the heat exchanging portion 220. Because the heat dissipation part 210 is located at one side of the heat exchanging part 220 away from the magnetocaloric component 100, the heat of the heat dissipation part 210 is prevented from being further transferred to the magnetocaloric component 100, so that the dissipation of the heat on the heat dissipation part 210 is facilitated, and the refrigeration effect in the demagnetization process is prevented from being influenced. The magnetic regenerator 10 can effectively ensure the refrigeration effect on the refrigerant in the demagnetization process, thereby ensuring the refrigeration efficiency of the refrigeration system.

In order to dissipate heat of the magnetocaloric component 100, a conventional scheme is to provide a heat dissipation flow path, and during cooling, the first heat exchange channel 110 of the magnetocaloric component 100 is communicated with the cold-end heat exchanger. When heating, the heat dissipation flow path is communicated with the first heat exchange path 110 by using the reversing valve. Therefore, the first heat exchange path 110 of the magnetocaloric unit 100 is a common path for cooling and heating processes. Thereby causing a portion of refrigerant to remain in the first heat exchange path 110 when switched by the reversing valve. When the magnetocaloric component 100 is switched from the heating state to the cooling state, the refrigerant in the heat dissipation flow path may remain in the first heat exchange channel 110, and then the magnetocaloric component 100 needs to cool the remaining refrigerant first, thereby affecting the cooling effect on the refrigerant in the cold-end heat exchanger.

In one embodiment, a second heat exchanging channel 222 is formed in the heat exchanging portion 220, a heat exchanging medium 230 is filled in the second heat exchanging channel 222, a heat dissipating channel 212 is formed in the heat dissipating portion 210, and the heat dissipating channel 212 is communicated with the second heat exchanging channel 222, so that the heat exchanging medium 230 can flow into the heat dissipating channel 212 through the second heat exchanging channel 222. Through forming second heat exchange passageway 222 and heat dissipation channel 212, make things convenient for the circulation of heat transfer medium 230, utilize the flow of heat transfer medium 230 in second heat exchange passageway 222 and heat dissipation channel 212, and then can effectively take away the heat that magnetocaloric piece 100 produced, and then improve magnetocaloric efficiency of magnetocaloric piece 100.

Specifically, the height of the heat exchange medium 230 in the second heat exchange channel 222 is greater than or equal to the height of the magnetocaloric component 100. Since the heat exchanging portion 220 is disposed on the magnetocaloric component 100, the height of the heat exchanging medium 230 in the second heat exchanging channel 222 is greater than or equal to the height of the magnetocaloric component 100, so that the heat generated by the magnetocaloric component 100 can be fully exchanged with the heat exchanging medium 230, and the heat dissipation efficiency of the magnetocaloric component 100 is effectively improved.

In the present embodiment, the heat dissipating part 210 is disposed at a height higher than the heat exchanging part 220. Wherein, the heat exchange medium 230 is a heat-receiving volatile medium. Since the heat exchange medium 230 is a volatile medium that is heated, the heat exchange medium 230 is volatilized from a liquid state to a gaseous state when exchanging heat with the magnetocaloric element 100. The heat dissipation part 210 is higher than the heat exchange part 220, so that the gaseous heat exchange medium 230 can enter the heat dissipation channel 212 of the heat dissipation part 210, and flows back to the second heat exchange channel 222 after being cooled to be liquid in the heat dissipation channel 212, thereby realizing the circulating heat dissipation of the heat exchange medium 230.

In one embodiment, the heat exchange medium 230 may be Freon, ethylene, or the like.

In one embodiment, the heat dissipation part 210 is a tubular structure, and the heat dissipation part 210 is folded away from the magnetocaloric element 100. Through folding the heat dissipation part 210, the length of the heat dissipation channel 212 can be effectively prolonged in a certain space, so that the time of the heat exchange medium 230 flowing in the heat dissipation channel 212 is prolonged, the heat dissipation time is prolonged, and the heat dissipation efficiency is improved. In other embodiments, the heat dissipation portion 210 may not be folded.

In one embodiment, the heat dissipating portion 210 has a plurality of heat dissipating fins 214 disposed on an outer wall thereof. The heat dissipation efficiency of the heat dissipation portion 210 can be further improved by providing the heat dissipation fins 214, and the heat dissipation efficiency of the magnetocaloric device 100 can be further improved.

In one embodiment, the heat dissipating member 200 further includes a backflow portion 240, the backflow portion 240 is disposed between the heat dissipating portion 210 and the heat exchanging portion 220, a backflow channel 242 is formed in the backflow portion 240, one end of the backflow channel 242 is communicated with the heat dissipating channel 212, the other end of the backflow channel 242 is communicated with the second heat exchanging channel 222, and the backflow channel 242, the heat dissipating channel 212 and the second heat exchanging channel 222 are communicated to form a heat dissipating circulation loop. The return channel 242 is formed by providing the return portion 240 so that the heat exchange medium 230, which is changed from the gaseous state to the liquid state by the cooling of the heat dissipation channel 212, can flow back into the second heat exchange channel 222 from the return channel 242. The second heat exchange channel 222, the heat dissipation channel 212 and the return channel 242 are communicated with each other to form a heat dissipation circulation return flow, so that a flowing circulation loop of the heat exchange medium 230 is formed, the heat exchange medium 230 is heated and gasified in the second heat exchange channel 222, enters the heat dissipation channel 212, is cooled and liquefied in the heat dissipation channel 212, and then flows back to the second heat exchange channel 222 through the return channel 242, and the heat exchange efficiency is effectively improved.

Specifically, the size of the cross section of the return channel 242 tends to decrease toward the heat exchanging part 220. Since the other end of the backflow channel 242 is communicated with the heat exchanging portion 220, one end of the backflow portion 240 tends to approach the heat exchanging portion 220 toward the other end, so that the heat exchanging medium 230 in the backflow portion 240 close to the heat exchanging portion 220 can absorb part of the heat emitted from the heat exchanging portion 220 and the magnetocaloric component 100. By reducing the size of the return channel 242 close to the heat exchanging portion 220, the heat absorption of the heat exchanging medium 230 in the return channel 242 can be reduced, so that the vaporization amount of the heat exchanging medium 230 in the return channel 242 is reduced, and the heat exchanging efficiency of the heat exchanging medium 230 in the second heat exchanging channel 222 is improved.

In the present embodiment, the size of the cross-section of the return channel 242 is gradually reduced toward the heat exchanging part 220. Of course, in another embodiment, the return channel 242 has a larger cross-sectional dimension at one end of the return channel 242 and a smaller cross-sectional dimension at the other end of the return channel 242.

In other embodiments, the size of the cross-section of the return channel 242 may also be smaller than the size of the cross-section of the second heat exchange channel 222. The size of the cross-section of the return channel 242 may also be smaller than the size of the cross-section of the heat dissipation channel 212.

In the present embodiment, the reflow portion 240 gradually approaches the heat exchanging portion 220 from one end to the other end. In another embodiment, when the reflow part 240 is provided, a portion of the reflow part 240 near the heat exchanging part 220 may be provided to a position far from the heat exchanging part 220. For example, the return portion 240 may be provided in an "L" shape, or a configuration that approximates an "L" shape.

In this embodiment, the backflow portion 240, the heat dissipation portion 210 and the heat exchange portion 220 are integrally formed, and the backflow channel 242, the heat dissipation channel 212 and the second heat exchange channel 222 are closed circulation channels, so that leakage of the heat exchange medium 230 is effectively avoided, and the heat exchange efficiency is improved.

In an embodiment, the heat dissipating element 200 further includes a mounting portion 250, the mounting portion 250 is disposed on the heat exchanging portion 220, a mounting hole 252 is formed on the mounting portion 250, and the magnetic heat element 100 is disposed in the mounting hole 252 in a penetrating manner. The heat exchanging portion 220 can be conveniently disposed on the magnetocaloric element 100 by providing the mounting portion 250, and thus the heat exchanging portion 220 and the magnetocaloric element 100 can exchange heat.

In this embodiment, the mounting portion 250 is integrally formed on the heat exchanging portion 220, so that the stability of the mounting portion 250 on the heat exchanging portion 220 can be improved.

In this embodiment, the heat dissipation member 200 is made of a material with good heat dissipation performance, so that heat generated by the magnetocaloric element 100 can be conveniently transferred to the heat exchange portion 220, and heat of the heat dissipation portion 210 can be conveniently dissipated. For example, the heat sink 200 is made of copper, or may be made of other materials with better heat dissipation performance.

In one embodiment, the number of the heat dissipation members 200 is at least two, at least two heat dissipation members 200 are spaced around the outer periphery of the magnetocaloric element 100, and the heat exchanging portion 220 of each heat dissipation member 200 is disposed on the magnetocaloric element 100. The heat dissipation efficiency of the magnetocaloric component 100 can be effectively improved by providing at least two heat dissipation members 200.

In the present embodiment, different heat dissipation members 200 share one mounting part 250, and the heat exchange parts 220 of different heat dissipation members 200 are disposed on one mounting part 250. Different heat dissipation members 200 are effectively connected by a mounting portion 250, which facilitates installation and mounting of different heat dissipation members 200 on the magnetocaloric unit 100.

In an embodiment, the different heat dissipation members 200 are uniformly disposed around the magnetocaloric element 100, so as to improve the heat dissipation uniformity of the different heat dissipation members 200, thereby improving the heat dissipation efficiency. In the present embodiment, the heat dissipation members 200 are two, and the two heat dissipation members 200 are symmetrically disposed with respect to the magnetocaloric element 100. In another embodiment, the number of heat dissipation elements 200 may be one, three, or other number.

In other embodiments, the different heat dissipation members 200 may be arranged in an asymmetric structure, for example, according to the actual installation space.

In this embodiment, the magnetic regenerator 10 further comprises a heat exchange tube 300, and the heat exchange tube 300 is communicated with the first heat exchange channel 110. The flow of the refrigerant in the first heat exchange channel 110 is facilitated by the heat exchange tube 300. Specifically, the cold side heat exchanger is in communication with the first heat exchange channel 110 through a heat exchange tube 300. And then make things convenient for the refrigerant to flow to the cold junction heat exchanger through heat exchange tube 300, realize the refrigeration effect through the cold junction heat exchanger.

In the present embodiment, the magnetocaloric unit 100 is disposed in the heat exchange tube 300, and the heat exchange portion 220 is disposed on the heat exchange tube 300. By disposing the magnetic heat element 100 in the heat exchange tube 300, the refrigerant in the heat exchange tube 300 can be more sufficiently contacted with the magnetic heat element 100, thereby effectively improving the refrigeration efficiency. Specifically, the heat exchange pipe 300 is inserted into the installation hole 252.

In other embodiments, the heat exchange tube 300 can also be inserted into the first heat exchange channel 110 of the magnetocaloric element 100, as long as the heat exchange between the magnetocaloric element 100 and the refrigerant inside the heat exchange tube 300 is conveniently achieved.

The refrigerator in one embodiment comprises the refrigeration system in any one of the above embodiments, and the refrigeration effect is realized by using the principle that the demagnetization process of the magnetocaloric element 100 absorbs heat. Meanwhile, the heat dissipation of the magnetocaloric component 100 in the heating process is effectively realized by using the heat dissipation member 200, so that the refrigeration efficiency of the magnetocaloric component 100 in the refrigeration process is ensured.

In the present embodiment, the refrigerator is an in-vehicle refrigerator. Of course, in other embodiments, the refrigerator may be a home refrigerator. Alternatively, the refrigeration system can be used in other occasions requiring refrigeration.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (15)

1. A magnetic regenerator, comprising:

the magneto-thermal piece is provided with a first heat exchange channel; and

the heat dissipation part comprises a heat dissipation part and a heat exchange part, the heat exchange part is arranged on the magnetocaloric component, and the heat dissipation part is connected to the heat exchange part and is positioned on one side, far away from the magnetocaloric component, of the heat exchange part.

2. A magnetic regenerator according to claim 1, wherein the outer wall of the heat radiating portion is provided with a plurality of heat radiating fins arranged at intervals.

3. A magnetic regenerator according to claim 1, wherein a second heat exchange channel is formed in the heat exchanging portion, a heat exchange medium is filled in the second heat exchange channel, and a heat dissipation channel is formed in the heat dissipation portion, the heat dissipation channel being communicated with the second heat exchange channel so that the heat exchange medium can flow from the second heat exchange channel into the heat dissipation channel.

4. A magnetic regenerator according to claim 3 wherein the height of the heat exchange medium in the second heat exchange channel is greater than or equal to the height of the magnetocaloric elements.

5. A magnetic regenerator according to claim 3, wherein the heat radiating part is arranged at a height higher than that of the heat exchanging part, and the heat exchanging medium is a heated volatile medium.

6. A magnetic regenerator according to claim 5 wherein the heat sink is of tubular construction, the heat sink being folded away from the magnetocaloric element.

7. A magnetic regenerator according to claim 3, wherein the heat sink further comprises a return portion disposed between the heat sink portion and the heat exchanging portion, a return channel is formed in the return portion, one end of the return channel is communicated with the heat sink channel, the other end of the return channel is communicated with the second heat exchanging channel, and the return channel, the heat sink channel and the second heat exchanging channel are communicated to form a heat sink circulation loop.

8. A magnetic regenerator according to claim 7 wherein the size of the return channel cross-section tends to decrease towards the heat exchanging portion.

9. A magnetic regenerator according to any of claims 1-8, wherein the heat sink further comprises a mounting portion, the mounting portion is disposed on the heat exchanging portion, a mounting hole is opened on the mounting portion, and the magnetic thermal element is inserted into the mounting hole.

10. A magnetic regenerator according to any of claims 1-8, wherein the number of the heat dissipating members is at least two, at least two of the heat dissipating members are spaced around the periphery of the magnetocaloric element, and the heat exchanging portion of each of the heat dissipating members is disposed on the magnetocaloric element.

11. A magnetic regenerator according to any of claims 1 to 8 further comprising a heat exchange tube in communication with the first heat exchange channel.

12. A magnetic regenerator according to claim 11 wherein the magnetocaloric elements are disposed within the heat exchange tubes and the heat exchange sections are disposed on the heat exchange tubes.

13. A refrigeration system, comprising:

a magnetic regenerator as claimed in any of claims 1 to 12; and

and the cold end heat exchanger is communicated with the first heat exchange channel of the magnetocaloric element.

14. A refrigerator comprising a refrigeration system as claimed in claim 13.

15. The refrigerator of claim 14, wherein the refrigerator is an in-vehicle refrigerator.

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