TWI243884B - Reciprocating and rotary magnetic refrigeration apparatus - Google Patents

Abstract

The present invention relates to a reciprocating and rotating magnetic refrigeration apparatus which adopts a rotating dynamo concept and the design of magnetic supply path and heat transfer unit to alternately magnetize and demagnetize a magnetocaloric material to generate thermo-magnetic effect for cooling. The apparatus includes magnetocaloric material located on the head of stator nose poles, magnetic supply coils surrounding the magnetocaloric material, permanent magnets located on a rotating stator, and a heat transfer unit in contact with the magnetocaloric material. Two adjacent magnetocaloric materials magnetize and demagnetize alternately to alter the temperature and entropy of the magnetocaloric material, and through the heat transfer unit, heat exchange occurs between the magnetocaloric materials and the atmosphere to achieve the cooling effect.

Description

1243884 发明 Description of the invention: [Technical field to which the invention belongs] The present invention relates to a magnetic refrigeration device, in particular, a re-spinning R, a father-in-place by reconfiguring magnetocaloric materials and magnetizing / demagnetizing mechanisms. The operation of magnetizing and demagnetizing magnetic thermal materials is supplemented by the design of the magnetic circuit and the heat transfer unit, so as to exert the magnetic thermal effect of the repetitive rotary cooling device. [Previous Technology] Warburg discovered the magnetocaloric effect, that is, certain materials will produce a phenomenal temperature rise when entering a magnetic field, and the temperature will also decrease when leaving a magnetic field. A combination of application and thinking is generated between the electromagnetic and thermal reaction actions; however, the magneto-caloric effect is manifested in the way of magnetic field generation and the design of the selection mechanism of magneto-caloric materials, which have great differences in the target of application. Leng; Dong applied the most known related technologies and their research include: US Patent No. 4,916, issued to Munk et al. In 1990? Tiger, which disclosed a magnetic supply unit 'with a permanent magnet and electric supply, but its knot on a magnetic refrigerator: The application has not seen a complete and clear application scheme. In addition, in US Patent No. 6,526,75 "Tiger, a complete design of the magnetic refrigerator is disclosed, which is mainly based on the difference between hot pipes and hot spots, and operates in a rotating manner to form a thermal cycle. In addition, in The technology of U.S. Patent No. 4,107,935 also discloses a refrigerator using a rotating magnetic material, which mainly circulates a working fluid through a pump through a specially designed rotating 1243884 magnetic heating device. This rotating magnetic step is loaded with magnetocaloric material and continuously rotates unidirectionally in a strong magnetic field and a weak magnetic field, and the working fluid is sent into the rotating magnetic device. …, The complex flow path of the inner sigh leaf in the farm is exchanged with the magnetocaloric material to achieve the purpose of magnetic cooling. In the related magnetocaloric effect research, 'magnetic field intensity and magnetic field control are the fields that need to be researched, and & The use of hydro-magnets as the magnetic source has gradually replaced the design of super-conducted materials for super-conducted materials, which can simplify the needs of low-temperature operating environments. However, the current permanent magnets In terms of materials, its magnetic strength is much smaller than UTesla '. Therefore, for most applications of magnetic refrigerators, its magnetic heating effect is insufficient. [Summary of the invention] The main purpose of the present invention is to provide a kind of repetitive rotary magnetic refrigeration Device, in particular-a magnetic refrigeration device that performs magnetization and demagnetization operations on magnetocaloric materials in the process of repeated rotation. The specific solution of the present invention> the gray fΛ unclamping scheme is a combination of the concept of a rotary motor The main method of repetitive rotary motion is to generate or not the magnetic circuit; it is mainly to arrange the magnetocaloric material at the position of the sub salient poles and supplement it with the magnetic supply coil. The control method is to perform magnetization and demagnetization operations on the magnetocaloric material, and to generate the magnetocaloric effect through the change of the temperature and magnetic entropy of the magnetocaloric material. The effect of exchange and cooling. Another object of the present invention is to provide a magnetic cooling device capable of using a permanent magnet to enhance the magnetic field supply capability. The present invention is built into a stator and a rotor, respectively. There are permanent magnets, and then through 1243884 to alternately supply current to any two adjacent magnetic coils, it generates a reluctance and electromagnetic torque effect similar to rotating electric motors. It attracts the rotor to rotate repeatedly. The permanent magnets in the rotor and the magnetic circuit formed by the magnetic supply coils surrounding the magnetocaloric material are used to enhance the magnetic field strength of the magnetizing and demagnetizing operations of the magnetocaloric material. The embodiment is described below with reference to the drawings. [Performance] First, please refer to "Fig. 1". The repeatedly rotating magnetic refrigeration device of the present invention includes: a rotor 10, placed in the repeatedly rotating In the center position of the magnetic cooling device, a permanent magnet 11 is embedded, which has two magnetic poles N, s, and can rotate freely; a stator 20 is a ring-shaped element, which surrounds the periphery of the rotor 10, in this stator A permanent magnet 21 is arranged in 20, and it can be seen from the figure that the permanent magnet 21 has two magnetic poles, n and S; a plurality of stator salient poles 1 ~ 8, the total number of which is even, and they are arranged on the inner circumference of the mule 20. The circumferential position is equally divided, and the magnetocaloric material 30 is arranged on the surface; the magnetic supply coil 40 'surrounds the stator salient poles 1-8, and through the control method of alternately supplying current to any two adjacent magnetic supply coils 40, Generates magnetic reluctance and electromagnetic torque effects similar to rotating electric motors to attract the rotor 10 to rotate repeatedly. The permanent magnet 11 of the rotor 10 and the electromagnetic field of the magnetic supply coil 40 form a magnetic circuit to circulate. The operation of magnetizing and demagnetizing, 1243884 causes the temperature and magnetic entropy of the magnetocaloric material 30 to change; and the heat transfer unit includes a first heat pipe 51 and a second heat pipe 52 in thermal contact with the magnetocaloric material 30, by The heat transfer effect of the first and second heat pipes 51% causes the magnetocaloric material 30 to perform heat exchange and cooling operation with the outside world. Many types of magnetocaloric materials have been disclosed on the surfaces of the stator salient poles 1 ~ 8, such as Dy3Ga5012, DyAl5012, EuS,

Tb-Gd, and Er (NiC0) 2, etc., and the present invention will use the rare earth metal Gd (gadolin) which is traditionally used for generating the magnetocaloric effect as a preferred embodiment. The permanent magnet u, 21 is provided in the rotor 10 and the stator 20 to increase the magnetic field strength when the magnetocaloric material 30 is magnetized. In the embodiment of the present invention, the geometry of the permanent magnet Η built into the rotor 10 The design is similar to the horseshoe type. Its geometric dimensions are designed to match the position of the salient poles of the stator. When any two adjacent magnetic supply coils 40 surrounding the salient poles of 1 to 8 are alternately supplied with current, When an electromagnetic field is generated, magnetic reluctance and electromagnetic torque effects similar to those of a rotating electric motor are generated to attract the permanent magnet η built in the rotor 10, thereby driving the rotor 10 to rotate repeatedly, and by being built in the rotor 10 and the stator 2 The magnetic circuit formed by the permanent magnets η, 2 丨 and the magnetic supply coil 40 surrounding the magnetocaloric material 30 can not only magnetize the magnetocaloric material 30, but also enhance the magnetocaloric material. 30 Magnetic field strength for performing the magnetization operation. In the preferred embodiment shown in the figure, there are a total of eight stator salient poles 〜 ~ 8, and the horseshoe-shaped permanent magnets embedded in the rotor 10 are two η and 11, and any one of the horseshoe-shaped Permanent magnets 丨 丨 or u each have two permanent magnetic poles ΠA, ΠB or 12A, 12B, so there are 4 permanent magnetic poles 12A, 12B, 12A ', 12B'. The shape design, 1243884 makes the two permanent magnet poles 12A, 12B of any permanent magnet 11 at the same time facing any two stator salient poles that are closest to each other but not adjacent (such as stator salient poles 1, 3) 'So At the same time, the four permanent magnetic poles 12A, 12B, 12A, and 12B of the two permanent magnets u and u, will be respectively connected with four stator salient poles (such as stator salient poles 1, 3, and 5). 7) The electromagnetic field generated by the magnetic supply coil 40 attracts each other. By causing the magnetic circuit to flow, the magnetocaloric material 30 provided on the surface of the stator salient pole is magnetized. According to this principle, the stator salient pole The total number is even, and the total number of permanent type magnetic poles of the permanent magnet u embedded in the rotor 10 is Half of the total number of stator salient poles. For example, when the permanent magnets embedded in the rotor 10 (three, and the total number of permanent magnetic poles is six, the total number of stator salient poles should be i 2, In order to strengthen the circulation of the magnetic circuit, the salient poles of the stator are directly opposite the horseshoe-shaped permanent magnets 11 or 11, and the permanent magnetic poles 12A, 12B, or 12 are at one end, and 128 are added. Fluxconce material body 60 (fluxconce, as shown in the figure, the size of the magnetic flux material material 60 can be larger than the size of one of the stator salient poles 1 to 8 and is equal to the permanent magnet 丨 丨 or u The permanent magnetic poles 12A, 12B or 12A ', 12B, have the same size to increase their magnetic induction capacity. Regarding the repeated rotation of the rotor 10 and how to use the magnetocaloric effect to achieve cooling in the process of repeated rotation The effect is described with the action of "Figure 2A ~ 2B"; in the case of "Figure", the four permanent magnetic poles 12A, 12B, 12a, and i2b of the horseshoe-shaped permanent magnets 11 and 11 ', * Don't directly face the salient poles of the stator 2,4,6,8 , 3,5,7 10 1243884 The current is supplied by the magnetic coil 40 (the current supply coil 40 is shown in the figure. The color of the magnetic coil 40 is shown in the color chart, and the magnetic coil 40 that is not supplied with current is white) And the generation—electromagnetic field 'thereby attracts the horseshoe-shaped permanent magnet 11 # σ „, and rotates in the direction of the arrow (clockwise) according to the figure. At this time, the magnetic heat set on the surface of the stator salient poles U, 5, 7 The material 30 will increase its temperature due to the operation of magnetization, which will produce an exothermic effect. ^ Μ Your brother's picture, "Nihon," and "J w" causes the magnetic coil 40 to supply an electric current to generate an electromagnetic field, thereby attracting a horseshoe. "The bodies η and η follow the directions shown by the arrows in the figure (the direction of the counterclockwise" movement 'at this time, the magnetocaloric material 30 disposed on the surface of the stator salient poles 2,4,6,8 will greatly increase: Operating to increase its temperature 'produces an exothermic effect; on the other hand, the magnetic supply coil 4G around the stator salient poles 1'3'5,7 of g stops supplying current to live. The magnetocaloric material 3 () placed on the surface of the salient salient poles 1, 3, 5, and 7 also reduces the temperature due to the demagnetization, resulting in the effect of heat absorption. In this way, through the magnetization and demagnetization operation of the magnetocaloric material 3 {) disposed on the surface of any two adjacent stator salient poles (ι, 3, 5, 7, or 2, 4'6, 8), it can promote The magnetocaloric material 30 generates a magneto-caloric effect of exothermic and endothermic heat, that is, through the first heat pipe 51 and the second heat pipe 52 having thermal contact with the magnetocaloric material 30, the magneto-caloric material 30 is caused to perform heat exchange with the outside world and achieve Cold effect. The role of the heat leaflet 7L · is to promote the magnetic heat material 30 to achieve heat exchange and cooling with the outside world. The first heat pipe 51 and the second heat pipe are a siphon type micro heat pipe structure. They both have Part of the length is attached to the surface of the magnetocaloric material 3 on both sides of the stator salient poles 1 ~ 8 (as shown in the "i" figure), while the other part extends to the repeatedly rotating magnetic field. The heat transfer effect of the cooling device 1243884 p 9 '1 heat pipe 51, 52 urges the magnetocaloric material 30 to perform heat exchange and cooling operation with the outside world.

As shown in "Figure 3", the first heat pipe 51, the second heat pipe 52, and the vehicle's good-percentage are arranged in a parental configuration, and a flow control room 53 (such as a 4 / 2-position valve) is used to carry out Switching of the heat transfer flow path, that is, the first heat conducting tube 51 and the first heat pipe 52 are respectively salient poles of any two adjacent stators (1, 3, 5, 7 or 2, 4, 6, 8) The surface of the magnetocaloric material 30 provides heat transfer services, as shown in Figure 1 ". The first heat pipe 51 is used to provide heat transfer services to the magnetothermal material 30 on the surface of the stator salient pole numbered my. The second heat pipe 52 provides a heat transfer service to the magnetocaloric material 30 on the surface of the stator salient poles numbered 2, 4, 6, 8; the first and second interfaces 531 on the side of the flow path control valve 53, 532 is connected to the first heat pipe 51 and the second heat pipe, respectively, and the third and fourth interfaces on the other side of the flow control valve 53 are connected to a heat sink 54 and a heat exhauster 55, respectively, and this The two heat sinks% and the heat sink% are basically a siphon type micro heat pipe structure, which differs only in that they have a larger heat transfer than the first heat pipe 51 and the second heat pipe 52. Area, where the heat sink 55 is used to transfer heat flow (that is, the heat generated by the magnetocaloric material 30 is discharged to the outside), and the other heat sink 54 is used to transfer cold flow (that is, to the outside) Absorbs heat and conducts heat to the magnetocaloric material 30, which is cooled due to demagnetization, to achieve the cooling effect of heat absorption and cooling to the outside), so with the repeated rotary motion of the repetitive rotary magnetic refrigeration device, the flow path control valve is switched by The flow path position of 53 can send the heat generated by the magnetocaloric material 30 of the revolving magnetic refrigeration device to the heat exhauster 55 through the first heat pipe 51 or the second heat pipe 52, and vice versa. When the magnetic heating material 30 of the rotary magnetic refrigeration device 12 1243884 is cooled, the heat absorbed by the heat absorber 54 provided in the outside (such as a cold room) can be sent to the first heat pipe 51 or the second heat pipe 52 to The magnetocaloric material 30 'at a relative bottom temperature performs an endothermic cooling operation. The working fluids filled in the first and second heat pipes 51 and 52 are generally gas-liquid mixed type, but are not limited to this. In addition, such as pure gas, pure liquid or nitrogen, or Is helium, etc. are also feasible options. In summary, the above are merely preferred embodiments of the present invention, and are not intended to limit the scope of implementation of the present invention. That is, all equivalent changes and modifications made within the scope of the patent application for the present invention shall be the technical scope of the present invention. [Brief description of the drawings] Fig. 1 is a plan view of the present invention. Figures 2A ~ 2B 'are the operation of the present invention, r-shape ~, the picture shows the movement of the rotor in the process of no magnetization and magnetic connection. "Figure 3 'shows the configuration of the preferred embodiment of the heat transfer unit. [Explanation of Symbols] 1 ~ 8 ...... 10 · · · · .... 11, 11, 21 · · · · 12A , 12B, 12A ', 12B,. 20. 30 ···· ... 40 ······ · • • • Salient pole • • • Rotor • • • • Permanent magnet type • • • Stator • ·· Magnetic thermal material •. · Magnetic coil 13 1243884 51 ...... First heat pipe 52 ............. ... Second heat pipe 53 ...... Flow control valve 531,532 ............ First and second connection 533,534 .. ..... 3rd and 4th connection 54 ... heat sink 55 ........... .. Exhaust Heater 60 ...... flux concentrator

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Claims (1)

1243884 Scope of patent application:】 · -An iterative rotating magnetic refrigeration device that repeatedly rotates magnetic and thermal materials to perform magnetization and demagnetization operations, including: χ, a rotor can be freely Rotating, the rotor is placed in the center of the reciprocating refrigeration device, with permanent magnets embedded in it; a stator, which is a ring-shaped element, surrounds the periphery of the rotor, and a permanent magnet is built-in; The total number is an even number, which are respectively arranged in equal positions on the inner circumference of the stator. The surface is provided with a magnetocaloric material # magnetic coil, which surrounds the salient poles of the stator. The magnetic supply coil alternately supplies current and generates reluctance and electromagnetic torque to attract the rotor's repeated rotation 'and whether or not a magnetic circuit flows through the permanent magnets of the rotor and the electromagnetic force of the magnetic supply coil. The magnetocaloric material conducts magnetization and demagnetization operations, which causes the temperature and magnetic entropy of the magnetocaloric material to change; and a heat transfer unit, which is used to take away the generated heat energy. Lu 2. 如 申 #Patent The iterative rotary magnetic refrigeration device described in item 1 of the scope, wherein the total number of permanent magnetic poles of the permanent magnet embedded in the rotor is half of the total number of salient poles of the stator. The repetitive rotating magnetic refrigeration device described above, wherein the permanent magnet system embedded in the rotor is a horseshoe-type permanent magnet. 4. The repetitive rotating magnetic refrigeration device described in item 1 of the scope of patent application, The salient pole of the stator is directly opposite to the permanent magnetic pole of the permanent magnet embedded in the rotor, and a magnetic flux chain polyconducting material body is further provided. 15 1243884 5 · As described in the patent claim ^ 1 Rotary rotating magnetic refrigeration device, in which the magnetocaloric material is a rare earth metal called ㈣Turn. 6. The repeated rotating magnetic refrigeration device as described in the scope of the patent application! Item 3, 4 heat transfer In the early stage, the first heat conductor and the second heat pipe and the first-stage control valve that are substantially in contact with the magnetocaloric material are used to promote heat exchange and cooling operations between the magnetocaloric material and the outside by the heat transfer effect of the heat pipe. ', 7 ·-a kind of repetitive rotating magnetic refrigeration device' The method of heating and demagnetizing the hot material to produce cooling effect includes: a rotor, which can rotate freely, the rotor is placed at the center of the revolving rotary magnetic repair refrigeration device, and is embedded in it A permanent magnet; a stator, which is a ring-shaped element that surrounds the periphery of the rotor, which has a built-in permanent magnet; a plurality of stator salient poles, the total of which is an even number, which are respectively arranged at equal positions on the inner circumference of the stator. A magnetocaloric material is arranged on the surface; a magnetic supply coil surrounds the salient poles of the stator, alternately supplies current to any two adjacent magnetic supply coils, and generates magnetic resistance and electromagnetic torque to attract the rotor Rotating repeatedly, and through the formation of a magnetic circuit between the permanent magnet of the rotor and the magnetic supply coil, whether the magnetic heating material is magnetized and demagnetized to promote the temperature of the magnetic heating material and The magnetic entropy changes; and a heat transfer unit is used to take away the generated heat energy. 8. The repetitive rotating magnetic refrigeration device described in item 7 of the scope of the patent application, wherein the total number of permanent type magnetic poles of the permanent magnet embedded in the A rotor is half of the total number of salient poles of the stator. 16 1243884 9. The reciprocating rotary magnetic refrigeration device as described in item 7 of the scope of patent application, wherein the permanent magnet system embedded in the rotor is a horseshoe-type permanent magnet. 10. The repetitive rotating magnetic refrigeration device as described in item 7 of the scope of the patent application, wherein the stator salient pole is directly opposite one end of the permanent magnetic pole of the permanent magnet embedded in the rotor, and a magnetic flux is further provided. Chain polyconducting material body. 11. According to the iterative rotary magnetic refrigeration device described in item 7 of the scope of the patent application, the 8-β beta magnetic thermal material is a rare earth metal Gd (gadolinium). 12. The repetitive rotating magnetic refrigeration device as described in item 7 of the scope of the patent application, wherein the heat transfer unit includes a first heat conductor and a second heat pipe that are substantially in contact with the magnetocaloric material. The heat transfer effect of the duct promotes the heat exchange and cooling operation of the magnetocaloric material with the outside world. • Ru Shenming's repetitive rotating magnetic refrigeration device described in item 12 of the patent, wherein the first heat pipe and the second heat pipe are a siphon type micro heat pipe structure. The revolving magnetic cooling device described in item 12 of the declared patent scope, wherein the first and second heat pipes are partially attached to the magnetic heat on both sides of the salient pole of the stator The surface of the material, while the other part extends to the outside of the repetitive rotating magnetic refrigerator. 15. If the repeated rotating magnetic refrigeration device described in item 14 of the scope of the patent application, the ## duct and the second heat pipe are arranged in a cross configuration, and include a flow control valve for The heat transfer flow path is switched, that is, the first heat pipe and the second heat pipe are respectively used for the magnetic heat material on the surface of the salient poles of two adjacent stators for radon transfer. Μ • Repetitive rotation as described in item 15 of the scope of the patent application :; Magnetic refrigeration device, 17 1243884 "further includes a heat sink and _ heat exhauster, one side of the flow path control valve has-第-、 The second interface is respectively connected to the first heat pipe and the second heat pipe, and the other side of the flow path control unit has a third and fourth interface respectively connected to the heat sink and the heat exhauster. 17 The iterative rotary magnetic refrigeration device described in item 16 of the scope of patent application, wherein the heat exhauster is used to absorb heat from the magnetocaloric material and discharge the heat generated outdoors, and the heat absorber is used In order to absorb heat to the outside world and conduct heat to the magnetocaloric material, which is cooled due to demagnetization, the repetitive rotating magnetic refrigeration device described in item 16 of the scope of patent application, wherein the heat absorber and the heat exhauster are a siphon Type micro heat pipe structure, 18 and has a larger heat transfer area than the first heat pipe and the second heat pipe 18