JP2005090921A - Temperature controlling device using magnetic body - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a temperature controlling device which can reduce a device cost and an operation cost, has a simple structure, and employs a small and high performance magnetic body. <P>SOLUTION: This device is configured such that a cylindrical structure 1 filled with a magnetic body having positive magnetocaloric effect and a cylindrical structure 2 filled with a magnetic body exhibiting negative magnetocaloric effect are connected on a straight line, and that a cooler 4 and a radiator 5 are connected to one end and the other end, respectively, of the straight line. A magnet 3 is mounted so that it can reciprocate between the cylindrical structures 1 and 2. When the magnet 3 moves in a heat insulation state leading to the heating or cooling of the magnetic bodies with positive and negative magnetocaloric effects, which are filled with the respective cylindrical structures, a heat exchange medium is configured to move toward the cooler 4 or radiator 5 with a pump 6. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a temperature control device using a magnetic material, and more specifically, a magnetic material that moves heat by increasing and decreasing a magnetic field applied to a magnetic material having a magnetocaloric effect in an adiabatic state. The present invention relates to a temperature control device using

  Conventional temperature control devices include air conditioners, heat pumps used for hot water supply and air conditioning, and the like. These temperature control devices use carbon dioxide or the like, which is chlorofluorocarbon or alternative chlorofluorocarbon, as the refrigerant, and since heat is transferred by compressing and expanding these refrigerants, in order to compress and expand refrigerants such as compressors Equipment that requires a lot of power. In addition, adverse environmental impacts such as the destruction of the ozone layer by chlorofluorocarbons and the global greenhouse effect of carbon dioxide, which is a substitute for chlorofluorocarbons, must be considered. A magnetic refrigerator is known as a temperature control device that does not require compression / expansion of a refrigerant or the like.

  By the way, when a magnetic field is applied to the magnetic material and the magnetic field is increased, the magnetization of the magnetic material changes, and the magnetic material generates heat or absorbs heat according to the change of the magnetization. On the other hand, by decreasing the applied magnetic field, the magnetization of the magnetic material changes, and the magnetic material may absorb heat or generate heat depending on the magnetization. Such a phenomenon is called a magnetocaloric effect.

  In general, a magnetic material whose temperature increases when the strength of the magnetic field applied to the magnetic material in the adiabatic state is increased is called a magnetic material having a positive magnetocaloric effect, and applied to the magnetic material in the adiabatic state. A magnetic material whose temperature decreases as the strength of the magnetic field is increased is called a magnetic material having a negative magnetocaloric effect. In addition, when a magnetic material having a positive magnetocaloric effect has a constant temperature, the entropy is reduced when the applied magnetic field is increased, and the amount of heat proportional to the reduced entropy is radiated. For a magnetic material having a negative magnetocaloric effect, when the applied magnetic field is increased when the temperature of the magnetic material is constant, the entropy increases, and the amount of heat proportional to the increased entropy is absorbed. A method of cooling an object to be cooled using the magnetocaloric effect having such properties is called magnetic refrigeration.

  When the magnetic refrigeration technology using the magnetocaloric effect described above is used, the conventional chlorofluorocarbon or alternative chlorofluorocarbon is not compressed and expanded, so that the environment is not adversely affected. In addition, since no compressor or the like is used, less power is required, which can contribute to energy saving. Therefore, interest in magnetic refrigeration utilizing the magnetocaloric effect is increasing.

  The principle of magnetic refrigeration has been known for a long time and was proposed by Debye and Jioc in the 1920s. This technology is used at low temperatures such as low temperature generation below liquid helium temperature, generation of superfluid helium, and liquefaction of helium. In this cooling technique, the temperature showing the magnetocaloric effect varies depending on the magnetic material. Therefore, the adaptive temperature and the ultimate temperature of the cooling process can be changed by appropriately selecting the magnetic material.

  The method of cooling by magnetic refrigeration is a method of increasing and decreasing the magnetic field applied to a magnetic body having a magnetocaloric effect only once, and an increase of the magnetic field applied to a magnetic body having a magnetocaloric effect. And a method of performing reduction in a cycle. The former is often used when generating a cryogenic temperature below the helium temperature. For the purpose of liquefying a gas such as helium or cooling the object to be cooled constantly, the latter method is often used in which the magnetic field applied to the magnetic material having the magnetocaloric effect is increased and decreased in a cycle. As a magnetic refrigerator using such a method of increasing and decreasing the magnetic field applied to a magnetic body having a magnetocaloric effect in a cycle, a piston including the magnetic body having a magnetocaloric effect is generated by a magnet. It has been proposed to increase and decrease the magnetic field applied to a magnetic material having a magnetocaloric effect in a cycle by putting it in and out of the magnetic field. FIG. 11 is a schematic diagram of a conventional magnetic refrigerator that increases and decreases the magnetic field applied to a magnetic material having a magnetocaloric effect in a cycle.

  In this method, as can be seen from FIG. 11, when pulling out or pushing out the piston 41 including the magnetic material from the magnet 43, a large force is required against the attractive force between the magnetized magnetic material in the piston 41 and the magnet 43. It becomes. For this reason, a driving device such as a motor capable of generating a large driving force is required, and the device manufacturing cost is high.

  FIG. 12 is a diagram showing a conventional wheel type magnetic refrigerator. In FIG. 12, a magnet 53 or a magnetic field generator is disposed so that a magnetic field is applied only to a part of a disk-shaped magnetic body (hereinafter referred to as a magnetic disk) 51 having a magnetocaloric effect. By rotating 51, the magnetic field applied to each part of the magnetic disk 51 is continuously increased and decreased. At that time, the cooled or heated liquid such as water that has passed through the magnetic disk 51 reaches the cooler 54 and the radiator 55 and cools the object to be cooled. According to this method, the force acting on the portion of the rotating magnetic disk 51 that is pulled out from the space to which the magnetic field is applied is simultaneously moved toward the space to which the magnetic field is applied. Since it is offset by the pulling force, the force for rotating the magnetic disk 51 can be reduced. Further, since two or more cooling cycles are performed simultaneously, the apparatus can be reduced in size and performance. (See Patent Document 1)

  However, in this method, a thermal connection between the rotating magnetic disk 51 and a device that exchanges a heat load such as a cold heat exchanger or a cooler, and a device that excludes heat such as a heat exchanger or a radiator. The structure for performing the thermal connection with is complicated.

  FIG. 13 is a diagram illustrating a conventional magnetic refrigerator including a piston including a magnetic body having two magnetocaloric effects. In FIG. 13, a piston 61 including a magnetic body having two magnetocaloric effects is supported by a piston rod and reciprocates between two coolers 64. The magnet 63 or the magnetic field generator is arranged to apply a magnetic field to a part of the moving region of the piston 61, and the piston 61 reciprocates in the space to which the magnetic field is applied. The magnetic field applied to the magnetic material having the magnetocaloric effect is increased and decreased. According to this method, the force required to extract one piston 61 from the space to which the magnetic field is applied is offset by the force that pulls the other piston 61 to the space to which the magnetic field is applied. It is possible to reduce the force for driving the. Further, since two or more cooling cycles are performed simultaneously, the apparatus can be reduced in size and performance. (See Patent Document 2)

  However, in this method, when the magnetic body having the magnetocaloric effect in one piston 61 generates heat, the magnetic body having the magnetocaloric effect in the other piston 61 absorbs heat. It is necessary to devise measures such as incorporating a heat insulating structure for preventing the inflow of heat between the pistons 61 including, or increasing the distance between the pistons 61 including the two magnetic bodies so as to prevent the inflow of heat. Therefore, it can be considered that the structure of the magnetic refrigerator becomes complicated. Further, in this method, the cooler 64 is separated into two, so that it is not suitable for efficiently cooling one place.

  Conversely, a structure has been proposed in which an apparatus for exchanging cold heat such as a cooler is placed between two magnetic bodies exhibiting a magnetocaloric effect. FIG. 14 is a view showing a conventional magnetic refrigerator having a structure in which a cooler is placed between two magnetic bodies showing the magnetocaloric effect. In FIG. 14, a piston 71 including two magnetic bodies having a magnetocaloric effect and a cooler 74 disposed between the two pistons 71 are supported by a piston rod and can reciprocate. The magnet 73 or the magnetic field generator is arranged to apply a magnetic field to a part of the moving region of the piston 71, and the piston 71 reciprocates in the space to which the magnetic field is applied. The magnetic field applied to the magnetic material having the magnetocaloric effect is increased and decreased. According to this method, as in Patent Document 2, the force required to extract one piston 71 from the space to which the magnetic field is applied is canceled by the force that pulls the other piston 71 to the space to which the magnetic field is applied. Therefore, the force for driving the two pistons 71 can be reduced. Moreover, since the cooler 74 is arrange | positioned between the two pistons 71, it can cool one place efficiently. Further, as in the above-mentioned two patent documents, since this apparatus simultaneously performs two or more cooling cycles, the apparatus can be reduced in size and performance can be improved. (See Non-Patent Document 1)

  However, in this method, since the cooling capacity from the magnetic body having two magnetocaloric effects is concentrated in one place, cooling can be performed efficiently, but placing the cooler 74 between the two pistons 71 is not possible. The structure of the apparatus becomes complicated, and in practice, the cooler 74 must be disposed at a location away from the piston 71 and the magnet 73.

Japanese Patent Publication No. 3-25710 Japanese Patent Publication No. 1-526668 Advances In Cryogenic Engineering (issued by Plenum Press) Volume 37, page 875 (1992)

  As described above, in the conventional configuration shown in FIG. 11, an apparatus for reciprocating the piston 41 including a magnetic body (hereinafter referred to as a magnetic material) having a magnetocaloric effect in a space to which a magnetic field is applied. However, a large force is required to pull out or push out the piston 41 including the magnetic material from the magnet 43. Therefore, since a large power source is required, the apparatus cost and the operating cost have increased. In the conventional configurations shown in FIGS. 12, 13 and 14, the forces acting between the magnetic material and the magnetic field generator such as a magnet are canceled out, so that a large power source is not required. Although the device can be downsized and improved in performance, the structure of the connection between the magnetic material and the heat exchanger such as a cooler has become complicated.

  Therefore, the present invention provides a temperature control device using a small and high-performance magnetic material that can reduce the device cost and the operation cost, and is not complicated in structure.

  Therefore, the present invention uses a magnetic material whose temperature changes when a magnetic field is applied in an adiabatic state, and by applying a magnetic field by means for generating a magnetic field to the magnetic material and changing the strength of the magnetic field received by the magnetic material. In a temperature control apparatus that performs heating or cooling, a first magnetic body that increases in temperature when a magnetic field is applied in an adiabatic state, a second magnetic body that decreases in temperature when a magnetic field is applied in an adiabatic state, and one of the magnets When a magnetic field is applied to a body, a magnetic field having a strength lower than that of the magnetic field is applied to the other magnetic body or a magnetic field is not applied, and the heat exchange medium is moved to a radiator or a cooler. And heat transfer means.

Furthermore, the present invention provides a temperature control apparatus using a magnetic body that changes in temperature when a magnetic field is applied in an adiabatic state, and a first magnetic body that increases in temperature when the magnetic field is applied in an adiabatic state, and a magnetic field in the adiabatic state. A second magnetic body that decreases in temperature when applied, means for applying a magnetic field to the magnetic body, and means for moving the heat exchange medium to a radiator or cooler are provided.

The means for generating a magnetic field of the present invention is composed of a magnetic field generator such as a magnet.
The heat transfer means of the present invention is constituted by a pump.

  According to the above configuration, by providing a magnetic body having a positive magnetocaloric effect and a magnetic body having a negative magnetocaloric effect for applying a magnetic field, it is easy to dispose a cooler and a radiator, and the magnetic field It is possible to transfer heat to the cooler and the radiator with a simple and compact device configuration without requiring a driving device that requires a large amount of power to move the generating means, rotate the rotating magnetic field generator, and the like. In addition, since two or more cooling cycles are simultaneously performed, a small and high-performance apparatus can be obtained.

  In the present invention, a magnetic body having a positive magnetocaloric effect (hereinafter referred to as a positive magnetic material) and a magnetic body having a negative magnetocaloric effect (hereinafter referred to as a negative magnetic material) are arranged in the same apparatus. When a magnetic field is applied to one of the two magnetic materials by the magnetic field generating means, the other magnetic material has a magnetic field smaller than the magnetic field applied to one magnetic material or A zero magnetic field is configured to be applied. Preferably, when the maximum magnetic field is applied to one magnetic material by the magnetic field generator, the minimum magnetic field or the zero magnetic field is applied to the other magnetic material. A temperature control apparatus using a magnetic material configured as described above is provided.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
(Embodiment 1)
In this embodiment, a magnetic refrigerator using a positive magnetic material and a negative magnetic material will be described as a temperature control device using a magnetic material.

  In the magnetic refrigerator according to the present embodiment, a positive magnetic material and a negative magnetic material are linearly connected in a thermally insulated state, a magnetic field is applied to one magnetic material, and a magnetic field is not applied to the other magnetic material. Or a weak magnetic field is applied, the force required when one magnetic material is pulled out of the magnetic field space by the movement of the magnetic material or magnet is the same as that of the background art described above. Since the material is offset by the force attracted to the magnetic field space, the force required to move the magnetic material or magnet is reduced. Therefore, it is not necessary to use a drive device that requires a large amount of power, which is necessary in the magnetic refrigerator having the configuration shown in FIG.

  At this time, when the magnetic material extracted from the magnetic field space is a positive magnetic material, the magnetic field applied to the positive magnetic material is reduced by being extracted from the magnetic field space (hereinafter referred to as demagnetization), and positive magnetic Since the material is in an adiabatic state, the temperature drops and heat is taken away from the surroundings (hereinafter referred to as endotherm). At the same time, the negative magnetic material, which is a magnetic material attracted to the other magnetic field space, increases the magnetic field applied by being attracted to the magnetic field space (hereinafter referred to as magnet increase), and the negative magnetic material also absorbs heat in the same way. To do. On the other hand, when the magnetic material drawn out from the magnetic field space is a negative magnetic material, the negative magnetic material is demagnetized and in a heat insulating state, the temperature rises and heat is given to the surroundings (hereinafter referred to as heat generation). At the same time, since the magnetic material attracted to the magnetic field space is a positive magnetic material, the positive magnetic material is magnetized, and since it is in an adiabatic state, the temperature rises and heat is generated. That is, a positive magnetic material and a negative magnetic material can be obtained by moving a magnet or magnetic material so that one magnetic material is in a magnetized or demagnetized state and the other magnetic material is in the opposite magnetic field state. Absorbs heat or heats depending on the state of the magnetic field.

  Therefore, if a cooler is installed at either end of a magnetic material structure connected in a straight line, when both the positive magnetic material and the negative magnetic material absorb heat, the cooler and the magnetic material The object to be cooled in the cooler can be cooled by performing heat transfer at. On the other hand, a heat radiator is disposed at the other end of the magnetic material structure. When both the positive magnetic material and the negative magnetic material generate heat, heat is transferred between the heat radiator and the magnetic body, thereby radiating heat. It can be performed. Thus, since the cooler, the positive magnetic material, the negative magnetic material, and the radiator are arranged on a straight line, the structure in the apparatus is simplified. Also, a cylindrical magnet capable of obtaining a strong magnetic field can be used without making a cut. That is, since two or more cooling cycles are simultaneously performed, a small and high-performance apparatus can be obtained.

FIG. 1 is a diagram illustrating a magnetic refrigerator using a magnetic material according to the present embodiment. In the figure, a cylindrical structure 1 filled with a granular positive magnetic material and a cylindrical structure 2 filled with a granular negative magnetic material are cylindrical structures that are not filled with a magnetic material on a straight line. 7 are connected. The structure 7 may be filled with a magnetic material other than the magnetic material filled in the tubular structure 1 and the tubular structure 2, but the magnetic material filled in the structure 7 at this time It is desirable that the magnetocaloric effect is sufficiently smaller than the magnetocaloric effect of the magnetic material filled in the cylindrical structure 1 and the cylindrical structure 2. The internal volume of the structure 7 is sufficiently smaller than the volume other than the volume occupied by the magnetic material filled with the cylindrical structure 1 and the cylindrical structure 2. The magnet 3 is a cylindrical permanent magnet called a hullback cylinder having a cylindrical shape. The magnet 3 is disposed on a carriage (not shown), and can move while accommodating the cylindrical structure 1 and the cylindrical structure 2 inside the cylinder. On the other hand, the carriage is configured to reciprocate on a rail (not shown) by a motor (not shown). Thereby, a magnetic field can be alternately applied to the cylindrical structure 1 and the cylindrical structure 2. The cooler 4 is disposed at one end on a straight line where the tubular structure 1 and the tubular structure 2 are connected, and the radiator 5 is disposed at the other end. The pump 6 serving as a driving source for the movement of the heat exchange medium is formed by connecting the cylindrical structure 2 and the radiator 5 on a straight line connecting the cooler 4 and the cylindrical structure 1, the cylindrical structure 2, and the radiator 5. It is arranged in between. The inside of the cooler 4, the cylindrical structure 1, the structure 7, the cylindrical structure 2, the pump 6 and the radiator 5 connected in a straight line is filled with a mixture of water and ethanol as a heat exchange medium. Yes. The synchronization between the motor 6 and the pump 6 required for synchronization between the movement of the magnet 3 and the movement of the heat exchange medium is controlled by a synchronization means (not shown). In the above configuration, the magnetic refrigeration cycle can be performed in an adiabatic state by covering the space between the cooler 4 and the radiator 5 with a heat insulating material (not shown).
The moving means in this embodiment includes a carriage, a rail, and a motor.

  As described above, the present embodiment includes the cooler 4, the cylindrical structure 1 filled with the positive magnetic material, the structure 7, the cylindrical structure 2 filled with the negative magnetic material, the pump 6, and the radiator 5. Can be realized in a simpler configuration than the above-described conventional magnetic refrigerator. Further, with the configuration of the present embodiment, a cylindrical magnet can be used as the magnet 3 without making a cut.

  In the present embodiment, a cylindrical structure filled with a granular positive magnetic material and a negative magnetic material is connected, but a porous positive magnetic material and a negative magnetic material are connected. Also good.

  In the present embodiment, the structure 7 need not be provided. However, in this case, in order to minimize the magnetic field applied to the magnetic material filled in the cylindrical structure to which the magnetic field is not applied, it is necessary to minimize the leakage magnetic field of the magnet 3.

  Further, in the present embodiment, an opposed permanent magnet that generates a dipole magnetic field may be used as the magnet 3, or a magnetic field generator using a coil such as a superconducting magnet may be used.

  Further, in the present embodiment, the pump 6 may be disposed between the cylindrical structure 1 and the cooler 4, or may be incorporated in the cooler 4, the radiator 5, or the structure 7. good.

  Furthermore, in the present embodiment, a liquid such as water or an organic solvent, or a gas such as nitrogen or helium may be used as the heat exchange medium.

  2 (a), (b), (c), (d), (e), and (f) are diagrams showing a refrigeration cycle by the magnetic refrigerator according to the present embodiment. In addition, about the structure of the magnetic refrigerator in FIG.2 (a)-(f), since it is the same as that of FIG. 1, it attaches | subjects the same code | symbol and abbreviate | omits description.

  In FIG. 2A, a magnetic field is applied to the cylindrical structure 2 filled with the negative magnetic material by the magnet 3, whereas the cylindrical structure 1 filled with the positive magnetic material is almost magnetic field. Is not applied.

  As shown in FIG. 2B, when the magnet 3 moves to apply a magnetic field to the cylindrical structure 1, the negative magnetic material filled in the cylindrical structure 2 is brought into a demagnetized state and the cylindrical structure. The positive magnetic material filled in the object 1 is in a magnetized state, and since it is in an adiabatic state, both the temperatures of the magnetic materials rise. At this time, the temperature rise between the positive magnetic material filled in the cylindrical structure 1 and the negative magnetic material filled in the cylindrical structure 2 is approximately the same, or the heat transfer between these magnetic materials is good. Then, the temperatures of these magnetic materials are almost equal to TH.

  As shown in FIG. 2 (c), the heat exchange medium heated in the cylindrical structure 1 and the cylindrical structure 2 is moved by the pump 6 to the radiator 5 having a temperature lower than TH. Thus, in the radiator 5, heat is radiated by the heated heat exchange medium. At this time, the temperature of the radiator 5 becomes TH−Δ (TH−Δ <TH). On the other hand, since the heat exchange medium moves between the cooler 4 and the cylindrical structure 1 and the cylindrical structure 2 at the same time, heat transfer occurs. At this time, since the temperature of the cooler 4 is lower than TH, The temperature of the magnetic material filled in the cylindrical structure 1 and the cylindrical structure 2 is TH−α (TH−α <TH−Δ <TH).

  As shown in FIG. 2 (d), the magnet 3 moves to apply a magnetic field to the cylindrical structure 2.

  As shown in FIG. 2E, the negative magnetic material filled in the cylindrical structure 2 is in a demagnetized state, and the positive magnetic material filled in the cylindrical structure 1 is in a demagnetized state. Since they are in an adiabatic state, the temperature of these magnetic materials decreases. At this time, the temperature drop between the positive magnetic material filled in the cylindrical structure 1 and the negative magnetic material filled in the cylindrical structure 2 is approximately the same, or the heat transfer between these magnetic materials is good. And the temperature of these magnetic materials becomes substantially equal TL.

  As shown in FIG. 2 (f), the heat exchange medium cooled in the tubular structure 1 and the tubular structure 2 is moved by the pump 6 to the cooler 4 having a temperature higher than TL. Thus, in the cooler 4, the object to be cooled is cooled by the cooled heat exchange medium. At this time, the temperature of the cooler 4 is TL + σ (TL <TL + σ). On the other hand, since the heat exchange medium moves between the radiator 5 and the cylindrical structure 1 and the cylindrical structure 2 at the same time, heat transfer occurs. At this time, the temperature of the radiator 5 is higher than TL. The temperature of the magnetic material filled in the cylindrical structure 1 and the cylindrical structure 2 is TL + β (TL <TL + σ <TL + β).

  The object to be cooled by the cooler 4 can be cooled by repeating the cycle shown in FIGS.

  Furthermore, in this embodiment, the temperature range showing the magnetocaloric effect of the positive magnetic material is different from the temperature range showing the magnetocaloric effect of the negative magnetic material, and the magnetic material is selected so that these temperature ranges are continuous. Then, a temperature difference occurs between the two kinds of magnetic materials when heating and cooling, and the temperature difference between the cooler 4 and the radiator 5 can be increased. That is, the temperature reached by the cooler 4 can be lowered.

FIG. 3 is a diagram showing a magnetic refrigerator using MnAs as a positive magnetic material and Fe _0.49 Rh _0.51 as a negative magnetic material according to the present embodiment. In FIG. 3, the components other than 1A and 2A are the same as those in FIG.

In FIG. 3, the cylindrical structure 1A is filled with MnAs having a diameter of about 1 mm. MnAs is a positive magnetic material with a Curie temperature from 300 Kelvin to 310 Kelvin. The cylindrical structure 2A is filled with Fe _0.49 Rh _0.51 . Fe _0.49 Rh _0.51 is a negative magnetic material having a Curie temperature from 310 to 350 Kelvin. As can be seen from the above, the temperature range between the positive magnetic material MnAs and the negative magnetic material Fe _0.49 Rh _0.51 is continuous. The structure 7 may be filled with a magnetic material other than MnAs or Fe _0.49 Rh _0.51 . It is desirable that the magnetocaloric effect of the magnetic material at this time is sufficiently small as compared with MnAs or Fe _0.49 Rh _0.51 .

In FIG. 3, when the magnet 3 moves from the state in which the maximum magnetic field is applied to Fe _0.49 Rh _0.51 in the cylindrical structure 2A toward the cylindrical structure 1A so as to apply a magnetic field to MnAs, the cylindrical structure The magnetic field applied to Fe _0.49 Rh _0.51 in object 2A decreases. Eventually, the magnet 3 completely moves to the cylindrical structure 1A, and the strength of the magnetic field applied to Fe _0.49 Rh _0.51 becomes minimum or zero. In this process, Fe _0.49 Rh _0.51, which is a negative magnetic material, generates heat and the temperature becomes about 350 Kelvin, and heats the heat exchange medium. On the other hand, the magnetic field applied to MnAs in the cylindrical structure 1A increases at the same time, and when the magnet 3 is completely moved to the cylindrical structure 1A, the magnetic field applied to MnAs is maximized. In this process, MnAs, which is a positive magnetic material, generates heat and has a temperature of about 310 Kelvin, which heats the heat exchange medium. At this time, the pump 6 is operated to the left in FIG. 3, that is, to move the heat exchange medium to the radiator 5, and the heated heat exchange medium is transferred from the cylindrical structure 2 </ b> A to the radiator 5 and also to the cylindrical structure. It moves from 1A to the cylindrical structure 2A. The heated heat exchange medium that has moved to the radiator 5 is radiated to the outside by the radiator 5, and the temperature of the heat exchange medium is lowered. The heat exchange medium heated by MnAs in the cylindrical structure 1A has a temperature lower than the heat generated Fe _0.49 Rh _0.51, and moves to the cylindrical structure 2A by the pump 6 to cool Fe _0.49 Rh _0.51 . Similarly, the heat exchange medium present in the cooler 4 moves to the cylindrical structure 1A and cools the generated MnAs. By this first step, a temperature gradient is formed in the order of the radiator 5, the cylindrical structure 2A, the cylindrical structure 1A, and the cooler 4 from the higher temperature.

Next, when the magnet 3 moves from the state in which the maximum magnetic field is applied to MnAs in the cylindrical structure 1A to the direction of the cylindrical structure 2A so as to apply a magnetic field to Fe _0.49 Rh _0.51 , the cylindrical structure 1A. The magnetic field applied to the MnAs inside decreases. Eventually, the magnet 3 completely moves to the cylindrical structure 2A, and the strength of the magnetic field applied to MnAs becomes minimum or zero. In this process, the temperature of MnAs, which is a positive magnetic material, is reduced to 300 Kelvin, and the heat exchange medium is cooled. On the other hand, when the applied magnetic field to Fe _0.49 Rh _0.51 in the cylindrical structure 2A is increased at the same time and the magnet 3 is completely moved to the cylindrical structure 2A, the applied magnetic field to Fe _0.49 Rh _0.51 is maximized. In this process, the temperature of the negative magnetic material Fe _0.49 Rh _0.51 is lowered to 310 Kelvin, and the heat exchange medium is cooled. At this time, the pump 6 is operated to the right in FIG. 3, that is, to move the heat exchange medium to the cooler 4, and the cooled heat exchange medium is transferred from the cylindrical structure 1 </ b> A to the cooler 4 and also to the cylindrical structure. It moves from 2A to the cylindrical structure 1A. The object to be cooled in the cooler 4 is cooled by the cooled heat exchange medium moved to the cooler 4. The heat exchange medium cooled by Fe _0.49 Rh _0.51 has a temperature higher than that of MnAs, and moves to the cylindrical structure 1A by the pump 6 to raise the temperature of MnAs. Further, the heat exchange medium radiated by the radiator 5 moves to the cylindrical structure 2A and raises the temperature of Fe _0.49 Rh _0.51 . By this second step, a temperature gradient is formed in the order of the radiator 5, the cylindrical structure 2 </ b> A, the cylindrical structure 1 </ b> A, and the cooler 4 from the higher temperature.

  By executing the above first stroke and second stroke as a cycle, the temperature gradient formed in order of the radiator 5, the cylindrical structure 2A, the cylindrical structure 1A, and the cooler 4 is made steady. The object to be cooled can always be cooled by the cooler 4.

In addition to MnAs, the positive magnetic material of the present embodiment is a magnetic material having a positive magnetocaloric effect, for example, a compound represented by Mn (As _1-x Sb _x ) (0 <x ≦ 0.2) , MnFe (P _1-x As _x ) (0.2 ≦ x ≦ 0.8), or Gd ₅ (Si _1-x Ge _x ) ₄ (0.4 ≦ x ≦ 0.6) Or a plurality of these materials may be used. Further, the negative magnetic material of the present embodiment can include, in addition to Fe _0.49 Rh _0.51 , a magnetic material having a negative magnetocaloric effect, such as a NiMnGa alloy, a MnCrSb alloy, a MnSi alloy, or a MnGaC alloy. A plurality of these materials may be used.

  As described above, according to the present embodiment, a positive magnetic material and a negative magnetic material are connected on a straight line, a magnet is provided on the straight line, and a cooler is provided at one end on the straight line. Since the radiator is disposed at the other end, it is possible to cool with a simple device configuration without requiring a driving device that requires large electric power to move the magnet. In addition, since two or more cooling cycles are simultaneously performed, a small and high-performance apparatus can be obtained.

(Embodiment 2)
In the present embodiment, a mode in which the positive magnetic material and the negative magnetic material in the first embodiment are configured by a plurality of magnetic bodies having a magnetocaloric effect with the same sign will be described.

  FIG. 4 is a diagram illustrating the magnetic refrigerator according to the present embodiment. In FIG. 4, the components other than 1B and 2B are the same as those in FIG.

  In FIG. 4, the cylindrical structure 1 </ b> B filled with the positive magnetic material is selected from a plurality of magnetic bodies having different magnetocaloric effects and cooled from the radiator 5 side in descending order of the temperature indicating the magnetocaloric effect. It arranges for every predetermined distance toward the container 4 side. Also in the cylindrical structure 2B filled with the negative magnetic material, a plurality of magnetic bodies having different temperatures showing the magnetocaloric effect are selected, and the radiator 5 to the cooler 4 in descending order of the temperature showing the magnetocaloric effect. It is installed side by side at a predetermined distance toward the side. The plurality of positive magnetic materials and negative magnetic materials are selected so that the temperature ranges showing the magnetocaloric effect are continuous.

  By using the cylindrical structure 1B and the cylindrical structure 2B having the above configuration, the temperature difference between the radiator 5 and the cooler 4 can be increased, and the temperature reached by the cooler can be lowered. .

  Since the magnetic refrigeration cycle in the present embodiment is the same as the magnetic refrigeration cycle described in FIG. 3, the description thereof will be omitted, and a characteristic part of the present embodiment will be described.

  In the magnetic refrigeration cycle of the present embodiment, the first positive magnetic material having a Curie temperature from −5 ° C. to 0 ° C., the second positive magnetic material having the Curie temperature from 0 ° C. to 5 ° C., and from 5 ° C. to 10 ° C. The third positive magnetic material having a Curie temperature and the fourth positive magnetic material having a Curie temperature from 10 ° C. to 25 ° C. are sequentially moved from the cooler 4 to the cylindrical structure 2B in the cylindrical structure 1B. A first negative magnetic material having a Curie temperature from 15 ° C. to 20 ° C., a second negative magnetic material having a Curie temperature from 20 ° C. to 25 ° C., and a Curie temperature from 25 ° C. to 30 ° C. In order, the third negative magnetic material having a third negative magnetic material and the fourth negative magnetic material having a Curie temperature from 30 ° C. to 35 ° C. are disposed in the cylindrical structure 2B from the cylindrical structure 1B toward the radiator 5. It arranges for every L. When the magnetic material in the cylindrical structure 1B and the cylindrical structure 2B is heated by the movement of the magnet 3 to heat the heat exchange medium, the pump 6 is moved to the radiator 5 by the distance L. The heated heat exchange medium is moved by a distance L from the structure 2B to the radiator 5 and from the structure 1B to the structure 2B. The heated heat exchange medium that has moved to the radiator 5 is radiated to the outside by the radiator 5, and the temperature of the heat exchange medium is lowered. By this third step, a temperature gradient is formed in the order of the radiator 5, the cylindrical structure 2B, the cylindrical structure 1B, and the cooler 4 from the higher temperature. At this time, a temperature gradient is also formed from the radiator 5 toward the cooler 4 for each magnetic material in the cylindrical structure 1 </ b> B and the cylindrical structure 2 </ b> B.

  Next, when the magnet 3 is moved to lower the temperature of each magnetic material in the cylindrical structure 1B and the cylindrical structure 2B to cool the heat exchange medium, the pump 6 is transferred to the cooler 4 with the heat exchange medium. It is operated so as to move by the distance L, and the cooled heat exchange medium is moved by the distance L from the structure 1B to the cooler 4 and from the structure 2B to the structure 1B. The object to be cooled in the cooler 4 is cooled by the cooled heat exchange medium moved to the cooler 4. By this fourth stroke, a temperature gradient is formed in the order of the radiator 5, the cylindrical structure 2 </ b> B, the cylindrical structure 1 </ b> B, and the cooler 4 from the higher temperature. At this time, a temperature gradient is also formed from the radiator 5 toward the cooler 4 for each magnetic material in the cylindrical structure 1 </ b> B and the cylindrical structure 2 </ b> B.

  By executing the above-described third stroke and fourth stroke as a cycle, the temperature gradient formed in order of the radiator 5, the cylindrical structure 2B, the cylindrical structure 1B, and the cooler 4 is made steady. The object to be cooled can always be cooled by the cooler 4.

  In this embodiment, four types of positive magnetic materials and negative magnetic materials are selected, but the number is not limited to this number, and can be set as appropriate according to the purpose of use.

  As the positive magnetic material of this embodiment, a magnetic material similar to that described in Embodiment 1 can be used. Further, the same negative magnetic material as that described in the first embodiment can be used for the negative magnetic material of the present embodiment.

  As described above, according to the present embodiment, it is possible to cool with a simple apparatus configuration as in the first embodiment. In addition, since two or more cooling cycles are simultaneously performed, a small and high-performance apparatus can be obtained.

  In addition, the temperature gradient is constantly formed in the order of the radiator, the structure filled with the negative magnetic material, the structure filled with the positive magnetic material, and the cooler, so that there is no gap between the radiator and the cooler. The temperature difference can be increased, and the temperature reached by the cooler can be lowered.

(Embodiment 3)
In the present embodiment, the process of changing the magnetic field applied to the positive magnetic material and the negative magnetic material in the first and second embodiments is not based on the movement of the magnet, but the positive magnetic material and the negative magnetic material. This is done by moving the material in a magnetic field.

  FIG. 5 is a view showing a magnetic refrigerator using the magnetic material according to the present embodiment. In the figure, a cylindrical structure 11 filled with a granular positive magnetic material and a cylindrical structure 12 filled with a granular negative magnetic material have a cylindrical shape that is not filled with a magnetic material on a straight line. It is connected via a structure 17. The structure 17 may be filled with a magnetic material other than the magnetic material filled in the cylindrical structure 11 and the cylindrical structure 12, but the magnetic material filled in the structure 17 at this time The magnetocaloric effect is desirably sufficiently smaller than the magnetocaloric effect of the magnetic material filled in the cylindrical structure 11 and the cylindrical structure 12. Further, the volume inside the structure 17 is sufficiently smaller than the volume other than the volume occupied by the magnetic material filled with the cylindrical structure 11 and the cylindrical structure 12. Moreover, the radiator 15 is connected to one end on the straight line to which the cylindrical structure 11 and the cylindrical structure 12 are connected via a first movable tube (not shown), and the other end is illustrated. The cooler 14 is connected through a second movable tube that is not. A motor (not shown) is connected to the first movable tube and the second movable tube. When the motor is driven, each movable tube expands and contracts and is connected between the movable tubes. Each cylindrical structure moves. The magnet 13 is a cylindrical permanent magnet called a hullback cylinder having a cylindrical shape, and is disposed so as to apply a magnetic field to a part of a moving region of the cylindrical structure. Further, the cylindrical structure 11 and the cylindrical structure 12 are configured to be accommodated in the cylinder of the magnet 13. The pump 16 serving as a movement source of the heat exchange medium is formed by connecting the cylindrical structure 12 and the first movable tube on a straight line connecting the cooler 14 and the cylindrical structure 11 and the cylindrical structure 12 and the radiator 15. It is arranged in between. Heat exchange is performed inside the cooler 14, the second movable tube, the cylindrical structure 11, the structure 17, the cylindrical structure 12, the pump 16, the first movable tube, and the radiator 15 connected in a straight line. The medium is filled with a mixture of water and ethanol. The synchronization between the motor 16 and the pump 16 required for synchronization between the expansion and contraction of the movable tube and the movement of the heat exchange medium is controlled by synchronization means (not shown). In the above configuration, the magnetic refrigeration cycle can be performed in an adiabatic state by covering the space between the cooler 14 and the radiator 15 with a heat insulating material (not shown).

  The moving means of this embodiment is composed of a movable tube and a motor.

  As described above, the present embodiment includes the cooler 14, the cylindrical structure 11 filled with the positive magnetic material, the structure 17, the cylindrical structure 12 filled with the negative magnetic material, the pump 16, and the radiator 15. Can be realized in a simpler configuration than the above-described conventional magnetic refrigerator. Further, with the configuration of the present embodiment, a cylindrical magnet can be used as the magnet 13 without making a cut.

  In the present embodiment, the positive magnetic material and the negative magnetic material are linearly connected in a heat-insulating state, and a magnetic field is applied to one magnetic material and no magnetic field is applied to the other magnetic material. Therefore, as in the background art described above, the force required when one magnetic material is pulled out of the magnetic field space by the movement of the magnetic material or magnet is offset by the force with which the other magnetic material is attracted to the magnetic field space. Therefore, the force required for moving the magnetic material or the magnet is reduced. Therefore, it is not necessary to use a drive device that requires a large amount of power, which is necessary in the magnetic refrigerator having the configuration shown in FIG.

  As the positive magnetic material of this embodiment, a magnetic material similar to that described in Embodiment 1 can be used. Further, the same negative magnetic material as that described in the first embodiment can be used for the negative magnetic material of the present embodiment.

  In the present embodiment, as described in the second embodiment, a plurality of positive magnetic materials and negative magnetic materials are selected, and from the radiator to the cooler in descending order of the temperature showing the magnetocaloric effect. A configuration may also be adopted in which they are arranged side by side at a predetermined distance.

  Further, in this embodiment, as described in Embodiment 1, a porous positive magnetic material and a negative magnetic material may be used.

  In the present embodiment, as described in the first embodiment, the structure 17 need not be provided.

  Further, in the present embodiment, as described in the first embodiment, an opposed permanent magnet that generates a dipole magnetic field may be used as the magnet 13.

  Further, in the present embodiment, as described in the first embodiment, the pump 16 may be disposed between the tubular structure 11 and the second movable tube.

  Further, in the present embodiment, the heat exchange medium similar to that described in the first embodiment can be used as the heat exchange medium.

  Since the magnetic refrigeration cycle in the present embodiment is the same as the magnetic refrigeration cycle described in FIG. 2, the description thereof will be omitted, and a characteristic part of the present embodiment will be described.

  In the present embodiment, the process of changing the magnetic field applied to the positive magnetic material and the negative magnetic material is not the movement of the magnet 13 but the cylindrical structure 11 and the cylindrical structure 12 are moved in the magnetic field. By doing so, the positive magnetic material filled in the cylindrical structure 11 and the negative magnetic material filled in the cylindrical structure 12 can be alternately applied with a magnetic field.

  As described above, according to the present embodiment, the positive magnetic material and the negative magnetic material connected in a straight line are configured to be movable in a magnetic field, and a cooler is provided at one end on the straight line. Since the heat radiator is arranged at the other end, it is possible to cool with a simple device configuration without requiring a driving device requiring a large electric power to move the positive magnetic material and the negative magnetic material in the magnetic field. Is possible. In addition, since two or more cooling cycles are simultaneously performed, a small and high-performance apparatus can be obtained.

(Embodiment 4)
In this embodiment, as a temperature control device using a magnetic material, a magnetic refrigerator using a positive magnetic material and a negative magnetic material is applied to the positive magnetic material and the negative magnetic material by rotation of the magnet. This changes the magnetic field.

  FIG. 6A is a diagram showing the magnetic field direction of the cylindrical magnetic field generator according to the present embodiment, and FIGS. 6B and 6C are diagrams showing the magnetic field directions of the cylindrical magnetic field generator according to the present embodiment. In the figure, the cylindrical magnetic field generator according to the present embodiment is configured by installing a second cylindrical magnet that is concentric and rotatable inward with respect to a fixed first cylindrical magnet. Yes. The magnetic field directions of the first cylindrical magnet and the second cylindrical magnet are the arrow directions in the figure. Since the second cylindrical magnet can freely rotate in the circumferential direction, the magnetic field inside the cylindrical magnetic field generator can be variably controlled by changing the angle α in FIG. As shown in FIG. 6 (b) by rotating the second cylindrical magnet, when the magnetic field directions of the first and second cylindrical magnets are matched, the magnetic field inside the cylindrical magnetic field generator becomes the strongest magnetic field. . Further, the rotational torque generated at this time becomes almost zero. Conversely, by rotating the second cylindrical magnet, as shown in FIG. 6C, if the magnetic field directions of the first and second cylindrical magnets are just opposite directions, that is, α is 180 °, the cylindrical magnetic field The magnetic field inside the generator is zero. Further, the torque generated at this time is almost zero. As described above, the magnetic field inside the cylindrical magnetic field generator can be controlled by rotating the second cylindrical magnet. Furthermore, when the cylindrical magnetic field generator is connected with the strongest magnetic field and the cylindrical magnetic field generator with zero magnetic field, the rotational torque applied to both cylindrical magnetic field generators is almost zero. Even if both the second cylindrical magnets are rotated at the same rate from the state, the rotational torques of both of them just cancel each other. Therefore, at this time, the force required to rotate the second cylindrical magnets of both cylindrical magnetic field generators becomes small.

  FIG. 7 is a diagram illustrating the magnetic refrigerator according to the present embodiment. In the figure, a cylindrical structure 21 filled with a granular positive magnetic material and a cylindrical structure 22 filled with a granular negative magnetic material are cylindrical structures that are not filled with a magnetic material on a straight line. 28 are connected. The structure 28 may be filled with a magnetic material other than the magnetic material filled in the cylindrical structure 21 and the cylindrical structure 22, but the magnetic material filled in the structure 28 at this time The magnetocaloric effect is desirably sufficiently smaller than the magnetocaloric effect of the magnetic material filled in the cylindrical structure 21 and the cylindrical structure 22. Further, the internal volume of the structure 28 is sufficiently smaller than the volume other than the volume occupied by the magnetic material filled with the cylindrical structure 21 and the cylindrical structure 22. The cylindrical magnetic field generator 23 is concentric with the connected cylindrical structure 21 and is disposed so as to cover the cylindrical structure 21. The cylindrical magnetic field generator 24 is concentric with the connected cylindrical structures 22 and is disposed so as to cover the cylindrical structures 22. The cylindrical magnetic field generators 23 and 24 are connected to a motor (not shown) for controlling those magnetic fields. When one cylindrical magnetic field generator is the strongest magnetic field by the control of the motor, the other cylindrical magnetic field generator can be set to zero magnetic field. A cooler 25 is disposed at one end on a straight line where the tubular structure 21 and the tubular structure 22 are connected, and a radiator 26 is disposed at the other end. The pump 27, which is a movement source of the heat exchange medium, is arranged between the cylindrical structure 22 and the radiator 26 on a straight line connecting the cooler 25 and the cylindrical structure 21, and the cylindrical structure 22 and the radiator 26. It is arranged. The cooler 25, the cylindrical structure 21, the structure 28, the cylindrical structure 22, the pump 27, and the radiator 26 connected in a straight line are filled with a mixture of water and ethanol as a heat exchange medium. Yes. Synchronization between the motor 27 and the pump 27 required for synchronization between the control of the magnetic fields of the cylindrical magnetic field generators 23 and 24 and the movement of the heat exchange medium is controlled by synchronization means (not shown). In the above configuration, the magnetic refrigeration cycle can be performed in an adiabatic state by covering the space between the cooler 25 and the radiator 26 with a heat insulating material (not shown).

  As described above, the present embodiment includes the cooler 25, the cylindrical structure 21 filled with the positive magnetic material, the structure 28, the cylindrical structure 22 filled with the negative magnetic material, the pump 27, and the radiator 26. Can be realized in a simpler configuration than the above-described conventional magnetic refrigerator. In addition, according to the configuration of the present embodiment, the cylindrical magnetic field generators 23 and 24 can be used without being cut.

  As the positive magnetic material of this embodiment, a magnetic material similar to that described in Embodiment 1 can be used. Further, the same negative magnetic material as that described in the first embodiment can be used for the negative magnetic material of the present embodiment.

  In the present embodiment, as described in the second embodiment, a plurality of positive magnetic materials and negative magnetic materials are selected, and from the radiator to the cooler in descending order of the temperature showing the magnetocaloric effect. A configuration may also be adopted in which they are arranged side by side at a predetermined distance.

  Further, in this embodiment, as described in Embodiment 1, a porous positive magnetic material and a negative magnetic material may be used.

  In the present embodiment, as described in the first embodiment, the structure 28 may not be provided.

  Furthermore, in the present embodiment, the cylindrical magnetic field generator 23 is used for the cylindrical structure 21 and the cylindrical magnetic field generator 24 is used for the cylindrical structure 22. In addition, the cylindrical structure 21 and the cylindrical structure 22 are installed concentrically, the second cylindrical magnet that applies a magnetic field to the cylindrical structure 21, and the portion that applies a magnetic field to the cylindrical structure 22 A cylindrical magnetic field generator configured to be able to rotate independently of the second cylindrical magnet may be used.

  Further, in the present embodiment, as described in the first embodiment, the pump 27 may be disposed between the cylindrical structure 21 and the cooler 25 or the like.

  Further, in the present embodiment, the heat exchange medium similar to that described in the first embodiment can be used as the heat exchange medium.

  FIGS. 8A and 8B are diagrams showing a refrigeration cycle of the magnetic refrigerator according to the present embodiment.

  In FIG. 8A, since the cylindrical magnetic field generator 23 applies the strongest magnetic field, the temperature of the positive magnetic material in the cylindrical structure 21 rises and heats the heat exchange medium. At this time, since the cylindrical magnetic field generator 24 has a zero magnetic field, the temperature of the negative magnetic material in the cylindrical structure 22 also rises and heats the heat exchange medium. The pump 27 is operated to move the heat exchange medium to the radiator 26, and the heated heat exchange medium is transferred from the cylindrical structure 22 to the radiator 26 and from the cylindrical structure 21 to the cylindrical structure 22. Move. The heated heat exchange medium that has moved to the radiator 26 is radiated to the outside by the radiator 26, and the temperature of the heat exchange medium is lowered. Further, the heat exchange medium heated by the cylindrical structure 21 is lower in temperature than the heated cylindrical structure 22, and is moved to the cylindrical structure 22 by the pump 27, so that the negative heat in the cylindrical structure 22 is negative. Cool the magnetic material. Similarly, the heat exchange medium present in the cooler 25 moves to the cylindrical structure 21 and cools the positive magnetic material in the cylindrical structure 21 that has generated heat. By this fifth stroke, a temperature gradient is formed in the order of the radiator 26, the cylindrical structure 22, the cylindrical structure 21, and the cooler 25 from the higher temperature.

  Next, as shown in FIG. 8B, since the cylindrical magnetic field generator 23 has a zero magnetic field, the temperature of the positive magnetic material in the cylindrical structure 21 is lowered and the heat exchange medium is cooled. At this time, since the cylindrical magnetic field generator 24 applies the strongest magnetic field, the temperature of the negative magnetic material in the cylindrical structure 22 decreases, and the heat exchange medium is cooled. At this time, the pump 27 is operated to move the heat exchange medium to the cooler 25, and the cooled heat exchange medium is transferred from the tubular structure 21 to the cooler 25 and from the tubular structure 22 to the tubular structure. Move to 21. The object to be cooled in the cooler 25 is cooled by the cooled heat exchange medium that has moved to the cooler 25. The heat exchange medium cooled by the negative magnetic material in the cylindrical structure 22 has a temperature higher than that of the positive magnetic material in the cylindrical structure 21, and moves to the cylindrical structure 21 by the pump 27 so as to be cylindrical. The temperature of the magnetic material in the structure 21 is raised. Further, the heat exchange medium after radiating heat by the radiator 26 moves to the cylindrical structure 22 and raises the temperature of the negative magnetic material in the cylindrical structure 22. By this sixth step, a temperature gradient is formed in the order of the radiator 26, the cylindrical structure 22, the cylindrical structure 21, and the cooler 25 from the higher temperature.

  By executing the above-mentioned fifth and sixth strokes as a cycle, the temperature gradient formed in order of the radiator 26, the cylindrical structure 22, the cylindrical structure 21, and the cooler 25 is made steady, The object to be cooled can always be cooled by the cooler 25.

  As described above, according to the present embodiment, the cylindrical magnetic field generator is disposed so as to cover the positive magnetic material and the negative magnetic material connected on a straight line, and cooling is performed at one end on the straight line. Since the radiator is provided with a radiator at the other end, it can be cooled with a simple device configuration. In addition, when one cylindrical magnetic field generator is the strongest magnetic field, the second cylindrical magnetic field generator is connected so that the other cylindrical magnetic field generator has zero magnetic field. The rotational torque when rotating can be reduced. In addition, since two or more cooling cycles are simultaneously performed, a small and high-performance apparatus can be obtained.

(Embodiment 5)
In this embodiment, as a temperature control device using a magnetic material, in a magnetic refrigerator using a positive magnetic material and a negative magnetic material, cooling is performed by rotating the magnetic material.

  FIG. 9 is a view showing a cross section of a cylindrical structure filled with a positive magnetic material and a negative magnetic material according to the present embodiment.

  In FIG. 9, a region 91 is filled with a granular negative magnetic material and the easy axis of magnetization is in the direction of arrow 94, and a region 92 is filled with a granular positive magnetic material and the easy magnetization axis is of arrow 92. Direction. In the figure, since the easy magnetization axis of the negative magnetic material in the region 91 is parallel to the magnetic field application direction 93, the negative magnetic material in the region 91 is magnetized. On the other hand, since the easy magnetization axis of the positive magnetic material in the region 92 is perpendicular to the magnetic field application direction 93, the positive magnetic material in the region 92 is not magnetized. At this time, the temperature of the negative magnetic material in the region 91 decreases, and the temperature of the positive magnetic material in the region 92 also decreases. That is, the temperature in the cylindrical structure decreases. Conversely, if the easy axis of magnetization of the negative magnetic material in the region 91 is perpendicular to the magnetic field application direction 93, the negative magnetic material in the region 91 is not magnetized, and the region 92 relative to the magnetic field application direction 93. When the easy magnetization axis of the positive magnetic material in the inside is parallel, the positive magnetic material in the region 92 is magnetized. At this time, the temperature of the negative magnetic material in the region 91 increases, and the temperature of the positive magnetic material in the region 92 also increases. That is, the temperature in the cylindrical structure increases. In this way, by controlling the easy axis of the negative magnetic material (or the easy axis of the positive magnetic material) in parallel and perpendicular to the magnetic field direction, the positive structure filled in the cylindrical structure is controlled. It is possible to control the temperature of the magnetic material and the negative magnetic material. Moreover, if it is the structure of the same figure, the rotational torque at the time of rotating a cylindrical structure can be made small.

  FIG. 10 is a diagram showing a magnetic refrigerator using the magnetic material according to the present embodiment. In FIG. 9, one end of the cylindrical structure 31 described in FIG. 9 is connected to the cooler 33, and the other end is connected to the radiator 34. Moreover, the cylindrical structure 31 is connected to a motor (not shown), and when this motor is driven, the magnetization easy axis direction of the negative magnetic material in the cylindrical structure with respect to the magnetic field direction of the magnet 32 described later is driven. Perform parallel and vertical control. The magnet 32 is a cylindrical permanent magnet called a hullback cylinder having a cylindrical shape, and the cylindrical structure 31 is accommodated inside the cylinder. A pump 35 that is a movement source of the heat exchange medium is disposed between the radiator 34 and the cylindrical structure 31. The inside of the cooler 33, the cylindrical structure 31, the pump 35, and the radiator 34 connected on a straight line is filled with a mixture of water and ethanol as a heat exchange medium. The synchronization between the motor 35 and the pump 35 required for synchronizing the rotation of the cylindrical structure 31 and the movement of the heat exchange medium is controlled by a synchronization means (not shown). In the above configuration, the magnetic refrigeration cycle can be performed in an adiabatic state by covering the space between the cooler 33 and the radiator 34 with a heat insulating material (not shown).

  The rotating means of this embodiment is composed of a motor.

  As described above, the present embodiment has a configuration in which the cooler 33, the cylindrical structure 31, the pump 35, and the radiator 34 are arranged in a straight line, and thus a simpler configuration than the above-described conventional magnetic refrigerator. Can be realized. Further, according to the configuration of the present embodiment, a cylindrical magnet can be used as the magnet 32 without making a cut.

  As the positive magnetic material of this embodiment, a magnetic material similar to that described in Embodiment 1 can be used. Further, the same negative magnetic material as that described in the first embodiment can be used for the negative magnetic material of the present embodiment.

  In the present embodiment, as described in the second embodiment, a plurality of positive magnetic materials and negative magnetic materials are selected, and from the radiator to the cooler in descending order of the temperature showing the magnetocaloric effect. A configuration may also be adopted in which they are arranged side by side at a predetermined distance.

  Further, in this embodiment, as described in Embodiment 1, a porous positive magnetic material and a negative magnetic material may be used.

  In the present embodiment, parallel and vertical control is performed from the direction of the easy axis of the negative magnetic material in the cylindrical structure 31 with respect to the magnetic field direction of the magnet 32. Parallel and vertical control may be performed depending on the easy axis direction of the magnetization of the positive magnetic material in 31. Further, by fixing the cylindrical structure 31 and rotating the magnet 32, the magnetic field application direction is changed with respect to the easy axis of magnetization of the negative magnetic material (or the easy axis of magnetization of the positive magnetic material) in the cylindrical structure. Alternatively, the configuration may be such that parallel and vertical control is performed.

  Further, in the present embodiment, as described in the first embodiment, an opposed permanent magnet that generates a dipole magnetic field may be used as the magnet 32.

  Further, in the present embodiment, as described in the first embodiment, the pump 35 may be disposed between the cylindrical structure 31 and the cooler 33 or the like.

  Further, in the present embodiment, the heat exchange medium similar to that described in the first embodiment can be used as the heat exchange medium.

  Since the magnetic refrigeration cycle in the present embodiment is the same as the magnetic refrigeration cycle described in FIG. 2, the description thereof will be omitted, and a characteristic part of the present embodiment will be described.

  When the magnetization easy axis direction of the negative magnetic material in the cylindrical structure 31 is perpendicular to the magnetic field direction by the magnet 32, the negative magnetic material in the cylindrical structure 31 is hardly magnetized, so the temperature rises. And heat the heat exchange medium. At this time, since the magnetization easy axis of the positive magnetic material in the cylindrical structure 31 is parallel to the magnetic field direction, the positive magnetic material in the cylindrical structure 31 is magnetized and the temperature rises. Heat the heat exchange medium. At this time, the pump 35 is operated so as to move the heat exchange medium to the radiator 34, and the heated heat exchange medium is moved from the cylindrical structure 31 to the radiator 34. The heated heat exchange medium moved to the radiator 34 is radiated to the outside by the radiator 34, and the temperature of the heat exchange medium is lowered. Further, the heat exchange medium present in the cooler 33 moves to the cylindrical structure 31, and cools the positive magnetic material and the negative magnetic material in the heated cylindrical structure 31. By this seventh step, a temperature gradient is formed in the order of the radiator 34, the cylindrical structure 31, and the cooler 33 from the higher temperature.

  Next, when the cylindrical structure 31 is rotated so that the easy axis of magnetization of the negative magnetic material in the cylindrical structure 31 is parallel to the magnetic field direction by the magnet 32, the negative magnetic material in the cylindrical structure 31 is obtained. Is magnetized, the temperature drops and cools the heat exchange medium. At this time, since the easy magnetization axis of the positive magnetic material in the cylindrical structure 21 is perpendicular to the magnetic field direction, the positive magnetic material in the cylindrical structure 31 is hardly magnetized and the temperature decreases. And cooling the heat exchange medium. At this time, the pump 35 is operated to move the heat exchange medium to the cooler 33, and the cooled heat exchange medium is moved from the cylindrical structure 31 to the cooler 33. The object to be cooled in the cooler 33 is cooled by the cooled heat exchange medium that has moved to the cooler 33. The heat exchange medium after radiating heat with the radiator 34 moves to the cylindrical structure 31 and raises the temperatures of the positive magnetic material and the negative magnetic material in the cylindrical structure 31. By the eighth step, a temperature gradient is formed in the order of the radiator 34, the cylindrical structure 31, and the cooler 34 from the higher temperature.

  By executing the seventh and eighth strokes as a cycle, the temperature gradient formed in the order of the radiator 34, the cylindrical structure 31, and the cooler 33 is made steady, and is always covered by the cooler 33. Coolant can be cooled.

  As described above, according to the present embodiment, a positive magnetic material and a negative magnetic material are connected on a straight line, a magnet is provided on the straight line, and a cooler is provided at one end on the straight line. Since the radiator is disposed at the other end, it is possible to cool with a simple device configuration without requiring a driving device that requires large electric power to move the magnet. Further, when the cylindrical structure is rotated in a magnetic field, the rotational torque can be reduced. In addition, since two or more cooling cycles are simultaneously performed, a small and high-performance apparatus can be obtained.

(Embodiment 6)
In this embodiment, a heating apparatus using a positive magnetic material and a negative magnetic material will be described as a temperature control apparatus using a magnetic material.

  In the heating device according to the present embodiment, the positive magnetic material and the negative magnetic material are linearly connected in a heat-insulating state, and a magnetic field is applied to one magnetic material and a magnetic field is not applied to the other magnetic material. Therefore, as in the background art described above, the force required when one magnetic material is pulled out of the magnetic field space by the movement of the magnetic material or magnet is canceled by the force that the other magnetic material is attracted to the magnetic field space. Therefore, the force required for moving the magnetic material or magnet is reduced. Therefore, it is not necessary to use a drive device that requires a large amount of power, which is necessary in the magnetic refrigerator having the configuration shown in FIG.

  Since the configuration of the heating device in the present embodiment is the same as that in FIG.

  In the present embodiment, when the magnet 3 moves in the direction of the cylindrical structure 2 from the state in which the maximum magnetic field is applied to the positive magnetic material in the cylindrical structure 1, the positive in the cylindrical structure 1 The applied magnetic field to the magnetic material decreases. Eventually, the magnet 3 completely moves to the cylindrical structure 2, and the strength of the magnetic field applied to the positive magnetic material in the cylindrical structure 1 becomes minimum or zero. In this process, the temperature of the positive magnetic material is lowered and the heat exchange medium is cooled. On the other hand, when the magnetic field applied to the negative magnetic material in the cylindrical structure 2 is increased at the same time and the magnet 3 is completely moved to the cylindrical structure 2A, the application to the negative magnetic material in the cylindrical structure 2A is performed. The magnetic field is maximized. In this process, the temperature of the negative magnetic material is lowered and the heat exchange medium is cooled. At this time, the pump 6 is operated to the right in FIG. 1, that is, to move the heat exchange medium to the cooler 4, and the cooled heat exchange medium is transferred from the tubular structure 1 to the cooler 4 and the tubular structure. 2 is moved to the cylindrical structure 1. The cooled heat exchange medium moved to the cooler 4 cools the cooler 4, and the temperature of the heat exchange medium rises. The heat exchange medium cooled by the negative magnetic material in the cylindrical structure has a higher temperature than the positive magnetic material in the cylindrical structure 1, and is moved to the cylindrical structure 1 by the pump 6 so that the positive magnetic material is used. Increase material temperature. Further, the temperature of the negative magnetic material in the cylindrical structure 2 rises due to the heat exchange medium moved from the radiator 5. By this ninth step, a temperature gradient is formed in the order of the radiator 5, the cylindrical structure 2, the cylindrical structure 1, and the cooler 4 from the higher temperature.

  Next, when the magnet 3 moves from the state in which the maximum magnetic field is applied to the negative magnetic material in the cylindrical structure 2 toward the cylindrical structure 1, the negative magnetic material in the cylindrical structure 2 changes. The applied magnetic field decreases. Eventually, the magnet 3 moves completely to the cylindrical structure 1 and the intensity of the magnetic field applied to the negative magnetic material in the cylindrical structure 2 is minimized or zero. In this process, the temperature of the negative magnetic material rises and heats the heat exchange medium. On the other hand, when the magnetic field applied to the positive magnetic material in the cylindrical structure 1 increases at the same time and the magnet 3 is completely moved to the cylindrical structure 1, the applied magnetic field is applied to the positive magnetic material in the cylindrical structure 1. The magnetic field is maximized. In this process, the temperature of the positive magnetic material rises and heats the heat exchange medium. At this time, the pump 6 is operated to the left in FIG. 1, that is, to move the heat exchange medium to the radiator 5, and the heated heat exchange medium is transferred from the cylindrical structure 2 to the radiator 5, and the cylindrical structure. Move from 1 to the cylindrical structure 2. The heated object of the radiator 5 is heated by the heated heat exchange medium moved to the radiator 5. Further, the heat exchange medium heated by the positive magnetic material in the cylindrical structure 1 has a lower temperature than the negative magnetic material in the heated cylindrical structure 2 and is moved to the cylindrical structure 2 by the pump 6. This cools the negative magnetic material. Similarly, the heat exchange medium present in the cooler 4 moves to the cylindrical structure 1 and cools the positive magnetic material in the heated cylindrical structure. By the tenth step, a temperature gradient is formed in the order of the radiator 5, the cylindrical structure 2, the cylindrical structure 1, and the cooler 4 from the higher temperature.

  By executing the above 9th and 10th cycles as a cycle, the temperature gradient formed in the order of the radiator 5, the cylindrical structure 2, the cylindrical structure 1, and the cooler 4 is made steady. The object to be heated can always be heated by the radiator 5.

  As described above, according to the present embodiment, a positive magnetic material and a negative magnetic material are connected on a straight line, a magnet is provided on the straight line, and a cooler is provided at one end on the straight line. Since the heat dissipator is arranged at the other end, it is possible to heat with a simple device configuration without requiring a driving device that requires large electric power to move the magnet.

It is a figure which shows the magnetic refrigerator using the magnetic material which concerns on one Embodiment of this invention. It is a figure which shows the refrigerating cycle by the magnetic refrigerator based on one Embodiment of this invention. The MnAs as a positive magnetic material according to an embodiment of the present invention, showing a magnetic refrigerator using Fe _0.49 Rh _0.51 as a negative of the magnetic material. It is a figure which shows the magnetic refrigerator using the magnetic material which concerns on one Embodiment of this invention. It is a figure which shows the magnetic refrigerator using the magnetic material which concerns on one Embodiment of this invention. (A) is a cylindrical magnetic field generator which concerns on one Embodiment of this invention, (b) And (c) is a figure which shows the magnetic field direction of the cylindrical magnetic field generator which concerns on one Embodiment of this invention. It is a figure which shows the magnetic refrigerator concerning one Embodiment of this invention. It is a figure which shows the refrigerating cycle of the magnetic refrigerator based on one Embodiment of this invention. It is a figure which shows the cross section of the cylindrical structure filled with the positive magnetic material and negative magnetic material which concern on one Embodiment of this invention. It is a figure which shows the magnetic refrigerator using the magnetic material which concerns on one Embodiment of this invention. It is a figure which shows the conventional magnetic refrigerator. It is a figure which shows the conventional magnetic refrigerator. It is a figure which shows the conventional magnetic refrigerator. It is a figure which shows the conventional magnetic refrigerator.

Claims (11)

The temperature at which heating or cooling is performed by using a magnetic material that changes in temperature when a magnetic field is applied in an adiabatic state, applying a magnetic field to the magnetic material by means of generating a magnetic field, and changing the strength of the magnetic field received by the magnetic material In the adjustment device,
A first magnetic body whose temperature rises when a magnetic field is applied in an adiabatic state;
A second magnetic body whose temperature decreases when a magnetic field is applied in an adiabatic state;
Means for applying a magnetic field having a lower strength than the magnetic field to the other magnetic body or applying no magnetic field to the other magnetic body when applying a magnetic field to the one magnetic body;
And a heat transfer means for moving the heat exchange medium to a radiator or a cooler.   2. The temperature control device using a magnetic body according to claim 1, wherein the first magnetic body and the second magnetic body are arranged in a straight line.   3. The temperature control using a magnetic body according to claim 2, further comprising moving means for relatively moving the means for generating the magnetic field, the first magnetic body, and the second magnetic body. apparatus.   The means for generating the magnetic field is concentric with the first cylindrical magnet, and the second cylindrical magnet is disposed inside, and the magnetic field applied to the magnetic body is formed by rotating the first or second cylindrical magnet. A temperature adjusting device using the magnetic material according to claim 1. A cylindrical structure including the first magnetic body and the second magnetic body;
Rotating means for rotating the cylindrical structure,
2. The temperature adjusting device using a magnetic material according to claim 1, wherein an easy axis of magnetization of the first magnetic body and an easy axis of magnetization of the second magnetic body are perpendicular to each other.   5. The temperature control device using a magnetic body according to claim 1, wherein the first magnetic body is made of a plurality of magnetic bodies that increase in temperature when a magnetic field is applied in an adiabatic state.   5. The temperature control device using a magnetic body according to claim 1, wherein the second magnetic body is made of a plurality of magnetic bodies whose temperature is lowered when a magnetic field is applied in an adiabatic state. The first magnetic material is MnAs, a compound represented by Mn (As _1-x Sb _x ) (0 <x ≦ 0.2), or MnFe (P _1-x As _x ) (0.2 ≦ 2. A compound represented by x ≦ 0.8) or a compound represented by Gd ₅ (Si _1-x Ge _x ) ₄ (0.4 ≦ x ≦ 0.6) The temperature control apparatus using the magnetic body of thru | or 6.   The second magnetic body is an Fe-Rh alloy, Ni-Mn-Ga alloy, Mn-Cr-Sb alloy, Mn-Si alloy, or Mn-Ga-C alloy. Item 7. A temperature control device using the magnetic material according to items 1 to 6. In a temperature control device using a magnetic material whose temperature changes when a magnetic field is applied in an adiabatic state,
A first magnetic body whose temperature rises when a magnetic field is applied in an adiabatic state;
A second magnetic body whose temperature decreases when a magnetic field is applied in an adiabatic state;
A temperature control apparatus using a magnetic material, comprising: means for applying a magnetic field to the magnetic material; and means for moving a heat exchange medium to a radiator or cooler. When the means for applying a magnetic field to the magnetic body applies a magnetic field to one of the magnetic bodies, a magnetic field having a lower strength than the magnetic field is applied to the other magnetic body, or a magnetic field is applied The temperature adjusting device using a magnetic material according to claim 10, wherein the temperature adjusting device is a device that does not.

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