WO2022209610A1 - 磁気冷凍装置及び冷凍装置 - Google Patents
磁気冷凍装置及び冷凍装置 Download PDFInfo
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- WO2022209610A1 WO2022209610A1 PCT/JP2022/009764 JP2022009764W WO2022209610A1 WO 2022209610 A1 WO2022209610 A1 WO 2022209610A1 JP 2022009764 W JP2022009764 W JP 2022009764W WO 2022209610 A1 WO2022209610 A1 WO 2022209610A1
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- Prior art keywords
- magnetic
- working material
- magnetic field
- field applying
- protrusion
- Prior art date
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- 238000005057 refrigeration Methods 0.000 title claims description 22
- 239000000126 substance Substances 0.000 claims abstract description 92
- 239000008207 working material Substances 0.000 claims description 329
- 230000035699 permeability Effects 0.000 claims description 9
- 230000004907 flux Effects 0.000 description 103
- 238000012986 modification Methods 0.000 description 47
- 230000004048 modification Effects 0.000 description 23
- 239000000696 magnetic material Substances 0.000 description 13
- 239000000463 material Substances 0.000 description 12
- 230000002093 peripheral effect Effects 0.000 description 12
- 238000010438 heat treatment Methods 0.000 description 8
- 230000009471 action Effects 0.000 description 5
- 238000001816 cooling Methods 0.000 description 5
- 230000007246 mechanism Effects 0.000 description 5
- 239000003507 refrigerant Substances 0.000 description 5
- 239000011347 resin Substances 0.000 description 4
- 229920005989 resin Polymers 0.000 description 4
- 229910052782 aluminium Inorganic materials 0.000 description 3
- XAGFODPZIPBFFR-UHFFFAOYSA-N aluminium Chemical compound [Al] XAGFODPZIPBFFR-UHFFFAOYSA-N 0.000 description 3
- XEEYBQQBJWHFJM-UHFFFAOYSA-N iron Substances [Fe] XEEYBQQBJWHFJM-UHFFFAOYSA-N 0.000 description 3
- 230000007423 decrease Effects 0.000 description 2
- 230000000694 effects Effects 0.000 description 2
- 229910000976 Electrical steel Inorganic materials 0.000 description 1
- 239000012267 brine Substances 0.000 description 1
- 230000008859 change Effects 0.000 description 1
- 238000010586 diagram Methods 0.000 description 1
- 230000001771 impaired effect Effects 0.000 description 1
- 229910052742 iron Inorganic materials 0.000 description 1
- 239000007769 metal material Substances 0.000 description 1
- 238000005192 partition Methods 0.000 description 1
- 239000004065 semiconductor Substances 0.000 description 1
- HPALAKNZSZLMCH-UHFFFAOYSA-M sodium;chloride;hydrate Chemical compound O.[Na+].[Cl-] HPALAKNZSZLMCH-UHFFFAOYSA-M 0.000 description 1
- 230000007723 transport mechanism Effects 0.000 description 1
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 1
Images
Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B21/00—Machines, plants or systems, using electric or magnetic effects
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B2321/00—Details of machines, plants or systems, using electric or magnetic effects
- F25B2321/002—Details of machines, plants or systems, using electric or magnetic effects by using magneto-caloric effects
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B2321/00—Details of machines, plants or systems, using electric or magnetic effects
- F25B2321/002—Details of machines, plants or systems, using electric or magnetic effects by using magneto-caloric effects
- F25B2321/0022—Details of machines, plants or systems, using electric or magnetic effects by using magneto-caloric effects with a rotating or otherwise moving magnet
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B30/00—Energy efficient heating, ventilation or air conditioning [HVAC]
Definitions
- the present disclosure relates to magnetic refrigerators and refrigerators.
- Patent Document 1 a plurality of material containers are arranged along the circumferential direction of the rotating shaft so as to surround the outer periphery of the built-in yoke, and by rotating the built-in yoke in the circumferential direction, the magnetic material contained in the material container is A magnetic heat pump device is disclosed that applies a magnetic field to a working substance (magnetic material).
- the space between adjacent material containers may be included in the path of the magnetic flux flowing in the circumferential direction inside the material container, increasing the magnetic resistance.
- the purpose of this disclosure is to suppress the increase in magnetic resistance by devising the direction of the magnetic flux flowing through the magnetic working material.
- a first aspect of the present disclosure applies a magnetic field to the magnetic working substance (11) and the magnetic working substance (11) while relatively moving in a first direction with respect to the magnetic working substance (11).
- a magnetic field applying section (20) wherein the magnetic pole (24) of the magnetic field applying section (20) is arranged on one end side of the magnetic working material (11) in a second direction orthogonal to the first direction, And the magnetic refrigerator is spaced apart in a third direction orthogonal to the first direction and the second direction in the magnetic working material (11).
- the magnetic field applying section (20) relatively moves in the first direction with respect to the magnetic working substance (11).
- the magnetic pole (24) of the magnetic field applying section (20) is arranged on one end side of the magnetic working material (11) in the second direction orthogonal to the first direction. Furthermore, the magnetic poles (24) of the magnetic field applying section (20) are spaced apart in a third direction orthogonal to the first and second directions in the magnetic working material (11).
- the first direction in which the magnetic field applying section (20) relatively moves and the third direction in which the magnetic flux flows in the magnetic working material (11) are perpendicular to each other, thereby suppressing an increase in magnetic resistance. can.
- a second aspect of the present disclosure is the magnetic refrigeration system of the first aspect, wherein the relative movement is relative rotational movement rotating around a predetermined axis, the first direction is the circumferential direction, and the second direction is the circumferential direction. is the radial direction, and the third direction is the axial direction, and the magnetic working material (11) and the magnetic pole (24) of the magnetic field applying section (20) are arranged with a gap in the radial direction, and the magnetic field applying The magnetic poles (24) of the portion (20) are axially spaced apart.
- the magnetic flux can flow along the axial direction of the magnetic working material (11).
- a third aspect of the present disclosure is the magnetic refrigeration system of the first aspect, wherein the relative movement is relative rotational movement rotating around a predetermined axis, the first direction is the circumferential direction, and the second direction is the circumferential direction. is the axial direction, and the third direction is the radial direction.
- the magnetic poles (24) of the portion (20) are radially spaced apart.
- the magnetic flux can flow along the radial direction of the magnetic working material (11).
- a fourth aspect of the present disclosure is the magnetic refrigeration apparatus of the first aspect, wherein the relative movement is relative linear movement that moves linearly along the first direction, and the magnetic working material (11) and The magnetic poles (24) of the magnetic field applying section (20) are spaced apart in the second direction, and the magnetic poles (24) of the magnetic field applying section (20) are spaced apart in the third direction. be provided.
- a fifth aspect of the present disclosure is the magnetic refrigerating apparatus according to any one of the first to fourth aspects, wherein the magnetic working material (11) is provided at both ends in the third direction of the magnetic working material (11) A yoke (13) is provided that has a higher permeability than the
- a magnetic field can be uniformly applied to the magnetic working material (11) by causing magnetic flux to flow through the yoke (13) at both ends of the magnetic working material (11) in the third direction.
- the surface of the magnetic pole (24) of the magnetic field applying section (20) facing the magnetic working material (11) is The length in the first direction is greater than the length in the first direction of the surface of the magnetic working material (11) facing the magnetic pole (24) of the magnetic field applying section (20).
- the alignment accuracy between the magnetic working material (11) and the magnetic pole (24) of the magnetic field applying section (20) can be lowered without increasing the magnetic resistance.
- a seventh aspect of the present disclosure is a refrigeration comprising a magnetic refrigerator (10) according to any one of the first to sixth aspects and a heat medium circuit (2) that exchanges heat with the magnetic refrigerator (10) It is a device.
- FIG. 1 is a piping system diagram of a refrigeration system of Embodiment 1.
- FIG. FIG. 2 is a plan view showing the configuration of the magnetic refrigerator.
- 3 is a cross-sectional view taken along line AA of FIG. 2.
- FIG. 4 is a side sectional view showing Modification 1 of Embodiment 1.
- FIG. 5 is a plan view showing Modification 2 of Embodiment 1.
- FIG. 6 is a cross-sectional view taken along line BB in FIG. 7 is a side cross-sectional view showing Modification 3 of Embodiment 1.
- FIG. 8 is a side cross-sectional view showing Modification 4 of Embodiment 1.
- FIG. 9 is a side cross-sectional view showing Modification 5 of Embodiment 1.
- FIG. 10 is a side sectional view showing Modification 6 of Embodiment 1.
- FIG. 11 is a side sectional view showing Modification 7 of Embodiment 1.
- FIG. 12 is a side sectional view showing Modification 8 of Embodiment 1.
- FIG. 13 is a plan view showing the configuration of the magnetic refrigeration system of Embodiment 2.
- FIG. 14 is a plan view showing the configuration of the magnetic field applying section.
- 15 is a cross-sectional view taken along line CC of FIG. 13.
- FIG. 16 is a side sectional view showing Modification 1 of Embodiment 2.
- FIG. 17 is a side sectional view showing Modification 2 of Embodiment 2.
- FIG. 18 is a side cross-sectional view showing Modification 3 of Embodiment 2.
- FIG. 19 is a side cross-sectional view showing Modification 4 of Embodiment 2.
- FIG. 20 is a side sectional view showing Modification 5 of Embodiment 2.
- FIG. 21 is a side cross-sectional view showing Modification 6 of Embodiment 2.
- FIG. 22 is a plan view showing the configuration of a magnetic refrigerator according to Embodiment 3.
- FIG. 23 is a side sectional view showing the configuration of the magnetic refrigerator.
- FIG. 24 is a plan view showing a state in which the magnetic field applying section is linearly moved relative to the magnetic working material.
- 25 is a side cross-sectional view showing Modification 1 of Embodiment 3.
- FIG. 26 is a side sectional view showing Modification 2 of Embodiment 3.
- FIG. 27 is a side sectional view showing Modification 3 of Embodiment 3.
- FIG. 28 is a side sectional view showing Modification 4 of Embodiment 3.
- FIG. 29 is a plan view showing the configuration of the magnetic refrigerator of Embodiment 4.
- FIG. 30 is a side cross-sectional view showing Modification 1 of Embodiment 4.
- FIG. 31 is a plan view showing the configuration of the magnetic refrigeration system of Embodiment 5.
- FIG. 32 is a plan view showing the configuration of the magnetic field applying section.
- 33 is a side cross-sectional view showing the configuration of the magnetic refrigeration system of Embodiment 6.
- FIG. 34 is a plan view showing a modification of Embodiment 6.
- FIG. 35 is a cross-sectional view taken along line DD of FIG. 34.
- Embodiment 1 ⁇ Embodiment 1>> Embodiment 1 will be described.
- the refrigeration system (1) has a heat medium circuit (2).
- a refrigerator (1) is applied to, for example, an air conditioner.
- the heat medium circuit (2) is filled with a heat medium.
- the heat medium includes, for example, refrigerant, water, brine, and the like.
- the refrigeration system (1) includes a low temperature side heat exchanger (3), a high temperature side heat exchanger (4), a pump (5), and a magnetic refrigerator (10).
- the magnetic refrigerator (10) uses the magnetocaloric effect to adjust the temperature of the heat medium.
- the heat medium circuit (2) is formed in a closed loop.
- a pump (5), a low temperature side heat exchanger (3), a magnetic refrigerator (10), and a high temperature side heat exchanger (4) are connected in this order to the heat medium circuit (2).
- the heat medium circuit (2) includes a low temperature side channel (2a) and a high temperature side channel (2b).
- the low temperature side channel (2a) connects the temperature control channel (10a) of the magnetic refrigerator (10) and the first port (6a) of the pump (5).
- the high temperature side channel (2b) connects the temperature control channel (10a) of the magnetic refrigerator (10) and the second port (6b) of the pump (5).
- the low-temperature side heat exchanger (3) exchanges heat between the heat medium cooled by the magnetic refrigeration system (10) and a predetermined object to be cooled (eg, secondary refrigerant, air, etc.).
- the high-temperature side heat exchanger (4) exchanges heat between the heat medium heated by the magnetic refrigeration system (10) and a predetermined heating target (eg, secondary refrigerant, air, etc.).
- the pump (5) alternately and repeatedly performs the first operation and the second operation.
- the heat medium in the heat medium circuit (2) is conveyed leftward in FIG.
- the heat medium in the heat medium circuit (2) is conveyed rightward in FIG.
- the pump (5) constitutes a transport mechanism that reciprocates the heat medium in the heat medium circuit (2).
- the pump (5) consists of a reciprocating piston pump.
- the pump (5) has a pump case (6) and a piston (7).
- the piston (7) is movably arranged inside the pump case (6).
- the piston (7) partitions the interior of the pump case (6) into a first chamber (S1) and a second chamber (S2).
- a first port (6a) and a second port (6b) are formed in the pump case (6).
- the first port (6a) communicates with the first chamber (S1).
- the first port (6a) is connected to the low temperature side flow path (2a).
- the second port (6b) communicates with the second chamber (S2).
- the second port (6b) is connected to the high temperature side flow path (2b).
- the piston (7) is driven by a drive mechanism (not shown).
- the piston (7) moves to the first port (6a) side.
- the volume of the first chamber (S1) decreases and the volume of the second chamber (S2) increases.
- the heat medium in the first chamber (S1) is discharged through the first port (6a) to the low temperature side flow path (2a).
- the heat medium in the high temperature side flow path (2b) is sucked into the second chamber (S2) through the second port (6b).
- the piston (7) moves to the second port (6b) side.
- the volume of the second chamber (S2) decreases and the volume of the first chamber (S1) increases.
- the heat medium in the second chamber (S2) is discharged through the second port (6b) to the high temperature side flow path (2b).
- the heat medium in the low temperature side flow path (2a) is sucked into the first chamber (S1) through the first port (6a).
- the refrigerator (1) has a control section (8).
- a control section (8) controls the operation of the pump (5) and the magnetic refrigerator (10) in accordance with a predetermined operation command.
- the control unit (8) is configured using a microcomputer and a memory device (specifically, a semiconductor memory) that stores software for operating the microcomputer.
- the magnetic refrigerator (10) includes a magnetic working substance (11), a magnetic field applying section (20), and a rotating mechanism (15).
- the magnetic working substance (11) is stored in a material container (not shown).
- the material container is made of non-magnetic metal material or resin material.
- the magnetic working material (11) generates heat when a magnetic field is applied.
- the magnetic working material (11) absorbs heat when the magnetic field is removed.
- the magnetic working material (11) also generates heat as the applied magnetic field becomes stronger.
- the magnetic working material (11) also absorbs heat when the applied magnetic field weakens.
- Materials for the magnetic working substance (11) include, for example, Gd5 ( Ge0.5Si0.5 ) 4 , La( Fe1 - xSix)13, La(Fe1-xCoxSiy ) 13 , La ( Fe 1-x Si x ) 13 H y , Mn(As 0.9 Sb 0.1 ) and the like can be used.
- a plurality of magnetic working materials (11) are arranged at intervals in the circumferential direction.
- eight magnetic working materials (11) extending in an arc shape along the circumferential direction are arranged at equal intervals in the circumferential direction.
- the magnetic working material (11) is provided with a yoke (13) having a higher magnetic permeability than the magnetic working material (11).
- the yokes (13) are provided at both axial ends of the magnetic working material (11) (see FIG. 3).
- the rotating mechanism (15) has a rotating shaft (16) and a motor (17).
- the rotating shaft (16) is connected to a motor (17).
- the motor (17) rotates the rotating shaft (16).
- a magnetic field applying section (20) is connected to the rotating shaft (16).
- the magnetic field applying section (20) moves relative to the magnetic working substance (11) in the first direction. Specifically, the magnetic field applying section (20) rotates about the axis along with the rotating shaft (16) as the motor (17) rotates. As a result, the magnetic field applying section (20) rotates relative to the magnetic working substance (11). That is, the first direction is the circumferential direction.
- the magnetic field applying unit (20) is arranged radially inside the plurality of magnetic working substances (11).
- the magnetic field applying section (20) applies a magnetic field to the magnetic working substance (11).
- the magnetic field applying section (20) has a core (21) and a magnetic pole (24).
- the core (21) is made of a magnetic material.
- a rotary shaft (16) is connected to the center of the core (21).
- the core (21) has a plurality of protrusions (23).
- the plurality of protrusions (23) protrude radially outward from the center of the core (21).
- the plurality of projections (23) are circumferentially spaced apart. In the example shown in FIG. 2, four protrusions (23) are arranged at regular intervals in the circumferential direction.
- the projection (23) is arranged radially away from the magnetic working material (11).
- the magnetic pole (24) of the magnetic field applying section (20) is arranged only on one end side of the magnetic working material (11) in the second direction perpendicular to the first direction.
- the magnetic working substance (11) and the magnetic pole (24) of the magnetic field applying section (20) are arranged with a gap in the radial direction.
- a first magnet (25) and a second magnet (26) are arranged between the magnetic working substance (11) and the protrusion (23) of the core (21).
- the first magnet (25) and the second magnet (26) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the magnetic poles (24) are spaced apart in a third direction orthogonal to the first and second directions in the magnetic working material (11).
- the first direction is the circumferential direction
- the second direction is the radial direction
- the third direction is the axial direction.
- the first magnet (25) and the second magnet (26) that constitute the magnetic pole (24) are spaced apart in the axial direction.
- the first magnet (25) and the second magnet (26) apply a magnetic field to the magnetic working material (11) so that magnetic flux flows in the axial direction of the magnetic working material (11).
- the first magnet (25) has an N pole on the side of the magnetic working substance (11) (outside in the radial direction in FIG. 3) and an S pole on the side of the protrusion (23) of the core (21) (inside in the radial direction in FIG. 3). are arranged so that
- the second magnet (26) has an S pole on the side of the magnetic working substance (11) (inward in the radial direction in FIG. 3) and an N pole on the side of the protrusion (23) of the core (21) (outward in the radial direction in FIG. 3). are arranged so that The positional relationship between the N pole and S pole of the first magnet (25) and the second magnet (26) may be reversed.
- the first magnet (25) and the second magnet (26) rotate relative to the magnetic working material (11) in the circumferential direction together with the core (21).
- magnetic flux flows in the axial direction of the magnetic working substance (11).
- the flow of magnetic flux is indicated by dashed arrow lines.
- the first magnet (25) and the second magnet (26) are arranged to face the magnetic working substance (11). Specifically, the first magnet (25) and the second magnet (26) are located at both ends of the magnetic working substance (11) in the axial direction when the magnetic working substance (11) in which the magnetic flux is flowing is viewed from the radial direction. are arranged along the part.
- the magnetic field applying section (20) applies a magnetic field to the magnetic working material (11).
- magnetic flux flows from the first magnet (25) toward the upper yoke (13) in FIG.
- a magnetic flux flows along the axial direction inside the magnetic working material (11) from the upper yoke (13) toward the lower yoke (13).
- Magnetic flux flows from the lower yoke (13) toward the second magnet (26).
- a magnetic flux flows axially through the protrusion (23) of the core (21) from the second magnet (26) toward the first magnet (25).
- the magnetic field applying section (20) is rotated to bring the first magnet (25) and the second magnet (26) to face the adjacent magnetic working material (11).
- the magnetic working material (11) to which the magnetic field was first applied absorbs heat as the magnetic field is removed.
- the adjacent magnetic working material (11) generates heat when a magnetic field is applied.
- a refrigerating device (1) alternately and repeatedly performs a heating operation and a cooling operation.
- the period of switching between the heating operation and the cooling operation is set to, for example, about 0.1 second to 1 second.
- the pump (5) performs the first operation and the magnetic field application section (20) performs the first magnetic field application operation. That is, in the heating operation, the heat medium is discharged from the first port (6a) of the pump (5). At the same time, a magnetic field is applied to the magnetic working material (11).
- the heat medium in the low-temperature side flow path (2a) is adjusted to the temperature control flow of the magnetic refrigeration system (10). into the road (10a).
- the heat medium flowing through the temperature control channel (10a) is heated by the magnetic working substance (11).
- the heat medium heated in the temperature control channel (10a) flows out to the high temperature side channel (2b) and flows through the high temperature side heat exchanger (4).
- the high-temperature heat medium heats a predetermined heating target (eg, secondary refrigerant, air, etc.).
- a predetermined heating target eg, secondary refrigerant, air, etc.
- the heat medium in the high temperature side flow path (2b) is sucked into the second chamber (S2) through the second port (6b) of the pump (5).
- the pump (5) performs the second operation and the magnetic field application section (20) performs the second magnetic field application operation. That is, in the heating operation, the magnetic field of the magnetic working material (11) is removed at the same time that the heat medium is discharged from the second port (6b) of the pump (5).
- the heat medium in the high temperature side flow path (2b) is adjusted to the temperature control flow of the magnetic refrigerator (10). into the road (10a).
- the magnetic working material (11) draws heat from its surroundings. Therefore, the heat medium flowing through the temperature control channel (10a) is cooled by the magnetic working substance (11).
- the heat medium cooled in the temperature control channel (10a) flows out to the low temperature side channel (2a) and flows through the low temperature side heat exchanger (3).
- a predetermined cooling object eg, secondary refrigerant, air, etc.
- the heat medium in the low temperature side flow path (2a) is sucked into the first chamber (S1) through the first port (6a) of the pump (5).
- the magnetic field applying section (20) relatively moves in the first direction with respect to the magnetic working material (11).
- the magnetic pole (24) of the magnetic field applying section (20) is arranged only on one end side of the magnetic working material (11) in the second direction orthogonal to the first direction. Furthermore, the magnetic poles (24) of the magnetic field applying section (20) are spaced apart in a third direction orthogonal to the first and second directions in the magnetic working material (11).
- the first direction in which the magnetic field applying section (20) relatively moves and the third direction in which the magnetic flux flows in the magnetic working material (11) are perpendicular to each other, thereby suppressing an increase in magnetic resistance. can.
- the length of the magnetic path is shortened. can be done.
- the relative movement is relative rotational movement that rotates around a predetermined axis.
- the first direction is the circumferential direction
- the second direction is the radial direction
- the third direction is the axial direction.
- the magnetic working substance (11) and the magnetic pole (24) of the magnetic field applying section (20) are arranged with a gap in the radial direction.
- the magnetic poles (24) of the magnetic field applying section (20) are spaced apart in the axial direction.
- the magnetic flux can flow along the axial direction of the magnetic working material (11).
- yokes (13) having higher magnetic permeability than the magnetic working material (11) are provided at both ends of the magnetic working material (11) in the third direction.
- iron and silicon steel which are common materials for the yoke (13), have a relative magnetic permeability of about 4000 to 5000.
- the magnetic working material (11) has a relative magnetic permeability of about 1.5 to 3.0.
- a magnetic field can be uniformly applied to the magnetic working material (11) by causing magnetic flux to flow through the yoke (13) at both ends of the magnetic working material (11) in the third direction.
- the yokes (13) provided at both ends in the third direction are arranged along the first direction of the magnetic working material (11). Therefore, when the magnetic working material (11) and the magnetic field applying section (20) are moved relative to each other in the first direction, the change in the magnetic attraction force between the yoke (13) and the magnetic field applying section (20) (so-called cogging torque ) is small. As a result, the torque required for relative movement can be reduced, and the size and power consumption of the motor (17) can be reduced.
- the magnetic refrigerator (10) and the heat medium circuit (2) that exchanges heat with the magnetic refrigerator (10) are provided.
- the magnetic pole (24) of the magnetic field applying section (20) is composed of the first protrusion (31a) of the first core (31) and the second protrusion (32a) of the second core (32).
- the core (30) has a first core (31), a second core (32) and a permanent magnet (34).
- a 1st core (31) and a 2nd core (32) are comprised by a plate-shaped member.
- the first core (31) and the second core (32) are axially spaced apart.
- a permanent magnet (34) is sandwiched between the first core (31) and the second core (32).
- the permanent magnet (34) is, for example, annular.
- the permanent magnet (34) has an N pole on the side of the first core (31) (upper side in FIG. 4) and an S pole on the side of the second core (32) (lower side in FIG. 4). are arranged as follows. The positional relationship between the N pole and the S pole of the permanent magnet (34) may be reversed.
- a plurality of first projections (31a) are provided on the first core (31) at intervals in the circumferential direction.
- a plurality of second protrusions (32a) are provided on the second core (32) at intervals in the circumferential direction.
- the first core (31) and the second core (32) are formed in the same shape and at the same position when viewed from the axial direction.
- the first protrusion (31a) and the second protrusion (32a) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the first protrusion (31a) and the second protrusion (32a) are located at both ends of the magnetic working material (11) in the axial direction when the magnetic working material (11) in which the magnetic flux is flowing is viewed from the radial direction. placed respectively.
- the magnetic field applying section (20) applies a magnetic field to the magnetic working substance (11).
- magnetic flux flows from the permanent magnet (34) toward the first protrusion (31a) of the first core (31).
- Magnetic flux flows from the first protrusion (31a) toward the upper yoke (13) in FIG.
- a magnetic flux flows along the axial direction inside the magnetic working material (11) from the upper yoke (13) toward the lower yoke (13).
- Magnetic flux flows from the lower yoke (13) toward the second protrusion (32a) of the second core (32).
- Magnetic flux flows from the second protrusion (32a) toward the permanent magnet (34).
- the magnetic working material (11) to which the magnetic field is applied generates heat.
- the magnetic field applying part (20) is rotationally moved so that the first protrusion (31a) and the second protrusion (32a) face the adjacent magnetic working material (11).
- the magnetic working material (11) to which the magnetic field was first applied absorbs heat as the magnetic field is removed.
- the adjacent magnetic working material (11) generates heat when a magnetic field is applied.
- the magnetic poles (24) of the magnetic field applying section (20) may be arranged radially outward of the magnetic working material (11).
- the magnetic field applying section (20) is arranged radially outside the plurality of magnetic working substances (11).
- the magnetic field applying section (20) has a core (21) and a magnetic pole (24).
- the core (21) has a plurality of protrusions (23).
- the plurality of protrusions (23) protrude radially outward from the central portion of the core (21).
- the protrusion (23) extends from the radially inner side to the radially outer side of the magnetic working material (11) through below the magnetic working material (11) in FIG.
- a standing portion (50) is provided at the tip of the protrusion (23).
- the erected portion (50) is erected along the outer peripheral surface of the magnetic working material (11) to a position facing the magnetic working material (11).
- the standing portion (50) is arranged radially away from the magnetic working material (11).
- a first magnet (25) and a second magnet (26) are arranged between the magnetic working substance (11) and the standing portion (50) of the core (21).
- the first magnet (25) and the second magnet (26) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the magnetic working substance (11) and the magnetic pole (24) of the magnetic field applying section (20) are arranged with a gap in the radial direction.
- the first magnet (25) and the second magnet (26) are axially spaced apart.
- the core (30) has a first core (31), a second core (32) and a permanent magnet (34).
- the first core (31) is composed of a plate-like member.
- the first core (31) is provided with a plurality of first protrusions (31a).
- the first protrusion (31a) is arranged radially away from the magnetic working material (11).
- the second core (32) has a plurality of projections (23) and standing portions (50).
- the protrusion (23) extends from the radially inner side to the radially outer side of the magnetic working material (11) through below the magnetic working material (11) in FIG.
- An upright portion (50) is provided at the tip of the protrusion (23).
- the erected portion (50) is erected along the outer peripheral surface of the magnetic working material (11) to a position facing the lower end of the magnetic working material (11).
- the standing portion (50) is arranged radially away from the magnetic working material (11).
- a second projecting portion (32a) is provided on the standing portion (50).
- the second protrusion (32a) protrudes radially inward from the tip of the standing portion (50).
- the second projection (32a) is arranged radially away from the magnetic working material (11).
- the first core (31) and the second core (32) are spaced apart in the axial direction.
- a permanent magnet (34) is sandwiched between the first core (31) and the second core (32).
- the first protrusion (31a) and the second protrusion (32a) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the magnetic pole (24) of the magnetic field applying section (20) may be composed of the first magnet (25) and the magnetic pole protrusion (51).
- the magnetic field applying section (20) is arranged radially inside the plurality of magnetic working substances (11).
- the magnetic field applying section (20) has a core (21) and a magnetic pole (24).
- the core (21) has a plurality of protrusions (23).
- the plurality of protrusions (23) protrude radially outward from the central portion of the core (21).
- the projection (23) is arranged radially away from the magnetic working material (11).
- a first magnet (25) and a magnetic pole protrusion (51) are arranged between the magnetic working substance (11) and the protrusion (23) of the core (21).
- the magnetic pole protrusion (51) protrudes radially outward from the lower end of the protrusion (23) of the core (21).
- the first magnet (25) and the magnetic pole protrusion (51) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the first magnet (25) and the magnetic pole protrusion (51) are axially spaced apart.
- the magnetic pole (24) of the magnetic field applying section (20) is arranged radially inward (one end side in the second direction) of the magnetic working material (11) and axially (first end side) of the magnetic working material (11). 3 directions).
- the magnetic field applying section (20) is arranged radially inside the plurality of magnetic working substances (11).
- the magnetic field applying section (20) has a core (21) and a magnetic pole (24).
- the core (21) has a plurality of protrusions (23).
- the plurality of protrusions (23) protrude radially outward from the central portion of the core (21).
- the projection (23) is arranged radially away from the magnetic working material (11).
- a first magnet (25) is arranged between the magnetic working substance (11) and the protrusion (23) of the core (21).
- a magnetic pole protrusion (51) is provided on the protrusion (23).
- the magnetic pole protrusion (51) protrudes radially outward from the lower end of the protrusion (23).
- the magnetic pole protrusion (51) extends to a position facing the lower surface of the magnetic working material (11). In other words, the magnetic pole projections (51) extend to positions facing the magnetic working material (11) in the axial direction.
- the first magnet (25) and the magnetic pole protrusion (51) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the first magnet (25) and the magnetic pole protrusion (51) are spaced apart in the axial direction.
- the magnetic poles (24) of the magnetic field applying section (20) are arranged on one end side of the magnetic working material (11) in the second direction orthogonal to the first direction and in the third direction.
- the first direction is the circumferential direction
- the second direction is the radial direction
- the third direction is the axial direction.
- one end side in the second direction is the radially inner side of the magnetic working substance (11).
- the magnetic pole (24) is not provided on the other end side in the second direction (the radially outer side of the magnetic working material (11) in FIG. 9).
- the magnetic poles (24) of the magnetic field applying section (20) are arranged radially outward (the other end side in the second direction) of the magnetic working material (11) and in the axial direction (third direction).
- the magnetic field applying section (20) is arranged radially outside the plurality of magnetic working substances (11).
- the magnetic field applying section (20) has a core (21) and a magnetic pole (24).
- the core (21) has a plurality of protrusions (23).
- the plurality of protrusions (23) protrude radially outward from the central portion of the core (21).
- the projection (23) extends from the radially inner side to the radially outer side of the magnetic working material (11) through below the magnetic working material (11) in FIG.
- the protrusion (23) is arranged to have a surface axially facing the magnetic working material (11) in FIG. 10, and extends from the radially inner side to the radially outer side of the magnetic working material (11).
- a standing portion (50) is provided at the tip of the protrusion (23).
- the erected portion (50) is erected along the outer peripheral surface of the magnetic working material (11) to a position facing the magnetic working material (11).
- the standing portion (50) is arranged radially away from the magnetic working material (11).
- a first magnet (25) is arranged between the magnetic working substance (11) and the protrusion (23) of the core (21). In the protrusion (23), the magnetic flux flows in a position facing the magnetic working material (11) in the axial direction.
- the first magnet (25) and the protrusion (23) constitute a magnetic pole (24) of the magnetic field applying section (20).
- the first magnet (25) and the protrusion (23) are spaced apart in the axial direction.
- the magnetic poles (24) of the magnetic field applying section (20) are arranged on the other end side of the second direction orthogonal to the first direction in the magnetic working material (11) and in the third direction.
- the first direction is the circumferential direction
- the second direction is the radial direction
- the third direction is the axial direction.
- the other end side in the second direction is the radially outer side of the magnetic working material (11).
- the magnetic pole (24) is not provided on one end side in the second direction (inward in the radial direction of the magnetic working material (11) in FIG. 10).
- the magnetic pole (24) of the magnetic field applying section (20) is arranged radially inward (one end side in the second direction) of the magnetic working material (11) and It is good also as the structure arrange
- the core (30) has a first core (31), a second core (32) and a permanent magnet (34).
- a 1st core (31) and a 2nd core (32) are comprised by a plate-shaped member.
- the first core (31) and the second core (32) are axially spaced apart.
- a permanent magnet (34) is sandwiched between the first core (31) and the second core (32).
- a plurality of first projections (31a) are provided on the first core (31) at intervals in the circumferential direction.
- the first protrusion (31a) is arranged radially away from the magnetic working material (11).
- a plurality of second protrusions (32a) are provided on the second core (32) at intervals in the circumferential direction.
- the second protrusion (32a) extends to a position facing the lower surface of the magnetic working material (11).
- the second projection (32a) is axially spaced from the magnetic working material (11).
- the first protrusion (31a) and the second protrusion (32a) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the magnetic poles (24) of the magnetic field applying section (20) are arranged on one end side of the magnetic working material (11) in the second direction orthogonal to the first direction and in the third direction.
- the first direction is the circumferential direction
- the second direction is the radial direction
- the third direction is the axial direction.
- one end side in the second direction is the radially inner side of the magnetic working substance (11).
- the magnetic pole (24) is not provided on the other end side in the second direction (the radially outer side of the magnetic working material (11) in FIG. 11).
- the magnetic pole (24) of the magnetic field applying section (20) is arranged radially outward (the other end side in the second direction) of the magnetic working material (11) and the magnetic working material (11). may be arranged in the axial direction (third direction).
- the core (30) has a first core (31), a second core (32) and a permanent magnet (34).
- a 1st core (31) and a 2nd core (32) are comprised by a plate-shaped member.
- the first core (31) and the second core (32) are axially spaced apart.
- a permanent magnet (34) is sandwiched between the first core (31) and the second core (32).
- a plurality of first projections (31a) are provided on the first core (31) at intervals in the circumferential direction.
- the first protrusion (31a) is spaced radially outward from the magnetic working material (11).
- a plurality of second protrusions (32a) are provided on the second core (32) at intervals in the circumferential direction.
- the second protrusion (32a) passes under the magnetic working material (11) and extends from the radially inner side to the radially outer side of the magnetic working material (11).
- the second protrusion (32a) is arranged to have a surface axially facing the magnetic working material (11) and extends from the radially inner side to the radially outer side of the magnetic working material (11).
- the second projection (32a) is axially spaced from the magnetic working material (11).
- the first protrusion (31a) and the second protrusion (32a) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the magnetic poles (24) of the magnetic field applying section (20) are arranged on the other end side of the second direction orthogonal to the first direction in the magnetic working material (11) and in the third direction.
- the first direction is the circumferential direction
- the second direction is the radial direction
- the third direction is the axial direction.
- the other end side in the second direction is the radially outer side of the magnetic working material (11).
- the magnetic pole (24) is not provided on one end side in the second direction (inward in the radial direction of the magnetic working material (11) in FIG. 12).
- Embodiment 1 a plurality of magnetic field applying units (20) and magnetic working substances (11) may be arranged in the axial direction and relatively rotated by one motor (17).
- a plurality of magnetic working materials (11) are arranged at intervals in the circumferential direction.
- eight substantially fan-shaped magnetic working substances (11) are arranged at equal intervals in the circumferential direction.
- the magnetic working material (11) is provided with a yoke (13) having a higher magnetic permeability than the magnetic working material (11).
- the yokes (13) are provided at both radial ends of the magnetic working material (11).
- the magnetic field applying section (20) relatively moves in the first direction with respect to the magnetic working material (11). Specifically, the magnetic field applying section (20) rotates about the axis along with the rotating shaft (16) as the motor (17) rotates. As a result, the magnetic field applying section (20) rotates relative to the magnetic working material (11). That is, the first direction is the circumferential direction.
- the magnetic field applying unit (20) is arranged axially away from the magnetic working material (11).
- the magnetic field applying section (20) applies a magnetic field to the magnetic working material (11).
- the magnetic field applying section (20) has a core (21) and a magnetic pole (24).
- the core (21) is made of a magnetic material.
- a rotary shaft (16) is connected to the center of the core (21).
- the core (21) has a plurality of protrusions (23).
- the plurality of protrusions (23) protrude radially outward from the center of the core (21).
- the plurality of projections (23) are circumferentially spaced apart. In the example shown in FIG. 13, four protrusions (23) are arranged at regular intervals in the circumferential direction.
- the protrusion (23) is axially spaced from the magnetic working material (11).
- the tip of the projection (23) is formed in a substantially fan shape when viewed from the axial direction.
- the magnetic pole (24) of the magnetic field applying section (20) is arranged only on one end side of the magnetic working material (11) in the second direction perpendicular to the first direction.
- the magnetic working material (11) and the magnetic poles (24) of the magnetic field applying section (20) are spaced apart in the axial direction.
- a first magnet (25) and a second magnet (26) are arranged between the magnetic working substance (11) and the protrusion (23) of the core (21).
- the first magnet (25) and the second magnet (26) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the magnetic poles (24) are spaced apart in a third direction orthogonal to the first and second directions in the magnetic working material (11).
- the first direction is the circumferential direction
- the second direction is the axial direction
- the third direction is the radial direction.
- the first magnet (25) and the second magnet (26) that make up the magnetic pole (24) are radially spaced apart.
- the first magnet (25) and the second magnet (26) apply a magnetic field to the magnetic working material (11) such that magnetic flux flows in the radial direction of the magnetic working material (11).
- the first magnet (25) is arranged so that the side of the magnetic working material (11) (upper side in FIG. 15) is the N pole, and the side of the projection (23) of the core (21) (lower side in FIG. 15) is the S pole. placed.
- the second magnet (26) is arranged so that the magnetic working material (11) side (upper side in FIG. 15) is the S pole and the projection (23) side of the core (21) (the lower side in FIG. 15) is the N pole. placed.
- the positional relationship between the N pole and S pole of the first magnet (25) and the second magnet (26) may be reversed.
- the first magnet (25) and the second magnet (26) rotate relative to the magnetic working material (11) in the circumferential direction together with the core (21).
- magnetic flux flows in the radial direction of the magnetic working substance (11).
- the flow of magnetic flux is indicated by dashed arrow lines.
- the first magnet (25) and the second magnet (26) are arranged to face the magnetic working substance (11). Specifically, the first magnet (25) and the second magnet (26) are located on both sides of the magnetic working material (11) in the radial direction when the magnetic working material (11) in which the magnetic flux is flowing is viewed from the axial direction. are respectively arranged along the The magnetic field applying section (20) applies a magnetic field to the magnetic working material (11).
- magnetic flux flows from the first magnet (25) toward the radially inner yoke (13) in FIG.
- a magnetic flux flows radially inside the magnetic working material (11) from the radially inner yoke (13) to the radially outer yoke (13).
- a magnetic flux flows from the radially outer yoke (13) toward the second magnet (26).
- Magnetic flux flows radially through the protrusion (23) of the core (21) from the second magnet (26) toward the first magnet (25).
- the magnetic working material (11) to which the magnetic field is applied generates heat.
- the magnetic field applying section (20) is rotated to bring the first magnet (25) and the second magnet (26) to face the adjacent magnetic working material (11).
- the magnetic working material (11) to which the magnetic field was first applied absorbs heat as the magnetic field is removed.
- the adjacent magnetic working material (11) generates heat when a magnetic field is applied.
- the relative movement is relative rotational movement rotating around a predetermined axis.
- the first direction is the circumferential direction
- the second direction is the axial direction
- the third direction is the radial direction.
- the magnetic working material (11) and the magnetic poles (24) of the magnetic field applying section (20) are spaced apart in the axial direction.
- the magnetic poles (24) of the magnetic field applying section (20) are spaced apart in the radial direction.
- the magnetic flux can flow along the radial direction of the magnetic working material (11).
- the magnetic pole (24) of the magnetic field applying section (20) may be composed of the first protrusion (35) and the second protrusion (36).
- the magnetic field applying section (20) has a core (21) and a permanent magnet (34).
- the core (21) has a plurality of protrusions (23).
- a first protrusion (35) and a second protrusion (36) are provided at the tip of the protrusion (23).
- the first protrusion (35) and the second protrusion (36) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the first protrusion (35) and the second protrusion (36) protrude toward the magnetic working material (11).
- the first protrusion (35) and the second protrusion (36) are radially spaced apart.
- the first protrusion (35) is arranged radially inward of the second protrusion (36).
- a permanent magnet (34) is embedded between the first protrusion (35) and the second protrusion (36) in the protrusion (23).
- the permanent magnet (34) has an N pole on the side of the first protrusion (35) (inward in the radial direction in FIG. 16), and a N pole on the side of the second protrusion (36) (outside in the radial direction in FIG. 16). is arranged to be the S pole.
- the positional relationship between the N pole and the S pole of the permanent magnet (34) may be reversed.
- the first projecting portion (35) and the second projecting portion (36) extend along both radial sides of the magnetic working material (11) when the magnetic working material (11) in which the magnetic flux is flowing is viewed from the axial direction. are placed respectively.
- the magnetic field applying section (20) applies a magnetic field to the magnetic working substance (11).
- magnetic flux flows from the permanent magnet (34) toward the first protrusion (35) of the core (21). Magnetic flux flows from the first protrusion (35) toward the yoke (13) radially inward in FIG. A magnetic flux flows radially inside the magnetic working material (11) from the radially inner yoke (13) to the radially outer yoke (13). A magnetic flux flows from the radially outer yoke (13) toward the second protrusion (36). A magnetic flux flows from the second protrusion (36) toward the permanent magnet (34). As a result, the magnetic working material (11) to which the magnetic field is applied generates heat.
- the magnetic field applying part (20) is rotationally moved so that the first protrusion (35) and the second protrusion (36) face the adjacent magnetic working material (11).
- the magnetic working material (11) to which the magnetic field was first applied absorbs heat as the magnetic field is removed.
- the adjacent magnetic working material (11) generates heat when a magnetic field is applied.
- the magnetic pole (24) of the magnetic field applying section (20) may be composed of the first magnet (25) and the magnetic pole protrusion (51).
- the magnetic field applying section (20) has a core (21) and magnetic poles (24).
- the core (21) has a plurality of protrusions (23).
- the plurality of protrusions (23) protrude radially outward from the central portion of the core (21).
- the protrusion (23) is axially spaced from the magnetic working material (11).
- a first magnet (25) and a magnetic pole protrusion (51) are arranged between the magnetic working material (11) and the protrusion (23) of the core (21).
- the magnetic pole protrusion (51) protrudes from the protrusion (23) of the core (21) toward the magnetic working material (11).
- the first magnet (25) and the magnetic pole protrusion (51) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the first magnet (25) and the magnetic pole protrusion (51) are radially spaced apart.
- the magnetic poles (24) of the magnetic field applying section (20) are positioned axially downward (one end side in the second direction) of the magnetic working material (11) and radially outward of the magnetic working material (11). (the other end side in the third direction).
- the magnetic field applying section (20) has a core (21) and magnetic poles (24).
- the core (21) has a plurality of protrusions (23).
- the plurality of protrusions (23) protrude radially outward from the central portion of the core (21).
- the protrusion (23) is axially spaced from the magnetic working material (11).
- a first magnet (25) is arranged between the magnetic working substance (11) and the protrusion (23) of the core (21).
- the protrusion (23) extends from the radially inner side to the radially outer side of the magnetic working material (11) through below the magnetic working material (11).
- the projecting portion (23) is provided with an upright portion (50).
- the standing portion (50) extends along the outer peripheral surface of the magnetic working material (11) to a position facing the magnetic working material (11) in the radial direction.
- the standing portion (50) is arranged radially away from the magnetic working material (11).
- the first magnet (25) and the standing portion (50) constitute the magnetic pole (24) of the magnetic field applying portion (20).
- the magnetic poles (24) of the magnetic field applying section (20) are arranged on one end side of the magnetic working material (11) in the second direction orthogonal to the first direction and on the other end side of the third direction.
- the first direction is the circumferential direction
- the second direction is the axial direction
- the third direction is the radial direction.
- One end side in the second direction is the axial lower side of the magnetic working material (11).
- the magnetic pole (24) is not provided on the other end side in the second direction (the axial direction upper side of the magnetic working material (11) in FIG. 18).
- the other end side in the third direction is the radially outer side of the magnetic working material (11).
- the magnetic pole (24) is not provided on one end side in the third direction (inward in the radial direction of the magnetic working substance (11) in FIG. 18).
- the magnetic poles (24) of the magnetic field applying section (20) are positioned axially below the magnetic working material (11) (one end side in the second direction) and radially inside the magnetic working material (11). (One end side in the third direction) may be arranged on the other side.
- the magnetic field applying section (20) is arranged axially away from the magnetic working material (11).
- the magnetic field applying section (20) has a core (21) and a magnetic pole (24).
- the core (21) has a plurality of protrusions (23).
- the plurality of protrusions (23) protrude radially outward from the central portion of the core (21).
- the protrusion (23) is axially spaced from the magnetic working material (11).
- a first magnet (25) is arranged between the magnetic working substance (11) and the protrusion (23) of the core (21).
- the projecting portion (23) is provided with an upright portion (50).
- the standing portion (50) extends along the inner peripheral surface of the magnetic working material (11) to a position facing the magnetic working material (11) in the radial direction.
- the standing portion (50) is arranged radially away from the magnetic working material (11).
- the first magnet (25) and the standing portion (50) constitute the magnetic pole (24) of the magnetic field applying portion (20).
- the magnetic poles (24) of the magnetic field applying section (20) are arranged on one end side of the magnetic working material (11) in the second direction orthogonal to the first direction and one end side of the third direction.
- the first direction is the circumferential direction
- the second direction is the axial direction
- the third direction is the radial direction.
- One end side in the second direction is the axial lower side of the magnetic working material (11).
- the magnetic pole (24) is not provided on the other end side in the second direction (upper axial direction of the magnetic working substance (11) in FIG. 19).
- one end side in the third direction is the radially inner side of the magnetic working material (11).
- the magnetic pole (24) is not provided on the other end side in the third direction (the radially outer side of the magnetic working material (11) in FIG. 19).
- the magnetic pole (24) of the magnetic field applying section (20) is arranged below the magnetic working material (11) in the axial direction (one end side in the second direction) and on the magnetic working material (11). may be arranged radially outside (the other end side in the third direction).
- the magnetic field applying section (20) has a core (21) and a permanent magnet (34).
- the core (21) has a plurality of protrusions (23).
- the protrusion (23) extends from the radially inner side to the radially outer side of the magnetic working material (11) through below the magnetic working material (11).
- the protrusion (23) is provided with a first protrusion (35) and a second protrusion (36).
- the first protrusion (35) and the second protrusion (36) are radially spaced apart.
- the first protrusion (35) is arranged radially inward of the second protrusion (36).
- a permanent magnet (34) is embedded between the first protrusion (35) and the second protrusion (36) in the protrusion (23).
- the first protrusion (35) is arranged below the magnetic working material (11).
- the second protrusion (36) extends from the protrusion (23) along the outer peripheral surface of the magnetic working material (11) to a position facing the magnetic working material (11) in the radial direction.
- the second projection (36) is radially spaced from the magnetic working material (11). Magnetic flux flows through the second protrusion (36) at a position facing the outer peripheral surface of the magnetic working material (11).
- the first protrusion (35) and the second protrusion (36) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the magnetic poles (24) of the magnetic field applying section (20) are arranged on one end side of the magnetic working material (11) in the second direction orthogonal to the first direction and on the other end side of the third direction.
- the first direction is the circumferential direction
- the second direction is the axial direction
- the third direction is the radial direction.
- One end side in the second direction is the axial lower side of the magnetic working material (11).
- the magnetic pole (24) is not provided on the other end side in the second direction (the axial direction upper side of the magnetic working material (11) in FIG. 20).
- the other end side in the third direction is the radially outer side of the magnetic working material (11).
- the magnetic pole (24) is not provided on one end side in the third direction (inward in the radial direction of the magnetic working material (11) in FIG. 20).
- the magnetic pole (24) of the magnetic field applying section (20) is arranged below the magnetic working material (11) in the axial direction (one end side in the second direction) and on the magnetic working material (11). may be arranged radially inside (one end side in the third direction).
- the magnetic field applying section (20) has a core (21) and a permanent magnet (34).
- the core (21) has a plurality of protrusions (23).
- the protrusion (23) is axially spaced from the magnetic working material (11).
- the protrusion (23) is provided with a first protrusion (35) and a second protrusion (36).
- the first protrusion (35) and the second protrusion (36) are radially spaced apart.
- the first protrusion (35) is arranged radially inward of the second protrusion (36).
- a permanent magnet (34) is embedded between the first protrusion (35) and the second protrusion (36) in the protrusion (23).
- the first protrusion (35) extends from the projection (23) to a position radially facing the magnetic working material (11) along the outer peripheral surface of the magnetic working material (11).
- the first protrusion (35) is arranged radially away from the magnetic working material (11). Magnetic flux flows through the first protrusion (35) at a position facing the outer peripheral surface of the magnetic working material (11).
- the second projection (36) is arranged below the magnetic working material (11).
- the first protrusion (35) and the second protrusion (36) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the magnetic poles (24) of the magnetic field applying section (20) are arranged on one end side of the magnetic working material (11) in the second direction orthogonal to the first direction and on the other end side of the third direction.
- the first direction is the circumferential direction
- the second direction is the axial direction
- the third direction is the radial direction.
- One end side in the second direction is the axial lower side of the magnetic working material (11).
- the magnetic pole (24) is not provided on the other end side in the second direction (the axial direction upper side of the magnetic working material (11) in FIG. 21).
- one end side in the third direction is the radially inner side of the magnetic working material (11).
- the magnetic pole (24) is not provided on the other end side in the third direction (the radially outer side of the magnetic working material (11) in FIG. 21).
- a plurality of magnetic field applying units (20) and magnetic working substances (11) may be arranged in the axial direction and relatively rotated by one motor (17).
- a plurality of magnetic field applying units (20) and magnetic working materials (11) may be arranged in the radial direction and relatively rotated by one motor (17).
- the magnetic refrigerator (10) includes a magnetic working material (11), a magnetic field applying section (20), and a linear motion mechanism (40).
- the linear motion mechanism (40) has a cylinder (41) and a cylinder rod (42).
- the cylinder rod (42) advances and retreats in the axial direction with respect to the cylinder (41).
- a magnetic field applying section (20) is connected to the cylinder rod (42).
- the magnetic field applying section (20) moves relative to the magnetic working substance (11) in the first direction. Specifically, the magnetic field applying section (20) moves linearly in the first direction together with the cylinder rod (42) as the cylinder (41) is driven. As a result, the magnetic field applying section (20) moves linearly relative to the magnetic working substance (11). That is, the first direction is the axial direction of the cylinder rod (42).
- Two magnetic working substances (11) are arranged with an interval in the first direction.
- the magnetic working substance (11) is spaced apart from the magnetic field applying section (20) in a second direction (horizontal direction in FIG. 22) orthogonal to the first direction.
- the magnetic working material (11) is provided with a yoke (13) having a higher magnetic permeability than the magnetic working material (11).
- the yokes (13) are provided at both ends of the magnetic working material (11) in a third direction (vertical direction in FIG. 23) orthogonal to the first direction and the second direction.
- the magnetic field application unit (20) applies a magnetic field to the magnetic working substance (11).
- the magnetic field applying section (20) has a core (21) and a magnetic pole (24).
- the core (21) is made of a magnetic material.
- a cylinder rod (42) is connected to the core (21).
- the magnetic pole (24) of the magnetic field applying section (20) is arranged on one end side of the magnetic working material (11) in the second direction (horizontal direction in FIG. 23).
- the magnetic working material (11) and the magnetic pole (24) of the magnetic field applying section (20) are spaced apart in the second direction.
- the magnetic poles (24) of the magnetic field applying section (20) are spaced apart in the third direction (vertical direction in FIG. 23) of the core (21). Specifically, a first magnet (25) and a second magnet (26) are arranged between the magnetic working material (11) and the core (21). The first magnet (25) and the second magnet (26) are spaced apart in the third direction. The first magnet (25) and the second magnet (26) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the first magnet (25) and the second magnet (26) apply a magnetic field to the magnetic working material (11) so that magnetic flux flows in the third direction of the magnetic working material (11).
- the first magnet (25) is arranged so that the magnetic working substance (11) side (left side in FIG. 23) is the N pole, and the core (21) side (the right side in FIG. 23) is the S pole.
- the second magnet (26) is arranged so that the magnetic working substance (11) side (left side in FIG. 23) is the S pole and the core (21) side (the right side in FIG. 23) is the N pole.
- the positional relationship between the N pole and S pole of the first magnet (25) and the second magnet (26) may be reversed.
- the first magnet (25) and the second magnet (26) move linearly relative to the magnetic working material (11) together with the core (21) in the first direction.
- magnetic flux flows in the third direction of the magnetic working material (11). The flow of magnetic flux is indicated by dashed arrow lines.
- the first magnet (25) and the second magnet (26) are arranged to face the magnetic working substance (11). Specifically, the first magnet (25) and the second magnet (26) move in the third direction of the magnetic working substance (11) when the magnetic working substance (11) in which the magnetic flux is flowing is viewed from the second direction. are placed along each end of the .
- the magnetic field applying section (20) applies a magnetic field to the magnetic working substance (11).
- magnetic flux flows from the first magnet (25) toward the upper yoke (13) in FIG.
- a magnetic flux flows along the third direction inside the magnetic working material (11) from the upper yoke (13) toward the lower yoke (13).
- Magnetic flux flows from the lower yoke (13) toward the second magnet (26).
- Magnetic flux flows in the core (21) along the third direction from the second magnet (26) toward the first magnet (25).
- the magnetic working material (11) to which the magnetic field is applied generates heat.
- the magnetic field applying section (20) is linearly moved to make the first magnet (25) and the second magnet (26) face the adjacent magnetic working material (11).
- the magnetic working material (11) to which the magnetic field was first applied absorbs heat as the magnetic field is removed.
- the adjacent magnetic working material (11) generates heat when a magnetic field is applied.
- the relative movement is relative linear movement that moves linearly along the first direction.
- the magnetic working material (11) and the magnetic pole (24) of the magnetic field applying section (20) are spaced apart in the second direction.
- the magnetic poles (24) of the magnetic field applying section (20) are spaced apart in the third direction.
- the magnetic pole (24) of the magnetic field applying section (20) is composed of the first protrusion (31a) of the first core (31) and the second protrusion (32a) of the second core (32).
- the core (30) has a first core (31), a second core (32) and a permanent magnet (34).
- a 1st core (31) and a 2nd core (32) are comprised by a plate-shaped member.
- the first core (31) and the second core (32) are spaced apart in the third direction (vertical direction in FIG. 25).
- a permanent magnet (34) is sandwiched between the first core (31) and the second core (32).
- the permanent magnet (34) has an N pole on the first core (31) side (upper side in FIG. 25) and an S pole on the second core (32) side (lower side in FIG. 25). are arranged as follows. The positional relationship between the N pole and the S pole of the permanent magnet (34) may be reversed.
- a first protrusion (31a) is provided on the first core (31).
- the second core (32) is provided with a second protrusion (32a).
- the first core (31) and the second core (32) are formed in the same shape and at the same position when viewed from the axial direction.
- the first protrusion (31a) and the second protrusion (32a) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the magnetic flux flows in the third direction (vertical direction in FIG. 25) of the magnetic working material (11). .
- the flow of magnetic flux is indicated by dashed arrow lines.
- magnetic flux flows from the permanent magnet (34) toward the first protrusion (31a) of the first core (31).
- Magnetic flux flows from the first protrusion (31a) toward the upper yoke (13) in FIG.
- a magnetic flux flows along the third direction (vertical direction in FIG. 25) inside the magnetic working material (11) from the upper yoke (13) toward the lower yoke (13).
- Magnetic flux flows from the lower yoke (13) toward the second protrusion (32a) of the second core (32).
- Magnetic flux flows from the second protrusion (32a) toward the permanent magnet (34).
- the magnetic working material (11) to which the magnetic field is applied generates heat.
- the magnetic field applying part (20) is linearly moved, and the first protrusion (31a) and the second protrusion (32a) are opposed to the adjacent magnetic working material (11).
- the magnetic working material (11) to which the magnetic field was first applied absorbs heat as the magnetic field is removed.
- the adjacent magnetic working material (11) generates heat when a magnetic field is applied.
- the magnetic pole (24) of the magnetic field applying section (20) may be composed of the first magnet (25) and the magnetic pole protrusion (51).
- the magnetic field applying section (20) has a core (21) and magnetic poles (24).
- the magnetic pole (24) of the magnetic field applying section (20) is arranged on one end side of the magnetic working material (11) in the second direction (horizontal direction in FIG. 26).
- the magnetic working material (11) and the magnetic pole (24) of the magnetic field applying section (20) are spaced apart in the second direction.
- a first magnet (25) and a magnetic pole protrusion (51) are arranged between the magnetic working substance (11) and the core (21).
- the magnetic pole protrusion (51) protrudes radially inward from the lower end of the core (21).
- the first magnet (25) and the magnetic pole protrusion (51) are spaced apart in the third direction (vertical direction in FIG. 26).
- the first magnet (25) and the magnetic pole protrusion (51) constitute the magnetic pole (24) of the magnetic field applying section (20).
- Magnetic flux flow is indicated by dashed arrow lines.
- the magnetic pole (24) of the magnetic field applying section (20) is arranged on one end side of the magnetic working material (11) in the second direction and in the third direction of the magnetic working material (11). good too.
- the magnetic field applying section (20) has a core (21) and magnetic poles (24).
- the magnetic pole (24) of the magnetic field applying section (20) is located on one end side (right side in FIG. 27) of the magnetic working material (11) in the second direction (horizontal direction in FIG. 27) and on the third side of the magnetic working material (11). It is arranged on one end side (lower side in FIG. 27) of the direction (vertical direction in FIG. 27).
- a first magnet (25) is arranged between the magnetic working material (11) and the core (21).
- a first magnet (25) is spaced apart in a second direction relative to the magnetic working material (11).
- the core (21) is provided with a magnetic pole protrusion (51).
- the magnetic pole protrusion (51) protrudes radially inward from the lower end of the core (21).
- the magnetic pole protrusion (51) extends below the magnetic working material (11) to a position facing the magnetic working material (11).
- the magnetic pole projection (51) is spaced apart from the magnetic working material (11) in the third direction.
- the first magnet (25) and the magnetic pole protrusion (51) constitute the magnetic pole (24) of the magnetic field applying section (20).
- Magnetic flux flow is indicated by dashed arrow lines.
- the magnetic pole (24) of the magnetic field applying section (20) is located on one end side (the right side in FIG. 27) in the second direction orthogonal to the first direction in the magnetic working material (11) and one end side (the right side in FIG. 27) in the third direction ( bottom) and .
- the magnetic pole (24) is not provided on the other end side in the second direction (left side in FIG. 27).
- the magnetic pole (24) is not provided on the other end side (upper side in FIG. 27) in the third direction.
- the magnetic pole (24) of the magnetic field applying section (20) is arranged on one end side of the magnetic working material (11) in the second direction and in the third direction of the magnetic working material (11). It is good also as the arrangement
- the core (30) has a first core (31), a second core (32) and a permanent magnet (34).
- the first core (31) and the second core (32) are spaced apart in the third direction (vertical direction in FIG. 28).
- a permanent magnet (34) is sandwiched between the first core (31) and the second core (32).
- a first protrusion (31a) is provided on the first core (31).
- the first protrusion (31a) is spaced apart from the magnetic working material (11) in the second direction (horizontal direction in FIG. 28).
- a second protrusion (32a) is provided on the second core (32).
- the second projection (32a) extends below the magnetic working material (11) to a position facing the magnetic working material (11).
- the magnetic pole projection (51) is spaced apart from the magnetic working material (11) in the third direction.
- the first protrusion (31a) and the second protrusion (32a) constitute the magnetic pole (24) of the magnetic field applying section (20).
- Magnetic flux flow is indicated by dashed arrow lines.
- the magnetic pole (24) of the magnetic field applying section (20) is located on one end side (the right side in FIG. 28) in the second direction perpendicular to the first direction in the magnetic working material (11) and one end side (the right side in FIG. 28) in the third direction ( bottom) and .
- the magnetic pole (24) is not provided on the other end side in the second direction (left side in FIG. 28).
- the magnetic pole (24) is not provided on the other end side (upper side in FIG. 28) in the third direction.
- Embodiment 3 a plurality of magnetic field applying units (20) and magnetic working substances (11) may be arranged and relatively linearly moved by one cylinder (41).
- a plurality of magnetic working materials (11) are arranged at intervals in the circumferential direction.
- eight magnetic working substances (11) extending in an arc shape along the circumferential direction are arranged at equal intervals in the circumferential direction.
- the magnetic field applying unit (20) is arranged radially inside the plurality of magnetic working substances (11).
- the magnetic field applying section (20) relatively moves in the first direction (circumferential direction) with respect to the magnetic working substance (11).
- the magnetic field applying section (20) applies a magnetic field to the magnetic working substance (11).
- the magnetic field applying section (20) has a core (21) and magnetic poles (24).
- the core (21) has a plurality of protrusions (23).
- the plurality of protrusions (23) protrude radially outward from the central portion of the core (21).
- the plurality of projections (23) are circumferentially spaced apart. In the example shown in FIG. 29, two protrusions (23) are arranged at regular intervals in the circumferential direction.
- the magnetic pole (24) of the magnetic field applying section (20) is arranged on one end side of the magnetic working material (11) in the second direction (radial direction) perpendicular to the first direction.
- a first magnet (25) and a second magnet (26) are arranged between the magnetic working material (11) and the protrusion (23) of the core (21).
- the first magnet (25) and the second magnet (26) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the magnetic poles (24) are spaced apart in a third direction (axial direction) orthogonal to the first and second directions in the magnetic working material (11).
- the length W1 of the surface facing the magnetic working material (11) in the magnetic pole (24) of the magnetic field applying part (20) in the first direction (circumferential direction) is the magnetic field applying part ( 20) is greater than the length W2 of the surface facing the magnetic pole (24) in the first direction (circumferential direction).
- the length of the surface facing the magnetic working material (11) in the magnetic pole (24) of the magnetic field applying section (20) in the first direction is equal to greater than the length of the surface of (20) facing the magnetic pole (24) in the first direction.
- the alignment accuracy between the magnetic working material (11) and the magnetic pole (24) of the magnetic field applying section (20) can be lowered without increasing the magnetic resistance.
- the magnetic poles (24) of the magnetic field applying section (20) may be arranged radially outward of the magnetic working material (11).
- the magnetic field applying section (20) is arranged radially outside the plurality of magnetic working substances (11).
- the magnetic field applying section (20) has a core (21) and a magnetic pole (24).
- the core (21) has a plurality of protrusions (23).
- the protrusion (23) extends from the radially inner side to the radially outer side of the magnetic working material (11) through below the magnetic working material (11).
- a standing portion (50) is provided at the tip of the protrusion (23).
- the erected portion (50) is erected along the outer peripheral surface of the magnetic working material (11) to a position facing the magnetic working material (11).
- the standing portion (50) is arranged radially away from the magnetic working material (11).
- a first magnet (25) and a second magnet (26) are arranged between the magnetic working substance (11) and the standing portion (50) of the core (21).
- the first magnet (25) and the second magnet (26) are axially spaced apart.
- the first magnet (25) and the second magnet (26) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the magnetic working substance (11) and the magnetic pole (24) of the magnetic field applying section (20) are arranged with a gap in the radial direction.
- Magnetic flux flow is indicated by dashed arrow lines.
- Embodiment 4 a plurality of magnetic field applying units (20) and magnetic working substances (11) may be arranged in the axial direction and relatively rotated by one motor (17).
- Embodiment 5 ⁇ Embodiment 5>> Embodiment 5 will be described.
- a plurality of magnetic working substances (11) are arranged at intervals in the circumferential direction.
- eight substantially fan-shaped magnetic working substances (11) are arranged at equal intervals in the circumferential direction.
- the magnetic field applying unit (20) is arranged axially away from the magnetic working material (11). As also shown in FIG. 32, the magnetic field applying section (20) relatively moves in the first direction (circumferential direction) with respect to the magnetic working material (11). The magnetic field applying section (20) applies a magnetic field to the magnetic working material (11).
- the magnetic field applying section (20) has a core (21) and magnetic poles (24).
- the core (21) has a plurality of protrusions (23).
- the plurality of protrusions (23) protrude radially outward from the central portion of the core (21).
- the plurality of projections (23) are circumferentially spaced apart. In the example shown in FIG. 32, two protrusions (23) are arranged at regular intervals in the circumferential direction.
- the tip of the projection (23) is formed in a substantially fan shape when viewed from the axial direction.
- the magnetic pole (24) of the magnetic field applying section (20) is arranged on one end side of the magnetic working material (11) in the second direction (axial direction) orthogonal to the first direction.
- a first magnet (25) and a second magnet (26) are arranged between the magnetic working material (11) and the protrusion (23) of the core (21).
- the first magnet (25) and the second magnet (26) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the magnetic poles (24) are spaced apart in a third direction (radial direction) orthogonal to the first and second directions in the magnetic working material (11).
- the length W1 of the surface facing the magnetic working material (11) in the magnetic pole (24) of the magnetic field applying part (20) in the first direction (circumferential direction) is the magnetic field applying part ( 20) is greater than the length W2 of the surface facing the magnetic pole (24) in the first direction (circumferential direction).
- the length of the surface facing the magnetic working material (11) in the magnetic pole (24) of the magnetic field applying section (20) in the first direction is equal to greater than the length of the surface of (20) facing the magnetic pole (24) in the first direction.
- the alignment accuracy between the magnetic working material (11) and the magnetic pole (24) of the magnetic field applying section (20) can be lowered without increasing the magnetic resistance.
- a plurality of magnetic field applying units (20) and magnetic working substances (11) may be arranged in the axial direction and relatively rotated by one motor (17).
- a plurality of magnetic field applying units (20) and magnetic working materials (11) may be arranged in the radial direction and relatively rotated by one motor (17).
- the magnetic field applying section (20) has a core (21), magnetic poles (24), and holding members (55).
- the core (21) is made of a magnetic material.
- a holding member (55) is provided at the center of the core (21).
- the core (21) is held by a holding member (55).
- the core (21) has a plurality of protrusions (23).
- the plurality of protrusions (23) protrude radially outward from the central portion of the core (21).
- the projection (23) is arranged radially away from the magnetic working material (11).
- the holding member (55) is composed of a cylindrical member.
- the holding member (55) is made of a non-magnetic material.
- the holding member (55) is made of, for example, aluminum or resin.
- the rotating shaft (16) is connected to the center of the holding member (55).
- a first magnet (25) and a second magnet (26) are arranged between the magnetic working substance (11) and the protrusion (23) of the core (21).
- the first magnet (25) and the second magnet (26) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the first magnet (25) and the second magnet (26) are axially spaced apart.
- the core (21) made of magnetic material is held by the holding member (55) made of non-magnetic material. is applicable.
- the core (21) through which the magnetic flux flows is made of a magnetic material, and the core (21) is held by the holding member (55) made of a non-magnetic material. Magnetic flux leakage between adjacent magnetic poles (24) can be further reduced. Further, by adopting a member (for example, aluminum or resin) whose weight per unit volume is lighter than that of the core (21) as the holding member (55), the weight of the entire magnetic refrigerator (10) can be reduced. can.
- a member for example, aluminum or resin
- the magnetic field applying section (20) may be formed in a cylindrical shape.
- the magnetic field applying section (20) has a core (21), magnetic poles (24), and holding members (55).
- the core (21) is made of a magnetic material.
- a holding member (55) is provided at the center of the core (21).
- the core (21) is held by a holding member (55).
- the core (21) has a plurality of protrusions (23).
- the plurality of protrusions (23) protrude radially outward from the central portion of the core (21).
- the projection (23) is arranged radially away from the magnetic working material (11).
- a first magnet (25) and a second magnet (26) are arranged between the magnetic working substance (11) and the protrusion (23) of the core (21).
- the first magnet (25) and the second magnet (26) constitute the magnetic pole (24) of the magnetic field applying section (20).
- the first magnet (25) and the second magnet (26) are axially spaced apart.
- the holding member (55) is provided between the central portion of the core (21), between the plurality of protrusions (23) spaced apart in the circumferential direction, and the first magnet (25) that constitutes the magnetic pole (24). and the second magnet (26).
- the holding member (55) is made of a non-magnetic material.
- the holding member (55) is made of, for example, aluminum or resin.
- the holding member (55) provided at the center of the core (21) is composed of a cylindrical member.
- the rotating shaft (16) is connected to the center of the holding member (55). Further, the holding member (55) is provided between the plurality of projections (23) and between the first magnet (25) and the second magnet (26), so that the magnetic field applying portion (20) has a columnar shape. formed in
- the first magnet (25) and the second magnet (26) are arranged to face the magnetic working material (11), but the present invention is not limited to this form.
- the magnetic pole (24) of the magnetic field applying section (20) may be arranged so as not to overlap the magnetic working material (11) when viewed from the third direction.
- the first magnet (25) and the second magnet (26) that make up the magnetic pole (24) are arranged apart from the magnetic working substance (11) in the third direction when viewed from the second direction.
- the magnetic working material (11) may be arranged in the magnetic gap between the magnetic poles (24) at a position not overlapping the magnetic working material (11) when viewed from the third direction.
- the configuration in which the yokes (13) are provided at both ends of the magnetic working material (11) in the third direction in order to uniformly apply a magnetic field to the magnetic working material (11) has been described. It is not limited to this form. Since the magnetic permeability of the magnetic working material (11) is higher than that of vacuum (air), the yoke (13) may not be provided at both ends of the magnetic working material (11) in the third direction. Alternatively, the yoke (13) may be provided at one end of the magnetic working material (11) in the third direction, and the yoke (13) may not be provided at the other end.
- the magnetic poles (24) of the magnetic field applying section (20) are configured using permanent magnets, but may be configured using electromagnets, for example.
- the number of magnetic poles (24) of the magnetic field applying section (20) and the number of magnetic working substances (11) were specifically explained based on the drawings, but the present invention is not limited to this form.
- the number of magnetic poles (24) of the magnetic field applying section (20) and the number of magnetic working substances (11) may be appropriately selected.
- the magnetic field applying unit (20) is rotated or linearly moved in order to move the magnetic field applying unit (20) relative to the magnetic working substance (11) in the first direction. It is not limited to this form. It may be configured to rotate or linearly move the magnetic working material (11).
- the shapes of the magnetic working substance (11) and the yoke (13) have been specifically described based on the drawings, but they are not limited to this form.
- the shape of the magnetic working material (11) and the yoke (13) can be any shape as long as it fits in the space between the magnetic poles (24).
- the present disclosure is useful for magnetic refrigerators and refrigerators.
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Abstract
Description
実施形態1について説明する。
低温側熱交換器(3)は、磁気冷凍装置(10)で冷却された熱媒体と、所定の冷却対象(例えば、二次冷媒や空気など)とを熱交換させる。高温側熱交換器(4)は、磁気冷凍装置(10)で加熱された熱媒体と、所定の加熱対象(例えば、二次冷媒や空気など)とを熱交換させる。
ポンプ(5)は、第1動作と、第2動作とを交互に繰り返し行う。第1動作では、熱媒体回路(2)の熱媒体を図1で左方向に搬送する。第2動作では、熱媒体回路(2)の熱媒体を図1で右方向に搬送する。ポンプ(5)は、熱媒体回路(2)の熱媒体を往復的に流動させる搬送機構を構成する。
冷凍装置(1)は、制御部(8)を備える。制御部(8)は、所定の運転指令に応じて、ポンプ(5)及び磁気冷凍装置(10)の動作を制御する。制御部(8)は、マイクロコンピュータと、マイクロコンピュータを動作させるためのソフトウエアを格納するメモリデバイス(具体的には半導体メモリ)とを用いて構成される。
図2及び図3に示すように、磁気冷凍装置(10)は、磁気作業物質(11)と、磁場印加部(20)と、回転機構(15)とを備える。
冷凍装置(1)の基本的な運転動作について、図1を用いて説明する。冷凍装置(1)は、加熱動作と、冷却動作とを交互に繰り返し行う。加熱動作と冷却動作とを切り換える周期は、例えば、0.1秒から1秒程度に設定される。
加熱動作では、ポンプ(5)が第1動作を行うとともに、磁場印加部(20)が第1磁場印加動作を行う。つまり、加熱動作では、ポンプ(5)の第1ポート(6a)から熱媒体が吐出される。同時に、磁気作業物質(11)に磁場が印加される。
冷却動作では、ポンプ(5)が第2動作を行うとともに、磁場印加部(20)が第2磁場印加動作を行う。つまり、加熱動作では、ポンプ(5)の第2ポート(6b)から熱媒体が吐出されると同時に、磁気作業物質(11)の磁場が取り除かれる。
本実施形態の特徴によれば、磁場印加部(20)は、磁気作業物質(11)に対して第1方向に相対移動する。磁場印加部(20)の磁極(24)は、磁気作業物質(11)における第1方向に直交する第2方向の一端側のみに配置される。さらに、磁場印加部(20)の磁極(24)は、磁気作業物質(11)における第1方向及び第2方向に直交する第3方向に間隔をあけて設けられる。
実施形態1において、磁場印加部(20)の磁極(24)を、第1コア(31)の第1突部(31a)及び第2コア(32)の第2突部(32a)で構成してもよい。
実施形態1において、磁場印加部(20)の磁極(24)を、磁気作業物質(11)の径方向外側に配置した構成としてもよい。
実施形態1の変形例2において、磁場印加部(20)の磁極(24)を、第1コア(31)の第1突部(31a)及び第2コア(32)の第2突部(32a)で構成してもよい。
前記実施形態1において、磁場印加部(20)の磁極(24)を、第1磁石(25)と、磁極突起部(51)と、で構成してもよい。
前記実施形態1において、磁場印加部(20)の磁極(24)を、磁気作業物質(11)の径方向内側(第2方向の一端側)と、磁気作業物質(11)の軸方向(第3方向)とに配置した構成としてもよい。
前記実施形態1において、磁場印加部(20)の磁極(24)を、磁気作業物質(11)の径方向外側(第2方向の他端側)と、磁気作業物質(11)の軸方向(第3方向)とに配置した構成としてもよい。
前記実施形態1の変形例1において、磁場印加部(20)の磁極(24)を、磁気作業物質(11)の径方向内側(第2方向の一端側)と、磁気作業物質(11)の軸方向(第3方向)とに配置した構成としてもよい。
前記実施形態1の変形例1において、磁場印加部(20)の磁極(24)を、磁気作業物質(11)の径方向外側(第2方向の他端側)と、磁気作業物質(11)の軸方向(第3方向)とに配置した構成としてもよい。
実施形態1において、磁場印加部(20)と磁気作業物質(11)とを軸方向に複数配置し、1つのモータ(17)で相対回転移動させてもよい。
実施形態2について説明する。
本実施形態の特徴によれば、相対移動は、所定の軸心周りに回転する相対回転移動である。第1方向が周方向、第2方向が軸方向、第3方向が径方向である。磁気作業物質(11)と磁場印加部(20)の磁極(24)とは、軸方向に間隔をあけて配置される。磁場印加部(20)の磁極(24)は、径方向に間隔をあけて設けられる。
実施形態2において、磁場印加部(20)の磁極(24)を、第1突起部(35)及び第2突起部(36)で構成してもよい。
前記実施形態1において、磁場印加部(20)の磁極(24)を、第1磁石(25)と、磁極突起部(51)と、で構成してもよい。
前記実施形態2において、磁場印加部(20)の磁極(24)を、磁気作業物質(11)の軸方向下側(第2方向の一端側)と、磁気作業物質(11)の径方向外側(第3方向の他端側)とに配置した構成としてもよい。
前記実施形態2において、磁場印加部(20)の磁極(24)を、磁気作業物質(11)の軸方向下側(第2方向の一端側)と、磁気作業物質(11)の径方向内側(第3方向の一端側)とに配置した構成としてもよい。
前記実施形態2の変形例1において、磁場印加部(20)の磁極(24)を、磁気作業物質(11)の軸方向下側(第2方向の一端側)と、磁気作業物質(11)の径方向外側(第3方向の他端側)とに配置した構成としてもよい。
前記実施形態2の変形例1において、磁場印加部(20)の磁極(24)を、磁気作業物質(11)の軸方向下側(第2方向の一端側)と、磁気作業物質(11)の径方向内側(第3方向の一端側)とに配置した構成としてもよい。
実施形態2において、磁場印加部(20)と磁気作業物質(11)とを軸方向に複数配置し、1つのモータ(17)で相対回転移動させてもよい。また、磁場印加部(20)と磁気作業物質(11)とを径方向に複数配置し、1つのモータ(17)で相対回転移動させてもよい。
実施形態3について説明する。
本実施形態の特徴によれば、相対移動は、第1方向に沿って直線的に移動する相対直線移動である。磁気作業物質(11)と磁場印加部(20)の磁極(24)とは、第2方向に間隔をあけて配置される。磁場印加部(20)の磁極(24)は、第3方向に間隔をあけて設けられる。
実施形態3において、磁場印加部(20)の磁極(24)を、第1コア(31)の第1突部(31a)及び第2コア(32)の第2突部(32a)で構成してもよい。
前記実施形態3において、磁場印加部(20)の磁極(24)を、第1磁石(25)と、磁極突起部(51)と、で構成してもよい。
前記実施形態3において、磁場印加部(20)の磁極(24)を、磁気作業物質(11)の第2方向の一端側と、磁気作業物質(11)の第3方向とに配置した構成としてもよい。
前記実施形態3の変形例1において、磁場印加部(20)の磁極(24)を、磁気作業物質(11)の第2方向の一端側と、磁気作業物質(11)の第3方向とに配置した構成としてもよい。
実施形態3において、磁場印加部(20)と磁気作業物質(11)を複数配置し、1つのシリンダ(41)で相対直線移動させてもよい。
実施形態4について説明する。
本実施形態の特徴によれば、磁場印加部(20)の磁極(24)における磁気作業物質(11)と対向する面の第1方向の長さは、磁気作業物質(11)における磁場印加部(20)の磁極(24)と対向する面の第1方向の長さよりも大きい。
前記実施形態4において、磁場印加部(20)の磁極(24)を、磁気作業物質(11)の径方向外側に配置した構成としてもよい。
実施形態4において、磁場印加部(20)と磁気作業物質(11)とを軸方向に複数配置し、1つのモータ(17)で相対回転移動させてもよい。
実施形態5について説明する。
本実施形態の特徴によれば、磁場印加部(20)の磁極(24)における磁気作業物質(11)と対向する面の第1方向の長さは、磁気作業物質(11)における磁場印加部(20)の磁極(24)と対向する面の第1方向の長さよりも大きい。
実施形態5において、磁場印加部(20)と磁気作業物質(11)とを軸方向に複数配置し、1つのモータ(17)で相対回転移動させてもよい。また、磁場印加部(20)と磁気作業物質(11)とを径方向に複数配置し、1つのモータ(17)で相対回転移動させてもよい。
実施形態6について説明する。
本実施形態の特徴によれば、磁束が流れるコア(21)を磁性材料で構成し、非磁性材料で構成された保持部材(55)によってコア(21)を保持することで、第1方向で隣り合う磁極(24)間での磁束漏れをより低減することができる。また、保持部材(55)として、コア(21)よりも単位体積当たりの重量が軽い部材(例えば、アルミニウムや樹脂)を採用することで、磁気冷凍装置(10)全体として軽量化を図ることができる。
前記実施形態6において、磁場印加部(20)を円柱状に形成してもよい。
前記実施形態については、以下のような構成としてもよい。
2 熱媒体回路
10 磁気冷凍装置
11 磁気作業物質
13 ヨーク
20 磁場印加部
24 磁極
Claims (7)
- 磁気作業物質(11)と、
前記磁気作業物質(11)に対して第1方向に相対移動するとともに、前記磁気作業物質(11)に対して磁場を印加する磁場印加部(20)と、を備え、
前記磁場印加部(20)の磁極(24)は、前記磁気作業物質(11)における前記第1方向に直交する第2方向の一端側に配置され、且つ前記磁気作業物質(11)における前記第1方向及び前記第2方向に直交する第3方向に間隔をあけて設けられる
磁気冷凍装置。 - 請求項1の磁気冷凍装置において、
前記相対移動は、所定の軸心周りに回転する相対回転移動であり、
前記第1方向が周方向、前記第2方向が径方向、前記第3方向が軸方向であり、
前記磁気作業物質(11)と前記磁場印加部(20)の磁極(24)とは、径方向に間隔をあけて配置され、
前記磁場印加部(20)の磁極(24)は、軸方向に間隔をあけて設けられる
磁気冷凍装置。 - 請求項1の磁気冷凍装置において、
前記相対移動は、所定の軸心周りに回転する相対回転移動であり、
前記第1方向が周方向、前記第2方向が軸方向、前記第3方向が径方向であり、
前記磁気作業物質(11)と前記磁場印加部(20)の磁極(24)とは、軸方向に間隔をあけて配置され、
前記磁場印加部(20)の磁極(24)は、径方向に間隔をあけて設けられる
磁気冷凍装置。 - 請求項1の磁気冷凍装置において、
前記相対移動は、前記第1方向に沿って直線的に移動する相対直線移動であり、
前記磁気作業物質(11)と前記磁場印加部(20)の磁極(24)とは、前記第2方向に間隔をあけて配置され、
前記磁場印加部(20)の磁極(24)は、前記第3方向に間隔をあけて設けられる
磁気冷凍装置。 - 請求項1~4のいずれか1つの磁気冷凍装置において、
前記磁気作業物質(11)における前記第3方向の両端部には、前記磁気作業物質(11)よりも透磁率の高いヨーク(13)が設けられる
磁気冷凍装置。 - 請求項1~5のいずれか1つの磁気冷凍装置において、
前記磁場印加部(20)の磁極(24)における前記磁気作業物質(11)と対向する面の前記第1方向の長さは、前記磁気作業物質(11)における前記磁場印加部(20)の磁極(24)と対向する面の前記第1方向の長さよりも大きい
磁気冷凍装置。 - 請求項1~6のいずれか1つの磁気冷凍装置(10)と、
前記磁気冷凍装置(10)と熱交換する熱媒体回路(2)と、を備える
冷凍装置。
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JP2012237496A (ja) * | 2011-05-11 | 2012-12-06 | Denso Corp | 磁気冷凍システム及び該磁気冷凍システムを用いた空気調和装置 |
JP2015031472A (ja) * | 2013-08-05 | 2015-02-16 | 日産自動車株式会社 | 磁気冷暖房装置 |
WO2019150819A1 (ja) | 2018-01-31 | 2019-08-08 | サンデンホールディングス株式会社 | 磁気ヒートポンプ装置 |
JP2020051693A (ja) * | 2018-09-27 | 2020-04-02 | ダイキン工業株式会社 | 磁気冷凍システム |
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JP2012237496A (ja) * | 2011-05-11 | 2012-12-06 | Denso Corp | 磁気冷凍システム及び該磁気冷凍システムを用いた空気調和装置 |
JP2015031472A (ja) * | 2013-08-05 | 2015-02-16 | 日産自動車株式会社 | 磁気冷暖房装置 |
WO2019150819A1 (ja) | 2018-01-31 | 2019-08-08 | サンデンホールディングス株式会社 | 磁気ヒートポンプ装置 |
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