JP6060789B2 - Thermomagnetic cycle equipment - Google Patents

Description

  The invention disclosed herein relates to a thermomagnetism cycle device that utilizes the temperature characteristics of a magnetic material, and can be used as a magnetocaloric effect type heat pump device.

  Patent Literature 1 and Patent Literature 2 disclose a magnetocaloric effect type heat pump device which is one of thermomagnetism cycle devices utilizing the temperature characteristics of a magnetic material. There has been proposed a heat pump device using the magnetocaloric effect of a magnetocaloric element which is a magnetic material. In these apparatuses, a permanent magnet is used to periodically switch between application of an external magnetic field to the magnetocaloric element (hereinafter also referred to as excitation) and removal of the external magnetic field to the magnetocaloric element (hereinafter also referred to as demagnetization). And a magnetic field modulation device having a yoke member for forming a magnetic path. The magnetic field modulator periodically modulates the strength of an external magnetic field applied to the magnetocaloric element by rotating a magnetic member including a permanent magnet.

  Patent Document 1 makes it possible to apply a strong magnetic field by arranging magnetic poles on both sides of a magnetocaloric element. Patent document 2 makes it possible to take out a heat transport medium outside by providing a valve mechanism at one end of the magnetocaloric element.

Japanese Patent No. 4284183 JP 2012-255642 A

  In the configuration of Patent Document 1, the moving direction of the magnetic pole for applying the external magnetic field is the same as the flow direction of the heat transport medium that transports heat. For this reason, the direction of temperature distribution generated in the magnetocaloric element coincides with the direction of change of the magnetic field. In this case, when the heat transport medium flows in one direction, a magnetic field intensity distribution is generated on the magnetocaloric element. Such a distribution of magnetic field strength causes a mismatch in timing of heat generation and endotherm, resulting in a decrease in thermal capability. From such a viewpoint, further improvement is demanded for the power conversion device.

  One of the objects of the invention is to provide a thermomagnetic cycle apparatus that exhibits high performance.

  Another object of the invention is to provide a thermomagnetism cycle device that can apply a strong magnetic field to the magnetocaloric element and suppress the distribution of the magnetic field intensity in the magnetocaloric element.

  The invention disclosed herein employs the following technical means to achieve the above object. Note that the reference numerals in parentheses described in the claims and in this section indicate a corresponding relationship with specific means described in the embodiments described later as one aspect, and limit the technical scope of the invention. Not what you want.

One of the inventions is a magnetocaloric element (12) that generates and absorbs heat due to the strength of an external magnetic field, an excitation range (PM) in which the magnetocaloric element is placed in a strong external magnetic field, and a magnetocaloric element from the excitation range . A magnetic field modulation device that modulates an external magnetic field applied to a magnetocaloric element by forming a demagnetization range (PN) placed in a weak external magnetic field and moving between an excitation range (PM) and a demagnetization range (PN) 13) and a heat transport medium that exchanges heat with the magnetocaloric element is caused to flow along the magnetocaloric element to generate a reciprocating flow (FM, FN) that reciprocates in synchronization with a change in the external magnetic field by the magnetic field modulator. The magnetic field modulator (13) includes a magnetic circuit (34, 35, 36; 434, 435) that magnetically connects between a pair of magnetic poles that apply an external magnetic field to the magnetocaloric element. 436, Has 61), the moving direction of the excitation range and demagnetization range is set so as to intersect with the flow direction of the heat transport medium, the magnetic field modulation system, the inner cylinder (34a, 434a), and the inner cylinder of the It includes an outer cylinder (34b, 434b) disposed on the radially outer side, has a closed end (34c; 434c) at one axial end between the inner cylinder and the outer cylinder, and an open end (34e; 434e) at the other end. The magnetocaloric element occupies a part of the cylinder in the circumferential direction and is arranged between the inner cylinder and the outer cylinder so as to extend in the axial direction, and has an open end. Is an element bed in which one end (12a) is positioned near the closed end and the other end (12b) is positioned near the closed end, and the magnetic field modulator (13) has one of a pair of magnetic poles arranged inside the cylinder. The other of the pair of magnetic poles is placed outside the cylinder, and the excitation range and demagnetization range are circled. Characterized in that to move along the circumferential direction rotationally.

  According to this configuration, a strong external magnetic field can be applied to the magnetocaloric element by the pair of magnetic poles. The strength of the external magnetic field in the magnetocaloric element changes along the direction of movement between the excitation range and the demagnetization range. On the other hand, a temperature gradient is generated in the magnetocaloric element along the flow direction of the heat transport medium. The direction of change of the external magnetic field and the direction of the temperature gradient intersect. Thereby, heat generation and heat absorption generated in the magnetocaloric element are efficiently used.

1 is a block diagram of a magnetocaloric effect type heat pump device (hereinafter referred to as an MHP device) according to a first embodiment of the invention. It is sectional drawing of the MHP apparatus of 1st Embodiment. It is sectional drawing of the MHP apparatus of 1st Embodiment. It is sectional drawing of the MHP apparatus of 1st Embodiment. It is sectional drawing of the MHP apparatus of 2nd Embodiment of invention. It is sectional drawing of the MHP apparatus of 3rd Embodiment of invention. It is sectional drawing of the MHP apparatus of 4th Embodiment of invention. It is sectional drawing of the MHP apparatus of 5th Embodiment of invention.

  A plurality of modes for carrying out the invention will be described below with reference to the drawings. In each embodiment, parts corresponding to the matters described in the preceding embodiment may be denoted by the same reference numerals, and redundant description may be omitted. When only a part of the configuration is described in each mode, the other modes described above can be applied to the other parts of the configuration. Further, in the following embodiments, the correspondence corresponding to the matters corresponding to the matters described in the preceding embodiments is indicated by adding reference numerals that differ only by one hundred or more, and redundant description may be omitted. . Not only combinations of parts that clearly show that combinations are possible in each embodiment, but also combinations of the embodiments even if they are not explicitly stated unless there is a problem with the combination. Is also possible.

(First embodiment)
FIG. 1 is a block diagram showing a vehicle air conditioner 10 according to a first embodiment to which the invention is applied. The vehicle air conditioner 10 includes a magnetocaloric effect type heat pump device 11. The magnetocaloric effect type heat pump apparatus 11 is also referred to as an MHP (Magneto-caloric effect Heat Pump) apparatus 11. The MHP apparatus 11 provides a thermomagnetic cycle apparatus.

  In this specification, the term heat pump device is used in a broad sense. That is, the term “heat pump device” includes both a device that uses the cold heat obtained by the heat pump device and a device that uses the heat obtained by the heat pump device. An apparatus using cold heat may be referred to as a refrigeration cycle apparatus. Therefore, in this specification, the term heat pump apparatus is used as a concept including a refrigeration cycle apparatus.

  The MHP device 11 includes a magnetocaloric element 12. The magnetocaloric element 12 is also called an MCE (Magneto-Caloric Effect) element 12. The MCE element 12 generates heat and absorbs heat due to the strength of the external magnetic field. The MCE element 12 generates heat when an external magnetic field is applied, and absorbs heat when the external magnetic field is removed. When the electron spin is aligned in the magnetic field direction by applying an external magnetic field, the MCE element 12 decreases in magnetic entropy and increases its temperature by releasing heat. In addition, when the electron spin becomes messy due to the removal of the external magnetic field, the MCE element 12 increases in magnetic entropy and decreases in temperature by absorbing heat. The MCE element 12 is made of a magnetic material that exhibits a high magnetocaloric effect in a normal temperature range. For example, a gadolinium-based material or a lanthanum-iron-silicon compound can be used. Also, a mixture of manganese, iron, phosphorus and germanium can be used.

  One MCE element 12 and its related elements constitute a magnetocaloric element unit. The magnetocaloric element unit is also called an MCD (Magneto-Caloric effect Device) unit. The MHP device 11 uses the magnetocaloric effect of the MCE element 12. The MHP device 11 includes a magnetic field modulation device 13 and a heat transport device 14 for causing the MCE element 12 to function as an AMR (Active Magnetic Refrigeration) cycle.

  The magnetic field modulator 13 applies an external magnetic field to the MCE element 12 and increases or decreases the strength of the external magnetic field. The magnetic field modulator 13 periodically switches between an excitation state in which the MCE element 12 is placed in a strong magnetic field and a demagnetization state in which the MCE element 12 is placed in a weak magnetic field or a zero magnetic field. The magnetic field modulator 13 forms an excitation range PM in which the MCE element 12 is placed in a strong external magnetic field and a demagnetization range PN in which the MCE element 12 is placed in an external magnetic field weaker than the excitation period PM. The magnetic field modulator 13 modulates the external magnetic field applied to the MCE element 12 by moving the excitation range PM and the demagnetization range PN. The magnetic field modulator 13 modulates the external magnetic field so as to periodically repeat the excitation range PM and the demagnetization range PN. The magnetic field modulation device 13 includes a magnetic source for generating an external magnetic field, such as a permanent magnet or an electromagnet.

  The heat transport device 14 includes a fluid device for flowing a heat transport medium for transporting heat that the MCE element 12 radiates or absorbs heat. The heat transport device 14 is a device that flows along the MCE element 12 a heat transport medium that exchanges heat with the MCE element 12. The heat transport device 14 generates the reciprocating flows FM and FN of the heat transport medium that reciprocates in synchronization with the change of the external magnetic field by the magnetic field modulation device 13.

  In this embodiment, the heat transport medium that exchanges heat with the MCE element 12 is called a primary medium. The primary medium can be provided by a fluid such as antifreeze, water, oil. The heat transport device 14 reciprocally moves the heat transport medium in synchronization with the increase / decrease of the magnetic field by the magnetic field modulation device 13. The heat transport device 14 may include a pump for flowing a heat transport medium. The heat transport device 14 includes a pump 41 for flowing the primary medium. The pump 41 supplies a reciprocating flow of the primary medium with respect to one MCE element 12. The pump 41 is arranged so as to periodically execute the suction stroke and the discharge process.

  The MHP device 11 includes a motor 15 as a power source. The motor 15 is a power source of the magnetic field modulator 13. The motor 15 is a power source of the heat transport device 14.

  The MHP device 11 includes a high temperature system 16 that transports the high temperature obtained by the MHP device 11. The high temperature system 16 is also a device that uses the high temperature obtained by the MHP device 11. The MHP device 11 includes a low-temperature system 17 that transports the low temperature obtained by the MHP device 11. The high temperature system 16 is also a device that uses the low temperature obtained by the MHP device 11.

  The high temperature system 16 includes a heat exchanger 51 that provides heat exchange between the primary medium and the secondary medium. The secondary medium is a heat transport medium used for transporting heat in the high-temperature system 16. The secondary medium can be provided by a fluid such as antifreeze, water, oil, or the like. The high temperature system 16 includes a path 52 through which the secondary medium is circulated. The high temperature system 16 includes a heat exchanger 53 that provides heat exchange between the secondary medium and the other medium. For example, the heat exchanger 53 provides heat exchange between the secondary medium and air. The high temperature system 16 is also a device that removes heat from the high temperature end of the MHP device 11 and cools the high temperature end.

  The low temperature system 17 uses a primary medium used for the MHP device 11. The low temperature system 17 includes a path 55 through which the primary medium flows. The low temperature system 17 includes a heat exchanger 56 that provides heat exchange between the primary medium and the other medium. For example, the heat exchanger 56 provides heat exchange between the primary medium and air. The low temperature system 17 is also a device that brings heat into the low temperature end of the MHP device 11 and heats the low temperature end.

  The vehicle air conditioner 10 is mounted on a vehicle and adjusts the temperature of the passenger compartment of the vehicle. The two heat exchangers 53 and 56 provide a part of the vehicle air conditioner 10. The heat exchanger 53 is a high temperature side heat exchanger 53 that has a higher temperature than the heat exchanger 56. The heat exchanger 53 is also referred to as an indoor heat exchanger 53. The heat exchanger 56 is a low temperature side heat exchanger 56 that has a lower temperature than the heat exchanger 53. The heat exchanger 56 is also referred to as an outdoor heat exchanger 56. The vehicle air conditioner 10 includes air system equipment such as an air conditioning duct and a blower for using the high temperature side heat exchanger 53 and / or the low temperature side heat exchanger 56 for indoor air conditioning.

  The vehicle air conditioner 10 is used as a cooling device or a heating device. The vehicle air conditioner 10 can include a cooler that cools air supplied to the room and a heater that heats the air cooled by the cooler again. The MHP device 11 is used as a cold source or a hot source in the vehicle air conditioner 10. That is, the high temperature side heat exchanger 53 can be used as the heater. The low temperature side heat exchanger 56 can be used as the cooler.

  When the MHP device 11 is used as a heat supply source, the air that has passed through the high temperature side heat exchanger 53 is supplied to the vehicle interior and used for heating. At this time, the air that has passed through the low temperature side heat exchanger 56 is discharged outside the vehicle. When the MHP device 11 is used as a cold heat supply source, the air that has passed through the low temperature side heat exchanger 56 is supplied to the vehicle interior and is used for cooling. At this time, the air that has passed through the high temperature side heat exchanger 53 is discharged outside the vehicle. The MHP device 11 may be used as a dehumidifying device. In this case, the air that has passed through the low temperature side heat exchanger 56 then passes through the high temperature side heat exchanger 53 and is supplied indoors. The MHP device 11 is used as a heat supply source both in winter and in summer.

  The vehicle air conditioner 10 includes a control device (CNTR) 18. The control device 18 controls a plurality of controllable elements of the vehicle air conditioner 10. For example, the control device 18 controls the motor 15 so as to at least switch between the operation and stop of the MHP device 11.

  The control device 18 is an electronic control device. The control device 18 includes a processing device (CPU) and a memory (MMR) as a storage medium for storing a program. The control device 18 is provided by a microcomputer provided with a computer-readable storage medium. The storage medium stores a computer-readable program non-temporarily. The storage medium can be provided by a semiconductor memory or a magnetic disk. The program is executed by the control device 18 to cause the control device 18 to function as a device described in this specification, and to cause the control device 18 to function so as to execute the control method described in this specification. The means provided by the controller 18 can also be referred to as a functional block or module that achieves a predetermined function.

  2, 3, and 4 are cross-sectional views of the MHP device 11 according to the first embodiment. 2 and 3 are longitudinal sectional views, and FIG. 4 is a transverse sectional view. FIG. 2 shows a cross section taken along the line II-II shown in FIG. FIG. 3 shows a cross section taken along line III-III shown in FIG. FIG. 4 shows a cross section taken along line IV-IV shown in FIGS.

  One MCE element 12 is formed in a rod shape having a longitudinal direction along the axial direction of the MHP device 11. The MCE element 12 has one end portion 12a and the other end portion 12b along the inclination direction of the temperature gradient generated by heat generation and heat absorption. The MCE element 12 occupies a part of the circumferential direction of the cylinder and is arranged to extend in the axial direction. The MCE element 12 is formed in a shape that can sufficiently exchange heat with the primary medium flowing in the working chamber 22. Each MCE element 12 is also called an element bed.

  A motor 15 provided as a power source of the MHP device 11 is driven by an in-vehicle battery. The motor 15 rotates the rotor 13 that provides the magnetic field modulation device 13. As a result, the motor 15 and the magnetic field modulation device 13 periodically cycle between a state in which an external magnetic field is applied to the MCE element 12 and a state in which the external magnetic field is removed from the MCE element 12 (a state in which no external magnetic field is applied). Cause alternate switching. The motor 15 drives the pump 41 of the heat transport device 14. As a result, the motor 15 and the pump 41 generate reciprocal flows FM and FN of the primary medium in one MCE element 12.

  The pump 41 generates a reciprocating flow of the primary medium in the MCD unit for causing the MCE element 12 to function as an AMR cycle. The pump 41 is a positive displacement pump. The pump 41 is a swash plate type piston pump. The pump 41 is a multi-cylinder axial piston pump. One cylinder of the pump 41 is associated with one MCE element 12. A reciprocating flow FM, FN of the primary medium flowing along the longitudinal direction of one MCE element 12 is provided. The heat transport device 14 includes a pump 41 connected to one end 12 a of the MCE element 12 and a motor 15 that drives the pump 41. The MHP apparatus 11 includes a plurality of MCE elements 12 that are thermally connected in parallel. In the MHP apparatus 11, six MCE elements 12 are thermally connected in parallel. Therefore, the pump 41 has 6 cylinders.

  The MHP apparatus 11 includes a housing 21 that can be called cylindrical. The housing 21 is arranged coaxially with the pump 41. One end of the housing 21 is connected to the pump 41. In the drawing, the lower end of the housing 21 is connected to the pump 41. The housing 21 can be installed with its central axis arranged in the vertical direction. The housing 21 has a connecting end 21 a connected to the pump 41 and a free end 21 b on the opposite side away from the pump 41. The connecting end 21a is also called one end 21a. The free end 21b is also called the other end 21b.

  The housing 21 defines at least one work chamber 22. The work chamber 22 is formed as a cavity extending in the axial direction in the wall of the cylindrical housing 21. The housing 21 defines a plurality of work chambers 22. The plurality of work chambers 22 are arranged at equal intervals along the circumferential direction. One housing 21 defines six working chambers 22. Each of the work chambers 22 forms a columnar space having a longitudinal direction along the axial direction of the housing 21. One work chamber 22 is provided to correspond to one cylinder of the pump 41.

  The work chamber 22 provides a flow path through which the primary medium flows. A primary medium flows in the working chamber 22 along the longitudinal direction thereof. The primary medium flows in the work chamber 22 so as to reciprocate along the longitudinal direction.

  Further, the work chamber 22 provides a storage chamber for storing the MCE element 12. The housing 21 provides a container in which a work chamber 22 is formed. In the working chamber 22, the MCE element 12 as a magnetic working material having a magnetocaloric effect is disposed.

  The housing 21 provides a cylindrical inner surface 31 on the radially inner side. The housing 21 provides a cylindrical outer surface 32 radially outward. The cylindrical inner surface 31 and the cylindrical outer surface 32 face the magnetic pole provided by the magnetic modulation device 13.

  The MHP device 11 has a discharge collecting passage 23 and a suction collecting passage 24 corresponding to one end of the MCE element 12 in the longitudinal direction. The collecting passages 23 and 24 are formed in an annular shape at the free end 21 b of the housing 21. The collecting passages 23, 24 provide a passage for the primary medium independent of each other.

  A check valve 25 is provided between the collecting passage 23 and the work chamber 22. The check valve 25 allows the primary medium to flow out from the working chamber 22 to the collecting passage 23 and prevents the primary medium from flowing into the working chamber 22 from the collecting passage 23. A check valve 26 is provided between the collecting passage 24 and the work chamber 22. The check valve 26 allows the primary medium to flow from the collecting passage 24 to the working chamber 22 and prevents the primary medium from flowing from the working chamber 22 to the collecting passage 24. The check valves 25 and 26 provide a valve mechanism that controls the outflow and inflow of the primary medium. The valve mechanism is provided at the free end 21b. The MHP device 11 includes a plurality of valve mechanisms provided corresponding to the plurality of work chambers 22. As a result, a plurality of work chambers 22 are connected in parallel between the collecting passages 23 and 24.

  The housing 21 includes passages 27 and 28 for flowing the primary medium. The passage 27 communicates with the collecting passage 23. The passage 28 communicates with the collecting passage 24. The passages 27 and 28 are formed along the longitudinal direction of the housing 21. The passages 27 and 28 reach the connecting end 21 a from the free end 21 b of the housing 21. The passages 27 and 28 are passages for drawing the collecting passages 23 and 24 to the outside. The passages 27 and 28 extend between one end and the other end of the housing 21. The passage 27 communicates with one of the paths 55. The passage 27 communicates with the other side of the path 55. The passages 27 and 28 make it possible to take out the high-temperature or low-temperature primary medium obtained at the free end 21b at the connecting end 21a and supply the primary medium to the free end 21b.

  The valve mechanism including the check valves 25 and 26 provides a flow control mechanism for circulating the primary medium in the path 55 of the low temperature system 17. The primary medium that has passed through the check valve 25 from the work chamber 22 reaches the heat exchanger 56 via the collecting passage 23, the passage 27, and the passage 55. The primary medium exiting the heat exchanger 56 returns from the check valve 26 to the working chamber 22 via the path 55, the passage 28, and the collecting passage 24.

  As described above, the heat transport device 14 is disposed inside the closed end 34c, and the folded flow paths 23, 24, 25, 26, which draw the heat transport medium from the other end 12b of the MCE element 12 to the outside of the open end 34e. 27, 28. The folded flow path includes valve mechanisms 25 and 26 that control the outflow and inflow of the heat transport medium from the other end 12b of the MCE element 12. The MHP device 11 has a plurality of MCE elements 12 arranged in parallel with each other. The return flow path has a plurality of valve mechanisms 25 and 26 provided corresponding to the plurality of MCE elements 12 respectively. Further, the folded flow path has collecting passages 23 and 24 for the heat transport medium passing through the plurality of valve mechanisms 25 and 26.

  According to this configuration, the reciprocating flows FM and FN are supplied into the working chamber 22 by the pump 41 connected to the one end 21 a of the cylindrical housing 21. Therefore, the primary medium existing at the one end 21 a of the MCE element 12 can be used for heat exchange at the one end 21 a of the housing 21. Further, the valve mechanisms 25, 26 and the passages 23, 24, 27, 28 return the primary medium present at the other end 21 b of the MCE element 12 to the one end 21 a of the housing 21. The passages 23, 24, 27, and 28 can also be referred to as folding passages. According to this configuration, the primary medium existing at the other end 21 b of the housing 21 can be used for heat exchange at the one end 21 a of the housing 21.

  The heat exchanger 51 is provided at one end 21 a of the housing 21. The heat exchanger 51 provides heat exchange between the primary medium between the pump 41 and the work chamber 22 and the secondary medium flowing in the high temperature system 16. The heat exchanger 51 is formed in an annular shape corresponding to the cylindrical housing 21. The heat exchanger 51 is an indirect heat exchanger for taking out the high temperature or low temperature of the primary medium.

  The MCE element 12 is placed under the influence of an external magnetic field applied or removed by the magnetic field modulator 13. That is, when the rotating shaft 33 rotates, a state in which an external magnetic field for magnetizing the MCE element 12 is applied and a state in which the external magnetic field is removed from the MCE element 12 are alternately switched.

  The magnetic modulation device 13 is provided over both the cylindrical inner surface 31 and the cylindrical outer surface 32 of the housing 21. A rotating shaft 33 is disposed along the central axis of the housing 21. The rotating shaft 33 is connected to the output shaft of the motor 15.

  A rotor core 34 is fixed to the rotating shaft 33. The rotor core 34 has a cylindrical inner cylinder 34a. The inner cylinder 34 a is also a boss connected to the rotation shaft 33. The rotor core 34 has a cylindrical outer cylinder 34b. The rotor core 34 has an annular bottom wall 34c that connects the inner cylinder 34a and the outer cylinder 34b. An annular recess 34d is defined between the inner cylinder 34a and the outer cylinder 34b. The rotor core 34 has an open end 34e that provides an annular opening in the recess 34d. Thus, the rotor core 34 provides an annular container that is open at one end.

  The magnetic field modulation device 13 provides a cylindrical yoke 34 by a rotor core 34. The yoke 34 includes an inner cylinder 34a and an outer cylinder 34b disposed on the radially outer side of the inner cylinder 34a. The yoke 34 has a closed end 34c at one end in the axial direction between the inner cylinder 34a and the outer cylinder 34b, and an open end 34e at the other end. The MCE element 12 is disposed between the inner cylinder 34a and the outer cylinder 34b. The MCE element 12 is arranged so that one end 12a is positioned in the vicinity of the open end 34e and the other end 12b is positioned in the vicinity of the closed end 34c.

  The recess 34d has a size that can accommodate the housing 21. The rotor core 34 receives the housing 21 from the open end 34e. The connecting end 21 a of the housing 21 is positioned in the vicinity of the opening end 34 e of the rotor core 34. The free end 21 b of the housing 21 is positioned in the vicinity of the bottom wall 34 c of the rotor core 34.

  The devices 51, 52, and 53 of the high-temperature system 16 are disposed in the vicinity of the open end 34 e and provide devices that exchange heat with the one end portion 12 a of the MCE element 12. The devices 55 and 56 of the low-temperature system 17 are disposed in the vicinity of the opening end 34 e and provide devices that exchange heat with the other end portion 12 b of the MCE element 12. This configuration makes it possible to take out the low temperature and the high temperature at the open end of the rotor core 34 that is a yoke with one end closed.

  The rotor core 34, together with the housing 21, provides a yoke for passing magnetic flux. A permanent magnet 35 is fixed to the outer surface of the inner cylinder 34a. A permanent magnet 36 is fixed to the inner surface of the outer cylinder 34b. The permanent magnets 35 and 36 are disposed so as to face each other with the housing 21 positioned therebetween. The permanent magnets 35 and 36 are disposed only in a part of the rotor core 34 in the circumferential direction. The permanent magnets 35 and 36 are partially cylindrical and have a fan-shaped cross section. The permanent magnets 35 and 36 are disposed so as to directly face the housing 21.

  The rotor core 34 and the permanent magnets 35 and 36 provide an outer magnetic pole located on the radially outer side of the housing 21 and an inner magnetic pole located on the radially inner side of the housing 21. In this embodiment, an inner magnetic pole is formed by the permanent magnet 35, and an outer magnetic pole is formed by the permanent magnet 36. The outer magnetic pole and the inner magnetic pole supply magnetic flux in the radial direction and form a strong magnetic field between them. The rotor core 34 provides a back yoke that provides a magnetic circuit between the permanent magnets 35, 36. The circumferential excitation range PM in which the permanent magnets 35 and 36 are disposed is substantially equal to the circumferential demagnetization range PN in which the permanent magnet 25 is not disposed.

  The permanent magnets 35 and 36 form a region where the external magnetic field is strong and a region where the external magnetic field is weak along the circumferential direction of the rotor core 34. In a region where the external magnetic field becomes weak, a state in which the external magnetic field is substantially removed is provided. The rotor core 34 and the permanent magnets 35 and 36 rotate in synchronization with the rotation of the rotating shaft 33. Therefore, the region where the external magnetic field is strong and the region where the external magnetic field is weak rotate in synchronization with the rotation of the rotation shaft 33. As a result, at one point on the housing 21 or on a line extending in the axial direction of the housing 21, a period in which the external magnetic field is strongly applied and a period in which the external magnetic field is weakened and almost removed are repeatedly generated. The rotor core 34 and the permanent magnets 35 and 36 provide the magnetic field modulation device 13 that repeatedly applies and removes an external magnetic field. The rotor core 34 and the permanent magnets 35 and 36 provide a device for switching between application and removal of an external magnetic field to the MCE element 12. Note that the term magnetic field can be read as magnetic field.

  According to this configuration, the MCE element 12 extends elongated along the axial direction of the housing 21. The permanent magnets 35 and 36 extend in an elongated manner along the axial direction of the housing 21, that is, along the longitudinal direction of the MCE element 12. In other words, the permanent magnets 35 and 36 are elongated along the direction of the reciprocating flow of the primary medium. The permanent magnets 35 and 36, that is, the inner magnetic pole and the outer magnetic pole move in the circumferential direction. The primary medium flows along the axial direction of the housing 21, that is, along the rotation axis of the rotor core 34. Therefore, the moving direction of the magnetic pole and the flow direction of the primary medium are set so as to intersect. In other words, the gradient direction of the magnetic field intensity distribution generated in the MCE element 12 with the movement of the magnetic pole intersects the gradient direction of the temperature distribution appearing in the MCE element 12. As a result, the distribution of the magnetic field strength along the flow direction of the primary medium is suppressed. Thereby, high thermal efficiency can be obtained in the MCE element 12. Specifically, the moving direction of the magnetic pole and the flow direction of the primary medium are set to be orthogonal.

  In this configuration, the magnetic field modulation device 13 has a pair of magnetic poles that apply an external magnetic field to the MCE element 12. In the magnetic field modulation device 13, one of the pair of magnetic poles is disposed inside the cylinder, and the other of the pair of magnetic poles is disposed outside the cylinder. The magnetic field modulation device 13 includes magnetic circuits 34, 35, and 36 that magnetically connect a pair of magnetic poles. The magnetic field modulator 13 is set so that the moving direction of the excitation range PM and the demagnetization range PN is orthogonal to the flow direction of the heat transport medium. The magnetic field modulator 13 rotationally moves the excitation range PM and the demagnetization range PN along the circumferential direction of the cylinder.

  In this configuration, the magnetic poles are disposed both inside and outside the housing 21, that is, both inside and outside the MCE element 12. For this reason, the MCE element 12 can be placed in a strong magnetic field. Further, permanent magnets 35 and 36 are disposed both inside and outside the housing 21, that is, both inside and outside the MCE element 12. Thereby, leakage of magnetic flux can be suppressed. The rotor core 34 and the permanent magnets 35 and 36 have a C-shaped cross section, and provide a magnetic circuit capable of positioning the MCE element 12 in the C-shaped opening. Thereby, leakage of magnetic flux is suppressed.

  The rotor core 34 and the permanent magnets 35 and 36 provide the magnetic field modulation device 13 opened at the opening end 34e. The check valves 25 and 26 and the passages 23, 24, 27 and 28 are folded back for leading the primary medium to the opening end 34 e side from the free end 21 b of the housing 21, that is, the end disposed at the back of the magnetic field modulator 13. Provide a flow path. As a result, even when the magnetic field modulator 13 closed by the bottom wall 34c is used, both the high temperature and low temperature appearing at both ends of the MCE element 12 can be used.

  The valve mechanism including the check valves 25 and 26 is positioned at the upper part of the housing 21. The rotor core 34 is positioned with its open end 34e facing downward in the direction of gravity. That is, the open end 34e is disposed below the gravity direction, and the closed end 34c is disposed above the gravity direction. This configuration is advantageous for discharging air bubbles from the pump 41 and the working chamber 22. For example, according to this configuration, air bleeding can be easily and reliably performed.

  The housing 21 accommodates a plurality of MCE elements 12 arranged along the circumference. For this reason, a large thermal output can be obtained. The other end 12b of the MCE element 12 is a low temperature end. As a result, the end of the housing 21 away from the motor 15, that is, the free end 21b of the housing 21 becomes the low temperature end. This configuration is advantageous in order to suppress the thermal influence from the motor 15 and the pump 41 which are heat generating parts.

(Second Embodiment)
This embodiment is a modification based on the preceding embodiment. In the said embodiment, the indirect heat exchanger 51 was employ | adopted at the high temperature end. Instead, in this embodiment, the primary medium is drawn out also at the high temperature end of the MCE element 12 and used as a heat source.

  In FIG. 5, the housing 21 has a passage 237 and a passage 238 at the connecting end 21a. The passage 237 communicates one cylinder of the pump 41 with one work chamber 22. The passage 237 provides a forward path of the primary medium from the pump 41 to the work chamber 22. The passage 238 is provided between one cylinder of the pump 41 and one work chamber 22, and communicates the pump 41 and the work chamber 22 via the path 52 and the heat exchanger 53. The passage 238 provides a return path for the primary medium from the working chamber 22 to the pump 41. A check valve 239 is provided in the passage 238. A check valve 240 is provided in the passage 237.

  The primary medium discharged from the pump 41 is supplied to the work chamber 22 via the passage 237 and the check valve 239. When the pump 41 sucks the primary medium, the primary medium flows from the work chamber 22 via the passage 238, the check valve 240, the path 52, and the heat exchanger 53. Thereby, the primary medium is directly supplied to the heat exchanger 53.

(Third embodiment)
This embodiment is a modification based on the preceding embodiment. In the said embodiment, the indirect heat exchanger 51 was employ | adopted only at the high temperature end. Instead, in this embodiment, an indirect heat exchanger 354 is also employed at the low temperature end of the MCE element 12.

  In FIG. 6, the low temperature system 17 is provided with a heat exchanger 354. The heat exchanger 354 provides heat exchange between the primary medium flowing from the passage 27 to the passage 28 and the secondary medium. The secondary medium circulates through the path 55 and the heat exchanger 56. According to this configuration, both low and high temperatures are taken out by the indirect heat exchangers 51 and 354.

(Fourth embodiment)
This embodiment is a modification based on the preceding embodiment. In the above-described embodiment, the magnetic field modulation device 13 that modulates the magnetic field intensity by rotating the magnetic pole is employed. Instead, it is possible to employ a magnetic field modulator 13 that employs fixed permanent magnets 435 and 436 and modulates the magnetic field intensity by periodically changing the transmission of magnetic flux.

  In FIG. 7, the magnetic field modulation device 13 includes a stator core 434 that is fixedly disposed with respect to the pump 41 and the housing 21. The stator core 434 has a shape corresponding to the rotor core 34 described above. The stator core 434 has an inner cylinder 434a, an outer cylinder 434b, a bottom wall 434c, a recess 434d, and an open end 434e. The bottom wall 434c provides a closed end. The stator core 434 is fixed to the pump 41 and the housing 21. The open end 434e of the stator core 434 is closed by the pump 41, but provides a magnetically open end. A permanent magnet 435 is fixed to the outer surface of the inner cylinder 434a. A permanent magnet 436 is fixed to the inner surface of the outer cylinder 434b. The permanent magnets 435 and 436 are cylindrical permanent magnets and are magnetized in the radial direction. The housing 21 is disposed between the permanent magnet 435 and the permanent magnet 436.

  A magnetic field shielding member 461 is provided between the permanent magnets 435 and 436 and the housing 21. The magnetic field shielding member 461 has a shape corresponding to the rotor core 34 described above. The magnetic field shielding member 461 includes an inner cylinder 461 a disposed between the permanent magnet 435 and the housing 21. The inner cylinder 461 a is connected to the rotation shaft 33. The magnetic field shielding member 461 includes an inner cylinder 461 a disposed between the permanent magnet 435 and the housing 21. The magnetic field shielding member 461 includes an outer cylinder 461 b disposed between the permanent magnet 436 and the housing 21. The magnetic shielding member 461 has a bottom wall 461c that connects the inner cylinder 461a and the outer cylinder 461b. A recess 461d is formed between the inner cylinder 461a and the outer cylinder 461b. The housing 21 is accommodated in the recess 461d.

  The magnetic field shielding member 461 includes a transmission part 462 that transmits the magnetic field along the circumferential direction and a shielding part 463 that shields the magnetic field. The transmission part 462 can be made of a nonmagnetic material such as aluminum or resin. The shield 463 can be made of a magnetic material that guides the magnetic flux. In this case, the shield 463 weakens the magnetic field in the recess 461d by passing the magnetic flux. Moreover, the shielding part 463 may be comprised by the member with low magnetic permeability. For example, the shielding part 463 can be provided by a vacuum container.

  The transmission part 462 can be formed over the circumferential range PM shown in FIG. The shielding part 463 can be formed over the circumferential range PN. The transmission unit 462 applies a magnetic field formed by the permanent magnets 435 and 436 to the MCE element 12. The transmission part 462 provides a magnetic pole and provides an excitation range. The shield 463 removes or weakens the magnetic field in the recess 461d. The shield 463 provides a demagnetization range. As the magnetic field shielding member 461 rotates, the transmission part 462 and the shielding part 463 rotate. Thereby, the application and removal of the magnetic field to the MCE element 12 are periodically switched.

(Fifth embodiment)
This embodiment is a modification based on the preceding embodiment. In the said embodiment, the check valve provided with a ball | bowl and a spring was illustrated as check valve 25,26,239,240. Instead, various types of check valves can be used. As shown in FIG. 8, this embodiment employs reed valve type check valves 525 and 526 that open and close the passage by being deformed in response to the flow direction of the primary medium. The drawing shows a state where the reed valve 526 on the suction side is open.

(Other embodiments)
The present invention is not limited to the above-described embodiment, and can be implemented with various modifications. The structure, operation, and effect of the above embodiment are merely examples, and the technical scope of the invention is not limited to the scope of these descriptions. The invention is not limited to the combinations shown in the embodiments, and can be implemented independently. Some technical scope of the invention is indicated by the description of the scope of claims, and further includes all modifications within the meaning and scope equivalent to the description of the scope of claims.

  In the said embodiment, the multicylinder pump was provided with the swash plate type pump. Alternatively, other types of positive displacement pumps may be used. In the first embodiment, one working chamber is arranged corresponding to one cylinder of the pump. Instead of this, a plurality of cylinders and one work chamber, or one cylinder and a plurality of work chambers, or a plurality of cylinders and a plurality of work chambers may be arranged in correspondence.

  In the above embodiment, the moving direction between the excitation range and the demagnetization range is set to be orthogonal to the flow direction of the primary medium. Instead, the moving direction of the excitation range and the demagnetization range and the flow direction of the primary medium may be set so as to intersect at a predetermined angle. For example, the moving direction of the excitation range and the demagnetization range and the flow direction of the primary medium can be set so as to intersect at an angle of more than 45 ° and less than 90 °.

  Moreover, in the said embodiment, this invention was applied to the vehicle air conditioner. Instead of this, the present invention may be applied to a residential air conditioner. Moreover, you may utilize as a hot-water supply apparatus which heats water. In the above-described embodiment, the MHP apparatus 11 using outdoor air as a main heat source has been described. Instead, other heat sources such as water and soil may be used as the main heat source.

  In the above embodiment, the MHP apparatus 11 which is one form of the thermomagnetic cycle apparatus has been described. Instead of this, the present invention may be applied to a thermomagnetic engine apparatus which is a form of a thermomagnetic cycle apparatus. For example, a thermomagnetic engine apparatus can be provided by adjusting the phase of the magnetic field change of the MHP apparatus 11 of the said embodiment and the flow of a heat transport medium.

  In the above embodiment, the gap between the magnetic pole provided by the permanent magnets 35, 36, 435, and 436 and the housing 21 is fixed. Instead of this, a magnetic field modulation device 13 that changes the strength of the external magnetic field applied to the MCE element 12 by changing the gap between the magnetic pole and the housing 21 may be adopted.

10 vehicle air conditioner, 11 magnetocaloric effect heat pump (MHP) device,
12 magnetocaloric (MCE) element, 13 magnetic field modulation device, 14 heat transport device,
15 motor, 16 high temperature system, 17 low temperature system, 18 control device,
21 housing, 21a connecting end, 21b free end, 22 working chamber,
23, 24 Collecting passageway, 25, 26 Check valve, 27, 28 passageway,
33 rotating shaft, 34 rotor core, 34e open end, 35, 36 permanent magnet,
41 pump, 51 heat exchanger, 52, 55 path, 53, 56 heat exchanger,
237, 238 passage, 239, 240 check valve,
354 heat exchanger,
434 stator core, 435, 436 permanent magnet, 461 magnetic field shielding member,
525, 526 Check valve.

Claims (10)

A magnetocaloric element (12) that generates heat and absorbs heat by the strength of an external magnetic field;
Forming an excitation range (PM) in which the magnetocaloric element is placed in the strong external magnetic field and a demagnetization range (PN) in which the magnetocaloric element is placed in the external magnetic field weaker than the excitation range , A magnetic field modulation device (13) for modulating the external magnetic field applied to the magnetocaloric element by moving a range (PM) and the demagnetization range (PN);
A heat transport medium that exchanges heat with the magnetocaloric element is caused to flow along the magnetocaloric element to generate a reciprocating flow (FM, FN) that reciprocates in synchronization with a change in the external magnetic field by the magnetic field modulator. A heat transport device (14),
The magnetic field modulation device (13)
A magnetic circuit (34, 35, 36; 434, 435, 436, 461) that magnetically connects between a pair of magnetic poles that apply the external magnetic field to the magnetocaloric element;
The moving direction of the excitation range and the demagnetization range is set to intersect the flow direction of the heat transport medium ,
The magnetic field modulation device includes an inner cylinder (34a, 434a) and an outer cylinder (34b, 434b) arranged on the radially outer side of the inner cylinder, and one axial end between the inner cylinder and the outer cylinder. A cylindrical yoke (34; 434) having a closed end (34c; 434c) and an open end (34e; 434e) at the other end,
The magnetocaloric element occupies a part of the circumferential direction of a cylinder and is arranged between the inner cylinder and the outer cylinder so as to extend in the axial direction, and one end (12a) is positioned in the vicinity of the opening end, An element bed in which the other end (12b) is positioned near the closed end;
The magnetic field modulation device (13) has one of the pair of magnetic poles arranged inside the cylinder, the other of the pair of magnetic poles arranged outside the cylinder, and the excitation range and the demagnetization range are arranged in the cylinder. A thermomagnetic cycle device characterized in that it is moved rotationally along the circumferential direction .   The thermomagnetic cycle apparatus according to claim 1, wherein a moving direction between the excitation range and the demagnetization range is set to be orthogonal to a flow direction of the heat transport medium. The heat transport device is:
A folded channel (23, 24, 25, 26, 27, 28; 525, 526) that is disposed inside the closed end and draws the heat transport medium out of the open end from the other end of the magnetocaloric element. The thermomagnetic cycle apparatus according to claim 1 or 2 , further comprising: The folded flow path, said magnetocaloric elements of the valves controlling the inflow and outflow of the heat transfer medium from the other end mechanism; claim 3, characterized in that it comprises a (25, 26 525 and 526) The thermomagnetic cycle apparatus according to 1. A plurality of the magnetocaloric elements arranged in parallel with each other;
The folded channel is
A plurality of the valve mechanisms provided corresponding to each of the plurality of magnetocaloric elements;
The thermomagnetic cycle device according to claim 4 , further comprising a collecting passage (23, 24) for the heat transport medium passing through a plurality of the valve mechanisms. The thermomagnetic cycle apparatus according to any one of claims 1 to 5 , wherein the other end portion of the magnetocaloric element is a low temperature end. The thermomagnetic cycle device according to any one of claims 1 to 6 , wherein the open end is disposed below the gravitational direction, and the closed end is disposed above the gravitational direction. The heat transport device is:
A pump (41) connected to the one end (12a) of the magnetocaloric element;
The thermomagnetic cycle device according to any one of claims 1 to 7 , further comprising a motor (15) for driving the pump. Is disposed near the open end, according to one of claims 1 to 8, characterized in that it comprises a first end and a heat exchange device of the magnetocaloric element (16,51,52,53) Thermomagnetic cycle device. To any one of claims 1 to 9, characterized in that it comprises a; (354 17,55,56) disposed near the open end, a device wherein to the other end and the heat exchanger of the magnetocaloric element The thermomagnetic cycle apparatus described.

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