JP4208106B2 - Magnetic heater - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
INDUSTRIAL APPLICABILITY The present invention is used for improving the startability of various vehicle engines such as automobiles mainly powered by a diesel engine or a gasoline engine in cold or extremely cold conditions, or for cabin heating of various vehicles or ships including electric vehicles. It is used as an auxiliary heating means for fluid in pipes such as engine cooling water, and for preheating or rapid heating (reducing warm-up time) of engine cooling water for generators, welding machines, compressors, construction machines, etc. that are driven by engines Further, the present invention relates to a magnet heater that can be used as a catalyst device for engine exhaust gas and for raising the temperature of fuel gas for fuel cells.
[0002]
[Prior art]
As an auxiliary heating heat source for a vehicle such as an automobile used for heating engine cooling water at the time of starting in a cold region, a viscous heater is known (Japanese Patent Laid-Open No. Hei 2-246823, Japanese Utility Model Laid-Open No. 4-11716). JP-A-9-254637, JP-A-9-66729, JP-A-9-323530, etc.).
The viscous heater is a system in which a viscous fluid such as silicone oil is heated by shearing, and is used as a heating heat source by exchanging heat with circulating water circulating in the water jacket. A water jacket is formed in the heat generating chamber and the outer region of the heat generating chamber, and a drive shaft is rotatably supported on the housing via a bearing device, and a rotor rotatable in the heat generating chamber is fixed to the drive shaft. Viscous fluid such as silicone oil is sealed in the gap between the wall of the heat generation chamber and the rotor, and circulating water is taken in from the water inlet port in the water jacket and circulated to be sent out from the water outlet port to the external heating circuit. .
[0003]
In this viscous heater incorporated in a vehicle heating device, if the drive shaft is driven by the engine, the rotor rotates in the heat generating chamber, so that viscous fluid is sheared in the gap between the wall surface of the heat generating chamber and the outer surface of the rotor. The generated heat is exchanged with the circulating water in the water jacket, and the heated circulating water is used for heating the vehicle such as engine cooling water in the heating circuit.
[0004]
Further, as a method of reducing and purifying NOx in engine exhaust gas, there is a method of purifying exhaust gas by heating a catalyst provided in a pipe with an energizing heater (EHC) arranged close to the catalyst. .
[0005]
[Problems to be solved by the invention]
However, the above-mentioned viscous heater can be reduced in size and cost by a simple structure, and can be secured with high reliability and safety by a non-contact mechanism without wear, and the water temperature can be further increased. However, since the operation is automatically stopped by temperature control when the auxiliary heater is not required, the use of wasted energy is not used. However, the viscosity of silicon oil used as a viscous fluid increases as the rotor speed increases. The temperature due to the heat generation of silicone oil is limited to about 240 ° C because it gradually decreases and the shear resistance falls, and the temperature of the circulating water cannot be raised too much, and it takes time until the silicone oil is stirred at start-up. There is a drawback that the rapid heating effect in the engine cold time cannot be obtained. For this reason, especially in cold district specification vehicles equipped with a diesel engine, such a viscous heater is not sufficient in effectiveness, and it is possible to efficiently heat the fluid in the pipe to a high temperature in a short time and efficiently. A heater was desired.
[0006]
Further, in the method of heating and activating the catalyst with an energizing heater (EHC), it takes time to increase the temperature to the catalyst activation temperature. For example, in the case of a diesel engine, the exhaust gas temperature is lowered due to high performance. At the time of idling or the like, the temperature becomes as low as about 100 ° C., and the NOx catalyst purification ability is not fully exhibited.
[0007]
The present invention has been considered in view of the problems of the above-described viscous heater and the problem that the purification performance of the NOx catalyst of the conventional engine exhaust gas is low, and the temperature is higher and shorter than that of the viscous heater. In addition, the temperature of the fluid in the pipe can be raised, and it has excellent heat resistance, and is also effective in reducing NOx and HC (hydrocarbon) contained in exhaust gas of gasoline engines and diesel engines. Another object of the present invention is to provide a magnet heater that can be used for raising the temperature of a fuel gas such as hydrogen for a fuel cell.
[0008]
[Means for Solving the Problems]
The magnet heater according to the present invention is a system in which slip heat generated on the conductor side is exchanged with the fluid in the pipe by shearing the magnetic path formed between the magnet and the conductor. Are arranged opposite to each other with a slight gap, and the fluid in the pipe is heated by slip heat generated in the conductor by relatively rotating the magnet and the conductor, and the first embodiment includes the fluid A permanent magnet disposed opposite to the conductor with a slight gap inside a cylindrical housing rotatably supported on the fluid pipe via a bearing device so as to surround a conductor fitted on the outer periphery of the pipe. It is provided in a fixed manner, and the fluid in the pipe is heated by the slip heat generated in the conductor by the rotation of the cylinder type housing,
In a second embodiment, the conductor is formed of a pipe body having the same inner diameter as the fluid pipe, and the conductor is slightly placed in the inside of a cylindrical housing rotatably supported on the outer periphery of the conductor via a bearing device. A permanent magnet disposed oppositely across a gap is fixed, and the fluid in the pipe is heated by the slip heat generated in the conductor by the rotation of the cylinder-type housing. In the second embodiment, the conductor is connected to a part of the fluid piping by a joint, or a heat radiating fin is provided on the inner peripheral surface of the conductor.
In a third embodiment, the fluid pipe is made of a conductor, and a pair of pipes supported on the outside of the conductor pipe so as to be rotatable on a plane center line in the radial direction of the pipe and parallel to the pipe axis direction. The disk-shaped permanent magnets are arranged to face each other with a slight gap, and the fluid in the pipe is heated by the slip heat generated in the conductor-made fluid pipe by the rotation of the disk-shaped permanent magnet, In addition, the pipe cross section disposed opposite to the disk-shaped permanent magnet of the conductor-made fluid pipe in the third embodiment is formed into a flat shape such as an ellipse or an ellipse, or the disk-shaped permanent magnet of the conductor-made fluid pipe is used. A pipe portion to be opposed is configured by a plurality of pipes having a flat cross section.
In the fourth embodiment, the fluid pipe is made of resin, and a pair of bearings are rotatably supported on a plane parallel to the pipe axis direction on the radial center line of the pipe outside the conductor fluid pipe. Disc-shaped permanent magnets are arranged to face each other with a slight gap, and a conductor tube is fitted and fixed in a fluid pipe facing the disc-shaped permanent magnet, and the conductor-made tube is rotated by the rotation of the disc-shaped permanent magnet. The structure is such that the fluid in the pipe is heated by slip heat generated in the body.
According to a fifth embodiment, the fluid pipe is made of a conductor, and a cylindrical permanent magnet disposed opposite to the outer circumference of the conductor fluid pipe with a slight gap is rotatably supported via a bearing device. In addition, a heat exchange core is provided in the fluid pipe disposed opposite to the cylindrical permanent magnet, and flows through the heat exchange core by slip heat generated in the conductor fluid pipe by the rotation of the cylindrical permanent magnet. It is characterized by a structure in which the fluid is heated,
According to a sixth embodiment, a conductor heat exchange core is disposed in the fluid pipe, and a permanent magnet with a flow hole arranged opposite to the conductor heat exchange core with a slight gap is interposed between the fluid via the bearing device. The structure is such that the fluid flowing in the heat exchange core is heated by slip heat generated in the heat exchange core made of conductor by the rotation of the permanent magnet with flow hole, which is rotatably supported in the pipe. Features and
In the seventh embodiment, a conductor heat exchange core is arranged in tandem in the fluid pipe, and a small gap is separated from each conductor heat exchange core between the upstream and downstream conductor heat exchange cores. The permanent magnets with flow holes arranged opposite to each other are rotatably supported on the fluid pipe line via a bearing device, and are generated in the upstream and downstream conductor heat exchange cores by the rotation of the permanent magnets with flow holes. It is characterized in that the fluid flowing through the upstream and downstream heat exchange cores is heated by slip heat generation,
In the eighth embodiment, a hollow conductor heat exchange core is disposed in the fluid pipe, and a cylindrical permanent magnet disposed opposite to the hollow conductor heat exchange core with a slight gap interposed therebetween via a bearing device. A structure that is rotatably supported in the fluid pipe and heats the fluid flowing through the hollow conductor heat exchange core by slip heat generated in the hollow conductor heat exchange core by the rotation of the cylindrical permanent magnet. It is characterized by
In the ninth embodiment, a hollow conductor heat exchange core is rotatably supported in the fluid pipe via a bearing device, and is further disposed opposite to the hollow conductor heat exchange core with a slight gap. A cylinder-shaped permanent magnet is rotatably supported in the fluid pipe via a bearing device, and the cylinder-shaped permanent magnet and the hollow conductor heat are produced by relative rotation of the cylinder-shaped permanent magnet and the hollow conductor heat-exchange core. It is characterized in that the fluid flowing through the hollow conductor heat exchange core is heated by slip heat generated in the hollow conductor heat exchange core by relatively rotating the exchange cores in opposite directions, Further, the heat exchange core in each of the fifth to ninth embodiments is constituted by a honeycomb core body, and further, a catalyst is supported on the honeycomb core body, and the treatment is performed through the honeycomb core body. Heating the fluid in which or to perform the catalytic reaction. As the conductor, a hysteresis material provided with a hysteresis material or an eddy current material on the magnet side can also be used.
[0009]
In the present invention, “slip heat generation” means that when a conductor is moved (rotated) in a direction to cut the magnetic field in the magnetic field generated by the magnet, an eddy current (eddy current) is generated in the conductor. This means that heat is generated by electrical resistance in the conductor.
[0010]
That is, according to the present invention, a permanent magnet (ferrite, rare earth, etc.) and a conductor (heating element) such as a material having a large magnetic hysteresis (hereinafter referred to as “hysteresis material”) or an eddy current material are separated by a slight gap. It uses slip heat generated on the conductor side by shearing the magnetic path by rotating the magnet and the conductor relative to each other. By using an eddy current material or a hysteresis material for the conductor, several seconds to several It has a feature that heat can be generated at a temperature of 200 to 600 ° C. in 10 seconds. The gap is not particularly limited, but is usually about 0.3 to 1.0 mm.
[0011]
As a heat exchange system in the present invention, a system in which a fluid in a pipe is brought into direct or indirect contact with a conductor which is a heating element can be used. As a method of exchanging heat by directly contacting the fluid in the pipe with the conductor, there are a method in which a window hole is provided in the fluid pipe in the pipe and the surface of the conductor is exposed in the fluid pipe in the pipe, or a method in which it is in contact with the radiation fin. In addition, as a method of exchanging heat by indirectly contacting the fluid in the pipe with the conductor, a method of exchanging heat through a fluid pipe wall in the pipe or by providing a heat exchange core in the pipe can be used.
[0012]
In addition, as a rotational drive system of the permanent magnet and the heat exchange core in the present invention, for example, a system that rotates using a rotating body or a pulley or a gear that is rotationally driven by a motor drive or an engine drive can be used. . Especially in the case of a motor drive system, the heat generation amount is set as desired by controlling the rotation speed, or the drive motor is turned off when the temperature reaches a predetermined temperature or reversely rotated for rapid heating. It is also possible.
[0013]
As the magnet heater ON / OFF control means, for example, a temperature sensor is used to measure the temperature of the fluid in the pipe, and when the temperature reaches a predetermined temperature, the rotation drive of the permanent magnet or the heat exchange core is stopped. Can be used.
[0014]
In the present invention, the conductor generates heat due to the relative rotation between the magnet and the conductor, and the amount of generated heat is not as high as that of the above-described viscous heater, and the amount of generated heat can be maintained at a high value. In addition, by using an eddy current material or a hysteresis material for the conductor, heat can be generated at a temperature of 200 to 600 ° C. in a few seconds to a few tens of seconds, so that a catalyst is supported on the honeycomb core body to reduce NOx in the exhaust gas. In addition, the catalyst activation temperature can be raised in a short time.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a longitudinal side view showing a first embodiment of the magnet heater according to the present invention, FIG. 2 is a view corresponding to FIG. 1 showing the second embodiment, and FIG. 3 is a view showing the third embodiment. FIG. 4 is a longitudinal sectional view taken along the line AA in FIG. 3, FIG. 5 is an illustration of the types of fins in FIG. 3, (a) is a ribbon-shaped fin, (b) is a cross-shaped fin. FIG. 6 is a longitudinal front view showing the fourth embodiment, FIG. 7 is a longitudinal front view showing the fifth embodiment, and FIG. 8 is a longitudinal front view showing the sixth embodiment. FIG. 9 is a longitudinal side view showing the seventh embodiment, FIG. 10 is an eighth embodiment, FIG. 9A is a longitudinal side view, and FIG. FIGS. 11A and 11B show the ninth embodiment, wherein FIG. 11A is a longitudinal side view, and FIG. 11B is a cross-sectional view taken along the line E in FIG. FIG. 12 also shows the tenth embodiment, where (a) is a longitudinal side view, (b) is a cross-sectional view on the Ea line of (a), and FIG. 13 is a longitudinal side view showing the eleventh embodiment. 14 is a longitudinal side view showing the twelfth embodiment, FIG. 15 is a longitudinal side view showing the thirteenth embodiment, FIG. 16 is a longitudinal front view showing the fourteenth embodiment, and FIG. It is a systematic diagram which shows the example which incorporated the magnet type heater of this invention in the heating apparatus of a vehicle, 1-1, 1-2, 1-3, 1-4, 1-5, 1-6, 1-7 1-8, 1-9, 1-10, 1-11, 1-12, 1-13, 1-14, MH is a magnet heater, 2 is a fluid pipe, 3 is a conductor tube, 3-1 Is an eddy current material, 4 is a fixed ring, 5 is a cylinder housing, 6 is a bearing device, 7 is a permanent magnet, 8 is a drive motor, 'Is a pulley driven and rotated by an engine, 9 is a rotating disk, 9-1 is a ring gear, 9-2 is a pinion gear, 10 is a flange joint, 10-1 is a fastening flange, 10-2 is a joint bolt, 11 is Radiation fins, 12 is a heat exchange core body, 12-1 is a honeycomb core body, 13 is an engine, 14 is an engine cooling water pipe, 15 is a heater core, and V is a valve.
[0016]
That is, in the magnet heater 1-1 shown in FIG. 1, the conductor tube 3 fitted around the fluid pipe 2 is fixed by the fixing rings 4 fitted around both sides of the conductor. A cylinder-type housing 5 is rotatably supported on the outer periphery of the fixed ring 4 via a bearing device 6 so as to surround. On the inner periphery of the cylinder-type housing 5, a cylindrical permanent magnet 7 arranged to face the conductor tube 3 with a slight gap is attached via a yoke 7a. A rotating disk 9 provided on the rotating shaft of the drive motor 8 is in contact with the outer peripheral surface of the cylinder type housing 5, and the cylinder type housing 5 is rotated via the rotating disk 9 when the drive motor 8 is activated. It is like that. In addition, the said conductor pipe 3 is comprised by sticking an eddy current material on the magnet side surface of base materials, such as a hysteresis material or this hysteresis material, or an iron material, an alnico material.
[0017]
In the magnet heater 1-1 having the above-described configuration, when the drive motor 8 is started, the cylinder-type housing 5 is rotated around the tube axis via the rotating disk 9 provided on the rotating shaft, and the permanent magnet 7 is a conductor. By rotating around the tube-forming body 3, the magnetic path formed between the conductor-made tube body 3 and the permanent magnet 7 is sheared, and slip heat is generated in the conductor 3. The heat generated by the conductor tube 3 is heated by exchanging heat with the fluid in the fluid pipe 2.
[0018]
Next, the magnet type heater 1-2 shown in FIG. 2 uses the fluid pipe 2 as a conductor, and the fluid pipe 2 is generally an iron pipe. A conductor is formed by sticking an eddy current material 3-1 made of copper or the like to the outside in a cylindrical shape.
[0019]
In the case of the magnet heater 1-2 shown in FIG. 2, when the drive motor 8 is activated, the cylinder-type housing 5 is rotated around the tube axis via the rotating disk 9 provided on the rotating shaft, and the cylinder is moved. As the permanent magnet 7 rotates around the eddy current material 3-1, the fluid pipe 2 as a conductor and the magnetic path formed between the eddy current material 3-1 and the permanent magnet 7 are sheared. In this manner, slip heat is generated mainly in the eddy current material 3-1.
[0020]
Moreover, the magnet type heater 1-3 shown in FIG. 3 is a system in which a part of the fluid pipe 2 is cut and a magnet type heater assembled separately from the fluid pipe 2 is incorporated in the cut portion. The cylindrical permanent magnet 7 is arranged on the outer periphery of the conductor tube 3 having the same inner diameter as the fluid pipe 2 and having the heat dissipating fins 11 on the inner peripheral surface with a slight gap therebetween. The cylinder housing 5 attached via the yoke 7a is rotatably supported via the bearing device 6, and is externally fitted to both ends of the conductor tube 3 and the joint pipe ends of the fluid pipe 2. In this structure, a flange joint 10 including a fixed fastening flange 10-1 and a joint bolt 10-2 for fastening the flange is incorporated into the fluid pipe 2.
[0021]
In addition, as the radiation fin 11 in the magnet type heater 1-3 shown in FIG. 3, the ribbon-shaped radiation fin 11-1 shown in FIG. 5A, the cross-type fin 11-2 shown in FIG. Can also be used. The ribbon-shaped radiating fin 11-1 is formed by twisting a single thin plate so as to be almost the same length as the conductor-made tubular body 3, and the ribbon-shaped radiating fin 11-1 is made of a conductor-made tubular body. 3. Insert into 3 and fix the appropriate part to the wall of the tube by brazing. For example, the cross-shaped fins 11-2 are formed by assembling two short flat plates into a cross shape, and the cross-shaped fins 11-2 are arranged at intervals in the tube axis direction by changing the phase to constitute a heat radiation fin. This cross-shaped fin 11-2 is also fixed to the inner wall of the tube by brazing at an appropriate location.
[0022]
In the case of the magnet heater 1-3 shown in FIG. 3, the conductor tube 3 constitutes a cut portion of the fluid pipe 2, and the operation is the same as that of the magnet heater 1-1 shown in FIG. When 8 is activated, the cylinder-type housing 5 is rotated around the tube axis via the rotating disk 9 provided on the rotating shaft, and the permanent magnet 7 is rotated around the conductor tube 3. The magnetic path formed between the conductor tube 3 and the permanent magnet 7 is sheared to generate slip heat in the conductor tube 3, and this slip heat is heat exchanged with the fluid in the conductor tube 3. Heated. Moreover, when the radiation fin 11 is provided in the conductor tube 3, the heat exchange efficiency with the fluid in the fluid pipe 2 is increased by increasing the heat transfer area.
[0023]
In addition, the rotation drive system of the cylinder type housing 5 in the embodiment shown in FIGS. 1 to 3 is not limited to the motor drive system as described above, and may be driven by an engine via a pulley, for example. Further, gears are provided on the outer peripheral surface of the cylinder-type housing 5 and the outer peripheral surface of the rotary disk 9 so as to mesh with each other, or a belt is stretched between the outer peripheral surface of the cylinder-type housing 5 and the outer peripheral surface of the rotary disk 9 to drive the belt. A desired driving method can be used as appropriate.
[0024]
The magnet type heater 1-4 shown in FIG. 6 is made of a plurality of segments having a fluid pipe 2 made of a conductor and attached to the magnet support 17-1 via a yoke 7a outside the conductor fluid pipe 2. Two disk-shaped permanent magnets 7-1 are arranged on the radial center line of the pipe so as to be rotatable on a plane parallel to the pipe axis direction of the conductor fluid pipe 2 with a slight gap therebetween. Has been. The two pairs of disk-shaped permanent magnets 7-1 are rotatably supported by pulleys 8 'driven by an engine, and parallel to the pipe axis direction of the conductor fluid piping 2 by the rotation of the pulleys 8'. They are preferably rotated on the same plane in the same direction and at the same rotational speed.
[0025]
In the magnet heater 1-4 having the configuration shown in FIG. 6, if each pulley 8 ′ is rotated by driving the engine, a pair of two disk-shaped permanent magnets 7-1 are respectively connected to the conductor fluid pipe 2. By rotating on a plane parallel to the axial direction, a magnetic path formed between the conductor fluid pipe 2 and the conductor fluid pipe 2 is sheared, and slip heat is generated in the conductor fluid pipe 2. The heat generated in the conductor fluid pipe 2 is heated by exchanging heat with the fluid in the fluid pipe 2.
[0026]
The magnet heater 1-5 shown in FIG. 7 is energy efficient by making the distance between the disk-shaped permanent magnet 7-1 and the pipe wall surface of the pipe 2 constant in the magnet heater 1-4 configured as shown in FIG. In order to improve, the pipe cross section in which the disk-shaped permanent magnet 7-1 attached to the magnet support 17-1 via the yoke 7a is opposed to each other has a flat shape such as an oval shape or an oval shape. The two pairs of disk-shaped permanent magnets 7-1 are supported on the outside of the flat conductor-made fluid piping 2 by the drive motor 8, preferably in the same direction and at the same speed. Is.
[0027]
Therefore, in the case of the magnet heater 1-5 having the configuration shown in FIG. 7, a stable magnetic path is formed between the flat conductor fluid pipe 2 and the disk-shaped permanent magnet 7-1. In addition, slip heat generation is efficiently generated in the flat conductor fluid pipe 2.
[0028]
The magnet type heater 1-6 shown in FIG. 8 replaces the pipe-shaped permanent magnet 7-1 of the conductor fluid pipe 2 with the flat conductor fluid pipe 2 shown in FIG. It is composed of a plurality of conductor fluid pipes 2-1 having a flat cross section. In this case, a pipe section disposed opposite to the disk-shaped permanent magnet 7-1 of the conductor fluid pipe 2 having a circular cross section is formed in a circular cross section. A plurality of conductor fluid pipes 2-1 having a flat cross section are branched from the conductor fluid pipe 2 on the same plane, and the conductor fluid pipes 2-1 having a flat cross section are formed. A disk-shaped permanent magnet 7-1 attached to the magnet support 17-1 via a yoke 7a is disposed on the outside of the pipe group so as to face the pipe group with a slight gap. Also in this case, the two pairs of disk-shaped permanent magnets 7-1 are each rotatably supported by the drive motor 8 on a plane parallel to the pipe axis direction of the pipe group, and the conductors are activated by the activation of each drive motor 8. The fluid pipe 2 is rotated on the plane parallel to the pipe axis direction, preferably in the same direction and at the same rotational speed.
[0029]
In the magnet heater 1-6 having the configuration shown in FIG. 8, when each drive motor 8 is activated, a pair of disk-shaped permanent magnets 7-1 each have a plurality of conductor fluid pipes 2 each having a flat cross section. -1 is rotated on a plane parallel to the pipe axis direction, the magnetic path formed with the conductor fluid pipe 2-1 is sheared, and slip heat is generated in the conductor fluid pipe 2-1. Occurs. In this case as well, a stable magnetic path is formed between the flat conductor fluid pipes 2-1 and the disk-shaped permanent magnet 7-1, so that a plurality of flat conductor fluids are formed. Slip heat is efficiently generated in the pipe 2-1, and heat is exchanged with the fluid in the fluid pipe 2-1, and the pipe is heated.
[0030]
A magnet heater 1-7 shown in FIG. 9 is applied to a resin-made fluid pipe. In this case, a conductor-made pipe body 3 having a predetermined length is fitted and fixed in the resin-made fluid pipe 2P. The disk-shaped permanent magnet 7-1 attached to the magnet support 17-1 via the yoke 7a at the pipe outer side position opposite to each other via the pipe wall of the pipe making body 3 and the resin fluid pipe 2P. Is disposed opposite to the resin fluid piping 2P with a slight gap therebetween. Also in this case, the two pairs of disk-shaped permanent magnets 7-1 are each rotatably supported by the drive motor 8 on a plane parallel to the pipe axis direction of the pipe group, and the conductors are activated by the activation of each drive motor 8. The fluid pipe 2 is rotated on the plane parallel to the pipe axis direction, preferably in the same direction and at the same rotational speed.
[0031]
In the magnet heater 1-7 having the configuration shown in FIG. 9, when each drive motor 8 is activated, two pairs of disk-shaped permanent magnets 7-1 are planes parallel to the tube axis direction of the resin fluid piping 2P. By rotating above, the magnetic path formed between the resin fluid pipe 2P and the conductor pipe body 3 inside the pipe is sheared, and slip heat is generated in the conductor pipe body 3. The heat generated in the conductor tube 3 is heated by exchanging heat with the fluid in the resin fluid pipe 2P. However, in the case of the magnet heater 1-7, the magnetic path formed between the disk-shaped permanent magnet 7-1 and the conductor tube 3 is formed through the tube wall of the resin fluid pipe 2P. The heat generation efficiency is slightly lower than that of each of the above-described magnet heaters having no inclusion between the magnet and the conductor.
[0032]
Next, a magnet type heater in which a heat exchange core is built in a conductor fluid pipe will be described with reference to FIGS.
First, a magnet type heater 1-8 shown in FIG. 10 is provided on the inner periphery of a cylinder-type housing 5 rotatably supported via a bearing device 6 on the outer periphery of a fixing ring 4 fitted on the conductor fluid pipe 2. A cylindrical permanent magnet 7 arranged opposite to the conductor fluid pipe 2 with a slight gap is attached via a yoke 7a. A heat exchange core 12 is built in the conductor fluid pipe 2 at a position facing the cylindrical permanent magnet 7. As the heat exchange core 12, for example, as shown in FIG. 2B, a honeycomb structure in which a flat plate made of a magnetic material and a corrugated plate are stacked and wound can be used. The honeycomb structure as the heat exchange core is preferably made of a metal carrier usually used for purifying the exhaust gas of the engine from the viewpoint of vibration resistance and heat resistance.
The cylinder housing 5 is rotated by a drive motor 8 through a pinion gear 9-2 that meshes with a ring gear 9-1 attached to the outer peripheral surface thereof.
[0033]
In the magnet heater 1-8 having the configuration shown in FIG. 10, when the drive motor 8 is activated, a cylinder housing is provided via a pinion gear 9-2 provided on the rotating shaft and a ring gear 9-1 meshing with the gear. 5 rotates around the pipe axis and the permanent magnet 7 rotates around the conductor fluid pipe 2, so that the magnetic path formed between the conductor fluid pipe 2 and the permanent magnet 7 is sheared. Slip heat is generated in the conductor fluid pipe 2. The heat generated in the conductor fluid pipe 2 is heated by heating the heat exchange core 12 installed in the conductor fluid pipe 2 and exchanging heat with the fluid flowing in the core.
[0034]
A magnet type heater 1-9 shown in FIG. 11 has a conductor heat exchange core (for example, made of ferritic steel) 12 installed in a fluid pipe 2 made of conductor or nonconductor, and upstream of the conductor heat exchange core 12. On the side, a segment-like permanent magnet 7 arranged to face the heat exchange core made of conductor with a slight gap is rotatably supported in the fluid pipe via a bearing device 6. The permanent magnet 7 is provided alternately with the flow hole 17-2a on a magnet support 17-2 having a flow hole 17-2a on the surface facing the conductor heat exchange core 12 as shown in FIG. And is configured to be rotationally driven by a drive motor 8 installed outside the fluid pipe 2. Also in this case, the conductor heat exchange core 12 may be a honeycomb structure made of a magnetic material in which flat plates and corrugated plates similar to those described above are stacked and wound.
[0035]
In the case of the magnet heater 1-9 configured as shown in FIG. 11, when the drive motor 8 is activated, it is attached to the magnet support 17-2 with the flow hole 17-2a supported on the rotating shaft. When the permanent magnet 7 rotates, the magnetic path formed between the permanent magnet 7 and the conductor heat exchange core 12 is sheared, and slip heat is generated in the conductor heat exchange core 12. The heat generated by the conductor heat exchange core 12 is heat-exchanged and heated by the fluid flowing in the core through the flow hole 17-2a of the magnet support 17-2 installed on the upstream side of the core. It has become so.
[0036]
A magnet heater 1-10 shown in FIG. 12 is a heater of a type in which conductor heat exchange cores are arranged in tandem in a fluid pipe, and the structure thereof is a fluid made of a conductor or a nonconductor on the downstream side and the upstream side. Permanent magnets in which a conductor heat exchange core 12 is disposed in the pipe 2 and is disposed between the upstream and downstream conductor heat exchange cores 12 so as to face each conductor heat exchange core with a slight gap therebetween. A magnet support 17-2 with a flow hole 17-2a having a bearing 7 is rotatably supported via the bearing device 6, and the magnet support 17-2 meshes with a ring gear 9-1 attached to the outer peripheral surface thereof. It is rotated by a drive motor 8 via a pinion gear 9-2. The magnet support 17-2 with the flow holes 17-2a has the flow holes 17-2a alternately with the segment-like permanent magnets 7 on the surface facing the conductor heat exchange core 12, as shown in FIG. It has a perforated structure. Also in this case, the conductor heat exchange core 12 may be a honeycomb structure made of a magnetic material in which flat plates and corrugated plates similar to those described above are stacked and wound.
[0037]
In the case of the magnet heater 1-10 having the configuration shown in FIG. 12, when the drive motor 8 is activated, the pinion gear 9-2 provided on the rotating shaft and the ring gear 9-1 meshing with the gear are used. By rotating the magnet support 17-2 around the tube axis, the magnetic paths formed between the upstream and downstream conductor heat exchange cores 12 and the respective permanent magnets 7 are sheared, so that Slip heat is generated in the conductor heat exchange core 12. The heat generated in the conductor heat exchange core 12 is heated by heat exchange with the fluid flowing in the core.
[0038]
A magnet heater 1-11 shown in FIG. 13 is a heater using a hollow conductor-made heat exchange core, and the structure thereof is a conductor-made or non-conductor-made fluid pipe 2 in a hollow conductor-made heat exchange core 12-1. The cylindrical permanent magnet 7 disposed opposite to the hollow conductor heat exchange core 12-1 with a slight gap is rotatably supported in the fluid pipe via the bearing device 6. Then, it is rotated by a drive motor 8 disposed outside the fluid pipe 2. Also in this case, as the conductor-made heat exchange core 12-1, a honeycomb structure made of a magnetic material in which flat plates and corrugated plates similar to those described above are stacked and wound can be used. The hollow conductor heat exchange core 12-1 may be attached using a conductor inner case.
[0039]
In the case of the magnet heater 1-11 having the configuration shown in FIG. 13, when the drive motor 8 is activated, the cylindrical permanent magnet 7 supported on the rotating shaft is rotated to thereby rotate the permanent magnet 7. And the hollow conductor heat exchange core 12-1 are sheared, and slip heat is generated in the hollow conductor heat exchange core 12-1. The heat generated by the hollow conductor heat exchange core 12-1 is heated by heat exchange with the fluid flowing in the core.
[0040]
A magnet heater 1-12 shown in FIG. 14 is a heater of a system in which a hollow conductor-made heat exchange core and a cylindrical permanent magnet are separately rotated, and the structure thereof is made of non-conductors on the upstream side and the downstream side. A hollow conductor heat exchange core 12-1 is supported on the inner wall of the pipe through the bearing device 6 so as to be able to rotate around the pipe axis so as to straddle the fluid pipe in the fluid pipe 2. The hollow conductor heat exchange core 12-1 is attached to the outer periphery thereof and is rotated by the drive motor 8 via a ring gear 9-1 and a pinion gear 9-2 meshing with the gear. . On the other hand, a cylindrical permanent magnet 7 disposed opposite to the hollow conductor heat exchange core 12-1 with a slight gap is rotatably supported in the fluid pipe 2 via a bearing device 6. It is rotated by a drive motor 8 disposed outside the fluid pipe 2. Also in this case, as the conductor-made heat exchange core 12-1, a honeycomb structure made of a magnetic material in which flat plates and corrugated plates similar to those described above are stacked and wound can be used. 12-1 may be attached using a conductor inner case.
[0041]
In the case of the magnet type heater 1-12 having the configuration shown in FIG. 14, the hollow conductor-made heat exchange core 12-1 and the cylindrical permanent magnet 7 can be separately rotated and driven, for example, the permanent magnet 7 Fluid that flows through the hollow conductor heat exchange core by slip heat generated in the hollow conductor heat exchange core by fixing the side and rotating the hollow conductor heat exchange core 12-1 side by the drive motor 8 Is heated. Further, by fixing the hollow conductor heat exchange core 12-1 side and rotating the permanent magnet 7 side by the drive motor 8, it is possible to generate slip heat generation in the hollow conductor heat exchange core. Furthermore, in the case of this magnet type heater 1-12, the permanent magnet 7 side and the hollow conductor heat exchange core 12-1 side can be driven to rotate in opposite directions. It can be secured in a sufficiently wide range, and heat exchange can be performed with high heat generation efficiency.
[0042]
Magnet heaters 1-13 and 1-14 shown in FIGS. 15 and 16 are applied to, for example, an exhaust gas catalyst device of a diesel engine, and the magnet heater 1-13 shown in FIG. Two disk-shaped permanent magnets 7-1 attached to the magnet support 17-1 via the yoke 7a outside the conductor fluid pipe 2 with the same configuration as the magnet heater 1-4 shown in FIG. The pipes are disposed opposite to each other with a slight gap so as to be rotatable on a plane parallel to the pipe axis direction of the conductor fluid pipe 2 on the center line in the radial direction of the pipe. The permanent magnet 7-1 is rotatably supported by each drive motor 8, and in addition to a mechanism that is rotated on a plane parallel to the pipe axis direction of the conductor fluid piping 2 by the activation of each drive motor 8, For example, disk-shaped permanent magnet 7-1 It is slidable to each tube-axis direction by the fluid pressure cylinder mode. A honeycomb core body 12-1 is built in the conductor fluid piping 2 at a position opposite to the permanent magnet 7, and a catalyst is supported on the honeycomb core body 12-1. The reason why the disk-shaped permanent magnet 7-1 is slidable in the tube axis direction is to prevent the permanent magnet from being heated to a temperature above the Curie point by slip heat generation, exhaust heat, or reaction heat, and the magnetic force disappearing. is there.
[0043]
In the case of the magnet heater 1-13 shown in FIG. 15, when each drive motor 8 is activated, a pair of two disk-shaped permanent magnets 7-1 are parallel to the pipe axis direction of the conductor fluid pipe 2 respectively. By rotating on a flat plane, the magnetic path formed between the conductor fluid pipe 2 is sheared and slip heat is generated in the conductor fluid pipe 2. The honeycomb core body 12-1 in the fluid pipe 2 is heated to activate the catalyst. In this case, the temperature can be raised to the catalyst activation temperature in a short time by the slip heat generated in the conductor fluid pipe 2. When the catalyst reaches a high temperature, the disk-shaped permanent magnet 7-1 is slid in the tube axis direction and retracted to prevent the permanent magnet from being heated above the Curie point to lose its magnetic force. On the other hand, when the temperature of the catalyst becomes low, the disk-shaped permanent magnet 7-1 is again slid in the opposite direction to the predetermined position, and the same operation as described above is performed.
In the magnet heater 1-13 shown in FIG. 15, the disk-shaped permanent magnet 7-1 is slidable in the tube axis direction, but the disk-shaped permanent magnet 7-1 is slidable in the direction perpendicular to the tube axis. It is good.
[0044]
16 is structurally the same as the magnet heater 1-5 shown in FIG. 7, and the distance between the disk-shaped permanent magnet 7-1 and the pipe wall surface of the pipe 2 is set. In order to improve the energy efficiency by keeping constant, the pipe cross section in which the disk-shaped permanent magnets 7-1 attached to the magnet support 17-1 via the yoke 7a are opposed to each other has a flat shape such as an ellipse or an ellipse. In this structure, the two pairs of disk-shaped permanent magnets 7-1 are rotatably supported by the drive motor 8 on the outside of the flat conductor fluid pipe 2. The permanent magnet 7-1 can be moved in the pipe diameter direction by, for example, a fluid pressure cylinder system. A honeycomb core body 12-1 is built in the conductor fluid piping 2 at a position opposite to the permanent magnet 7, and a catalyst is supported on the honeycomb core body 12-1. The disk-shaped permanent magnet 7-1 is made slidable in the tube diameter direction, as described above, because the permanent magnet is heated above the Curie point by slip heat generation, exhaust heat and reaction heat, and the magnetic force disappears. This is to prevent it.
[0045]
Also in the case of the magnet heater 1-14 shown in FIG. 16, if each drive motor 8 is activated, a pair of two disk-shaped permanent magnets 7-1 are parallel to the pipe axis direction of the conductor fluid pipe 2 respectively. By rotating on a flat plane, the magnetic path formed between the conductor fluid pipe 2 is sheared and slip heat is generated in the conductor fluid pipe 2. The honeycomb core body 12-1 in the fluid pipe 2 is heated to activate the catalyst. In the case of this heater, a stable magnetic path is formed between the flat conductor fluid pipe 2 and the disk-shaped permanent magnet 7-1, so that slip heat is generated in the flat conductor fluid pipe 2. Is efficiently generated, and the temperature can be raised to the catalyst activation temperature in a shorter time. When the catalyst reaches a high temperature, the disk-shaped permanent magnet 7-1 is moved outward in the radial direction of the tube and retracted to prevent the permanent magnet from being heated to a temperature above the Curie point to lose its magnetic force. On the other hand, when the temperature of the catalyst becomes low, the disk-shaped permanent magnet 7-1 is moved again in the opposite direction to the predetermined position, and the same operation as described above is performed.
[0046]
FIG. 17 shows an example in which the magnet heater of the present invention is incorporated in a piping configuration in which the cooling water of the engine 13 is circulated through the cooling water piping 14 through the valve V and the heater core 15. The engine coolant as the flowing fluid in the pipe is heated by exchanging heat by slip heat generation when passing through the magnet heater MH.
[0047]
FIG. 18 exemplifies heat generation data in the case where a rare earth magnet and an eddy current material were experimentally tested by the present inventor. This data indicates that the gap between the permanent magnet and the eddy current material is 1.0 mm. It shows the relationship between time (sec) and temperature measured by varying the number of rotations on the magnet side with the eddy current material side fixed, set and opposed.
From this data, when a magnet and a conductor are arranged facing each other with a slight gap and the magnet and the conductor are rotated relative to each other, slip heat generation of 200 to 600 ° C. occurs in the conductor in several seconds to several tens of seconds. Recognize. Therefore, when a conductor is attached to the engine cooling water piping side, the temperature of the heat exchange surface with the circulating water can be heated to a high temperature of 200 to 600 ° C. in a very short time.
[0048]
Needless to say, as the fluid in the pipe, liquids such as heat medium oil and silicon oil, or gas bodies such as gasoline, exhaust gas from diesel engines, air, and fuel gas from fuel cells can be used as the fluid in the pipe. . Further, the number of magnet heaters is not limited to one, and a necessary number may be installed according to the application.
[0049]
【The invention's effect】
As described above, the magnet heater according to the present invention utilizes the slip heat generated in the conductor by relatively rotating the permanent magnet and the conductor made of the hysteresis material provided with the hysteresis material or the eddy current material on the magnet side surface. As a result, the structure can be simplified, the size and cost can be reduced, and the non-contact mechanism without wear can ensure higher reliability and safety. For example, when heating is required rapidly when the engine is cold, the engine cooling water is rapidly warmed by starting the drive motor, and the heating function of the engine can be remarkably improved. Therefore, the present invention exhibits an excellent effect as an auxiliary heater capable of heating the fluid in the pipe to a high temperature in a shorter time and efficiently, and is particularly effective for a cold district specification vehicle equipped with a diesel engine.
Moreover, not only can the temperature rise characteristics be improved by the heat exchange core, but also the catalyst activation temperature can be raised in a short time by supporting the catalyst on the heat exchange core having a honeycomb structure, so that the catalyst is heated by an energizing heater (EHC). Compared with the conventional method of purifying exhaust gas, the purifying ability of a catalyst such as NOx is excellent, and the effect of reducing NOx and HC in exhaust gas of a gasoline engine, a diesel engine, etc. is greatly exhibited.
Furthermore, the present invention has an excellent effect that it can be used for raising the temperature of a fuel gas such as hydrogen gas for a fuel cell.
[Brief description of the drawings]
FIG. 1 is a longitudinal side view showing a first embodiment of a magnet heater according to the present invention.
FIG. 2 is a longitudinal side view showing the second embodiment.
FIG. 3 is a longitudinal side view showing the third embodiment.
4 is a longitudinal sectional view taken along the line E—I in FIG. 3;
FIGS. 5A and 5B exemplify the types of fins in FIG. 3, wherein FIG. 5A is a perspective view showing a ribbon-type fin and FIG. 5B is a cross-type fin.
FIG. 6 is a longitudinal sectional view showing a fourth embodiment.
FIG. 7 is a longitudinal sectional view showing a fifth embodiment.
FIG. 8 is a longitudinal front view showing the sixth embodiment.
FIG. 9 is a longitudinal sectional side view showing a seventh embodiment.
FIGS. 10A and 10B show an eighth embodiment, wherein FIG. 10A is a longitudinal side view, and FIG. 10B is a cross-sectional view on the Ea line of FIG.
FIGS. 11A and 11B show a ninth embodiment, wherein FIG. 11A is a longitudinal side view, and FIG. 11B is a cross-sectional view taken along the line E in FIG.
FIGS. 12A and 12B show the tenth embodiment, in which FIG. 12A is a longitudinal side view, and FIG. 12B is a cross-sectional view taken along the Ea line of FIG.
FIG. 13 is a longitudinal side view showing the eleventh embodiment.
FIG. 14 is a longitudinal sectional view showing the twelfth embodiment.
FIG. 15 is a longitudinal sectional side view showing the thirteenth embodiment.
FIG. 16 is a longitudinal sectional view showing the fourteenth embodiment.
FIG. 17 is a system diagram showing an example in which the magnet heater of the present invention is incorporated in a vehicle heating device.
FIG. 18 is a diagram showing an example of heat generation data when a rare earth magnet and an eddy current material were experimentally tested by the present inventors.
[Explanation of symbols]
1-1, 1-2, 1-3, 1-4, 1-5, 1-6, 1-7, 1-8, 1-9, 1-10, 1-11, 1-12, 1- 13, 1-14, MH Magnet heater
2 Fluid piping
3 Conductor tube
3-1 Eddy current material
4 Fixing ring
5 Cylinder type housing
6 Bearing device
7 Permanent magnet
8 Drive motor
9 rotating disk
9-1 Ring gear
9-2 Pinion gear
10 flange joint
10-1 Flange for fastening
10-2 Joint bolt
11, 11-1, 11-2 Radiation fin
12 Heat exchange core body
12-1 Honeycomb core body
13 engine
14 Engine cooling water piping
15 Heater core
V valve

Claims (2)

A system in which a magnet and a conductor are opposed to each other with a slight gap and the fluid is heated by slip heat generated in the conductor by relatively rotating the magnet and the conductor, and the fluid pipe is made of resin. Arranged inside the cylinder housing rotatably supported by the fluid pipe via a bearing device so as to surround the conductor fitted on the outer periphery of the resin fluid pipe with a slight gap therebetween. The permanent magnet is fixed, and a conductor tube is fitted and fixed in the resin fluid pipe facing the permanent magnet, and the fluid in the pipe is caused by slip heat generated in the conductor by the rotation of the cylinder housing. A magnet-type heater characterized by a heated structure. A system in which a magnet and a conductor are opposed to each other with a slight gap and the fluid is heated by slip heat generated in the conductor by relatively rotating the magnet and the conductor, and the fluid pipe is made of resin. A pair of disk-shaped permanent magnets rotatably supported on a plane parallel to the pipe axis direction on the radial center line of the pipe is arranged opposite to each other with a slight gap on the outside of the resin fluid pipe, A structure in which a conductor tube is fitted and fixed in a fluid pipe facing the disk-shaped permanent magnet, and the fluid in the pipe is heated by slip heat generated in the conductor tube by rotation of the disk-shaped permanent magnet; A magnet type heater characterized by what has been done.

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