JP6012188B2 - Coil unit - Google Patents

Description

  The present invention relates to a coil unit, and more particularly to a coil unit used in a non-contact power feeding device.

  In recent years, a non-contact power supply device that supplies power to, for example, a battery of an electric vehicle without mechanical contact such as a cable has been developed and put into practical use. This non-contact electric power feeder is comprised from the power receiving side coil mounted in the vehicle, and the electric power feeding side coil installed in the parking space where a vehicle parks. According to such a non-contact power feeding device, the vehicle is parked in the parking space, and AC power is supplied to the power feeding side coil in a state where the power receiving side coil and the power feeding side coil face each other with an interval therebetween in the axial direction. Then, the AC power is received by the power receiving coil in a non-contact manner by electromagnetic induction or magnetic field resonance.

  In the non-contact power feeding apparatus described above, heat is generated in the coil, and it is necessary to cool it. As such a cooling device for cooling the coil, for example, the one shown in FIG. 6 has been proposed (Patent Document 1). As shown in the figure, the cooling device 100 includes a cylindrical bobbin 101, a coil 102 wound around the outer peripheral wall of the bobbin 101, and a blower fan 103 provided in the bobbin 101. According to this cooling device 100, when the blower fan 103 is turned, air is introduced into the bobbin 101 from the axial opening of the bobbin 101 as indicated by an arrow 104, and then the air exhaust hole provided in the outer peripheral wall of the bobbin 101. 105 is exhausted from the bobbin 101.

  The coil 102 described above is generally accommodated in a case 106. For this reason, since air is introduced from the axial opening of the bobbin 101 with the above-described configuration, it is necessary to provide the air inlet 107 on the lid (or bottom surface) of the case 106. However, if the air inlet 107 is provided in the lid of the case 106, it is necessary to increase the distance between the power receiving side coil and the power feeding side coil, and there is a possibility that the power feeding efficiency may be lowered. There is also a problem that the dustproof and waterproof properties are not good. Therefore, it is conceivable to connect a duct hose to the air inlet 107 so that water and dust do not enter the case 106, but the thickness direction of the cooling device 100 increases.

  In order to solve this problem, for example, as shown in FIG. 7, it is conceivable to provide an intake port 107 and an exhaust port 108 on the outer peripheral wall along the winding direction of the coil 102 of the case 106. In this case, in order to improve the flow of wind, the inlet 107 and the outlet 108 are provided at opposing positions. However, the coil 102 described above generates heat at a plurality of locations. In this case, as shown in FIG. 7, there is a problem that a portion that is not on the extension line of the air introduction direction, such as the heat generation portion 109, cannot be cooled only by flowing straight air in the introduction direction indicated by the arrow. It was.

  Therefore, in order to send air along the coil 102 in the case 106, for example, as shown in FIG. 8, a hose 110 surrounding the coil 102 is provided to cool the entire coil 102 evenly. As shown in FIG. 9, a plurality of air inlets 107 may be provided to send air to a plurality of heat generating portions 109. However, these methods have a problem in that a step of covering the coil 102 with the hose 110 is required, resulting in an increase in cost, and a plurality of air inlets 107 are required, resulting in a complicated structure.

JP 2010-284011 A

  Then, this invention makes it a subject to provide the coil unit which can cool the whole coil by simple structure.

The invention according to claim 1 for solving the above-described problem is a coil unit including a coil and a case that accommodates the coil, and air is introduced into the outer peripheral wall of the case. An intake port and an exhaust port for exhausting air outside the case are provided, and an adjustment wall for adjusting the flow direction of the air introduced from the intake port is provided outside the coil, and is introduced from the intake port. The air traveling in the introduction direction changes the traveling direction from the introduction direction after hitting the adjustment wall from the introduction direction , then reaches the exhaust port, is introduced from the intake port, and proceeds in the introduction direction. The coil is characterized in that the adjustment wall is provided such that the contact angle between the air and the adjustment wall that the air that has advanced in the introduction direction hits is closer to the exhaust port than 90 degrees. To unit To.

According to a second aspect of the invention, the adjustment wall, consists in a coil unit according to claim 1, characterized in that it comprises a plurality of outer walls outwardly and inwardly the case disposed in a polygonal shape of the coil .

According to a third aspect of the present invention, there is provided the coil unit according to the second aspect, wherein the angle formed by the outer wall portions adjacent to each other is 120 to 160 degrees.

As described above, according to the first aspect of the present invention, the air that is introduced from the intake port and proceeds in the introduction direction passes through the coil , then strikes the adjusting wall, changes its traveling direction , and then reaches the exhaust port. Therefore, the air introduced from the intake port goes straight in the introduction direction and is not immediately discharged from the exhaust port, but is exhausted from the exhaust port after hitting the adjustment wall and traveling around the case. For this reason, the whole coil can be cooled with a simple configuration. In addition, since the contact angle on the side close to the exhaust port of the air introduced from the intake port and traveling in the introduction direction and the adjustment wall that the air traveling in the introduction direction hits is larger than 90 degrees, Even if a lot of air flows and is discharged slightly from the exhaust port, it is possible to earn an air volume that circulates along the coil.

According to the second aspect of the present invention, since the adjustment wall has a plurality of outer wall portions arranged in a polygonal shape outside the coil and inside the case, the adjustment wall advances along the coil while hitting the outer wall portion. The entire coil can be cooled more uniformly by the configuration.

According to the invention described in claim 3, since the angle formed between the adjacent outer wall portions is 120 degrees to 160 degrees, air does not stay at the corners of the outer wall portions. .

It is explanatory drawing which shows one Embodiment of the non-contact electric power feeder incorporating the coil unit of this invention. It is sectional drawing of the electric power feeding side coil unit shown in FIG. 1 in 1st Embodiment. It is the II sectional view taken on the line of FIG. It is sectional drawing of the electric power feeding side coil unit shown in FIG. 1 in a reference example . It is sectional drawing of the electric power feeding side coil unit shown in FIG. 1 in the modification of a reference example . It is sectional drawing which shows an example of the cooling device of the conventional coil. It is sectional drawing which shows an example of the cooling device of the conventional coil. It is sectional drawing which shows an example of the cooling device of the conventional coil. It is sectional drawing which shows an example of the cooling device of the conventional coil.

1st Embodiment Hereinafter, the coil unit in 1st Embodiment is demonstrated with reference to FIGS. 1-3. As shown in FIG. 1, a non-contact power feeding device 1 incorporating a coil unit includes a power feeding side coil unit 4 installed in a parking space 3 of a vehicle 2 and a power receiving side coil unit 5 mounted on the vehicle. ing. The power supply side coil unit 4 includes a coil 6 to which AC power is supplied, a resonance coil 7 electromagnetically coupled to the coil 6, and a case 8 that houses the coil 6 and the resonance coil 7. The power receiving side coil unit 5 includes a resonance coil 9 that electromagnetically resonates with the resonance coil 7, a coil 10 that is electromagnetically coupled to the resonance coil 9, and a case (not shown) that houses the resonance coil 9 and the coil 10. Yes. The coils 6 and 10 are provided by bending a belt-shaped metal plate into a loop shape. The resonance coils 7 and 9 are provided by bending a band-shaped metal plate in a spiral shape.

  According to the above-described contactless power supply device 1, as shown in FIG. 1, when the vehicle 2 stops on the parking space 3 and the resonance coils 7, 9 face each other, the resonance coils 7, 9 electromagnetically resonate with each other. Thus, power can be supplied from the power feeding side coil unit 4 to the power receiving side coil unit 5 in a non-contact manner.

  More specifically, when AC power is supplied to the coil 6, the power is sent to the resonance coil 7 by electromagnetic induction. When power is sent to the resonance coil 7, the power is sent wirelessly to the resonance coil 9 due to magnetic field resonance. Further, when electric power is sent to the resonance coil 9, the electric power is sent to the coil 10 by electromagnetic induction and supplied to a load connected to the coil 10.

  Next, details of the case 8 constituting the above-described power supply side coil unit 4 will be described. As shown in FIG. 3, the case 8 includes a bottomed cylindrical main body 8 a that houses the coil 6, the resonance coil 7, and a support member (not shown) that supports the coils 6 and 7, and a main body. A lid portion 8b that covers the opening of the portion 8a and a ring-shaped rubber sponge 8c provided between the main body portion 8a and the lid portion 8b are provided.

  The main body 8a is made of a conductive material such as metal, and includes a disc-shaped bottom wall 8a-1, an outer peripheral wall 8a-2 standing from the periphery of the bottom wall 8a-1, and an outer peripheral wall 8a-. 2 and a flange wall 8a-3 projecting inwardly from the end of the two. The bottom wall 8 a-1 is orthogonal to the axial direction of the coil 6 and the resonance coil 7, and the outer peripheral wall 8 a-2 is erected along the winding direction of the coil 6 and the resonance coil 7. As shown in FIG. 2, the outer peripheral wall 8 a-2 is provided with an intake port 8 a-4 for introducing air into the case 8 and an exhaust port 8 a-5 for exhausting air outside the case 8. ing. The exhaust port 8a-5 is provided so as not to be located on the extension line L in the introduction direction Y1 from the intake port 8a-4.

  The intake port 8a-4 and the exhaust port 8a-5 are provided with cylindrical mounting portions 8a-6 and 8a-7 for connecting a duct hose, which will be described later, projecting outward at the periphery. One end of a duct hose (not shown) is attached to the attachment portions 8a-6 and 8a-7. Thus, the intake port 8a-4 and the exhaust port 8a-5 are connected to a fan box (not shown) via the duct hose. Accordingly, the protruding direction of the mounting portion 8a-6 provided at the peripheral edge of the intake port 8a-4 is the air introduction direction Y1.

  As shown in FIG. 3, the lid portion 8b includes a disc-shaped upper wall 8b-1 that covers the opening of the main body portion 8a, and a standing wall 8b that stands from the peripheral edge of the upper wall 8b-1 toward the main body portion 8a. -2. This standing wall 8b-2 is overlapped with the flange wall 8a-3 of the main body 8a via the rubber sponge 8c. The rubber sponge 8c closes the gap between the main body portion 8a and the lid portion 8b, so that waterproof and dustproofing can be achieved.

In the case 8 described above, an adjustment wall 11 for adjusting the flow direction of the air introduced from the intake port 8a-4 is provided. The adjustment wall 11 is provided upright in the axial direction of the coil 6 and the resonance coil 7. The adjustment wall 11 is surrounded by a plurality of outer wall portions 111 arranged in a polygonal shape (an octagonal shape in this embodiment) outside the coil 6 and the resonance coil 7 and inside the case 8, and the outer wall portion 111. And a communication wall portion 112 that communicates the intake port 8a-4 and the exhaust port 8a-5. The outer wall 111 is provided such that an angle θ ₁ formed between adjacent outer walls 111 is 135 degrees. Further, the air inlet 8a-4 is provided so that the air introduced from the air inlet 8a-4 and traveling along the introduction direction Y1 hits the outer wall 111 at a contact angle θ ₂ of 107 degrees.

  Next, cooling of the power feeding side coil unit 4 will be described. When a fan in a fan box (not shown) is turned, air is introduced into the case 8 from the intake port 8a-4 through the intake duct hose as shown in FIG. The air introduced from the intake port 8a-4 and traveling in the introduction direction Y1 reaches the outer wall portion 111 of the adjustment wall 11 before reaching the intake port 8a-4 and changes its traveling direction. After that, it further strikes the outer wall 111 and proceeds along the coil 6 and the resonance coil 7, and is exhausted from the exhaust port 8a-5. The air exhausted from the exhaust port 8a-5 is returned to the fan box via a duct hose (not shown).

  According to the first embodiment described above, the air introduced from the intake port 8a-4 and proceeding in the introduction direction Y1 reaches the outer wall 111 constituting the adjustment wall 11 before reaching the exhaust port 8a-5. Since the traveling direction is changed, the air introduced from the intake port 8a-4 advances straight in the introduction direction Y1 and does not immediately exhaust from the exhaust port 8a-5, but hits the adjusting wall 11 and enters the case 8 After exhausting, the air is exhausted from the exhaust port 8a-5. For this reason, the coil 6 and the entire resonance coil 7 can be cooled with a simple configuration.

  According to 1st Embodiment mentioned above, the adjustment wall 11 exists in the outer side of the coil 6 and the resonance coil 7, and the exhaust port 8a-5 is located on the extension line L of the introduction direction Y1 from the inlet port 8a-4. Therefore, the air introduced from the intake port 8a-4 and traveling in the introduction direction Y1 hits the adjusting wall 11 outside the coil 6 and the resonance coil 7, travels inside the case 8, and is exhausted from the exhaust port 8a-5. . For this reason, the coil 6 and the entire resonance coil 7 can be cooled with a simple configuration.

According to the first embodiment described above, the air that is introduced from the intake port 8a-4 and travels in the introduction direction Y1 and the discharge port 8a-4 of the outer wall 111 that the air that travels in the introduction direction Y1 hits. Since the contact angle θ ₂ on the near side is larger than 107 degrees and 90 degrees, even if a lot of air flows to the discharge port 8a-4 side and is slightly discharged from the discharge port 8a-4, The air volume circulating along the coil 6 and the resonance coil 7 can be earned. Further, since the angle θ ₁ formed between the adjacent outer wall portions 111 is set to 135 degrees and 120 to 160 degrees, air does not stay at the corners of the outer wall portions 111.

  In addition, according to 1st Embodiment mentioned above, although the adjustment wall 11 used the outer side wall part 111 provided between the case 8, the coil 6, and the resonance coil 7, this invention is limited to this. is not. As the adjustment wall 11, the outer peripheral wall 8a-2 of the case 8 may be used. In this case, the air introduced from the intake port 8a-4 and traveling in the introduction direction Y1 hits the outer peripheral wall 8a-2 (= outer wall portion) outside the coil 6 and the resonance coil 7 and travels around the case 8 before exhausting. It exhausts from the opening 8a-5.

  Moreover, according to 1st Embodiment mentioned above, although the adjustment wall 11 was provided with the outer side wall part 111 and the communication wall part 112, this invention is not limited to this. Only the outer wall 111 may be provided without providing the communication wall 112.

  Moreover, according to 1st Embodiment mentioned above, although the outer side wall part 111 was provided with two or more, this invention is not limited to this. As the outer wall portion 111, only one outer wall portion 111 at a position intersecting the introduction direction Y1 may be used.

Further, according to the first embodiment described above, the contact angle θ ₂ is set to 107 degrees, but the present invention is not limited to this, and the contact angle θ ₂ may be larger than 90 degrees. If it is, much air can be flowed to the discharge port 8a-4 side.

Further, according to the first embodiment described above, the plurality of outer wall portions 111 are arranged in an octagonal shape and the angle θ _{1 is set} to 135 degrees, but the present invention is not limited to this. For example, the plurality of outer wall portions 111 are arranged in a hexagon shape to an 18 angle shape, and air does not stay at the corners of the outer wall portion 111 even if the angle θ ₁ is 120 degrees to 160 degrees.

Reference Example Next, a coil unit in a reference example will be described with reference to FIG. 4, parts that are the same as those already described in the first embodiment with reference to FIG. 2 are given the same reference numerals, and detailed descriptions thereof are omitted. The difference between the first embodiment and the reference example is the shape of the main body 8 a of the case 8 and the adjustment wall 11. In 1st Embodiment, it has arrange | positioned so that the exhaust port 8a-5 may not be on the extension line L of the introduction direction Y1 from the intake port 8a-4, but in the reference example , the exhaust port 8a-5 is It arrange | positions on the extension line | wire of the introduction direction Y1 from the inlet port 8a-4.

  In addition to the outer wall 111 and the communication wall 112, the adjustment wall 11 further includes three triangular inner wall portions 113 arranged inside the coil 6 and the resonance coil 7. One of the three inner wall portions 113 is arranged on the extended line Y1 of the intake port 8a-4 with the apex of the triangle facing the intake port 8a-4. The remaining two are arranged along the inner periphery of the coil 6 and the resonance coil 7 so that the apex of the triangle faces the outer peripheral wall 8a-2.

  Next, cooling of the power feeding side coil unit 4 will be described. The air taken in from the intake port 8a-4 and traveling in the introduction direction Y1 reaches the inner wall portion 113 disposed on the intake port 8a-4 side, and is diverted to the right and left in the drawing of the inner wall portion 113. The Thereafter, the diverted air passes between the outer wall 111 and the inner wall 113, flows along the coil 6 and the resonance coil 7, and is exhausted from the exhaust port 8a-5.

According to the reference example described above, since the adjustment wall 11 has the inner wall portion 113 disposed inside the coil 6 and the resonance coil 7, the air introduced from the intake port 8a-4 advances in the introduction direction Y1. In this case, the flow is divided by hitting the inner wall portion 113 disposed inside the coil 6 and the resonance coil 7 and proceeds along the coil 6 and the resonance coil 7. Therefore, the coil 6 and the resonance coil 7 as a whole are cooled more uniformly with a simple configuration. it can.

In the reference example described above, a triangular shape is used as the inner wall portion 113, but the present invention is not limited to this. The inner wall 113 may have any shape, for example, a shape as shown in FIG.

Further, in Reference Example described above, the inner wall portion 113, had plurality, as the inner side wall portion 113, may be only one thing at a position intersecting the direction of introduction Y1.

Further, in Reference Example described above, adjustment wall 11 and the outer wall portion 111 and Rendorikabe portion 112, an inner wall portion 113 has been composed, without providing the outer side wall portion 111 and Rendorikabe unit 112, You may be comprised only from the inner wall part 113. FIG.

Further, according to the first implementation described above, but the adjustment wall 11 and the casing 8 has been provided separately, the present invention is not limited thereto. For example, the case 8 may be provided in a polygonal shape so as to have the function of the adjustment wall 11.

Further, according to the first implementation described above, but describes the feeder coil unit 4 installed in the parking space 3, the present invention is not limited thereto. The power receiving side coil unit 5 arranged in the vehicle 2 may have the same configuration.

Further, according to the first implementation described above, had provided a coil 6, 10 and the resonance coil 7 and 9 by bending a strip-shaped metal plate, the present invention is not limited thereto. For example, a coil bobbin may be disposed in the case 8 and the coils 6 and 10 and the resonance coils 7 and 9 may be provided by winding the coil bobbin around the coil bobbin.

  In the above-described embodiment, the resonance type non-contact power feeding device 1 is used. However, the present invention is not limited to this, and the non-contact power feeding method may be an electromagnetic induction type. The coil unit 1 is not limited to non-contact power feeding, and may be applied to various devices as a single unit.

  Further, the above-described embodiments are merely representative forms of the present invention, and the present invention is not limited to the embodiments. That is, various modifications can be made without departing from the scope of the present invention.

4 Power supply coil unit (coil unit)
6 Coil 7 Resonance coil (coil)
8 Case 8a-2 Outer wall of the case 8a-4 Inlet 8a-5 Exhaust 11 Adjustment wall 111 Outer wall 113 Inner wall Y1 Introduction direction

Claims (3)

In a coil unit comprising a coil and a case for housing the coil,
The outer peripheral wall of the case is provided with an intake port for introducing air into the case, and an exhaust port for exhausting air outside the case,
On the outside of the coil, there is an adjustment wall for adjusting the flow direction of air introduced from the intake port,
The introduced from the intake port, the air proceeds to the introduction direction, after crossing the coil, the traveling direction is changed hits from the direction of introduction into the adjustment wall, then reaches the exhaust port,
The adjustment is performed so that the contact angle between the air introduced from the intake port and proceeding in the introduction direction and the adjustment wall against which the air proceeding in the introduction direction hits is closer to the exhaust port than 90 degrees. A coil unit characterized in that a wall is provided . The coil unit according to claim 1 , wherein the adjustment wall has a plurality of outer wall portions arranged in a polygonal shape outside the coil and inside the case. The coil unit according to claim 2 , wherein an angle formed by the outer wall portions adjacent to each other is set to be 120 degrees to 160 degrees.

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