JP2011009791A - Reactor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a reactor which is excellent in heat dissipation.SOLUTION: The reactor 1 is installed in vehicles such as hybrid vehicles and electric vehicles. The reactor 1 includes a core 2 having a coil winding portion, and a coil 3 disposed at the coil winding portion. In the coil 3, a heat sink 4 is disposed at the side of a cooling base where the reactor 1 is installed. The heat sink 4 which is a nonmagnetic material with thermal conductivity over 3 W/m×K is adhered to the coil 3 with an adhesive. Heat in the coil 3 is efficiently transferred to the cooling base via the heat sink 4 and the adhesive.

Description

  The present invention relates to a reactor used for components of an in-vehicle DC-DC converter such as a hybrid vehicle. In particular, it relates to a reactor with excellent heat dissipation.

  Conventionally, a reactor including a core made of a magnetic material and a coil disposed in the core is known. A typical example is a structure in which a reactor is housed in an aluminum case and sealed by injecting resin into this case. This case is cooled so that the coil and core that generate heat when energized can be cooled efficiently. It is attached to a base (cooler) (FIG. 5 of Patent Document 1).

JP 2007-129146 A

However, with a conventional reactor, it is difficult to further improve heat dissipation.
In recent years, reactors used in hybrid vehicles and the like are desired to further improve heat dissipation so as to cope with an increase in heat generation of coils and cores due to high frequency and large current.

  Then, the objective of this invention is providing the reactor which is excellent in heat dissipation.

  The reactor of the present invention is a reactor mounted on a vehicle such as a hybrid vehicle or an electric vehicle. The reactor includes a core having a coil winding portion and a coil disposed in the coil winding portion. In the coil, a heat radiating plate is disposed on the cooling base side where the reactor is installed. This heat radiating plate is a non-magnetic material, has a thermal conductivity of more than 3 W / m · K, and is bonded to the coil with an adhesive.

  The reactor of the present invention is configured to be directly attached to the cooling base. Moreover, this invention reactor is the structure which has arrange | positioned the heat sink which generally has a part which consists of an inorganic material whose heat conductivity is higher than a silicone resin in the coil which becomes easy to become high temperature rather than a core. With these configurations, the heat of the core and the coil can be efficiently transmitted to the cooling base and released, and the heat dissipation is excellent. In particular, the reactor of the present invention is small and light when it does not have a case for housing the coil and core assembly.

  The heat radiating plate is entirely made of a material having high thermal conductivity. Specifically, a material having a thermal conductivity α (W / m · K) of more than 3 W / m · K, particularly 20 W / m · K or more, more preferably 30 W / m · K or more is preferable. Further, since the heat radiating plate is disposed in contact with the coil, it is preferable that the whole is made of a nonmagnetic material in consideration of magnetic characteristics. The material satisfying such characteristics is preferably a nonmagnetic inorganic material. Inorganic materials include conductive materials and insulating materials. The constituent material of at least the coil-side contact surface that comes into contact with the coil in the heat sink is desired to be electrically insulated from the coil, and is therefore an insulating material. Therefore, the heat sink may be entirely composed of an insulating inorganic material, or may have a laminated structure in which a surface of a plate-like substrate made of a conductive inorganic material is provided with a layer made of an insulating inorganic material. . Note that “insulating” has an insulating property that can ensure electrical insulation with the coil.

Ceramics can be suitably used as the insulating inorganic material. Specifically, silicon nitride (Si ₃ N ₄ ): about 20 to 150 W / m · K, alumina (Al ₂ O ₃ ): about 20 to ₃₀ W / m · K, aluminum nitride (AlN): 200 to 250 W / Examples include at least one selected from about m · K, boron nitride (BN): about 50 to 65 W / m · K, and silicon carbide (SiC): about 50 to 130 W / m · K. That is, a heat dissipation plate made of one type of material may be used, or plate pieces made of a plurality of types of materials may be combined and integrated, and the thermal characteristics may be partially changed. Of the above ceramics, silicon nitride is preferable because it has high thermal conductivity and is superior in bending strength to alumina, aluminum nitride, and silicon carbide.

  The heat sink made of the ceramics can be easily manufactured in various sizes and shapes by, for example, sintering powder. Commercial products may be used. The reactor of the present invention can be constructed by separately manufacturing such a heat sink or by preparing it separately and placing it on a coil.

  In the reactor of the present invention, the core is a portion other than the coil winding portion, and the core installation surface located on the cooling base side is flush with the base side contact surface that contacts the cooling base in the heat sink. Is preferred.

  In the configuration in which the coil protrudes from the core, for example, a recess that accommodates the protruding portion is provided in the cooling base, and the core is located on both sides of the coil and the coil is not disposed (a portion other than the coil winding portion). The reactor is attached to the cooling base so that it is supported by the surface of the cooling base. At this time, a reactor is fully supported, so that the area of the exposed location supported by a cooling base is large. However, the increase in the area of the exposed portion increases the installation area of the reactor with respect to the cooling base, that is, the reactor becomes larger. On the other hand, when the volume of the exposed portion supported by the cooling base is made equal to that of a conventional reactor, the height of the core increases if the core installation surface of the core is flush with the base-side contact surface of the heat sink. However, since the area (projected area) of the exposed portion supported by the cooling base can be reduced, the installation area of the reactor with respect to the cooling base can be reduced, that is, the reactor can be reduced in size. Further, in this configuration, since the core can also directly contact the cooling base, the heat of the core can be efficiently transmitted to the cooling base, and the heat dissipation can be improved. Further, in this configuration, the surface on the cooling base side of the reactor is flat, so that the reactor can be stably attached to the cooling base without providing a recess for housing the coil in the cooling base.

  Furthermore, it is preferable that this invention reactor is provided with the resin coating part which covers the outer periphery. However, the resin coating portion is provided so that these surfaces are exposed so that the base side contact surface of the heat sink and the core installation surface of the core can contact the cooling base.

  According to this structure, a core, a coil, and a heat sink can be integrated by the resin coating | coated part, and it is excellent in handling property. Further, the reactor can be strengthened by the resin coating portion, and in particular, even a core made of a compacted body can be mechanically protected. Furthermore, the core and the coil can be protected from the external environment such as corrosion and dust by the resin coating portion. As the resin coating portion, an insulating resin, specifically, an epoxy resin, a urethane resin, a polyphenylene sulfide (PPS) resin, a polybutylene terephthalate (PBT) resin, an acrylonitrile-butadiene-styrene (ABS) resin, or the like can be used. The thickness of the resin coating portion is preferably about 1 to 2 mm in consideration of moldability.

  It is preferable that the resin covering portion is integrally formed with a fixing flange portion provided with an insertion hole through which a fastening member for fixing the reactor to the cooling base is inserted.

  In order to fix the reactor to the cooling base, a fastening member such as a screw or a bolt can be preferably used. If the insertion hole for the fastening member is provided integrally with the resin coating portion, the reactor of the present invention can be easily and reliably fixed to the cooling base. The cooling base is provided with a screw hole into which the fastening member is screwed.

  In order to fix the reactor of the present invention to the cooling base, a fixing member may be used separately. Specifically, a pressing member having a pair of leg portions fixed to the cooling base and an elastic portion that is disposed between the both leg portions and presses a surface located on the opposite side of the coil installation surface in the coil is used. Can be mentioned.

  When the reactor of the present invention is fixed to the cooling base by the above-described pressing member, the reactor is pressed against the cooling base by the elastic portion. Because of this pressing force, the adhesiveness of the coil, the heat radiating plate, and the cooling base can be enhanced, so that the heat dissipation is further improved. In consideration of corrosion resistance, the pressing member is preferably made of a metal such as stainless steel. In particular, stainless steel is preferable because of its excellent strength and elasticity.

  As another method for fixing the reactor of the present invention to the cooling base, a fastening member can be used in the same manner as described above, and the core itself can be provided with an insertion hole through which the fastening member is inserted. At this time, the insertion hole is provided at a location other than the coil winding portion in the core.

  According to this configuration, the pressing member as described above is unnecessary, and the number of parts can be reduced.

  The reactor of the present invention is excellent in heat dissipation.

1 is a perspective view of a reactor according to Embodiment 1. FIG. FIG. 3 is a right side view of the reactor according to the first embodiment. FIG. 3 is a top view of a core provided in the reactor according to the first embodiment. FIG. 5 is a right side view of the reactor according to the second embodiment. 6 is a front view of a reactor according to Embodiment 3. FIG.

  Hereinafter, a reactor according to an embodiment of the present invention will be described in detail with reference to the drawings.

(Embodiment 1)
FIG. 1 is a perspective view of a reactor of the present invention, FIG. 2 is a right side view showing a state in which the reactor of the present invention is fixed to a cooling base, and FIG. 3 is a top view of a core provided in the reactor of the present invention. In FIG. 2, the cooling base shows a cross section (the same applies to FIGS. 4 and 5 described later). In the drawings, the same reference numerals denote the same items. The reactor 1 is used by being directly attached to a cooling base B having a refrigerant circulation path (not shown) therein, a core 2 made of a magnetic material, and a coil 3 disposed in the core 2, The heat radiating plate 4 disposed between the coil 3 and the cooling base B is a main constituent member.

  As shown in FIG. 3, the core 2 is an annular member having a coil winding portion 2c facing each other and formed in a closed loop shape, and includes a magnetic body portion 2m and a gap portion 2g. Here, the magnetic body portion 2m is formed of a compacted body of soft magnetic powder, and includes a rectangular parallelepiped block 2a and a curved block 2b in which a corner portion of the rectangular parallelepiped is curved. The gap portion 2g is formed of a rectangular plate made of a nonmagnetic material such as alumina. Here, six rectangular parallelepiped blocks 2a and two curved blocks 2b are used, and a pair of rectangular parallelepiped assemblies each including three rectangular parallelepiped blocks 2a are prepared, and the rectangular parallelepiped assembly is interposed between a pair of curved blocks 2b. Are arranged apart from each other and bonded to form a closed-loop core 2. A total of four gap portions 2g are interposed between the rectangular parallelepiped blocks 2a. Each rectangular parallelepiped group constitutes a coil winding part 2c.

  The rectangular parallelepiped block 2a (cuboid assembly) and the curved block 2b have different heights (the length in the direction perpendicular to the surface of the cooling base B when the reactor 1 is installed on the cooling base B), as shown in FIG. As seen from the side, the core 2 is H-shaped. In the state where the coil 3 is arranged on the outer periphery of the coil winding part 2c, the height Lh of the curved block 2b (the reactor 1 is arranged on the cooling base B so that the coil 3 on the cooling base B side does not protrude from the core 2). In this state, the length between the upper and lower surfaces of the curved block 2b is adjusted, and one surface (core installation surface 2i) located on the cooling base side in the curved block 2b is in contact with the cooling base B.

  For the coil 3, here, a first coil 3a and a second coil 3b formed by winding an edge-wise winding having an enamel coating on the surface of a flat copper wire are prepared and arranged in the coil winding portion 2c. One end of both coils 3a, 3b is welded to form a continuous coil (FIG. 1). A coil can also be formed by continuous windings. In this case, the winding is wound from one end side of one coil winding portion 2c toward the other end side, and is turned back to return the other coil winding portion 2c. A coil can be formed by winding the winding so that the winding is continuous from the other end side toward the one end side. Here, since the coil 3 is not folded, the core length Lc (the length from the end surface of one curved block 2b to the end surface of the other curved block 2b, FIGS. 2 and 3) can be shortened accordingly.

  When the coil 3 is disposed in the coil winding portion 2c (a rectangular parallelepiped set of the rectangular parallelepiped blocks 2a), the coil winding portion 2c of the core 2 is covered with the coil 3, and the curved block 2b is exposed from the coil 3. .

  An insulator 5 is also provided in the assembly of the core 2 and the coil 3. The insulator 5 includes a cylindrical portion (not shown) that covers the outer periphery of the core 2 and a plate-like flange portion 5F that comes into contact with the end surface of the coil 3. The cylindrical portion covers the outer periphery of the coil winding portion 2c of the core 2 by engaging the half-broken square tube pieces. The flange portion 5F is a pair of rectangular frames that are opposed to both end portions of the cylindrical portion and abut against each end face of the coil 3. For the insulator 5, an insulating material such as polyphenylene sulfide (PPS), polytetrafluoroethylene (PTFE), and liquid crystal polymer (LCP) can be used.

  And in the coil 3, the heat sink 4 is arrange | positioned at the coil installation surface 3i located in the cooling base side. Here, the heat radiating plate 4 is made of silicon nitride (27 W / m · K), and is a plate material having an area that can cover the coil installation surfaces 3 i of both the first coil 3 a and the second coil 3 b. The heat sink 4 is opposed to the coil side contact surface 4c in contact with the coil installation surface 3i, and the base side contact surface 4b in contact with the cooling base B is coated with grease or the like. It is preferable because of excellent adhesion. Here, the heat radiating plate 4 is made of the coil 3 with an adhesive having excellent thermal conductivity (sheet-like thermally conductive epoxy adhesive (5 W / m ・ K) manufactured by Nagase ChemteX Corporation) so as not to peel from the coil 3. It is fixed to. Further, the base side contact surface 4b of the heat radiating plate 4 and the core installation surface 2i are flush with each other.

  Further, the reactor 1 includes a resin coating portion 6 so as to cover the outer periphery thereof. Here, the resin coating portion 6 is an assembly of the core 2 and the coil 3, and after placing a heat sink 4 fixed to a predetermined location on the outer peripheral surface of the coil 3 in a mold, an epoxy resin is injected. It is formed by molding. However, the base-side contact surface 4b of the heat radiating plate 4 and the core installation surface 2i of the core 2 are not covered with the resin coating portion 6, but are exposed. Further, an end portion of the coil 3 to which wiring is separately connected also protrudes from the resin coating portion 6. The resin-coated portion 6 has a rectangular parallelepiped shape, and bolts 7 (fastening) for fixing the reactor 1 to the cooling base B at locations (four corners of the resin-coated portion 6) that cover the curved portions of the curved block 2b of the core 2, respectively. A fixed flange portion 6f provided with an insertion hole 6h through which a member is inserted is provided. The average thickness of the portion covering the core 2 and the coil 3 in the resin coating portion 6 is 1 to 2 mm. The shape of the resin coating portion 6 is not particularly limited. A shape generally along the outer shape of the assembly of the core 2 and the coil 3 may be used. Further, the installation location, shape (thickness), and installation number of the fixed flange portion 6f can be selected as appropriate, and are not particularly limited. For example, the fixing flange portion may be provided so as to protrude from the curved block 2b side or from the side surface of the coil 3.

  Reactor 1 having the above configuration aligns insertion hole 6h of fixing flange portion 6f of resin coating portion 6 with screw hole Bh provided in cooling base B, and tightens bolt 7 to screw in and tighten cooling base B Can be attached to. With this attachment, the heat sink 4 and the core 2 come into contact with the cooling base B.

  According to such a reactor 1, since the structure is directly attached to the cooling base B, the heat radiation performance is excellent by interposing the heat radiating plate 4 having high thermal conductivity between the coil 3 and the cooling base B. In particular, when the case is unnecessary, the reactor can be made smaller and lighter.

  In addition, since the reactor 1 has the same base-side contact surface 4b of the heat sink 4 and the core installation surface 2i of the core 2, the heat of the core 2 can be efficiently transmitted to the cooling base B and has excellent heat dissipation. In addition, with this configuration, the area of the portion where the core 2 is supported by the cooling base B can be reduced, that is, the core length Lc can be shortened, so that the reactor 1 can be made smaller.

  Furthermore, the reactor 1 is provided with the resin coating portion 6 so that (1) the core 2, the coil 3, and the heat sink 4 can be handled integrally. (2) The heat sink 4 can be securely fixed to the coil 3. Various effects can be achieved, such as :) the core 2 can be reinforced, (4) the core 2 and the coil 3 can be protected from the external environment, and (5) insulation can be secured with surrounding members.

  In addition, the reactor 1 can be easily attached to the cooling base B without using a separate fixing member by integrally providing the resin covering portion 6 with the fixing flange portion 6f. In the resin-coated portion 6, the vicinity of the fixed flange portion 6f is thick in the resin, but this thick region is limited to the four corners of the outer periphery of the reactor 1, and as a whole is thin, A reduction in heat dissipation due to the presence of the fixed flange portion 6f can be reduced.

(Modification 1-1)
In the first embodiment, the resin covering portion 6 is provided with the reactor fixing portion (fixing flange portion 6f) with respect to the cooling base, but the core 2 itself is provided with an insertion hole (not shown) through which the bolt 7 is inserted. It can be configured. If the core 2 is provided with a portion other than the coil winding portion 2c, in particular, a portion protruding outward from the curved portion of the curved block 2b, and the insertion hole is provided in this protruding portion, the magnetic characteristics of the core 2 are affected. It is difficult and preferable. The shape and the number of the protruding portions can be selected as appropriate, and are not particularly limited. The core 2 having the insertion hole can be easily manufactured by forming a green compact. When this protruding portion is also covered with the resin coating portion 6, an insertion hole is also provided in the resin coating portion so as to be continuous with the insertion hole of the core 2.

(Embodiment 2)
FIG. 4 is a right side view showing a state in which another embodiment of the reactor of the present invention is fixed to the cooling base. The reactor 10 also includes the core 2, the coil 3, and the heat sink 4 as main components, and is different from the reactor 1 of the first embodiment in that it does not include a resin coating portion, and the other points are the same. Since such a reactor 10 has few constituent members, it is easy to manufacture the reactor.

  The reactor 10 is preferably integrated by fixing the heat radiating plate 4 to the coil 3 with an adhesive or the like. According to this configuration, when attaching to the cooling base B, it is not necessary to separately arrange the heat sink on the cooling base, and even when the reactor 10 is attached to the lower surface of the cooling base, there is no fear of the heat sink dropping, Excellent mounting workability.

  In order to fix the reactor 10 to the cooling base B, the bolt (fastening member, not shown) for fixing the reactor 10 to the cooling base B is inserted into the core 2 itself as described in Modification 1-1 above. For example, an insertion hole (not shown) may be provided, or a separate fixing member may be used. The fixing member has, for example, a pair of leg portions and a connecting portion that connects the leg portions, and the linear connecting portion along the outer periphery of the coil or core holds the core or coil to the cooling base side. Those attached are preferred. The leg is provided with an insertion hole through which the bolt is inserted.

(Embodiment 3)
FIG. 5 is a front view showing a state in which another embodiment of the reactor of the present invention is fixed to the cooling base. The reactor 20 also includes the core 2, the coil 3, and the heat radiating plate 4 as main components, and includes the resin coating portion 6 as in the first embodiment. This reactor 20 is different from the reactor 1 of the first embodiment in that the reactor 20 includes a pressing member 8 that presses the reactor 20 against the cooling base, and the other points are substantially the same. Hereinafter, the description will focus on the differences, and description of other points will be omitted.

  The pressing member 8 includes a pair of leg portions 8a and 8b and an elastic portion 8c arranged so as to connect the leg portions 8a and 8b, and the elastic portion 8c is an M-shaped member curved in an arc shape. is there. The ends of the leg portions 8a and 8b are bent outward and are L-shaped, and have insertion holes 8h through which the bolts 7 are inserted in the short piece portions. This pressing member 8 is formed by bending or bending a wide plate material (stainless steel such as SUS304, SUS316) having a width equivalent to the region sandwiched between one end of the coil 3 and the joined end as appropriate. It is an integrated object formed by making it. On the other hand, here, the fixing flange portion 6f of the resin coating portion 6 is formed on the side surface side of the coil 3 (left and right sides in FIG. 5) across the region sandwiched between one end portion of the coil 3 and the joined end portion. ), And has a long hole 6hl.

  The pressing member 8 is a member that presses the coil 3 against the heat radiating plate 4 and also functions as a member that attaches the reactor 20 to the cooling base B. Specifically, after the reactor 20 is mounted on the cooling base B, the pressing member 8 is placed on the outer periphery of the resin coating portion 6 so that the elastic portion 8c is in contact with the surface of the coil 3 opposite to the coil installation surface 3i. It arrange | positions and the edge part of leg part 8a, 8b is made to contact the fixed flange part 6f. And, by inserting the bolt 7 into the insertion holes 8h and 6hl and tightening it to the screw hole Bh of the cooling base B, the reactor 20 can be fixed to the cooling base B, and the coil 3 is connected to the heat sink 4 side by the elastic portion 8c. When pulled, it is pressed against the cooling base B side.

  According to this configuration, since the coil 3 and the heat radiating plate 4 and the heat radiating plate 4 and the cooling base B can be brought into contact with each other more reliably by the pressing member 8, the heat dissipation of the reactor can be further improved. In addition, here, since the insulating coating portion 6 exists between the pressing member 8 and the coil 3, it is possible to ensure insulation between them.

  In the above embodiment, an example in which the pressing member is formed of a wide plate-like material has been described. However, one or more pressing members formed of a narrow plate-like material may be used. In the above embodiment, the hole through which the bolt 7 is inserted in the fixed flange portion 6f is a long hole, but an insertion hole corresponding to the size of the bolt 7 may be provided.

(Modification 3-1)
In the third embodiment, the configuration including the resin coating portion 6 has been described. However, the pressing member 8 can also be used for the reactor 10 that does not include the resin coating portion as in the second embodiment. In this case, in order to ensure insulation at locations where the pressing member may come into contact with the core 2 or the coil 3, an insulating film is provided, or an insulating material is provided between the pressing member and the core 2 or the coil 3. It is preferable to arrange them.

(Modification I)
Although the said Embodiment 1-3 demonstrated the structure which attaches a reactor to the upper surface of a cooling base, it is also possible to attach a reactor to the lower surface of a cooling base. At this time, reactors 1, 10 and 20 are all fixed to the coil, so there is no need to fix the heat sink to the cooling base separately, and the heat sink will fall off. There is no fear of mounting and excellent workability.

(Modification II)
In the first to third embodiments, an example in which a heat sink made of ceramics is provided has been described. However, as another heat sink, a ceramic layer is provided on the surface of a plate-like substrate made of a conductive material on the contact surface with the coil. Can be used. The plate-like substrate is made of a nonmagnetic metal material such as aluminum (236 W / m · K), copper (390 W / m · K), alloys thereof, austenitic stainless steel (for example, SUS304: 16.7 W / m · K). The thing which consists of is mentioned. The ceramic layer can be formed by preparing a ceramic plate and attaching it to the plate substrate, or by forming a film on the surface of the plate substrate by a PVD method, a CVD method, or the like. The ceramic layer may be provided on only one surface of the plate-like substrate or on both surfaces. By constituting a part of the heat radiating plate with a metal material having high thermal conductivity, the heat dissipation of the reactor can be further improved.

In addition, a coating made of ceramics such as Si ₃ N ₄ , Al ₂ O ₃ , AlN, BN, SiC, etc. is formed by PVD or CVD at the location where the reactor is mounted on the cooling base where the coil contacts. Films can be substituted for the heat sink.

  The above-described embodiment can be appropriately changed without departing from the gist of the present invention, and is not limited to the above-described configuration. For example, the core may use a laminate in which a plurality of electromagnetic steel plates are laminated.

  Since the reactor of the present invention is excellent in heat dissipation, it can be suitably used, for example, as an in-vehicle component component such as an in-vehicle converter mounted on a vehicle such as a hybrid vehicle or an electric vehicle.

1,10,20 reactor
2 Core 2a Rectangular block 2b Curved block 2c Coil winding part
2m Magnetic body part 2g Gap part 2i Core installation surface
3 Coil 3a 1st coil 3b 2nd coil 3i Coil installation surface
4 Heat sink 4c Coil side contact surface 4b Base side contact surface
5 Insulator 5F Buttocks
6 Resin coating 6f Fixed flange 6h Insertion hole 6hl Long hole
7 volts
8 Pushing member 8a, 8b Leg part 8c Elastic part 8h Insertion hole
B Cooling base Bh Screw hole

Claims (3)

A reactor mounted on a vehicle such as a hybrid vehicle or an electric vehicle,
Comprising a core having a coil winding part, and a coil disposed in the coil winding part,
In the coil, a heat sink is arranged on the cooling base side where the reactor is installed,
The heat sink is a non-magnetic material and has a thermal conductivity of more than 3 W / m · K, and is bonded to the coil with an adhesive.   The reactor according to claim 1, wherein the adhesive has a thermal conductivity of 5 W / m · K or more.   The reactor according to claim 1, wherein the heat radiating plate has a plate-like substrate made of a nonmagnetic metal material.

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