JP7161344B2 - Reactor - Google Patents

Description

The present invention relates to a reactor in which a core, a coil and a sensor are integrated.

Reactors are used in a variety of applications, including drive systems for hybrid vehicles, electric vehicles, and fuel cell vehicles. For example, as a reactor used in a booster circuit for a vehicle, after winding a coil around a resin bobbin arranged around an annular core, these are housed in a metal case, and a filler is poured into the case. Hardened ones are often used (see Patent Document 1, for example).

JP 2011-124267 A

However, since it takes time to harden the filler, the reactor manufacturing time increases. Moreover, since the case is provided, the size of the reactor as a whole is increased. Therefore, there is a demand for a reactor that does not have a filler or a case. Fillerless, caseless reactors require the coil to be covered for insulation and the coil to be integrated with the core. Therefore, it is conceivable to mold the reactor by a molding method or the like and coat the periphery of the coil with resin.

Moreover, when providing a sensor in such a reactor, the sensor also needs to be insulated from the coil or integrated with the core or coil for fixing. Therefore, it is conceivable to integrate not only the core and the coil but also the sensor by resin molding.

However, since a plurality of members are housed in a mold and molded, it is difficult to fix the sensor with a jig. In particular, if resin molding is attempted without holding the lead wires in the mold of the sensor with a jig, the lead wires may be bent by the injection pressure of the resin and broken.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and an object thereof is to provide a reactor capable of preventing disconnection of lead wires and integrating a core, a coil, and a sensor. be.

The reactor of the present invention includes a core, a resin member covering the outer periphery of the core, a coil mounted on a part of the core, and a sensor fixed to the resin member and arranged to detect a physical quantity. , a coating member that coats the coil and the sensor with a resin and integrates the core, the coil, and the sensor, wherein the sensor includes a detection unit that detects a physical quantity; and a detection unit that is connected to the detection unit. a lead wire; and a first sensor covering portion covering the detecting portion and the lead wire in the covering member and fixed to the resin member , wherein the detecting portion detects temperature. The sensor is a sensor, and the covering member has a coil covering portion covering the inner and outer circumferences of the coil and a second sensor covering portion covering the first sensor covering portion, the coil covering portion and the second sensor covering portion. The sensor covering portion is formed seamlessly from a resin, the coil covering portion is in close contact with the coil, the second sensor covering portion is in close contact with the first sensor covering portion, and the first sensor covering portion is in contact with the coil covering portion. The inner circumference is in close contact with the detection section and the lead wire .

ADVANTAGE OF THE INVENTION According to this invention, the reactor which can prevent disconnection of a lead wire and can integrate a core, a coil, and a sensor can be obtained.

1 is a perspective view of a reactor according to an embodiment; FIG. 1 is an exploded perspective view of a reactor according to an embodiment; FIG. It is a perspective view of a reactor main body. It is a perspective view of a resin member. 1 is a perspective view of a sensor; FIG. It is an expansion perspective view of a sensor. FIG. 2 is a cross-sectional view taken along the line AA of FIG. 1; It is a figure which shows the resin member for demonstrating the reactor which concerns on other embodiment.

Hereinafter, reactors according to embodiments of the present invention will be described with reference to the drawings.

[1. embodiment]
[1-1. Constitution]
1 is a perspective view of a reactor according to an embodiment; FIG. FIG. 2 is an exploded perspective view of the reactor according to the embodiment. FIG. 3 is a perspective view of a reactor body.

In this specification, the z-axis direction shown in the drawings is the "upper" side, and the opposite direction is the "lower" side. "Bottom" is also referred to as "bottom" in describing the configuration of each member. "Upper" and "lower" refer to the positional relationship of each component of the reactor, and do not refer to the positional relationship or direction when the reactor is mounted on the actual device to be installed. The z-axis direction may also be referred to as the height direction. As will be described later, the winding axis direction of the coil 5 is the y-axis direction perpendicular to the z-axis direction, and the x-axis direction is the direction perpendicular to the z-axis and the y-axis. As will be described later, the x-axis direction is the direction in which the pair of coils 51a and 51b forming the coil 5 are arranged. These directions are expressions for indicating the positional relationship of each component of the reactor, and do not limit the positional relationship and direction when the reactor is installed in the installation target.

The reactor 100 of the present embodiment is a large-capacity reactor used, for example, in drive systems of hybrid vehicles, electric vehicles, and fuel cell vehicles. Reactor 100 is a main part of an electric circuit mounted on these automobiles.

As shown in FIGS. 1 to 3, the reactor 100 includes a reactor body 10, a sensor 3, and a covering member 4. As shown in FIGS.

The reactor body 10 has a core 1 , a coil 5 mounted around part of the core 1 , and a resin member 2 that covers the outer circumference of the core 1 and insulates the core 1 and the coil 5 .

(core)
As shown in FIG. 2, the core 1 has an annular shape having a pair of parallel straight portions and a U-shaped connecting portion connecting the straight portions. As shown in FIG. 3, straight portions of the core 1 around which the coils 5 are wound are legs where magnetic flux is generated. The U-shaped connecting portion where the coil 5 is not wound is a yoke portion through which the magnetic flux generated in the leg passes. That is, the yoke portion connects the pair of straight portions. Magnetic flux generated in the leg passes through the yoke to form an annular closed magnetic circuit in the core 1 .

The core 1 includes a magnetic material. Here, the core 1 has an annular shape in which legs of U-shaped cores 11 and 12 are butted against each other. The U-shaped cores 11 and 12 are made of a magnetic material such as a dust core, a ferrite core, or a laminated steel plate. Here, the U-shaped cores 11 and 12 are dust cores of the same shape. A gap may be provided between the abutting legs of the U-shaped cores 11 and 12 .

(Resin member)
4 is a perspective view of the resin member 2. FIG. The resin member 2 is a member that covers the outer periphery of the core 1 with resin, and is formed in an annular shape following the shape of the core 1 . Examples of the type of resin forming the resin member 2 include epoxy resin, unsaturated polyester resin, urethane resin, BMC (Bulk Molding Compound), PPS (Polyphenylene Sulfide), PBT (Polybutylene Terephthalate), and the like.

In this embodiment, the resin member 2 is divided into two parts, and has a resin body 2A and a resin body 2B. That is, the resin member 2 is formed by separately molding a substantially U-shaped resin body 2A and a resin body 2B, and placing the ends of the resin bodies 2A and 2B facing each other. The reason why the resin bodies 2A and 2B are formed separately is that the coils 5 are mounted on the resin member 2 by fitting the coils 5 into the pair of straight portions of the resin bodies 2A and 2B.

As shown in FIGS. 2 and 4, the resin bodies 2A and 2B include a pair of straight portions 21a and 21b, a connecting portion 21c connecting the straight portions 21a and 21b, and a fixing portion 22 for fixing the reactor 100. , a clamping portion 23 for clamping the end of the coil 5 , a mounting portion 24 for mounting the sensor 3 , and a partition plate 25 . In the resin bodies 2A and 2B, respective structures 21a to 21c and 22 to 25 are integrally formed of resin. That is, each of the components 21a to 21c and 22 to 25 is seamlessly formed from the same resin.

The straight portions 21a and 21b cover the legs of the U-shaped cores 11 and 12 and are portions to which the coil 5 is attached, and are also called bobbins. The connecting portion 21c covers the connecting portions of the legs of the U-shaped cores 11 and 12. As shown in FIG. That is, the U-shaped cores 11 and 12 are embedded in the resin bodies 2A and 2B by a resin molding method, and the outer peripheral portions of the U-shaped cores 11 and 12 covered with the resin bodies 2A and 2B are the resin bodies. It is in close contact with the inner peripheries of 2A and 2B. However, the end surfaces of the legs of the U-shaped cores 11 and 12 are exposed.

An opening (not shown) for exposing the bottom surfaces of the U-shaped cores 11 and 12 is provided on the bottom surface of the connecting portion 21c, and an opening for exposing the back surfaces of the U-shaped cores 11 and 12 is provided on the back surface of the connecting portion 21c. 210 is provided. These openings are configured to improve heat dissipation.

The fixing portions 22 are provided at both ends of the connecting portion 21c, respectively, and are provided at the four corners of the reactor 100 as a whole. The fixing portion 22 is provided with a screw hole into which a screw is inserted, and the reactor 100 is fixed to the installation target by inserting the screw and fastening. Installation targets include heat radiation sheets, PCU cases, mission cases, voltage control unit cases, bases of heat sinks, and the like.

The clamping portion 23 clamps and holds the end of the coil 5 . The holding portion 23 is provided on the upper surface of the connecting portion 21c. Specifically, a total of four holding portions 23 are provided on the upper surface of the connecting portion 21c and on the axes of the linear portions 21a and 21b. The clamping portion 23 has two plate-like bodies 231 erected on the upper surface of the connecting portion 21c separated by a thickness from the end portion 52 of the coil 5, which will be described later. The end portion 52 is held by inserting and pinching the end portion 52 .

The attachment portion 24 is a portion for attaching the sensor 3 . Specifically, a flange 34b provided on the sensor 3, which will be described later, is fixed (see FIG. 5). In this embodiment, the mounting portion 24 is two plate-like bodies 241 erected on the upper surface of the connecting portion 21c so as to be perpendicular to the winding axis direction (y-axis direction) of the coil 5. Between 241, a gap corresponding to the thickness of the brim portion 34b is provided. The attaching portion 24 determines the position of the sensor 3 in the y-axis direction by inserting the flange portion 34 b between the plate-like members 241 . Mounting portion 24 is provided on the upper surface of connecting portion 21 c on the center side of reactor 100 .

Further, the plate-like body 241 is provided with a notch 241a following the shape of the first sensor covering portion 34 (cylindrical portion 34a) described later. The position of the sensor 3 in the x-axis direction is determined by fitting the tubular portion 34a into the notch 241a.

The partition plate 25 is a plate-like body and is provided between the linear portions 21a and 21b in parallel with the yz plane. The partition plate 25 partitions the pair of coils 51 a and 51 b that constitute the coil 5 .

The partition plate 25 is a substantially right-angled triangular plate, one side of which is provided on the inner thigh portion of the U-shaped resin bodies 2A and 2B, that is, on the center side inner surface of the reactor 100 of the connecting portion 21c. . A side orthogonal to the one side extends parallel to the straight portions 21a and 21b (y-axis direction).

(coil)
The coil 5 is composed of a conductive wire having an insulating coating. As shown in FIGS. 2 and 3, the coil 5 has a pair of left and right coils 51a and 51b. The coils 51a and 51b are composed of a single copper wire coated with insulation such as enamel. The coils 51a and 51b of this embodiment are rectangular wire edgewise coils. However, the wire material and winding method of the coils 51a and 51b are not limited to edgewise coils of rectangular wires, and other forms may be used.

The coil 5 is mounted on the outer periphery of a pair of straight portions of the resin member 2 so that the coils 51a and 51b surround the leg portions of the core 1, and the coils 51a and 51b are parallel to each other. That is, the winding axis directions of the coils 51a and 51b are parallel to each other. This winding axis direction is parallel to the y-axis direction.

Ends 52 of the coils 51a and 51b are drawn out of the reactor body 10 through the upper sides of the resin bodies 2A and 2B, and are electrically connected to terminals by welding or the like. The end portion 52 is clamped by the clamping portion 23 and fixed in position.

(sensor)
FIG. 5 is a perspective view of the sensor 3. FIG. FIG. 6 is an enlarged perspective view of the sensor 3. FIG. However, in FIGS. 5 and 6, illustration of a connector 33, which will be described later, is omitted.

Sensor 3 detects a physical quantity related to reactor 100 . As shown in FIG. 3, the sensor 3 has a columnar shape and is provided between a pair of coils 51a and 51b.

As shown in FIGS. 2, 5 and 6, the sensor 3 has a detection portion 31, lead wires 32, a connector 33, and a first sensor covering portion .

Detector 31 detects a physical quantity related to reactor 100 . Here, the detection unit 31 is an element that detects the temperature of the reactor 100, and can use, for example, a thermistor. The detector 31 is arranged between the coils 51a and 51b.

The lead wire 32 has one end connected to the detection section 31 and the other end connected to the connector 33 . The lead wire 32 is composed of a metal wire and a covering portion covering it. The material of the metal wire may include copper, nickel, aluminum, silver, gold, or two or more thereof. The metal wire may be a single solid wire or a stranded wire in which multiple wires are twisted together. The covering portion covers the metal wire with an insulating member such as vinyl, silicone rubber, or fluororubber.

The connector 33 is configured such that a mating connector can be detachably attached. A physical quantity detected by the detection unit 31 is transmitted to an external device connected to the connector 33 via the lead wire 32 and the connector 33 .

The first sensor covering portion 34 is a resin member that covers the detecting portion 31 and the lead wires 32 . Examples of the type of resin that constitutes the first sensor covering portion 34 include epoxy resin, unsaturated polyester resin, urethane resin, BMC (Bulk Molding Compound), PPS (Polyphenylene Sulfide), PBT (Polybutylene Terephthalate), and the like. be done. The resin of the first sensor covering portion 34 may be of the same type as the resin forming the resin member 2, or may be of a different type.

The first sensor covering portion 34 has a cylindrical portion 34a, a flange portion 34b, a claw portion 34c, and a recessed portion 34d.

The tubular portion 34 a partially covers the detection portion 31 and the lead wire 32 . Specifically, the cylindrical portion 34 a covers the tip of the detection portion 31 to the middle of the lead wire 32 . That is, the cylindrical portion 34 a covers at least the detecting portion 31 and the lead wires 32 in the covering member 4 . The tubular portion 34a may cover the portion of the lead wire 32 located outside the covering member 4 as well. The front end portion of the cylindrical portion 34a provided with the detection portion 31 and the rear end portion on the opposite side are closed. However, the lead wire 32 is pulled out from the rear end portion to the outside of the cylindrical portion 34a.

The brim portion 34b is provided to protrude from the cylindrical portion 34a. Specifically, the brim portion 34b is provided so as to extend on a plane perpendicular to the axis of the tubular portion 34a, and here, protrudes in a C shape around the tubular portion 34a.

The claw portion 34c is provided to protrude from the cylindrical portion 34a. The claw portion 34c is provided apart from the brim portion 34b, and its projection length is shorter than that of the brim portion 34b. The claw portion 34 c is provided on the distal end side of the brim portion 34 b , that is, on the detection portion 31 side of the connector 33 . A notch 341 is provided at the end of the claw portion 34c projecting from the tubular portion 34a, ie, the lower end portion of the claw portion 34c. The upper edge of the partition plate 25 is fitted into this notch 341 .

34 d of recessed parts are the recesses provided in multiple numbers by the cylindrical part 34a. The inside of the cylindrical portion 34a is exposed to the recess 34d on the tip side of the flange portion 34b. The lead wire 32 inside the cylindrical portion 34a is not exposed in the recess 34d on the rear end side of the flange portion 34b.

Part of the detector 31 and the lead wire 32 may be protected by a heat-shrinkable tube that shrinks when heated, or a part of the lead wire 32 on the connector 33 side may be protected by a protective tube.

(coating member)
As shown in FIGS. 1 and 2, the covering member 4 covers the coil 5 and the sensor 3 with resin to integrate the core 1, the coil 5 and the sensor 3 together. Examples of the type of resin forming the coating member 4 include epoxy resin, unsaturated polyester resin, urethane resin, BMC (Bulk Molding Compound), PPS (Polyphenylene Sulfide), PBT (Polybutylene Terephthalate), and the like. The resin of the coating member 4 may be of the same type as the resin forming the resin member 2 or may be of a different type.

As the resin used for the covering member 4, a soft material that follows the vibration of the coils 51a and 51b is preferable. This is because the coating member 4 can be prevented from being peeled off from the resin member 2 and the coils 51a and 51b due to the vibration of the coils 51a and 51b. In other words, it is possible to suppress deterioration in heat dissipation due to the formation of an air layer between the coating member 4 and the resin member 2 or the coils 51a and 51b due to peeling.

As shown in FIGS. 1 and 2 , the covering member 4 has a coil covering portion 41 , a second sensor covering portion 42 and a terminal covering portion 43 . The coil covering portion 41 covers the coils 51a and 51b. The coil covering portions 41 for the coils 51a and 51b are referred to as coil covering portions 41a and 41b.

FIG. 7 is a cross-sectional view taken along line AA of FIG. As shown in FIGS. 2 and 7, the coil covering portions 41a and 41b have a double tube structure, that is, an outer tube 411, an inner tube 412 and a connecting portion 413. As shown in FIGS. The outer cylinder 411 covers the outer circumferences of the coils 51a and 51b. However, the upper and lower surfaces of the outer cylinder 411 are provided with openings 414 for exposing the upper and lower surfaces of the coils 51a and 51b.

The inner cylinder 412 covers the inner circumferences of the coils 51a and 51b. The connecting portion 413 connects the ends of the outer cylinder 411 and the inner cylinder 412 . Also, the connecting portion 413 connects the outer cylinder 411 and the inner cylinder 412 to the second sensor covering portion 42 and the terminal covering portion 43 .

The second sensor covering portion 42 fixes the position of the sensor 3 by covering the first sensor covering portion 34 . The terminal covering portion 43 fixes the position of the end portion 52 by covering the end portion 52 of the coils 51a and 51b drawn upward from the connecting portion 21c. However, the terminal covering portion 43 does not cover the tip of the end portion 52, and the wire material from which the insulating coating is removed is exposed so as to be electrically connected to the terminal. A sealing plate 431 that closes the opening 210 is provided at the tip of the terminal covering portion 43 .

In the covering member 4, each structure 41 to 43 is integrally formed of resin. In other words, each of the components 41 to 43 is seamlessly formed from the same resin.

[1-2. Production method]
A method for manufacturing reactor 100 will be described. The manufacturing method of the present reactor 100 has a primary molding process, an assembly process of the reactor body 10, and a secondary molding process.

(1) Primary molding process The primary molding process includes a mold core forming process and a first sensor covering part forming process.

In the mold core forming step, the resin bodies 2A and 2B are formed by a resin molding method. That is, the U-shaped cores 11 and 12 are placed in a mold, filled with resin, and solidified to form the mold core. Mold cores are resin bodies 2A and 2B in which U-shaped cores 11 and 12 are embedded. The periphery of the U-shaped cores 11 and 12 is in close contact with the resin bodies 2A and 2B.

The first sensor covering portion forming step is a step of forming the first sensor covering portion 34 by a resin molding method. That is, the detection part 31 and a part of the lead wire 32 are linearly accommodated in the mold, fixed with a jig, filled with resin, and solidified to form the first sensor covering part 34 . , sensor 3 is obtained. As a result, the cylindrical portion 34a, the flange portion 34b, and the claw portion 34c are seamlessly formed of resin. Since the first sensor covering portion 34 is formed by resin molding, the inner periphery of the cylindrical portion 34a, the detecting portion 31, and the lead wire 32 are in close contact with each other. The concave portion 34d of the first sensor covering portion 34 is a trace formed by pressing with a jig in this process.

A gate for injecting resin into the mold is provided on the front end side of the detection part 31 of the mold. Therefore, as shown in FIGS. 5 and 6, a resin injection mark 34e forming the first sensor covering portion 34 is provided at the tip of the cylindrical portion 34a. The tip referred to here is the end of the tubular portion 34 on the tip side of the detection portion 31, and is the end opposite to the side to which the lead wire 32 is connected.

In other words, by making the flow of the resin parallel to the direction in which the detection portion 31 and the lead wire 32 extend, the injection pressure of the resin can be suppressed from being applied to the lead wire 32, and the first sensor covering portion 34 can be prevented from being applied. It is possible to reduce the load on the lead wires 32 that may be caused by forming them.

(2) Assembly Process of Reactor Body 10 The assembly process of the reactor body 10 is a process of assembling the reactor body 10 . Coils 51a and 51b are fitted to the leg portions of the mold core, that is, straight portions 21a and 21b, and the ends of U-shaped cores 11 and 12 are butted against each other to form reactor body 10 having an annular shape. Also, the coils 51a and 51b are fixed by inserting each end portion 52 into the holding portion 23 respectively.

Also, as shown in FIG. 6, the sensor 3 is attached to the reactor body 10 . That is, the tubular portion 34a is fitted into the notch 241a, and the flange portion 34b is fitted into the plate-like body 241 so as to be attached to the mounting portion 24. The claw portion 34c is attached to the partition plate 25 by fitting the edge. As a result, the sensor 3 is fixed to the reactor body 10 by fixing the first sensor covering portion 34 to the resin member 2 (resin body 2B). When the sensor 3 is attached in this manner, the sensor 3 is positioned on one side of the partition plate 25 . In this embodiment, as shown in FIG. 6, the tip portion of the first sensor covering portion 34 (cylindrical portion 34a) is placed on the partition plate 25 of the resin body 2B.
(3) Secondary molding process The secondary molding process is a process of forming the covering member 4 by a resin molding method. A reactor body 10 to which the sensor 3 is attached is placed in a mold. At this time, the four ends 52 are inserted into recesses provided in the mold so as not to be covered with resin. Further, the side peripheral surface of the rear end portion of the tubular portion 34a is pressed by the inner peripheral wall of the mold. Therefore, the rear end of the tubular portion 34a is exposed to the outside of the mold. In this state, the mold is filled with resin. At this time, since the lead wire 32 in the mold is protected by the first sensor covering portion 34, it is possible to prevent the lead wire 32 from breaking due to the injection pressure of the resin. The covering member 4 is formed by solidifying the filled resin. Since the covering member 4 is formed by resin molding, the coil covering portion 41 is in close contact with the coil 5 and the resin member 2 and the second sensor covering portion 42 is in close contact with the first sensor covering portion 34 . Thereby, the core 1, the coil 5, and the sensor 3 are integrated.

[1-3. Action/effect]
(1) The reactor 100 of the present embodiment includes a core 1, a resin member 2 covering the outer circumference of the core 1, a coil 5 attached to a part of the core 1, and arranged fixedly with respect to the resin member 2. a sensor 3 for detecting a physical quantity; and a covering member 4 for covering the coil 5 and the sensor 3 with a resin to integrate the core 1, the coil 5 and the sensor 3, and the sensor 3 detects the physical quantity. a lead wire 32 connected to the detection part 31; I made it to have.

As a result, it is possible to obtain a reactor capable of preventing disconnection of the lead wire 32 and integrating the core 1 , the coil 5 and the sensor with the covering member 4 . That is, since the lead wire 32 is covered by the first sensor covering portion 34 to protect the lead wire 32 and the sensor 3 is fixed to the resin member 2, the core 1, the coil 5, and the sensor 3 are separated. The lead wires 32 can be prevented from being affected by the resin pressure even if the sensor 3 itself is not fixed with a jig when the sensor 3 is integrated by resin molding.

(2) The end of the first sensor covering portion 34 is exposed from the covering member 4 .

As a result, since the portion of the lead wire 32 embedded in the covering member 4 is protected by the first sensor covering portion 34, disconnection of the lead wire 32 can be prevented when the covering member 4 is formed by the resin molding method. can be prevented. Also, when forming the covering member 4, it is possible to prevent the generation of burrs at the end portion. That is, when forming the covering member 4, a plurality of members such as the core 1, the coil 5, and the sensor 3 are filled in the mold while the plurality of members are arranged in the mold. Therefore, it is necessary to increase the injection pressure of the resin in order to fill the resin to every corner. If the lead wire 32 is not covered with the first sensor covering portion 34, it is necessary to seal the inside of the mold by, for example, pressing the lead wire 32 strongly. difficult. As a result, the sealing becomes loose and resin burrs occur. On the other hand, since the end portion of the first sensor covering portion 34 is exposed from the covering member 4, the end portion, specifically, the side peripheral surface of the rear end portion of the tubular portion 34a can be formed with a mold. Since it can be pressed, it is possible to prevent the occurrence of burrs.

(3) The detection unit 31 is a temperature sensor that detects temperature, and the covering member 4 includes a coil covering portion 41 covering the inner and outer circumferences of the coil 5 and a second sensor covering portion covering the first sensor covering portion 34. , the coil covering portion 41 and the second sensor covering portion 42 are seamlessly formed of resin, the coil covering portion 41 is in close contact with the coil 5, and the second sensor covering portion 42 is the first sensor covering portion. The first sensor covering portion 34 is brought into close contact with the detecting portion 31 .

Thereby, the temperature of reactor 100 can be measured accurately. That is, most of the heat in the reactor 100 is generated from the coil 5, and the heat of the coil 5 is continuously applied to the coil covering portion 41, the second sensor covering portion 42, and the first sensor, which are seamlessly formed of resin. It is transmitted to the detection section 31 via the covering section 34 . In the heat conduction path formed by the coil covering portion 41, the second sensor covering portion 42, and the first sensor covering portion 34 from the coil 5 to the detecting portion 31, each part is in close contact with the air with poor heat conduction. is prevented from intervening, enabling accurate temperature measurement.

(4) The coil 5 is a pair of coils 51a and 51b, the sensor 3 has a columnar shape and is provided between the pair of coils 5, and the first sensor covering portion 34 includes the detection portion 31 and the lead wire 32. A tubular portion 34a that covers a part of the tubular portion 34a, a flange portion 34b that protrudes from the tubular portion 34a, is provided in the tubular portion 34a apart from the flange portion 34b, and protrudes from the tubular portion 34a, The resin member 2 includes a mounting portion 24 for fixing the flange portion 34b and a partition plate for partitioning between the pair of coils 51a and 51b. 25, and the flange portion 34b is attached to the attachment portion 24, and the claw portion 34c is attached to the partition plate 25. As shown in FIG.

As a result, the sensor 3 can be fixed to the reactor main body 10, so that there is no need to fix the sensor 3 with a jig when forming the covering member 4, and the sensor 3 can be resin-molded together with the reactor main body 10. . Further, since the flange portion 34b and the claw portion 34c are separated from each other, the columnar sensor 3 can be stably fixed. In other words, since the position of the detection portion 31 at the tip portion of the sensor 3 can be determined accurately, individual variations in the reactor 100 can be suppressed, and the temperature can be measured accurately.

(5) In the first sensor covering portion 34, a resin injection mark 34e forming the first sensor covering portion 34 is provided on the tip end side of the detection portion 31 opposite to the side to which the lead wire 32 is connected. made it As described above, when the first sensor covering portion 34 is formed by the resin molding method, the injection point of the resin is provided away from the lead wire 32, so that the injection pressure of the resin applied to the lead wire 32 is weakened. It is possible to prevent disconnection of the lead wire 32 .

[2. Other embodiments]
The present invention is not limited to the above embodiments, but also includes other embodiments shown below. In addition, the present invention also includes a form in which at least one of the above embodiments and other embodiments described below are combined.

(1) In the above embodiment, the detection unit 31 is a temperature sensor, but it is not limited to this. The detector 31 may use elements that detect other physical quantities such as magnetism, electricity, position, vibration, and humidity. Moreover, when the detection part 31 is used as a temperature sensor, the detection part 31 may be inserted between the coils 51a and 51b so as to be parallel to the vertical direction. Since the detector 31 is arranged near the heat-generating portion of the reactor 100, the temperature responsiveness is enhanced, and accurate temperature detection is possible. Note that the length of the lead wire 32 is longer than that of the above-described embodiment because the detecting portion 31 is inserted between the coils 51a and 51b so as to be parallel in the vertical direction. , the influence of the injection pressure of the resin when the covering member 4 is molded can be reduced.

(2) In the above embodiment, the claw portion 34c is provided to support the tip side of the sensor 3, but the claw portion 34c may not necessarily be provided.

(3) As shown in FIG. 8, the partition plate 25 may be provided with a holding portion 26 for holding the first sensor covering portion 34 . The holding part 26 is provided above the partition plate 25 and has a pair of arms 261 protruding from the partition plate 25 . The arm 261 is L-shaped, and one end of the arm 261 is connected to the partition plate 25, extends perpendicularly to the partition plate 25, bends halfway, and extends upward. The holding portion 26 is formed in a U shape by the pair of arms 261, the first sensor covering portion 34 is arranged in the pair of arms 261, and the cylindrical portion 34a is supported by the arms 261 to hold the sensor 3. . Alternatively, the sensor 3 may be held by fitting the arm 261 into the recess 34d.

100 Reactor 10 Reactor body 1 Cores 11, 12 U-shaped core 2 Resin members 2A, 2B Resin bodies 21a, 21b Linear part 21c Connecting part 210 Opening 22 Fixing part 23 Holding part 231 Plate-like body 24 Mounting part 241 Plate-like body 241a Notch 25 Partition plate 26 Holding portion 261 Arm 3 Sensor 31 Detecting portion 32 Lead wire 33 Connector 34 First sensor covering portion 34a Cylindrical portion 34b Collar portion 34c Claw portion 34d Concave portion 34e Injection mark 4 Covering member 41 Coil covering portion 411 Outer cylinder 412 Inner cylinder 413 Connecting portion 42 Second sensor covering portion 43 Terminal covering portion 431 Sealing plate 5 Coils 51a, 51b Coil 52 End

Claims (4)

a core;
a resin member covering the outer periphery of the core;
a coil attached to a portion of the core;
a sensor that is fixedly arranged with respect to the resin member and detects a physical quantity;
a coating member that coats the coil and the sensor with a resin to integrate the core, the coil, and the sensor;
with
The sensor is
a detection unit that detects a physical quantity;
a lead wire connected to the detection unit;
a first sensor covering portion covering the detecting portion and the lead wire in the covering member and fixed to the resin member;
has
The detection unit is a temperature sensor that detects temperature,
The covering member is
a coil covering portion that covers the inner and outer circumferences of the coil;
a second sensor covering that covers the first sensor covering;
has
The coil covering portion and the second sensor covering portion are seamlessly formed of resin,
the coil covering portion is in close contact with the coil,
The second sensor covering portion is in close contact with the first sensor covering portion,
the inner periphery of the first sensor covering portion is in close contact with the detection portion and the lead wire ;
A reactor characterized by An end of the first sensor covering portion is exposed from the covering member;
The reactor according to claim 1, characterized by: The coil is a pair of coils,
The sensor has a columnar shape and is provided between the pair of coils,
The first sensor covering part is
a cylindrical portion that covers the detection portion and a portion of the lead wire;
a brim-shaped portion projecting from the tubular portion;
a pawl provided on the tubular portion apart from the brim portion, protruding from the tubular portion, and having a notch provided at the protruding end;
has
The resin member is
a mounting portion for fixing the brim-shaped portion;
a partition plate that partitions between the pair of coils;
has
The brim-shaped portion is attached to the attachment portion,
the claw portion is attached to the partition plate;
The reactor according to claim 1 or 2, characterized by: The first sensor covering portion is provided with an injection mark of the resin forming the first sensor covering portion on the tip end side of the detection portion opposite to the side to which the lead wire is connected,
The reactor according to any one of claims 1 to 3 , characterized by:

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