JP2016127070A - Reactor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a reactor in which a film thickness of an adhesion layer between core members can be controlled properly.SOLUTION: The reactor includes: a ring-shaped core 1 comprising a plurality of core members 1a, 1b connected to each other via the adhesion layer having a predetermined film thickness; and a resin member covering the outer periphery of the ring-shaped core 1. The core members 1a, 1b have adhesive surfaces 15 bonded to other core members 1b, 1a, respectively. The resin member is configured by connecting a plurality of resin bodies 2a, 2b. The resin bodies 2a, 2b have connections 20 connected to other resin bodies 2b, 2a, respectively. The connection 20 of the resin body 2a includes a projecting portion 25, the projection direction of which has a directional component vertical to the adhesive surfaces 15 of the core members 1a, 1b. The projecting portion 25 butts against the connection 20 of other resin body 2b, thereby to separate between the adhesive surfaces 15 of the core members 1a, 1b.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a reactor in which cores are insulation-coated, and more particularly to a technique for ensuring a film thickness of an adhesive between cores.

  Reactors are used in various applications including drive systems for hybrid vehicles and electric vehicles. For example, as a reactor used in an in-vehicle booster circuit, after winding a coil around a resin bobbin placed around the core, place them in a metal case, and pour the filler into the case and harden it. Are often used (see, for example, Patent Document 1).

  This type of reactor includes a core made of a magnetic material, a resin coating portion covering the outer periphery of the core, and a coil wound around a part of the outer periphery of the core via the resin coating portion. In general, a molding method is employed to form a resin coating portion by arranging a resin around the core.

  In this type of reactor, the core is configured by abutting a plurality of core members made of a magnetic material. When a current flows from the external power source to the coil, a magnetic flux is generated in a portion where the coil of the core is wound, and a magnetic circuit is formed by passing through the core. As the magnetic flux is generated, a magnetic attractive force acts on the core member. Therefore, if the core members are not fixed, the core members may collide with each other and other members such as the core member and the resin coating portion may generate noise. Therefore, conventionally, a method of fixing core members with an adhesive has been adopted. As a result, even if a magnetic attractive force is applied to each core member, they do not collide with each other, so that the generation of large noise can be suppressed.

  The adhesive shear strength and adhesive peel strength of the adhesive are important for fixing the core members to each other, and the film thickness of the adhesive is important for any strength. That is, if the thickness of the adhesive is too thick or too thin, either the adhesive shear strength or the adhesive peel strength will decrease. Therefore, it is important to appropriately manage the film thickness of the adhesive.

  As a method for managing the film thickness of the adhesive, a method of mixing a filler, which is hard particles, with an adhesive has been conventionally employed. That is, in order to fix the core members, the core members are pressed with an adhesive interposed therebetween. In that case, a filler which has a predetermined particle size is contained in an adhesive agent, a filler is pinched | interposed between core members and it can ensure the adhesive film thickness more than a filler particle size. In addition to the method using a filler, a method of sandwiching ultrathin paper between core members has also been adopted.

JP 2012-212708 A

  However, in the technique of mixing the filler with the adhesive, since the particle size distribution exists in the filler, it is difficult to manage the film thickness of the adhesive with high accuracy. That is, since the adhesive contains a filler having a large particle size or a small filler, the adhesive film thickness varies. This variation in film thickness may occur for each reactor or for each bonded portion if there are a plurality of bonded portions in one reactor. In addition, the variation in the film thickness also affects the inductance value, which is one of the performances of the reactor. Therefore, it is desirable that the particle size distribution is as narrow as possible. However, the manufacturing cost increases and the productivity deteriorates.

  Moreover, when a filler of 0.1 mm or more is introduced in order to make the adhesive film thickness 0.1 mm or more, it settles inside the adhesive, the uniformity of the filler deteriorates, and the film thickness varies. . Furthermore, since the adhesive strength decreases due to a decrease in the adhesive ratio, handling becomes difficult and the productivity also decreases.

  In the film thickness management method using ultrathin paper, it is difficult to manage the film thickness with high accuracy because there is tolerance in the ultrathin paper. Further, when the ultrathin paper is sandwiched between the core members, the sandwiched portion is not attached with an adhesive, so that the adhesive strength is reduced and handling becomes difficult, and the productivity is lowered.

  Furthermore, the film thickness of the adhesive may affect the noise of the reactor, and appropriate management of the adhesive film thickness is required.

  SUMMARY An advantage of some aspects of the invention is to provide a reactor capable of appropriately managing the film thickness of an adhesive layer between core members.

A reactor of the present invention is a reactor including a core in which a plurality of core members are connected to each other via an adhesive layer having a predetermined film thickness, and a resin member that covers the outer periphery of the core, and has the following configuration It is characterized by having.
(1) Each of the core members has an adhesive surface to be bonded to another adjacent core member.
(2) The resin member is configured by connecting a plurality of resin bodies.
(3) The said resin body has a connection part connected with the said other resin body.
(4) The connecting portion has a protruding portion whose protruding direction has a direction component perpendicular to the bonding surface of the core member.
(5) The protruding portion hits a connecting portion of another resin body and separates the bonding surfaces of the core member.

The present invention may have the following configuration.
(6) The resin body connected to the resin body having the protrusion is provided with a recess into which the protrusion is fitted, and the length of the protrusion is longer than the length of the recess of the recess. The head of the protrusion is in contact with the bottom of the recess.
(7) The width of the projecting portion is substantially the same as the width of the recess of the concave portion.
(8) The connecting portion of the resin body with which the protruding portion abuts is configured to be flat.
(9) A plurality of the projecting portions are provided at a distance from the connecting portion, and the connecting portion is provided with a recess having a width between the at least one projecting portion, and the projecting portion hits. The connecting portion of the resin body is provided with a convex portion whose protruding direction has a direction component perpendicular to the bonding surface of the core member and is fitted into the concave portion, and the width of the convex portion is the width of the concave portion. It should be almost identical.
(10) Two protrusions are provided in total, and the protrusions are provided at the connection parts different from each other in the resin member.
(11) The protruding portion is configured to be continuous with a portion of the resin body that covers the core member.
(12) The resin member is made of a super engineering plastic resin.
(13) The material of the adhesive layer is an epoxy-based, silicone-based, acrylic-based, polyurethane-based adhesive, or a mixed adhesive of two or more of these.

  According to the present invention, since the protruding portion hits the connecting portion of another resin body and the bonding surfaces of the core member are separated from each other, it is possible to obtain a reactor capable of appropriately managing the film thickness of the adhesive.

It is a perspective view which shows the whole structure of the reactor which concerns on 1st Embodiment. It is a disassembled perspective view which shows the whole structure of the reactor which concerns on 1st Embodiment. It is a disassembled perspective view of the resin member which concerns on 1st Embodiment. It is a partial expanded side view of the resin member which concerns on 1st Embodiment. It is a partial expanded sectional view of the adhesion part periphery of the core member which concerns on 1st Embodiment. It is a side view of the resin member which concerns on 2nd Embodiment. It is a partial expanded sectional view of the adhesion part periphery of the core member which concerns on 2nd Embodiment. It is a graph which shows the relationship between an adhesive layer film thickness, a noise level, and adhesive shear strength. It is a partial expanded side view of the resin member which concerns on other embodiment. It is the elements on larger scale of the adhesion part periphery of the core member which concerns on other embodiment, and is AA sectional drawing of FIG. It is the elements on larger scale of the adhesion part periphery of the core member which concerns on other embodiment, and is BB sectional drawing of FIG. It is a decomposition | disassembly side view of the reactor which concerns on other embodiment. It is a decomposition | disassembly side view of the reactor which concerns on other embodiment.

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

[1. First Embodiment]
[1-1. Constitution]
FIG. 1 is a perspective view showing the overall configuration of the reactor according to the present embodiment, and FIG. 2 is an exploded perspective view thereof. The reactor according to the present embodiment is a large-capacity reactor used in, for example, a drive system for a hybrid vehicle or an electric vehicle. The reactor is the main component of the electric circuit mounted on these automobiles. This electric circuit includes a semiconductor switching element such as an IGBT in addition to a reactor. The reactor converts electric energy supplied from an external power source into magnetic energy by turning on and off the semiconductor switching element at high speed, and repeatedly stores and releases the energy, thereby controlling current and voltage.

  The reactor is housed in a heat radiating case (not shown) having a substantially rectangular parallelepiped housing space made of a light metal having high thermal conductivity, such as an aluminum alloy, and is fixed to the heat radiating case by fastening screws. .

  A filler is filled and solidified in the gap between the reactor and the heat radiating case to form a filled resin portion (not shown). As the filler, a resin that is relatively soft and has high thermal conductivity is suitable for ensuring the heat dissipation performance of the reactor and reducing the propagation of vibration from the reactor to the heat dissipation case.

  As shown in FIGS. 1 and 2, the reactor includes an annular core 1, a coil 5 wound around a part of the outer periphery of the annular core 1, an outer periphery of the annular core 1, and the annular core 1 and the coil 5. It has the resin member 2 which insulates.

  The annular core 1 is an annular magnetic body such as a dust core, a ferrite core, or a laminated steel plate. The annular core 1 of the present embodiment has a substantially θ shape. The annular core 1 is configured by connecting a plurality of core members to each other with an adhesive, and in the present embodiment, the pair of E-shaped cores 1a and 1b form a substantially θ shape.

  That is, the E-shaped cores 1a and 1b include a central middle leg part 11 and outer leg parts 12 and 13 disposed on both sides of the middle leg part 11 in parallel and spaced apart from the middle leg part 11, and these leg parts 11 to 11. And a back surface portion 14 that connects the three. The E-shaped cores 1a and 1b respectively have square bonding surfaces 15 bonded to the E-shaped cores 1b and 1a, which are other core members, on the leg portions 11 to 13, respectively. The length of each leg part 11-13 is the same, and the adhesion surface 15 of each leg part 11-13 is located on the same plane. As described above, the annular core 1 has a θ-shape formed by abutting the adhesive surfaces 15 provided on the end surfaces of the leg portions 11 to 13 with the adhesive. In other words, the annular core 1 includes a pair of E-shaped cores 1a and 1b and an adhesive layer 1c (see FIG. 5 described later) having a predetermined film thickness formed between the leg portions 11 to 13. Have.

  The adhesive layer 1c is made of an adhesive. The adhesive is not particularly limited, and a thermosetting adhesive can be used. For example, an epoxy-based, silicone-based, acrylic-based, polyurethane-based adhesive, or a mixed adhesive of two or more of these can be used. Can be mentioned. Epoxy adhesives are preferred because of their high strength. In the case of a thermosetting adhesive, since high heat resistance is required, an adhesive having a higher glass transition point is preferable. The adhesive preferably has a low viscosity during stirring and a thixotropy that is a physical property of high viscosity in a normal state. When a one-component thermosetting adhesive is used as the adhesive, it is easy to handle because it does not cure until heated after application of the adhesive. Further, two types of adhesives may be mixed and cured using a two-component adhesive.

  The resin member 2 is a member that covers the outer periphery of the annular core 1 with resin, and has a θ shape following the annular core 1 as a whole. As this resin, a super engineering plastic resin is used. For example, PEEK (peak), PBI (polybenzimidazole), PPS (polyphenylene sulfide), PEI (polyetherimide), PAI (polyamideimide), PTFE (polytetrafluoroethylene), PSF (polysulfone), PCTFE (polychloro) Trifluoroethylene), PAR (polyarylate), PI (polyimide), PES (polyethersulfone), PFA (neoflon), ETFE (fullon, neoflon), PVDF (polyvinylidene fluoride), or two of these A resin combining the above is preferred.

  The resin member 2 is divided into two parts. That is, the resin member 2 includes a first resin body 2a and a second resin body 2b each having a substantially E shape. The first resin body 2a and the second resin body 2b (hereinafter also simply referred to as resin bodies 2a and 2b) have E-shaped cores 1a and 1b embedded therein, and the core members 1a and 1b. It has a shape following the above. In other words, the resin bodies 2 a and 2 b include the middle leg portion 21, the outer leg portions 22 and 23, and the back surface portion 24. The middle leg portion 21 covers the middle leg portion 11 of the core members 1a and 1b. The outer leg portions 22 and 23 are arranged in parallel on both sides of the middle leg portion 21 and cover the outer leg portions 12 and 13. The back surface portion 24 connects these leg portions 21 to 23 and covers the back surface portion 14.

  These resin bodies 2a and 2b are molded by a resin mold molding method. More specifically, for example, in a state where the E-shaped cores 1a and 1b, which are core members, are set as inserts in the molds of the resin bodies 2a and 2b, the mold is filled with resin and solidified. Thus, the resin bodies 2a and 2b are molded so as to fit the outer peripheries of the E-shaped cores 1a and 1b. However, before the resin body 2a and the resin body 2b are assembled, the bonding surfaces of the E-shaped cores 1a and 1b are exposed.

  Moreover, the resin bodies 2a and 2b have the connection part 20 connected with the other resin bodies 2b and 2a. In more detail, the connection part 20 of resin body 2a, 2b is an edge part of the leg parts 21-23, and opposes the connection part 20 of the other resin bodies 2b, 2a, respectively. Although the connection part 20 contains the end surface of the leg parts 21-23, the side peripheral surface of the leg parts 21-23, or both, the connection part 20 of this embodiment is an end surface of the leg parts 21-23. The resin member 2 is configured to abut each other with the connecting portions 20 of the leg portions 21 to 23 facing each other, and has a substantially θ shape.

  FIG. 3 is an exploded perspective view of the resin member 2 of the present embodiment. FIG. 4 is a partially enlarged side view of the resin member 2 of the present embodiment, and shows the outer leg portions 22 of the resin bodies 2a and 2b. FIG. 5 is a partial enlarged cross-sectional view around the bonded portion of the core members 1 a and 1 b when the reactor is cut in the horizontal direction, and shows the bonded portion of the outer leg portion 12.

  The connection part 20 has the protrusion part 25 in which the protrusion direction has a direction component perpendicular to the bonding surface 15 of the core members 1a and 1b. In this embodiment, as shown in FIGS. 3-5, the protrusion part 25 is provided in the connection part 20 of the resin body 2a. The resin body 2b is provided with a recess 26 into which the protruding portion 25 of the resin body 2a is fitted. The protrusion part 25 and the recessed part 26 are provided in the outer peripheral side of the annular core 1 of the outer leg parts 22 and 23 of each resin body 2a, 2b. That is, the protruding portion 25 and the recessed portion 26 are provided in a portion of the connecting portion 20 around the bonding surface 15 of the outer leg portions 12 and 13 that is located outside the reactor. Moreover, the recessed part 26 is provided from the end surface of the outer leg parts 22 and 23 to the side surface as shown in FIG.3 and FIG.5, and has a shape with a level | step difference in the outer peripheral surface of the outer leg parts 22 and 23. FIG. .

  In the present embodiment, the protruding portion 25 and the recessed portion 26 are molded together when resin molds for molding the resin bodies 2a and 2b are filled with resin, and the protruding portion 25 and the recessed portion 26 are formed of resin. The outer legs 22 and 23 of the bodies 2a and 2b are seamlessly connected.

  The protrusion part 25 and the recessed part 26 are demonstrated in detail. The protruding portion 25 only has to protrude from the connecting portion 20 and hit the connecting portion 20 of the other resin bodies 2a and 2b, and the protruding direction includes a direction perpendicular to the bonding surface 15 of the core members 1a and 1b. 15 may protrude obliquely. In the present embodiment, the protrusion 25 is a flat projection extending in a direction perpendicular to the bonding surface of the outer legs 12 and 13 on the end surfaces of the outer legs 22 and 23. The recess 26 has a dent so that the protrusion of the protrusion 25 fits, and in the present embodiment, this dent is a step. The length of the protrusion of the protrusion 25 and the depth of the recess of the recess 26 are different.

  In this embodiment, as shown in FIGS. 4 and 5, the length of the protrusion of the protruding portion 25 is configured to be longer than the length of the recess of the recessed portion 26, and when the resin bodies 2 a and 2 b are brought into contact with each other, the protrusion The head of the portion 25 abuts against the bottom of the recess of the recess 26. Moreover, the adhesion surface 15 of each leg part 11-13 of the E-shaped core 1a and the end surface of each leg part 21-23 of the resin body 2a exist in the same plane. The adhesion surface 15 of each leg part 11-13 of the E-shaped core 1a and the end surface of each leg part 21-23 of the resin body 2a are in the same plane. Accordingly, the E-shaped cores 1a and 1b are separated by the difference G obtained by subtracting the length of the recess of the recess 26 from the length of the protrusion of the protrusion 25. That is, the difference G is a gap between the bonding surfaces 15 of the core members 1a and 1b, and is the film thickness of the bonding layer 1c. The difference G between the length of the protrusion of the protruding portion 25 and the length of the recess of the recessed portion 26 can be appropriately changed in design to form the adhesive layer 1c having a predetermined film thickness.

  Further, as shown in FIG. 3, the width in the direction orthogonal to the length direction of the protrusions of the protrusion 25 is substantially the same as the width of the recess of the recess 26. The protrusions 25 are fitted into the recesses 26, whereby the resin bodies 2a and 2b are positioned and can be abutted with high accuracy. In this case, “substantially coincide” means that the width in the direction orthogonal to the length direction of the protrusion of the protrusion 25 is the same as or slightly smaller than the width of the recess of the recess 26, and the resin bodies 2 a and 2 b What is necessary is just to position in the range which position alignment accept | permits.

  An adhesive may be applied to the connecting portion 20 other than the portion where the protruding portion 25 and the recessed portion 26 are provided to increase the adhesive strength of the resin bodies 2a and 2b. In other words, the adhesive layer 1c may bond not only between the bonding surfaces of the core members 1a and 1b but also between the connection portions 20 of the resin bodies 2a and 2b. However, in this case, the resin body 2a, 2b is pressed so as to be sandwiched in the direction perpendicular to the bonding surface of the E-shaped cores 1a, 1b, so that the head of the protrusion 25 comes into contact with the bottom of the recess of the recess 26. Let

  The resin bodies 2a and 2b are provided with fixing portions 27a and 27b for fixing the reactor to the heat radiating case. The fixing portions 27a and 27b are formed by solidifying the resin by a mold for forming the resin bodies 2a and 2b, similarly to the protruding portion 25 and the recessed portion 26. The fixing portions 27a and 27b are arranged at diagonal positions of the resin member 2 when the resin members 2 are configured by abutting the resin bodies 2a and 2b. The fixing portions 27a and 27b are provided with through holes into which screws are inserted, and the reactor is fixed to the heat dissipation case by inserting and fastening screws into these through holes.

  The coil 5 is a conducting wire having an insulating coating. The coil 5 of this embodiment is a flat wire edgewise coil. However, the wire material and winding method of the coil 5 are not limited to the rectangular wire edgewise coil, and may be in other forms.

  The coil 5 is mounted via the middle leg portion 21 of the resin member 2 so as to wind around the outer periphery of the middle leg portion 11, and is insulated from the annular core 1 by the middle leg portion 21 of the resin member 2. Yes. Both ends of the coil 5 are drawn to the outer leg 12 side, joined to a bus bar (not shown), and connected to an external power source (not shown) via the bus bar. When power is supplied from the external power source and a current flows through the coil 5, a magnetic flux that links the coil 5 is generated in the middle leg portion 11. This magnetic flux is divided into two at the back surface portion 14, one passing through the outer leg portion 12 and the back surface portion 14, and the other passing through the outer leg portion 13 and the back surface portion 14 and joining at the middle leg portion 11. That is, two closed magnetic circuits are formed in the annular core 1.

[1-3. Effect]
(1) The reactor of the present embodiment includes an annular core 1 in which a plurality of core members 1a and 1b are connected to each other via an adhesive layer 1c having a predetermined film thickness, and a resin member 2 that covers the outer periphery of the annular core 1. The core members 1a and 1b have an adhesive surface 15 to be bonded to the other core members 1b and 1a, and the resin member 2 is configured by connecting a plurality of resin bodies 2a and 2b. 2a, 2b has a connecting part 20 connected to other resin bodies 2b, 2a, and the connecting part 20 of the resin body 2a has a direction component whose protruding direction is perpendicular to the bonding surface 15 of the core members 1a, 1b. The protrusion part 25 is provided, the protrusion part 25 is abutted against the connection part 20 of the other resin body 2b, and the bonding surfaces 15 of the core members 1a and 1b are separated from each other.

  Thereby, since the core members 1a and 1b can be separated by the length of the protruding portion 25, the film thickness of the adhesive layer between the adhesive surfaces of the core members 1a and 1b can be managed. That is, in the technique of adding a filler to the conventional adhesive, the film thickness of the adhesive layer varies greatly, and it is difficult to obtain a desired thickness. Thus, the film thickness of the adhesive layer 1c can be set to a desired thickness. As a result, both the adhesive shear strength and the adhesive peel strength can be improved.

  Furthermore, since the film thickness of the adhesive layer 1c can be set to a desired thickness depending on the length of the protruding portion 25, the noise of the reactor can be suppressed.

(2) The resin body 2b connected to the resin body 2a having the protrusion 25 is provided with a recess 26 into which the protrusion 25 is fitted, and the length of the protrusion 25 is longer than the length of the recess of the recess 26. In addition, the head of the protrusion 25 is abutted against the bottom of the recess 26. Thereby, the distance between the core members 1a and 1b can be separated by the difference between the length of the protruding portion 25 and the length of the recess of the concave portion 26, and the adhesive layer 1c having a predetermined film thickness can be obtained.

(3) The width of the projecting portion 25 was made to substantially coincide with the width of the recess of the recessed portion 26. As a result, the resin bodies 2a and 2b are positioned and can be matched with high accuracy. Moreover, since the protrusion part 25 fits into the recessed part 26, it is also possible to comprise the resin member 2 without using an adhesive agent.

(4) Two protrusions 25 are provided in total, and the protrusions 25 are provided at different connection parts 20 of the resin member 2. In the present embodiment, one protruding portion 25 is provided at each of the connecting portions 20 of the outer leg portions 22 and 23 of the resin body 2a. Thus, since the number of protrusions 25 is minimized, the amount of resin used can be reduced. Further, if three or more protrusions 25 are provided, the tolerances of the protrusions 25 are stacked accordingly. However, since the two are the minimum necessary, the stacking of the tolerances on the protrusions 25 can be minimized, and the adhesive layer The film thickness can be managed with high accuracy of 1c.

(5) The protrusion 25 is configured to be continuous with the outer legs 22 and 23 covering the core member 1a of the resin body 2a. Thereby, the film thickness of the adhesive layer 1c can be managed with high accuracy. In the technique of controlling the film thickness by containing the filler, for example, in the case of a filler having an average particle diameter of 80 μm, the deviation is about ± 50 μm. On the other hand, the dimensional variation of the protrusion 25 of the present invention is as small as σ3 μm in standard deviation. From this, it can be seen that highly accurate film thickness management is possible.

  Furthermore, the film thickness of the adhesive layer 1c can be managed with higher accuracy than when the protruding portion 25 is separately provided and adhered to the end surfaces of the outer leg portions 22 and 23 with an adhesive. Moreover, since the process and adhesive agent for attaching the protrusion part 25 become unnecessary, a manufacturing man-hour and manufacturing cost can be reduced.

(6) The resin member 2 is made of a super engineering plastic resin. Thereby, the shaping | molding precision of the protrusion part 25 and the recessed part 26 which the connection part of the resin member 2 protruded can be improved. That is, by using this resin, when filling the resin for molding the resin bodies 2a and 2b with the resin, it can be spread all over. Moreover, since it has durability, the burden on the adhesive layer 1c is reduced, and deterioration of the adhesive strength can be suppressed.

(7) As a material of the adhesive layer 1c, an epoxy-based, silicone-based, acrylic-based, polyurethane-based adhesive, or a mixed adhesive of two or more of these is used. These adhesives are highly adhesive and have a low viscosity during stirring and a thixotropy that is a high viscosity property under normal conditions. Therefore, even if the adhesive is applied to the adhesive surface, it does not sag and forms the adhesive layer 1c. It's easy to do.

[2. Second Embodiment]
A second embodiment will be described with reference to FIGS. The basic configuration of the second embodiment is the same as that of the first embodiment. Therefore, only a different point from 1st Embodiment is demonstrated, the same code | symbol is attached | subjected about the same part as 1st Embodiment, and detailed description is abbreviate | omitted.

  FIG. 6 is a partially enlarged side view of the resin member according to the second embodiment. FIG. 7 is a partially enlarged cross-sectional view around the bonded portion of the core member when the reactor according to the second embodiment is cut in the horizontal direction.

  The resin member 2 according to the second embodiment includes a first resin body 2c and a second resin body 2d. The 1st resin body 2c has the two protrusion parts 28 which protruded in the direction orthogonal to the adhesion surface of the E-shaped core 1a in each end surface of the outer leg parts 22 and 23. As shown in FIG. The bonding surfaces of the leg portions 11 to 13 of the E-shaped core 1a and the end surfaces of the leg portions 21 to 23 of the resin body 2c are in the same plane, and the protruding portion 28 protrudes from this plane. In the second resin body 2d, the end surfaces of the outer leg portions 22 and 23 are flat. That is, the adhesive surfaces of the leg portions 11 to 13 of the E-shaped core 1b and the end surfaces of the leg portions 21 to 23 of the resin body 2d are in the same plane, and the recesses of the first embodiment are not provided.

  Therefore, when each leg part 21-23 of resin body 2c, 2d is faced | matched, the head of the protrusion part 28 of the resin body 2c will contact | abut the end surface of the outer leg parts 22 and 23 of the resin body 2d which opposes. Therefore, the E-shaped cores 1a and 1b are separated by the length of the protruding portion 28 in the direction perpendicular to the bonding surface 15 of the E-shaped cores 1a and 1b. Therefore, the film thickness of the adhesive layer 1 c interposed between the adhesive surfaces 15 can be ensured by the length of the protruding portion 28.

  An adhesive may be applied to the connecting portion 20 other than the portion where the protruding portion 28 is provided to increase the adhesive strength of the resin bodies 2c and 2d. However, in this case, the resin bodies 2c and 2d are pressed so as to be sandwiched in a direction perpendicular to the bonding surface 15 of the E-shaped cores 1a and 1b, so that the head of the protrusion 26 is bonded to the other resin body 2d. Butt against part 20.

  According to the present embodiment, as compared with the first embodiment, it is only necessary to provide the protruding portion 28, so the thickness of the adhesive layer can be managed with a simple configuration.

[3. Example]
Examples of the present invention will be described below.

[3-1. Reactor sample]
The reactor sample of this example is a reactor having the same form as that of the first embodiment shown in FIGS. Samples A to I having different thicknesses of the adhesive layer 1c were prepared by changing the difference G obtained by subtracting the length of the dent of the recessed portion 26 from the length of the protrusion of the protruding portion 25. Samples A to I are thicker in the order of A, B, C, D, E, F, G, H, and I. In addition, the film thickness between the intermediate leg parts 11, the outer leg parts 12, and the outer leg parts 13 is the same.

  All the samples have the same configuration except for the difference G and the film thickness of the adhesive layer 1c. In any sample, the annular core 1 is a pure iron-based dust core, and its magnetic path length is 110 mm. The coil 5 is an edgewise winding of a rectangular wire t1.6 × w5.0, and the number of turns is seven. As the adhesive constituting the adhesive layer 1c, an epoxy-based one-component thermosetting adhesive (Sumitomo 3M Limited, product number: EW2046) was used.

[3-2. Measurement item and measurement method]
Measurement items are noise and adhesive shear strength.
(1) As a condition for noise measurement, an applied current was passed through the coil 5 with a driving frequency of 10 kHz in the audible frequency band. Under these conditions, the noise level L _p (i) (i = 1 to 6) was measured on the six surfaces around each sample using a sound level meter. The macrophone of the sound level meter was placed at a distance of 80 mm from the sample. Next, the average value L _pave of the noise levels L _p (i) (i = 1 to 6) on each of the six surfaces was calculated.

(2) The adhesive shear strength was measured as follows. First, after making each said sample and comprising the annular core 1, other members were removed and it was made only the annular core 1. FIG. After that, in a state where one E-shaped core of the annular core 1 is sandwiched and fixed by a clamp jig, the other E-shaped core is pressed against the other E-shaped core in a direction parallel to the bonding surface by using the jig. Pulled in the direction, a shearing force was applied to the adhesive surface. The tensile shear load at that time was measured.

  FIG. 8 shows the results of noise level and adhesive shear strength of each sample obtained. As shown in FIG. 8, as the adhesive film thickness increases, the adhesive shear strength increases and the noise level tends to decrease.

Moreover, when the adhesive film thickness is too thick, the noise level tends to increase. In the present example, an increasing tendency is shown above the adhesive film thickness of Sample E. The reason for this tendency is not clear in detail, but it is thought that the resonance frequency has an effect. The resonance frequency f is expressed by f = (1 / 2π) × (K / M) ^1/2 (K: spring constant, M: mass), and the amount of adhesive increases as the adhesive film thickness increases. The resonance frequency is reduced. It is considered that the noise increased due to the resonance point existing on the high frequency side shifting to the drive frequency side of 10 kHz.

  As described above, the adhesive film thickness affects the noise level. However, according to the present invention, since the adhesive film thickness can be managed accurately, both the improvement of the adhesive shear strength and the reduction of the noise level are achieved. The effect of can be obtained.

  The difference G between the protrusion 25 and the recess 26 is preferably the adhesive film thickness of Samples B to G from the viewpoint of noise suppression. If the difference G is less than the adhesive film thickness of the sample B, an increase in noise, a decrease in adhesive force, and a decrease in durability occur, which is not preferable. If the difference G is larger than the adhesive film thickness of the sample G, problems such as an increase in noise, deterioration in workability due to dripping of the adhesive, and an increase in the cost of the material occur. Further, the difference G is preferably the adhesive film thickness of the samples B to G even in the second embodiment. That is, in the case of the second embodiment, if the length of the protruding portion 28 is in the above range, the noise suppressing effect is particularly high. Thus, if the film thickness of the adhesive layer 1c is the adhesive film thickness of the samples B to G, the noise suppression effect is high. Moreover, if the film thickness of the contact bonding layer 1c is the said range, the noise suppression effect can be acquired irrespective of the magnitude | size of a reactor (core member).

[4. Other Embodiments]
The present invention is not limited to the first and second embodiments, and includes other embodiments described below. In addition, the present invention also includes a combination of the following other embodiments.

(1) In 2nd Embodiment, although the protrusion part 28 was provided in the connection part 20 of the resin body 2c, and nothing was provided in the connection part 20 of the resin body 2d, it comprised flat, FIG. As shown, a concave portion 29 may be provided in the connecting portion 20 of the resin body 2c, and a convex portion 30 may be provided in the connecting portion 20 of the resin body 2d. That is, the resin body 2 c is provided with a recess 29 having a width that is the distance between the two protrusions 28, and the resin body 2 d has a width that substantially matches the length between the protrusions 28, and is fitted in the recess 29. Convex portions 30 are provided. The term “substantially coincides” means that the width of the convex portion 30 is the same as or slightly smaller than the width of the concave portion 29. The protruding portion 30 has a direction component whose protruding direction is perpendicular to the bonding surface of the core member. By fitting the convex portion 30 to the concave portion 29, the bonding relationship between the resin bodies 2c and 2d is strengthened, and it is not necessary to bond the resin bodies 2c and 2d with an adhesive. Thus, the film thickness securing of the adhesive layer 1c and the positioning function can be obtained. 9 to 11, the length of the convex portion 30 protruding in the direction perpendicular to the bonding surface 15 is shorter than the depth of the concave portion 29, but may be the same.

(2) In 1st Embodiment, although the protrusion part 25 and the recessed part 26 were provided in the outer peripheral side of the annular core 1 of the outer leg parts 22 and 23 of the resin bodies 2a and 2b, the outer leg parts 22 and 23 are provided. The inner peripheral side, upper surface side, or bottom surface side of the annular core 1 may be used. Moreover, you may provide in the connection part 20 of the middle leg part 21 not only in the outer leg parts 22 and 23. FIG. Similarly, the protruding portion 28 of the second embodiment may be provided anywhere as long as it is the connecting portion 20 of the outer leg portions 22 and 23. The number is not limited. Furthermore, you may provide in the connection part 20 of the middle leg part 21. FIG.

(3) In 1st Embodiment, although the protrusion part 25 was provided in the resin body 2a and the recessed part 26 was provided in the resin body 2b, the protrusion part 25 is provided in the resin body 2b, and the recessed part 26 is provided in the resin body 2a. It may be provided. Moreover, you may provide both the protrusion part 25 and the recessed part 26 in both resin body 2a, 2b. For example, the protrusion 25 and the recess 26 may be provided on the outer legs 22 and 23 of the resin body 2a, and the protrusion 25 and the recess 26 may be provided on the outer legs 22 and 23 of the outer legs 22 and 23 of the resin body 2b. good. Similarly, in the second embodiment, the protrusions 28 may be provided on the resin body 2d, or the protrusions 28 may be provided on both of the resin bodies 2c and 2d.

(4) In the first embodiment, one protrusion 25 and one recess 26 are provided on the outer legs 22 and 23, respectively, and two protrusions 28 are provided on the outer legs 22 and 23 in the second embodiment. However, the number of the protrusions 25 and 28 and the recesses 26 is not particularly limited, and one or more protrusions may be provided.

(5) In the first and second embodiments, the protrusions 25 and 28 have a rectangular shape, but may have a triangular shape, a cylindrical shape, a conical shape, or a truncated cone shape. Further, these tips may be rounded or sharpened. Moreover, even if the shape of the recessed part 26 and the shape of the protrusion part 25 differ, the adhesive layer 1c should just ensure a predetermined film thickness.

(6) In the first embodiment, the projecting portion 25 has a flat plate shape, but a bulging portion is provided on the front end side of one plane in contact with the concave portion 26, and a recess in which the bulging portion fits in the concave portion 26 is formed. It may be provided. When the protruding portion 25 is inserted into the concave portion 26 by the bulging portion and the dent, the bulging portion fits into the dent and the resin bodies 2a and 2b can be prevented from coming off. Further, the positioning accuracy can be further improved.

(7) In the first and second embodiments, the concave portion 26 is provided as a step on the side surfaces of the outer leg portions 22 and 23, but may be provided as a hole in the end portion of the outer leg portions 22 and 23. The protrusion 25 of the resin body 2a is inserted into the recess 26, which is the hole.

(8) In the first and second embodiments, the protruding portions 25 and 28 are provided so as to protrude from the end surfaces with the connecting portion 20 as the end surfaces of the outer leg portions 22 and 23, but are not limited thereto. . For example, the protrusions 25 and 28 may be provided on the side peripheral surfaces of the legs 21 to 23.

(9) In the first and second embodiments, the lengths of the leg portions 11 to 13 of the E-shaped cores 1a and 1b are the same, but may be different lengths. For example, the lengths of the outer leg portions 12 and 13 may be the same, and the length of the middle leg portion 11 may be shorter than the length of the outer leg portions 12 and 13.

(10) In the first and second embodiments, the E-shaped cores 1a and 1b are used as the core member in order to configure the annular core 1, but the present invention is not limited to this. That is, the annular core 1 only needs to be configured by abutting a plurality of core members, and the core member has a shape capable of constituting a U-shaped core, an I-shaped core, a T-shaped core, and other annular cores. The core which has can be used.

(11) In the first and second embodiments, the adhesive layer 1c is composed of a liquid adhesive, but may be composed of an adhesive sheet.
(12) In the first and second embodiments, the adhesive surfaces 15 of the core members 1a and 1b and the connecting surfaces 20 of the resin bodies 2a and 2b are in the same plane, but the film thickness of the adhesive layer 1c is If it can be ensured, it does not necessarily have to be in the same plane.
(13) A spacer may be interposed between the core members 1a and 1b.

(14) In the first and second embodiments, the resin member 2 is composed of two resin bodies 2a, 2b or resin bodies 2c, 2d, but the resin member 2 is composed of three or more resin bodies. May be.
(15) In the first and second embodiments, the leg portions 21 to 23 of the resin bodies 2a to 2d cover the entire circumference (four sides) of the leg portions 11 to 13 of the core members 1a and 1b. If the protrusions 25 and 28 are provided, the side surfaces 21 to 23 may be covered by three side surfaces, two side surfaces, or one side surface.

(16) In the first and second embodiments, the end surfaces of the leg portions 21 to 23 of the resin bodies 2a to 2d and the bonding surfaces 15 of the core members 1a and 1b are parallel to each other. However, the present invention is not limited to this. . For example, as shown in FIG. 12, the bonding surfaces 15 of the core members 1 a and 1 b may be inclined with respect to the end surfaces of the legs 21 to 23. Further, as shown in FIG. 13, the bonding surface 15 of the core member 1a may have a pointed shape, and the bonding surface 15 of the core member 1b may have a concave shape following this.

DESCRIPTION OF SYMBOLS 1 Ring core 1a, 1b E-shaped core 1c Adhesion layer 11 Middle leg part 12, 13 Outer leg part 14 Back surface part 15 Adhesive surface 2 Resin member 2a, 2b Resin body 2c, 2d Resin body 20 Connection part 21 Middle leg part 22 , 23 Outer leg portion 24 Back portion 25 Protruding portion 26 Recessed portion 27a, 27b Fixed portion 28 Protruding portion 29 Recessed portion 30 Protruding portion 5 Coil G Adhesive layer thickness (gap between core members)

Claims (9)

A core in which a plurality of core members are connected to each other through an adhesive layer having a predetermined film thickness;
A resin member covering the outer periphery of the core;
With
Each of the core members has an adhesive surface to be bonded to another adjacent core member,
The resin member is configured by connecting a plurality of resin bodies,
The resin body has a connection portion that connects to the other resin body,
The connecting portion has a protruding portion whose protruding direction has a direction component perpendicular to the bonding surface of the core member,
The projecting portion hits the connecting portion of the other resin body and separates the bonding surfaces of the core member;
Reactor characterized by. The resin body connected to the resin body having the protrusion is provided with a recess into which the protrusion is fitted,
The length of the protrusion is longer than the length of the recess of the recess, and the head of the protrusion hits the bottom of the recess,
The reactor according to claim 1. The width of the protrusion is substantially the same as the width of the recess of the recess;
The reactor according to claim 2. The connecting portion of the resin body with which the protruding portion abuts is configured to be flat;
The reactor according to claim 1. A plurality of the protrusions are provided apart from the connection part;
The connection portion is provided with a recess having a width as a width between at least one of the protrusions,
The connecting portion of the resin body against which the protruding portion abuts is provided with a protruding portion that has a directional component in which the protruding direction is perpendicular to the bonding surface of the core member, and is fitted into the recessed portion.
The width of the convex portion substantially matches the width of the concave portion,
The reactor according to claim 4. A total of two protrusions are provided, and the protrusions are provided at different connection portions of the resin member;
The reactor of any one of Claims 1-4 characterized by these. The projecting portion is configured to be continuous with a portion covering the core member of the resin body,
The reactor of any one of Claims 1-6 characterized by these. The resin member is made of a super engineering plastic resin;
The reactor of any one of Claims 1-7 characterized by these. The material of the adhesive layer is an epoxy-based, silicone-based, acrylic-based, polyurethane-based adhesive, or a mixed adhesive of two or more of these,
The reactor of any one of Claims 1-8 characterized by these.

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