JP2021068830A - Busbar assembly - Google Patents

Abstract

To provide a mold coil capable of preventing a core from cracking while ensuring insulation between the core and a busbar.SOLUTION: A busbar assembly 1 includes: an annular core 2 formed with a magnetic material included therein, the annular core having a through hole; a busbar 3 having conductivity and penetrating through the through hole; an insulating spacer 4 supporting the busbar 3 such that there is a space between the busbar 3 and the through hole; a mold part 5 formed by an insulating resin and covering the core 2 by adhering to the outer surface of the core 2; a space where the mold part 5 does not adhere to the core 2, the space being provided between the spacer 4 and an end face of the core 2 including at least one end of the through hole; and an opening 521 where a part of a side face of the core 2 is exposed, the opening being provided in the mold part 5.SELECTED DRAWING: Figure 1

Description

The present invention relates to a busbar assembly.

In order to remove electromagnetic noise and the like, electronic components equipped with a core made of a magnetic material and a conductive bus bar are used. Such electronic components are configured as resin molded busbar assemblies for insulation and fixation of the core and busbar. For example, when an annular core is used, the bus bar is arranged and molded so as to penetrate the inside of the core.

Japanese Unexamined Patent Publication No. 2005-236026

In the busbar assembly, the resin covering the core expands and contracts due to the heat generated in the core and the busbar. Then, due to the difference in linear expansion between the resin and the core, a large stress may be generated in the core and cracks may occur. In order to deal with this, instead of covering the entire core with resin, it is possible to alleviate the stress generated in the core due to the expansion and contraction of the resin by providing an exposed part without resin in a part of the core. It is done.

However, when the core is annular, the bus bar is arranged inside the core. Then, it is necessary to secure the insulation between the inside of the core and the bus bar. If a resin is filled between the inside of the core and the bus bar, contact between the two can be prevented and insulation can be achieved. However, when the inside of the core is filled with resin, stress may be generated inside the core due to expansion and contraction of the resin, and cracks may occur.

The present invention has been proposed to solve the above problems, and an object of the present invention is to provide a bus bar assembly capable of preventing cracking of the core while ensuring insulation between the core and the bus bar.

In order to achieve the above object, the bus bar assembly of the present invention includes an annular core formed of a magnetic material and having a through hole, a conductive bus bar that penetrates the through hole, and the bus bar and the above. An insulating spacer that supports the bus bar, a mold portion that is formed of an insulating resin and adheres to the outer surface of the core to cover the core, and a mold portion that covers the core so as to leave a space between the through holes. A gap provided between the spacer and the end face of the core including at least one end of the through hole and the mold portion is not in close contact with the core, and a gap provided in the mold portion and provided on the side surface of the core. It has an opening, which is partially exposed.

According to the present invention, it is possible to provide a molded coil capable of preventing cracking of the core while ensuring insulation between the core and the bus bar.

Top side perspective view of the bus bar assembly of the embodiment. An exploded perspective view of the bus bar assembly of the embodiment. Bottom view of the bus bar assembly of the embodiment. Perspective view of the core. Perspective view of the busbar. Perspective view of the spacer. The perspective view of the core in which the 1st mold part was formed. The vertical sectional view at the time of forming the 2nd mold part.

[Constitution]
The bus bar assembly 1 of the embodiment will be described with reference to FIGS. 1 to 8. The bus bar assembly 1 is used as an in-vehicle noise filter. As shown in FIGS. 1 to 3, the bus bar assembly 1 has a core 2, a bus bar 3, a spacer 4, and a mold portion 5. In the description of the members shown in each figure, the side where both ends of the bus bar 3 protrude is the upper side, and the opposite side is the bottom. However, the top and bottom described here do not indicate the positional relationship when the bus bar assembly 1 is actually used.

(core)
As shown in FIG. 4, each core 2 is an annular member formed containing a magnetic material and having a through hole 21. As the core 2 of this embodiment, two cores 2A and 2B are used. Hereinafter, when the cores 2A and 2B are not distinguished, they will be described as the core 2.

The core 2 is, for example, a rectangular parallelepiped-shaped dust core. The outer surface is composed of the upper surface 22 and the lower surface 23 of the core 2 and the four side surfaces 24. Hereinafter, the upper surface 22 and the bottom surface 23 may be referred to as end faces. The boundaries of the four side surfaces 24 are curved and rounded. Of the four side surfaces 24, the two planes in contact with the long sides of the upper surface 22 and the bottom surface 23 are referred to as wide surfaces 241 and the two planes in contact with the short sides are referred to as narrow surfaces 242. In the following description, the direction parallel to the long side of the upper surface 22 and the bottom surface 23 is the long side direction, and the direction parallel to the short side is the short side direction.

The through hole 21 is a rectangular parallelepiped hole, and is provided coaxially with an axis passing through the centers of the upper surface 22 and the bottom surface 23. Therefore, the upper surface 22 which is one end surface of the core 2 includes one end portion of the through hole 21, and the bottom surface 23 which is the other end surface includes the other end portion of the through hole 21. Further, the boundaries of the four planes forming the through hole 21 are curved and rounded.

The two cores 2A and 2B have the same size and shape. The two cores 2A and 2B are arranged side by side in a direction in which their axes are parallel to each other and their wide surfaces 241 are parallel to each other. However, since the two cores 2A and 2B are arranged so as to be offset in the long side direction, only a part of the wide surfaces 241 adjacent to the core 2A and the core 2B face each other. In the following description, the side where the core 2A and the core 2B face each other is the inside, and the side opposite to the core 2A is the outside.

(Busbar)
As shown in FIGS. 2 and 5, the bus bar 3 is a member that has conductivity and penetrates through the through hole 21 of the core 2. The bus bar 3 is, for example, a copper flat plate, and is formed in a U shape by flatwise bending. The bus bar 3 has two terminal portions 31A and 31B parallel to each other, a connecting portion 32 for connecting the terminal portions 31A and 31B, and a mounting portion 33 protruding from the connecting portion 32.

As described above, the terminal portions 31A and 31B are formed so as to be offset in the long side direction in accordance with the through holes 21 of the cores 2A and 2B that are displaced in the long side direction. The terminal portions 31A and 31B are inserted into the through holes 21 of the two cores 2A and 2B from the bottom surface 23 side, respectively. Then, the tip of the terminal portion 31 projects upward from the upper surface 22 of the core 2 and is exposed. However, as will be described later, a spacer 4 is interposed between the terminal portions 31A and 31B and the cores 2A and 2B.

The portions exposed above the terminal portions 31A and 31B are electrically connected to an external device such as an external power supply. Since the terminal portions 31A and 31B are displaced in the long side direction, when connecting to one of the terminal portions 31A and 31B, the other portion is less likely to get in the way and the work is easy. When electric power is supplied to the bus bar 3 from an external power source, a current flows through the U-shaped bus bar 3 to form a coil for one turn, and magnetic flux is generated in the cores 2A and 2B. As a result, the generated magnetic flux passes through the cores 2A and 2B to form an annularly closed magnetic circuit.

The connecting portion 32 is continuously provided on the terminal portions 31A and 31B on the side opposite to the tips of the terminal portions 31A and 31B. When the terminal portions 31A and 31B are inserted into the through hole 21 with the spacer 4 interposed therebetween, the connecting portion 32 is exposed on the bottom surface 23 side of the cores 2A and 2B.

The mounting portion 33 is a tongue piece that protrudes in a direction along the cores 2A and 2B so as not to face the bottom surface 23. A mounting hole 33a, which is a through hole, is formed in the mounting portion 33. The position of the mounting hole 33a corresponds to the empty area F caused by the deviation of the cores 2A and 2B in the long side direction (see FIG. 2). That is, the expansion of the outer shape is prevented by utilizing the space created by the arrangement of the cores 2A and 2B.

Further, a nut 6 is arranged on the mounting portion 33 of the bus bar 3. The nut 6 is a cylindrical member having a screw hole 6a formed inside. The nut 6 is arranged so that the opening 6b of the screw hole matches the mounting hole 33a formed in the mounting portion 33 of the bus bar 3.

(Spacer)
As shown in FIGS. 2 and 6 (A) and 6 (B), the spacers 4Aa, 4Ab, 4Ba, and 4Bb are insulating members that support the bus bar 3 so as to be spaced from the through hole 21. is there. In this embodiment, four spacers 4Aa, 4Ab, 4Ba, and 4Bb are used. The four spacers 4Aa, 4Ab, 4Ba, and 4Bb have the same size and shape. Hereinafter, when the spacers 4Aa, 4Ab, 4Ba, and 4Bb are not distinguished, they are referred to as the spacer 4.

The spacer 4 has a sleeve 41 and a collar portion 42. The sleeve 41 is a tubular body whose one end is inserted into a part of the through hole 21. The cross section of the outer circumference orthogonal to the axis of the sleeve 41 is a rectangle with rounded corners and coincides with the inner circumference of the through hole 21. Further, the cross section of the inner circumference of the sleeve 41 is rectangular, and the terminal portions 31A and 31B of the bus bar 3 can be inserted. However, the axial length of the sleeve 41 does not have a length extending over the entire length of the through hole 21 in the axial direction, and only a part of the through hole 21 is inserted (see FIG. 8). A gap S is provided between the end surface of the core 2 including the end of the through hole 21 and the spacer 4 (see FIG. 8). That is, the gap S is created by the interposition of the first mold portion 51, which will be described later, between the flange portion 42 of the spacer 4 and the upper surface 22 and the bottom surface 23 of the core 2. Here, FIG. 8 is a vertical cross-sectional view when the bus bar assembly 1 is formed by the mold D, and includes a cross section of the bus bar assembly 1 cut downward from the center of the upper surface.

The collar portion 42 is a portion where the other end of the sleeve 41 has an enlarged diameter. The collar portion 42 is a plate-like body having a rectangular shape with rounded corners. The collar portion 42 is provided with a rectangular opening 42a communicating with the inner circumference of the sleeve 41. The short side of the opening 42a is formed longer than the short side of the inner circumference of the sleeve 41. Then, the flange portion 42 is formed with a curved surface 42b that enters inward from the pair of long sides of the opening 42a and is continuous on the long side of the inner circumference of the sleeve 41. Such a spacer 4 has rotational symmetry so that even if it is rotated by 180 ° about the axis of the sleeve 41, the shape becomes the same before and after the rotation.

As shown in FIG. 2, spacers 4Aa, 4Ab, 4Ba, and 4Bb are provided corresponding to a pair of end faces of the core 2A and the core 2B including both ends of the through hole 21, respectively. That is, the sleeves 41 of the spacers 4Aa and 4Ab are inserted into the ends of the through holes 21 of the core 2A on the upper surface 22 side and the ends of the bottom surface 23, respectively, and the sleeves 41 of the spacers 4Ba and 4Bb penetrate the core 2B, respectively. It is inserted into the end of the hole 21 on the upper surface 22 side and the end on the bottom surface 23 side.

The terminal portion 31A of the bus bar 3 is inserted into the sleeve 41 of the spacer 4Ab on the bottom surface 23 side, further inserted into the sleeve 41 of the spacer 4Aa on the top surface 22 side, and the tip protrudes to the outside (see FIG. 8). Similarly, the terminal portion 31B of the bus bar 3 is inserted into the sleeve 41 of the spacer 4Bb on the bottom surface 23 side, and further inserted into the sleeve 41 of the spacer 4Ba on the top surface 22 side, so that the tip protrudes to the outside.

(Mold part)
As shown in FIGS. 2 and 7, the mold portion 5 is a member formed of an insulating resin and which covers the core 2 by being in close contact with the outer surface of the core 2. Adhesion means that the core 2 and the mold portion 5 are integrated, that is, they are in contact with each other and fixed, and does not include the case where the core is housed in a resin case prepared in advance. Covering does not completely cover the whole, but includes a case where there is a part that is not in close contact with the core 2 or a part where the core 2 is exposed. The mold portion 5 has a first mold portion 51A and 51B and a second mold portion 52. The first mold portions 51A and 51B are members that individually cover the cores 2A and 2B, respectively. The second mold portion 52 is a member that covers the first mold portions 51A and 51B. Hereinafter, when the first mold portions 51A and 51B are not distinguished, they will be described as the first mold portion 51.

The first mold portion 51 has a plurality of openings 511, 512, and 513 in which a part of the core 2 is exposed. The opening 511 exposes a pair of wide surfaces 241 of the side surfaces 24. That is, the resin constituting the first mold portion 51 covers the curved surface that is the boundary between the wide surface 241 and the narrow surface 242, but the wide surface 241 is exposed by the rectangular opening 511 in the center. The surface of the first mold portion 51 on which the opening 511 is formed and the wide surface 241 are flush with each other. The pair of openings 511 have the same size and shape, and have the same position with respect to the wide surface 241.

The opening 512 exposes a part of the pair of narrow surfaces 242 of the side surface 24. That is, the resin constituting the first mold portion 51 covers the portion of the narrow surface 242 adjacent to the wide surface 241 in a rectangular shape, but the narrow surface 242 is exposed by the rectangular opening 512 in the center. .. The upper and lower end faces of the opening 512 of the first mold portion 51 and the narrow surface 242 are flush with each other. The pair of openings 511 are the same in size and shape, and are also in the same position with respect to the narrow surface 242.

The opening 513 exposes a part of the upper surface 22 and the bottom surface 23. That is, the upper surface 22 and the bottom surface 23 are covered with the regions along the four sides by the resin constituting the first mold portion 51, but the end of the through hole 21 is covered by the central rectangular opening 513. The circumference of the part is exposed. The openings 513 formed in the upper surface 22 and the bottom surface 23 have the same size and shape, and the positions with respect to the upper surface 22 and the bottom surface 23 are also the same.

The cores 2A and 2B on which the first mold portion 51 is formed have openings 511, 512, and 513 formed in the first mold portion 51 as described above, so that the lines pass through the centers of the two opposite surfaces. Even if it is rotated 180 ° around the axis, it has rotational symmetry so that the shape matches before and after rotation.

The opening 513 is larger than the through hole 21 and smaller than the flange 42 of the spacer 4. As a result, when the sleeve 41 of the spacer 4 is inserted into the through hole 21, the collar portion 42 comes into contact with the first mold portion 51. However, the void S is formed without contacting the upper surface 22 and the bottom surface 23 of the core 2 (see FIG. 8). That is, the first mold portion 51 is interposed between the core 2 and the spacer 4 to form the above-mentioned gap S. In this gap S, the mold portion 5 is not in close contact with the core 2.

The first mold portion 51 is formed by injection molding in which a resin material is injected and solidified with the core 2 set in the mold. The first mold portion 51 has no undercut shape so that the mold does not require a slider. That is, since the surface on which the opening 511 is formed and the wide surface 241 are flush with each other, and the upper and lower end faces and the narrow surface 242 of the opening 512 are flush with each other, they are divided into two directions, upper and lower. The second mold portion 52 can be formed by the mold D (see FIG. 8).

As shown in FIG. 1, the second mold portion 52 constitutes a single resin molded body by collecting the two cores 2A and 2B and covering each of the first mold portions 51. The second mold portion 52 is provided with an opening 521, and a part of the core 2 is exposed. That is, in the two cores 2A and 2B, of the pair of wide surfaces 241 exposed by the opening 511 of the first mold portion 51, the wide surface 241 located on the outer side is provided with the opening 521 of the second mold portion 52. As a result, a part of the wide surface 241 is exposed. The wide surface 241 and the lower part of the opening 511 and the lower part of the opening 521 are flush with each other.

Further, as shown in FIG. 1, the second mold portion 52 has a rectangular shape with rounded corners so that a part of the flange portion 42 of the spacer 4 is exposed around the terminal portions 31A and 31B of the bus bar 3. An opening 522 is formed. Further, in the second mold portion 52, a flange portion 523 having an enlarged outer shape is formed on the entire peripheral edge of the region including the upper surface 22 of the core 2A and the core 2B. As shown in FIG. 3, the flange portion 523 is formed with an annular groove 523a that is recessed over the entire circumference on the surface of the core 2 on the bottom surface 23 side. At the bottom of the second mold portion 52, the mounting portion 33 of the bus bar 3 is exposed.

The second mold portion 52 is formed by injection molding in which a resin material is injected and solidified in a state where the core 2A and the core 2B on which the first mold portion 51 is formed are set in a common mold D. (See Fig. 8). The second mold portion 52 has no undercut shape so that the mold does not require a slider. That is, since the wide surface 241 and the lower part of the opening 511 and the lower part of the opening 521 are flush with each other, the second mold portion 52 can be formed by the mold divided in the upper and lower two directions.

An injection mark is provided on the upper surface of the second mold portion 52 between the core 2A and the core 2B (for example, the position shown by the dotted line in FIG. 1). That is, the core 2A and the core 2B are set in the mold D so that when the resin material is injected from the gate, the resin material is injected between the core 2A and the core 2B (see the black arrow in FIG. 8). ). The position of the injection mark is opposite to the wide surface 241 which is one side surface of the core 2 exposed by the opening 512 and exceeds the upper surface 22 which is the end surface when viewed from the single core 2.

(Assembly procedure)
The bus bar assembly 1 of the present embodiment as described above is assembled as follows. First, the core 2A and the core 2B are set in the mold D, and the first mold portion 51 is formed by injection molding.

Then, the sleeves 41 of the spacers 4Aa and 4Ab are inserted into the upper and lower ends of the through holes 21 of the core 2A in which the first mold portion 51 is formed, and the spacers 4Ba and the spacers 4Ba are inserted into the upper and lower ends of the through holes 21 of the core 2B. By inserting the sleeve 41 of 4Bb, the opening 513 is closed by the collar portion 42. Then, a gap S is formed between the collar portion 42 and the upper surface 22 of the core 2. Further, a gap S is also formed between the collar portion 42 and the bottom surface 23 of the core 2.

Next, the terminal portions 31A and 31B of the bus bar 3 are inserted into the through hole 21 of the bottom surface 23 via the spacer 4, and the tips of the terminals 31A and 31B of each are projected from the through hole 21 of the upper surface 22. At this time, the cores 2A and 2B are positioned so as to be displaced in the long side direction. In this way, the bus bar 3 inserted into the through hole 21 of the core 2 becomes a through coil for one turn.

The core 2A, core 2B, and spacer 4 on which the first mold portion 51 is formed have rotational symmetry as described above. Therefore, the operator is less likely to get lost in the direction of the spacer 4 when inserting the spacer 4 into the through holes 21 of the core 2A and the core 2B. Further, when the bus bar 3 is inserted through the spacer 4, the operator is unlikely to be confused as to which one to insert. That is, which of the end faces into which the spacer 4 is inserted is the upper surface 22 and which is the bottom surface 23 is free, and is determined at the stage when the bus bar 3 is inserted. Further, which of the openings 511 with the pair of wide surfaces 241 exposed is the outside and which is the inside, and which of the openings 512 with the pair of narrow surfaces 242 exposed is the side closer to the outer circumference, which is the inside. It is also free to set it to the side, and it is decided when the bus bar 3 is inserted.

In this way, the core 2A and the core 2B into which the bus bar 3 is inserted are set in the mold D as shown in FIG. Since the core 2A, the core 2B, and the first mold portion 51 do not have an undercut shape, the upper die D1 and the lower die D2 that are divided in two directions, upper and lower, can be used without the need for a slider. Further, the nut 6 is positioned in the mounting hole 33a formed in the mounting portion 33.

The core 2A and the core 2B are set on the lower mold D2 from the bottom surface 23 side of the cores 2A and 2B where the terminal portions 31A and 31B of the bus bar 3 do not protrude, and further, the upper mold D1 is closed from the upper surface 22 side. Here, for example, when the end portion of the through hole 21 is not closed, the terminal portions 31A and 31B sides of the cores 2A and 2B are set in the lower mold D2 in order to prevent the resin material from flowing into the through hole 21. At the same time, it is necessary to form the lower mold D2 in advance with high dimensional accuracy so that a gap between the terminal portions 31A and 31B and the lower mold D2 does not occur. However, in the present embodiment, since the opening 513 is closed by the flange portion 42 of the spacer 4, it is possible to prevent the resin material from flowing into the through hole 21 without relying on the mold D. Therefore, it may be set in the lower mold D2 from the bottom surface 23 side of the cores 2A and 2B.

Then, the second mold portion 52 is formed by injection molding in which the resin material is injected into the mold D and solidified. The location where the resin material is injected is between the core 2A and the core 2B, as shown by the black arrow in FIG. As a result, as shown by the white arrows in FIG. 8, the wide surface 241 of the core 2A and the wide surface 241 of the core 2B are pressed against the inner surface of the lower mold D2 by the injection pressure of the resin material. Therefore, it is prevented that the injected resin material flows between the wide surface 241 of the core 2A and the core 2B and the mold D to fill the opening 512.

In the present embodiment, the connecting portion 32 of the U-shaped bus bar 3 closes the bottom surface 23 side between the core 2A and the core 2B. However, since the resin material is injected from the upper surface 22 side, it is easy to inject the resin material between the cores 2A and 2B. Further, after injecting the resin material as described above, the bus bar assembly 1 in which the second mold portion 52 is formed by solidifying is taken out from the mold D.

(Action effect)
(1) The bus bar assembly 1 of the present embodiment has an annular core 2 formed of a magnetic material and having a through hole 21, a bus bar 3 having conductivity and penetrating the through hole 21, and a bus bar 3 and penetrating the bus bar 3. An insulating spacer 4 that supports the bus bar 3 and a mold portion 5 that is formed of an insulating resin and adheres to the outer surface of the core 2 to cover the core 2 so as to leave a space between the holes 21 and the core 2. Has. Then, a gap S is provided between the end surface of the core 2 including at least one end of the through hole 21 and the spacer 4, and the mold portion 5 is not in close contact with the core 2, and the mold portion 5 is provided with the core. It has an opening 521 in which a part of the side surface 24 of 2 is exposed.

Therefore, the resin is not in close contact with the core 2 in the gap S and the opening 521 between the bus bar 3 and the through hole 21, and an external force due to shrinkage of the resin is not directly applied to the core 2. Therefore, as compared with the case where the entire core 2 is covered with the resin, the stress generated in the entire core 2 due to the shrinkage of the resin is relaxed, and the occurrence of cracks in the core 2 is prevented. Since regions where the resin is not in close contact can be formed inside the through hole 21 and at the end of the through hole 21, cracking of the core 2 due to stress on the inner side is more likely to occur than when an opening is simply provided on the outer surface. Can be prevented.

Further, since the bus bar 3 is supported by the spacer 4, the insulation between the bus bar 3 and the through hole 21 is maintained while preventing the resin from flowing into the through hole 21 inside the mold portion 5. Further, since the spacer 4 prevents the resin from flowing into the through hole 21, it is not necessary to prevent the resin from flowing into the mold D, and the mold D is not required to have high dimensional accuracy.

(2) Spacers 4 are provided corresponding to a pair of end faces of the core 2 including both ends of the through hole 21, and gaps S are provided between the pair of end faces of the core 2 and the spacer 4, respectively. .. That is, both the upper surface 22 and the bottom surface 23, which are the end faces, have voids S in which the resin is not in close contact. Therefore, since the voids S are formed on both end faces of the core 2, the stress generated in the entire core 2 due to the shrinkage of the resin is further relaxed.

(3) The spacer 4 has a tubular sleeve 41 having one end inserted into a part of the through hole 21, and a collar portion 42 having an enlarged diameter at the other end of the sleeve 41, and has a collar portion 42 and a core. A gap S is formed between the two end faces. Therefore, the distance between the bus bar 3 and the through hole 21 is maintained by the sleeve 41, and the gap S is maintained by the collar portion 42. Further, by inserting the bus bar 3 into the through hole 21 into which the sleeve 41 is inserted, or by inserting the sleeve 41 into which the bus bar 3 is inserted into the through hole 21, the assembly in which the insulation between the bus bar 3 and the core 2 is secured is ensured. It will be easy. Further, the sleeve 41 inserted into the through hole 21 prevents the resin from flowing into the through hole 21.

(4) The mold portion 5 includes a first mold portion 51 that forms a gap S by interposing between the core 2 and the spacer 4, and a second mold portion 52 that covers the first mold portion 51. Have. Therefore, since it is sufficient to form the second mold portion 52 after securing the gap S by the first mold portion 51 and the spacer 4, the inside of the mold portion 5 is compared with the mold portion 5 formed at one time. The formation and maintenance of the void S is facilitated.

(5) The core 2 has two through holes 21, and the bus bar 3 has a U shape having both ends penetrating the two through holes 21. As a result, both ends of the bus bar 3 can be projected in the same direction, and the connection positions with the external devices can be aligned. Further, since the spacer 4 prevents the resin from flowing into the through hole 21 on the end face side on which the bus bar 3 protrudes, the mold D for forming the end face side is not required to have high dimensional accuracy.

(6) In the mold portion 5, resin injection marks are formed on the side opposite to the side surface of the core 2 exposed by the opening 521. Therefore, the side surface of the core 2 is pressed against the inner wall of the mold D by the injection pressure of the resin material, so that the injected resin material flows between the side surface of the core 2 and the mold D to fill the opening 521. Is prevented.

[Other Embodiments]
The present invention is not limited to the above embodiments. It can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope of the invention, the gist, and the scope thereof.

In the above embodiment, the two cores 2A and 2B are arranged so as to be offset in the long side direction as an example of a mode in which the two cores 2A and 2B are arranged so as to be displaced in the direction of one side of the upper surface 22 and the bottom surface 23. However, the cores 2A and 2B may not be arranged so as to be displaced. For example, the wide surfaces 241 adjacent to the core 2A and the core 2B may face each other as a whole. In accordance with this, the terminal portions 31A and 31B of the bus bar 3 may also be formed without deviation.

Further, for example, the number of cores 2 may be one. That is, one bus bar 3 may be passed through the one through hole 21 formed in the core 2 through the spacer 4 to form the mold portion 5 made of resin. A single bus bar 3 may be passed through one through hole 21 formed in the core 2 in which the partial cores are combined. As an example, an annular core 2 in which a C-shaped partial core is combined can be used. Further, the U-shaped bus bar 3 may be passed through the two through holes 21 provided in one core 2 or the two through holes 21 formed in the core 2 in which the partial cores are combined. As an example, a θ-shaped core 2 in which an E-shaped partial core is combined can be used. As described above, the through hole 21 includes the one formed by the divided core 2. Further, the annular core 2 may include an annular portion, and may have a shape having a plurality of through holes 21 such as a θ shape.

The outer shape of the core 2 is not limited to the rectangular parallelepiped shape. It may have a cubic shape, a cylindrical shape, a prismatic shape, or the like. Although the core 2 of the above embodiment is a dust core, a magnetic material such as a ferrite magnetic core or a laminated steel plate may be used. An insulating film such as polyamide or polyester may or may not be provided on the surface of the core 2.

The bus bar 3 may be insulated and coated. In this case, the portions exposed above the terminal portions 31A and 31B are not insulated and coated for electrical connection with an external device, and the copper plate is exposed.

The mold portion 5 may have a gap S and an opening 521, and does not need to be formed by a double mold of the first mold portion 51 and the second mold portion 52. Therefore, the mold portion 5 may be formed by molding once. Further, the number of openings 521 for exposing the side surface 24 was one for one core 2 in the above aspect, but two or more may be formed.

The spacer 4 may be provided only on one of the pair of end faces corresponding to both ends of the through hole 21. That is, the spacer 4 may be provided only on the upper surface 22 side or only on the bottom surface 23 side. The material constituting the spacer 4 and the mold portion 5 may be any material that can insulate the core 2 and the bus bar 3. For example, resins such as PPS (polyphenylene sulfide), unsaturated polyester resin, urethane resin, epoxy resin, BMC (bulk molding compound), and PBT (polybutylene terephthalate) can be appropriately selected and applied. Ceramic can also be used as the spacer 4.

1 Busbar Assembly 2, 2A, 2B Core 3 Busbar 4, 4Aa, 4Ab, 4Ba, 4Bb Spacer 5 Molded Part 6 Nut 6a Opening 21 Through Hole 22 Top 23 Bottom 24 Side 31, 31A, 31B Terminal 32 Connecting 33 Mounting 33a Mounting hole 41 Sleeve 42 Flange 42a Opening 42b Curved surface 51, 51A, 51B First mold 52 Second mold 241 Wide surface 242 Narrow surface 511, 512, 513, 521, 522 Opening 523 Flange part 523a Circular groove

Claims (6)

An annular core formed containing a magnetic material and having through holes,
A bus bar that has conductivity and penetrates the through hole,
An insulating spacer that supports the bus bar so that there is a space between the bus bar and the through hole.
A mold portion formed of an insulating resin and covering the core by adhering to the outer surface of the core,
A gap provided between the spacer and the end face of the core including at least one end of the through hole, and the mold portion is not in close contact with the core.
An opening provided in the mold portion and a part of the side surface of the core is exposed,
A busbar assembly characterized by having. The spacers are provided corresponding to the pair of end faces of the core including both ends of the through hole.
The bus bar assembly according to claim 1, wherein the gap is provided between each of the pair of end faces of the core and the spacer. The spacer is
A tubular sleeve with one end inserted into a part of the through hole,
A collar with an enlarged diameter at the other end of the sleeve,
Have,
The bus bar assembly according to claim 1 or 2, wherein the gap is formed between the collar portion and the end surface of the core. The mold part is
A first mold portion that forms the gap by interposing between the core and the spacer,
A second mold portion that covers the first mold portion and
The bus bar assembly according to any one of claims 1 to 3, wherein the bus bar assembly comprises. The core has two through holes.
The bus bar assembly according to any one of claims 1 to 4, wherein the bus bar has a U shape having both ends penetrating the two through holes. The bus bar assembly according to any one of claims 1 to 5, wherein an injection mark of the resin is formed on the mold portion on the side opposite to the side surface of the core exposed by the opening.

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