KR102647577B1 - Circle type terminal unit for driving motor - Google Patents

Abstract

The present invention relates to a round terminal unit for a drive motor that can increase the insulation performance between a plurality of round bus bars by increasing the internal space of the terminal holder and prevent the formation of space between the terminal holder and the overmold. A plurality of annular bus bars that are different and are concentrically disposed on a plurality of power sources; A spacer disposed between the plurality of circular bus bars to maintain a gap between the circular bus bars and insulate the circular bus bars from each other; a terminal holder in which the circular bus bar and the spacer are accommodated; and an overmold injected into the interior of the terminal holder in a molten resin state.

Description

Circular terminal unit for driving motor {CIRCLE TYPE TERMINAL UNIT FOR DRIVING MOTOR}

The present invention relates to a circular terminal unit for a drive motor, and more specifically, to increase the insulation performance between a plurality of circular bus bars by increasing the internal space of the terminal holder and to prevent space from being formed between the terminal holder and the overmold. It relates to a circular terminal unit for a drive motor that can be used.

Hybrid cars are equipped with a drive motor that generates power using electricity, and a key part of the drive motor includes a ring terminal.

The ring terminal of the drive motor is an element that supplies and distributes the voltage input from the outside to the drive motor. The ring terminal of the conventional drive motor has a configuration in which multiple bus bars are inserted into a terminal holder and arranged continuously close to each other to create space. Minimize occupancy.

This round terminal unit inserts a plurality of bus bars into a terminal holder and arranges spacers between the plurality of bus bars to secure the bus bars.

Then, after inserting and fastening into the upper and lower jigs, the jig is again inserted into the mold, and molten resin is injected through the ejection port of the jig to form an overmold integrated with the terminal holder on the bus bar in the terminal holder. do.

The overmold can maintain uniform spacing between multiple terminals by fixing the bus bar inserted into the terminal holder and precisely maintain the insulation distance according to the spacing.

Meanwhile, the ring-shaped terminal unit molded as described above has a problem in that a space is created between the overmold and the terminal holder during thermal shock.

For this reason, since the circular terminal unit according to the prior art is exposed to transmission oil, etc. when installed in a vehicle, there is a problem in which such impurities flow into the interior of the circular terminal unit through the space.

In order to solve the above problems, some prior arts propose a structure of a ring-shaped terminal that can prevent a space from being formed between the terminal holder and the overmold.

For example, in Republic of Korea Patent Publication No. 10-1073347 (2011.10.06.), as shown in FIG. 1, it consists of an inner wall 111, an outer wall 112, and a bottom 113, and the inner wall 111 In the terminal holder 11 in which the receiving space S is formed by the outer wall 112 and the bottom 113, at least one of the inner wall 111 and the outer wall 112 extends vertically from the bottom 113. A lower wall portion 112a, a horizontal portion 112b extending from the lower wall portion 112a in the opposite direction of the receiving space S, and an upper wall portion extending vertically from the end of the horizontal portion 112b. A ring-shaped terminal for a hybrid car drive motor is disclosed in which a stepped portion 112d protruding in the vertical direction is formed in the middle of the horizontal portion 112c and the horizontal portion 112b.

Then, an overmold is injected into the terminal holder 11.

That is, the circular terminal of the above application has a horizontal portion 112b structure to prevent the phenomenon of space being created between the overmold and the terminal holder 11 when manufacturing the circular terminal.

However, as the horizontal portion 112b is formed on the inner wall 111 or the outer wall 112 of the ring terminal of the above application, the thickness of the lower wall portion 112a becomes thicker.

Therefore, as the thickness of the lower wall portion 112a increases, the accommodation space S formed by the inner wall 111 and the outer wall 112 inevitably becomes narrower.

As a result, the insulation distance between a plurality of bus bars inserted into a terminal holder with a narrow accommodation space is narrowed, and there is a problem that the insulation performance between bus bars is deteriorated.

The present invention is intended to solve the above-mentioned problems, and is intended to increase the insulation performance between multiple bus bars by increasing the internal space of the terminal holder, and to provide a circular shape for a drive motor that can prevent space from being formed between the terminal holder and the overmold. The purpose is to provide a terminal unit.

The annular terminal unit for a drive motor according to an embodiment of the present invention includes a plurality of annular bus bars having different diameters and arranged concentrically on a plurality of power sources; A spacer disposed between the plurality of circular bus bars to maintain a gap between the circular bus bars and insulate the circular bus bars from each other; a terminal holder in which the circular bus bar and the spacer are accommodated; and an overmold injected into the interior of the terminal holder in a molten resin state.

The terminal holder includes an inner wall, an outer wall spaced apart from the inner wall, and a bottom connecting lower ends of the inner wall and the outer wall.

A plurality of the outer walls are spaced apart from each other along the circumference of the upper surface, and are in communication with the terminal holder to form a mold groove into which the overmold in a molten resin state injected into the terminal holder flows.

The mold groove includes: a first mold groove penetrating the inner peripheral surface of the outer wall and communicating with the outside of the outer peripheral surface in the inner peripheral surface direction; and a second mold groove formed in the first mold groove in the direction of the outer peripheral surface of the outer wall and communicating with the first mold groove.

The second mold groove is wider than the first mold groove, and a step is formed between the first mold groove and the second mold groove.

The mold groove is formed with an inclined surface so that the wall surfaces of the mold groove become more apart from the first mold groove to the second mold groove.

The second mold groove is wider than the first mold groove, penetrates the outer peripheral surface of the outer wall, and communicates with the outside in the outer peripheral surface of the outer wall.

The second mold groove communicates with second mold grooves arranged close to each other along the left and right circumferences, forming a closed loop shape.

The round terminal unit for a drive motor according to the present invention is made up of a plurality of spacers and is inserted between the plurality of round bus bars, thereby strengthening the insulation between each round bus bar and preventing the possibility of damage due to short circuit. There is an effect that can be done.

In addition, a plurality of insertion grooves are formed along the circumferential direction of the bottom so that a plurality of ring-shaped bus bars can be inserted into the bottom, which has the effect of firmly fixing the ring-shaped bus bar inserted into the receiving space.

In addition, a plurality of mold grooves along the upper circumference of the outer wall are spaced apart from each other and communicate with the terminal holder, thereby preventing the creation of space between the overmold and the terminal holder, thereby preventing waste, such as transmission oil, etc. It can effectively block impurities from flowing between the terminal holder and the solidified overmold, and the accommodation space of the terminal holder can be expanded, widening the gap between the circular bus bars inserted into the accommodation space, thereby increasing the insulation performance between the circular bus bars. There is a possible effect.

In addition, the area of the second mold groove is formed to be wider than the area of the first mold groove, thereby forming a step between the first mold groove and the second mold groove, so that the solidified overmold is formed between the first mold groove and the second mold groove. The solidified overmold is caught on the step formed in and is firmly and fixed to the second mold groove, and the first mold groove and the second mold groove have the effect of effectively preventing the solidified overmold from leaving the receiving space. .

In addition, an inclined surface is formed so that the walls of the mold grooves spread apart from the first mold groove to the second mold groove, so that the solidified overmold is caught on the inclined surface formed between the first mold groove and the second mold groove, thereby forming the solidified overmold. The mold is firmly fixed in the second mold groove, and the first mold groove and the second mold groove effectively prevent the solidified overmold from being separated from the receiving space.

In addition, the second mold groove penetrates the outer peripheral surface of the outer wall and communicates with the outside in the outer peripheral surface direction of the outer wall, thereby increasing the thickness of the overmold flowing into the second mold groove, so that the solidified overmold is strong and strong in the second mold groove. This has the effect of more effectively preventing the fixed and solidified overmold from leaving the receiving space.

Then, when the second mold grooves disposed close to each other on the left and right in the second mold groove are connected to each other and the overmold flowing into the second mold groove is solidified, the inner peripheral surface of the overmold flowing into the second mold groove is formed by the second mold. By making overall surface contact with the outer peripheral surface of the groove, the solidified overmold is firmly and fixed to the second mold groove, which has the effect of more effectively preventing the solidified overmold from being separated from the receiving space.

Figure 1 is a cross-sectional view showing a circular terminal unit for a drive motor according to the cited invention.
Figure 2 is a perspective view showing a circular terminal unit for a drive motor according to the first embodiment of the present invention.
Figure 3 is an exploded perspective view showing the disassembled state of the annular terminal unit for a drive motor according to the first embodiment of the present invention.
Figure 4 is a perspective view showing a terminal holder according to the first embodiment of the present invention.
Figure 5 is a perspective view showing a terminal holder according to a second embodiment of the present invention.
Figure 6 is a perspective view showing a terminal holder according to a third embodiment of the present invention.
Figure 7 is a perspective view showing a terminal holder according to a fourth embodiment of the present invention.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and will be implemented in various different forms. The present embodiments only serve to ensure that the disclosure of the present invention is complete and that common knowledge in the technical field to which the present invention pertains is not limited. It is provided to fully inform those who have the scope of the invention, and the invention is defined by the claims. Meanwhile, the terms used in this specification are for describing embodiments and are not intended to limit the present invention. As used herein, singular forms also include plural forms, unless specifically stated otherwise in the context. As used in the specification, “comprises” or “comprising” means the presence or presence of one or more other components, steps, operations and/or elements other than the mentioned elements, steps, operations and/or elements. Addition is not ruled out.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings.

Figure 2 is a perspective view showing the annular terminal unit for a drive motor according to the first embodiment of the present invention, and Figure 3 is an exploded perspective view showing the disassembled state of the annular terminal unit for a drive motor according to the first embodiment of the present invention. Figure 4 is a perspective view showing a terminal holder according to a first embodiment of the present invention, Figure 5 is a perspective view showing a terminal holder according to a second embodiment of the present invention, and Figure 6 is a perspective view showing a terminal holder according to a third embodiment of the present invention. It is a perspective view showing the terminal holder, and Figure 7 is a perspective view showing the terminal holder according to the fourth embodiment of the present invention.

Referring to Figures 1 to 4, the round terminal unit for a drive motor according to the first embodiment of the present invention includes a round bus bar 100, a spacer 200, a terminal holder 300, and an overmold 400. .

The annular bus bar 100 is preferably made of copper, and a plurality of them are arranged concentrically to correspond to the phases of the plurality of power sources to be connected.

These plurality of ring-shaped bus bars 100 are manufactured into circular ring shapes through a punching process using a press, and are manufactured with different diameters. At a predetermined position on the upper part of the ring-shaped bus bar 100, there is a binding vertically bent in the inner diameter direction. The terminal 110 is formed integrally.

The spacers 200 are inserted between the plurality of ring-shaped bus bars 100 to maintain the gap between the ring-shaped bus bars 100 and insulate the ring-shaped bus bars 100 from each other.

That is, the spacer 200 is made up of a plurality of spacers, and is inserted between the plurality of ring-shaped bus bars 100, thereby strengthening the insulation state between each ring-shaped bus bar 100 and preventing the possibility of damage due to short circuit. You can.

The terminal holder 300 is made of an insulating material such as plastic and has a circular closed loop structure.

Then, the terminal holder 300 has an open top, and a plurality of ring-shaped bus bars 100 and a plurality of spacers 200 are accommodated inside, that is, in the accommodation space 340.

This terminal holder 300 includes an inner wall 310, an outer wall 320, and a bottom 330.

The inner wall 310 is formed on the inner side in the radial direction, the outer wall 320 is formed radially spaced apart from the inner wall 310, and the bottom 330 is formed on the inner side wall 310 and the outer wall ( It is formed at the lower end of the inner wall 310 and the lower end of the outer wall 320 to each other.

In particular, the bottom portion 330 has a plurality of insertion grooves 331 formed along the circumferential direction of the bottom portion 330 to allow the plurality of annular bus bars 100 to be inserted.

Because of this, the bottom portion 330 can firmly fix the annular bus bar 100 inserted into the interior of the terminal holder 300, that is, the receiving space 340.

As described above, the terminal holder 300 has an internal receiving space 340 formed by the inner wall 310, the outer wall 320, and the bottom 330.

The overmold 400 in a molten resin state is injected into the receiving space 340.

The overmold 400 is made up of multiple pieces and is applied and solidified on the annular bus bar 100 and the spacer 200 respectively accommodated in the receiving space 340 of the terminal holder 300.

Because of this, the overmold 400 can effectively seal the annular bus bar 100 and the spacer 200 from the outside.

Meanwhile, a mold groove 321 is formed on the upper surface of the outer wall 320.

A plurality of mold grooves 321 are spaced apart from each other along the upper circumference of the outer wall 320 and communicate with the terminal holder 300.

That is, the overmold 400 in a molten resin state injected into the terminal holder 300 flows into the mold groove 321.

Therefore, the mold groove 321 is injected into the terminal holder 300, and during the process of solidification of the overmold 400 in a molten resin state introduced into the mold groove 321, or during thermal shock, the overmold 400 and the terminal It is possible to prevent space between the holders 300, and thus, impurities such as transmission oil can be effectively prevented from flowing between the terminal holder 300 and the solidified overmold 400.

In addition, as the horizontal portion 112b is formed on the inner wall 111 or the outer wall 112 of the annular bus bar 10, the receiving space S may become narrow as the thickness of the lower wall portion 112a increases. Unlike the prior art, in the present invention, a structure such as the horizontal portion 112b of the prior art is deleted from the outer wall 320, so that the accommodation space 340 of the terminal holder 300 can be expanded.

As a result, the distance between the round bus bars 100 inserted into the receiving space 340 of the terminal holder 300 is widened, so that the insulation performance between the round bus bars 100 can be improved.

The mold groove 321 according to the first embodiment of the present invention consists of a first mold groove 322 and a second mold groove 325.

The first mold groove 322 is formed through the inner peripheral surface of the outer wall 320 and communicates with the receiving space 340 of the terminal holder 300.

Therefore, the first mold groove 322 is in communication with the receiving space 340 of the terminal holder 300, so that the molten resin injected into the receiving space 340 of the terminal holder 300 is in the first mold groove 322. The overmold 400 may be introduced.

The second mold groove 325 is formed in the direction from the first mold groove 322 to the outer peripheral surface of the outer wall 320 and communicates with the first mold groove 322.

Therefore, the second mold groove 325 is in communication with the receiving space 340 and the first mold groove 322 of the terminal holder 300, so that the second mold groove 325 includes the receiving space 340 of the terminal holder. The overmold 400 in the molten resin state injected into flows into the first mold groove.

Meanwhile, in the mold groove 321 according to the first embodiment of the present invention, the area of the second mold groove 325 is formed to be wider than the area of the first mold groove 322, as shown in FIG. 4.

Accordingly, a step 323 is formed between the first mold groove 322 and the second mold groove 325.

That is, when the overmold 400 in the molten resin state injected into the receiving space 340 of the terminal holder 300 solidifies, the solidified overmold 400 is formed in the first mold groove 322 and the second mold groove 325. ) The solidified overmold 400 is caught on the step 323 formed between the molds and is firmly fixed to the second mold groove 325.

Because of this, the first mold groove 322 and the second mold groove 325 can effectively prevent the solidified overmold 400 from being separated from the receiving space 340.

And, in the mold groove 321 according to the second embodiment of the present invention, an inclined surface 324 is formed between the first mold groove 322 and the second mold groove 325 as shown in FIG. 5.

More specifically, the mold groove 321 is formed in an inclined shape so that the walls of the mold groove 321 spread apart from the first mold groove 322 to the second mold groove 325.

Accordingly, an inclined surface 324 is formed between the first mold groove 322 and the second mold groove 325.

That is, when the overmold 400 in the molten resin state injected into the receiving space 340 of the terminal holder 300 solidifies, the solidified overmold 400 is formed in the first mold groove 322 and the second mold groove 325. ) The solidified overmold 400 is caught on the inclined surface 324 formed between the molds and is firmly fixed to the second mold groove 325.

Because of this, the first mold groove 322 and the second mold groove 325 can effectively prevent the solidified overmold 400 from being separated from the receiving space 340.

In addition, in the mold groove 321 according to the third embodiment of the present invention, the area of the second mold groove 325 is formed to be wider than the area of the first mold groove 322, so that the first mold groove 322 and the second mold groove 321 are formed. A step 323 is formed between the mold grooves 325.

That is, when the overmold 400 in the molten resin state injected into the receiving space 340 of the terminal holder 300 solidifies, the solidified overmold 400 is formed in the first mold groove 322 and the second mold groove 325. ) The solidified overmold 400 is caught on the step 323 formed between the molds and is firmly fixed to the second mold groove 325.

And, as shown in FIG. 6, the second mold groove 325 penetrates the outer peripheral surface of the outer wall 320 and communicates with the outside of the outer peripheral surface of the outer wall 320.

Accordingly, the thickness of the overmold 400 flowing into the second mold groove 325 increases.

That is, as the thickness of the overmold 400 introduced into the second mold groove 325 increases, the solidified overmold 400 is firmly fixed to the second mold groove 325 and the solidified overmold 400 ) can be more effectively prevented from leaving the receiving space 340.

In addition, the mold groove 321 according to the fourth embodiment of the present invention is left and right in the second mold groove 325 of the first to third embodiments, which are spaced apart from each other along the upper surface of the outer wall 320. The second mold grooves 325 arranged close to each other communicate with each other as shown in FIG. 8 .

Accordingly, the second mold groove 325 has a closed loop cross-sectional shape.

Due to this, when the overmold 400 flowing into the second mold groove 325 is solidified, the inner peripheral surface of the overmold 400 flowing into the second mold groove 325 is the outer peripheral surface of the second mold groove 325. By fully contacting each other, the solidified overmold 400 is firmly fixed to the second mold groove 325 and can more effectively prevent the solidified overmold 400 from being separated from the receiving space 340.

As described above, the round terminal unit for a drive motor of the present invention is made up of a plurality of spacers 200, and is inserted between the plurality of round bus bars 100, thereby creating a gap between each round bus bar 100. By strengthening the insulation, you can prevent the possibility of damage due to short circuit.

A plurality of insertion grooves 331 are formed along the circumferential direction of the bottom 330 to allow the plurality of circular bus bars 100 to be inserted into the bottom 330, thereby inserting the circular bus bars into the receiving space 340. (100) can be firmly fixed.

A plurality of mold grooves 321 along the upper circumference of the outer wall 320 are spaced apart from each other and communicate with the terminal holder 300, thereby creating a space between the overmold 400 and the terminal holder 300. This can effectively prevent impurities such as transmission oil from flowing between the terminal holder 300 and the solidified overmold 400, and the accommodation space 340 of the terminal holder 300 is wide. As the space between the round bus bars 100 inserted into the receiving space 340 is widened, the insulation performance between the round bus bars 100 can be increased.

The area of the second mold groove 325 is formed to be wider than the area of the first mold groove 322, and a step 323 is formed between the first mold groove 322 and the second mold groove 325, thereby forming the solidified The overmold 400 is caught on the step 323 formed between the first mold groove 322 and the second mold groove 325, so that the solidified overmold 400 is firmly and fixed to the second mold groove 325. The first mold groove 322 and the second mold groove 325 can effectively prevent the solidified overmold 400 from being separated from the receiving space 340.

An inclined surface 324 is formed so that the walls of the mold groove 321 spread apart from the first mold groove 322 to the second mold groove 325, so that the solidified overmold 400 is formed in the first mold groove 322. ) and the second mold groove 325, the solidified overmold 400 is caught on the inclined surface 324 formed between the first mold groove 322 and the second mold groove 325. The mold groove 325 can effectively prevent the solidified overmold 400 from being separated from the receiving space 340.

The second mold groove 325 penetrates the outer peripheral surface of the outer wall 320 and communicates with the outside in the outer peripheral surface direction of the outer wall 320, thereby increasing the thickness of the overmold 400 flowing into the second mold groove 325. , the solidified overmold 400 is firmly and fixed to the second mold groove 325, so that the solidified overmold 400 can be more effectively prevented from being separated from the receiving space 340.

When the second mold grooves 325 arranged close to each other on the left and right in the second mold groove 325 communicate with each other and the overmold 400 flowing into the second mold groove 325 is solidified, the second mold groove ( The inner circumferential surface of the overmold 400 flowing into 325) is in overall surface contact with the outer circumferential surface of the second mold groove 325, so that the solidified overmold 400 is firmly fixed to the second mold groove 325 and solidifies. The overmold 400 can be more effectively prevented from being separated from the receiving space 340.

The present invention is not limited to the above-described embodiments, and can be implemented with various modifications within the scope permitted by the technical idea of the present invention.

100: round bus bar 110: terminal
200: Spacer 300: Terminal holder
310: inner wall 320: outer wall
321: Mold groove 322: First mold groove
323: step 324: slope
325: Second mold groove 330: Bottom part
331: Insertion groove 340: Accommodating space
400: Overmold

Claims (8)

In the round terminal unit for a drive motor,
A plurality of annular bus bars having different diameters and arranged concentrically on a plurality of power sources;
A spacer disposed between the plurality of circular bus bars to maintain a gap between the circular bus bars and insulate the circular bus bars from each other;
a terminal holder in which the circular bus bar and the spacer are accommodated; and
It includes an overmold injected into the interior of the terminal holder in a molten resin state,
The terminal holder is
It consists of an inner wall, an outer wall spaced apart from the inner wall, and a bottom connecting the lower ends of the inner wall and the outer wall,
The outer wall is,
A plurality of mold grooves are spaced apart from each other along the circumference of the upper surface, and are in communication with the terminal holder, forming a mold groove into which the overmold in the molten resin state injected into the terminal holder flows.
Round terminal unit for driving motors.
delete delete The method of claim 1, wherein the mold groove is:
a first mold groove penetrating the inner circumferential surface of the outer wall and communicating with the outside of the outer wall in the inner circumferential direction; and
A second mold groove formed in the first mold groove in the direction of the outer peripheral surface of the outer wall and communicating with the first mold groove.
Round terminal unit for driving motors.
The method of claim 4, wherein the second mold groove is:
The area is wider than the area of the first mold groove, and a step is formed between the first mold groove and the second mold groove.
Round terminal unit for driving motors.
The method of claim 4, wherein the mold groove is:
An inclined surface is formed so that the wall surfaces of the mold grooves spread apart as one moves from the first mold groove to the second mold groove.
Round terminal unit for driving motors.
The method of claim 4, wherein the second mold groove is:
The area is wider than the area of the first mold groove, and penetrates the outer peripheral surface of the outer wall to communicate with the outside in the outer peripheral surface of the outer wall.
Round terminal unit for driving motors.
The method of claim 4, wherein the second mold groove is:
Forming a closed loop shape by communicating with the second mold grooves arranged close to each other along the left and right circumferences.
Round terminal unit for driving motors.

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