WO2020153557A1 - Method for manufacturing busbar for connecting batteries for electric vehicle - Google Patents

Abstract

The present invention relates to a method for manufacturing a busbar for connecting batteries for an electric vehicle and, more particularly, to a method for manufacturing a busbar for connecting batteries for an electric vehicle, wherein the method enables easy manufacture of a busbar for electrically connecting a plurality of batteries used in an electric vehicle without defects. The method for manufacturing a busbar for connecting batteries for an electric vehicle of the present invention is a method for manufacturing a busbar electrically connecting batteries of an electric vehicle, and comprises: a cutting step of punching a metal plate into a busbar shape by means of a press to cut the metal plate; a deburring step of removing burrs formed at corner portions of the busbar in the cutting step; a masking step of covering a terminal portion formed on both ends of the busbar with a cap to mask the terminal portion; a coating step of forming an insulating coating layer on the outer peripheral surface of the busbar having both ends masked; a masking removal step of removing the cap covering both ends of the busbar; and a coating removal step of further removing a portion of the coating layer from a portion adjacent to the cap after removing the cap.

Description

Method for manufacturing a battery-connected busbar for electric vehicles

The present invention relates to a method for manufacturing a battery-connected busbar for an electric vehicle, and more particularly, to a method for manufacturing a battery-connected busbar for an electric vehicle that can easily manufacture a busbar for electrically connecting a plurality of batteries used in an electric vehicle without defect. will be.

In recent years, various electric devices are built in a modular form, and a flexible type power cable having sufficient power supply capability in a narrow space in each module of the electrical device is required.

In particular, due to the emergence of electric vehicles, a cable capable of stably supplying power within a given narrow space is required, and such a request can be said to be applied to a building or an instrumentation box or a power supply box in a building.

In order to solve the above-mentioned needs, a bus bar is provided, and the bus bar is a form in which a plurality of plate-shaped conductors are stacked and coated in a longitudinal direction, and bending is possible in a required form due to its flexibility, thereby consequently in a narrow space. Not only is it easy to install, but by providing a high current carrying capacity, it has been frequently used in many electric device modules or boxes in recent years.

In addition, a coating layer is formed on the surface of the bus bar for insulation or the like.

Existing bus bars are formed by coating synthetic resin onto the surface of a metal bus bar to form a coating layer, or by inserting a plurality of plate-shaped conductors into a tube to form a coating layer.

However, in the conventional manufacturing method as described above, when the shape of the busbar is complicated, it is difficult to form a coating layer of uniform thickness in close contact with the surface of the busbar, and a gap occurs between the busbar and the coating layer in the manufacturing process. There was a problem.

The present invention is to solve the above-mentioned problems, even if the bus bar of a complex shape, the coating layer of a uniform thickness on the surface of the bus bar to form a close contact of the battery connection bus bar for electric vehicles that can improve productivity and workability The purpose is to provide a manufacturing method.

In order to achieve the above object, a method of manufacturing a battery-connected busbar for an electric vehicle of the present invention is a method of manufacturing a busbar that electrically connects a battery of an electric vehicle, a cutting step of punching and cutting a metal plate into a busbar shape with a press Wow; A burr removing step of removing burrs formed at corner portions of the bus bar in the cutting step; A masking step of covering and masking a cap on terminal portions formed at both ends of the bus bar; A coating step of forming an insulating coating layer on the outer circumferential surface of the bus bar with both ends masked; A masking removal step of removing the caps on both ends of the bus bar; It characterized in that it comprises a; coating removal step of removing a portion of the coating layer adjacent to the cap after removing the cap.

In the burr removing step, the burr is disposed in the rounding groove of the die and then pressed to remove the burr.

In the masking step, a cap of a heat-resistant material is put on both ends of the bus bar, and in the coating step, the coating is formed by heating the bus bar and attaching a powder-form paint to the surface of the bus bar.

The coating step includes a preheating step of heating the bus bar; A dipping step of putting the heated bus bar into a powder-form paint; After removing the bus bar from the paint in powder form, heating the bus bar to melt the powder adhering to the outside of the bus bar to harden it to form the coating layer.

In the masking step, a cap having a size smaller than the line indicating the end portion of the terminal portion to be finally formed is covered at both ends of the bus bar, and a portion of the terminal portion including the line marking the end portion of the terminal portion is exposed to the outside, In the coating removal step, after removing the cap, the coating layer covering a part of the terminal portion is removed with a laser to a line marking the end of the terminal portion.

The metal plate is made of copper, and between the deburring step and the masking step, a plating step of nickel plating on the surface of the busbar to prevent oxidation of the busbar made of copper; further comprises a.

According to the manufacturing method of the battery connection bus bar for an electric vehicle of the present invention as described above has the following effects.

In the present invention, by coating the powder on the surface of the bus bar by fusion, it is possible to form a coating layer of uniform thickness on the surface of the bus bar, and even if the shape of the bus bar is made of a complex shape, the coating layer on the surface of the bus bar It can be formed in close contact with a uniform thickness, and it is easy to work, thereby improving productivity and workability.

And, by removing the burr generated during the punching of the metal plate by the press, so that the coating layer is formed to a uniform thickness in all parts of the bus bar, to prevent the breakdown of the insulating coating layer in a specific area when a high voltage is applied to the bus bar Can.

In addition, the terminal portion of the correct size on both ends of the bus bar to be exposed to the outside, the rest of the coating layer can be formed to a uniform thickness.

1 is a flow chart of a method of manufacturing a battery connection bus bar for an electric vehicle according to an embodiment of the present invention,

2 is a process diagram of the cutting step and the burr removing step according to an embodiment of the present invention

3 is a process diagram of the masking step and the coating step according to an embodiment of the present invention

4 is a process diagram of the masking removal step and the coating removal step according to an embodiment of the present invention

5 is a perspective view of a battery connection bus bar for an electric vehicle manufactured by a manufacturing method according to an embodiment of the present invention.

The present invention relates to a method for manufacturing a bus bar that electrically connects a battery of an electric vehicle, as shown in FIG. 1, a cutting step (S10), a burr removing step (S20), a plating step (S30), It comprises a masking step (S40), a coating step (S50), a masking removal step (S60), and a coating removal step (S70).

The cutting step (S10) is a step of punching and cutting a metal plate into a bus bar 10 shape using a press, as shown in FIGS. 2(a) and 2(b).

The shape of the bus bar 10 shown in the drawings of this embodiment is an example, and the shape of the bus bar 10 may be variously changed.

When the metal plate is punched with a press to cut it into the shape of the bus bar 10, as shown in FIG. 2(c) showing a cross-section of FIG. 2(b), a burr 11, burr).

In the burr removing step (S20), in the cutting step (S10), the burr 11 formed at the corner portion of the bus bar 10 is removed.

If the burr 11 formed in the corner portion of the bus bar 10 is not removed, when the coating layer 20 is formed on the bus bar 10, the coating layer 20 is applied locally to the corner portion where the burr 11 is formed. ) Becomes thin, and a problem that the coating layer 20 is destroyed when high voltage is applied may occur.

Therefore, the burr 11 in the corner of the bus bar 10 is removed in the burr removing step S20.

A method of removing the burr 11 is forging or buffing.

In this embodiment, as shown in FIG. 2(d), a die having a round groove is prepared, and after arranging the corner portion of the bus bar 10 in the rounding groove of the die and pressing it, FIG. 2(e) As shown in the was to remove the burr 11 in the corner portion of the bus bar 10.

The plating step (S30) is a step of nickel plating on the surface of the bus bar 10, and is performed to prevent oxidation of the bus bar 10 when the metal plate is made of copper.

If the metal plate is not made of copper, the plating step (S30) may be omitted.

It is preferable that the thickness of the nickel plating layer is about 3 to 8 µm.

The masking step (S40) is a step of masking the cap 30 by covering the terminal portion 12 formed on both ends of the bus bar 10, as shown in Figure 3 (b).

At this time, the cap 30 is made of a soft elastic heat-resistant material, so that it is covered on both ends of the bus bar 10.

Then, in the masking step (S40), a cap 30 having a size smaller than the terminal part 12 to be finally formed is covered.

In FIG. 3, a cap 30 smaller than the line 13 marking the end portion of the terminal portion 12 to be finally formed is covered.

Therefore, when the cap 30 is covered at both ends of the bus bar 10 in the masking step S40, a portion of the terminal portion 12 is covered by the cap 30, but the terminal portion 12 is A part including the line 13 marking the end part is exposed to the outside.

The coating step (S50) is a step of forming an insulating coating layer 20 on the outer circumferential surface of the bus bar 10 with both ends masked.

In the coating step (S50), after heating the bus bar 10, a coating in powder form is attached to the surface of the bus bar 10 to form the coating layer 20.

In this embodiment, the coating step (S50) comprises a preheating step (S51), a dipping step (S52) and a post-heating step (S53).

The preheating step (S51) is a step of heating the bus bar 10, which is masked with a cap 30 at both ends by a ring or the like, as shown in FIG. 3(c) to a temperature of about 250°C.

The dipping step (S52) is a step of putting the bus bar 10 heated in the preheating step (S51) into a powder-form paint, as shown in FIG. 3(d).

When the heated bus bar 10 is put in a powder-form coating, the powder in contact with the bus bar 10 is partially melted and attached to the surface of the bus bar 10.

The post-heating step (S53) is a step of heating the bus bar 10 after removing the bus bar 10 from the powder-form paint as shown in FIG. 3(e).

The powder attached to the outside of the bus bar 10 is cured while being melted by the post-heating step (S53), so that an insulating material coating layer 20 is applied to the surface of the bus bar 10 and the surface of the cap 12. To form.

By the above coating step (S50), the present invention may form a coating layer 20 of a uniform thickness on the surface of the bus bar 10, the shape of the bus bar 10 is made of a complex shape Even if the coating layer 20 is formed to be adhered to the surface of the bus bar 10 in a uniform thickness, it is easy to work and can improve productivity and workability.

The masking removing step (S60) is a step of removing the caps 30 covered on both ends of the bus bar 10.

When the cap 30 is removed, both ends of the bus bar 10 are exposed to the outside without being coated with the coating layer 20, as shown in FIG. 4(a).

At this time, when the size of the cap 30 covered on both ends of the bus bar 10 in the masking step (S40) is smaller than the size of the terminal portion 12 to be finally formed, when the cap 30 is removed Finally, a part of the terminal portion 12 to be formed is covered by the coating layer 20.

That is, as shown in Fig. 4 (a), the coating layer 20 covers the line 13 marking the end of the terminal portion 12.

Then, when the cap 30 is removed, powder of the powder penetrates through the gap between the cap 30 and the bus bar 10, and a slight coating layer 20 is also applied to the position where the cap 30 was covered. It may be formed.

The coating removal step (S70) is a step of removing a portion of the coating layer 20 adjacent to the cap 30 after the cap 30 is removed.

More specifically, in the coating removal step (S70), as shown in FIG. 4(b), the coating layer 20 overlying the terminal portion 12 to be finally formed after removal of the cap 30 is set in a predetermined dimension. To the end of the terminal portion 12 to fit, the laser is removed.

That is, as illustrated in FIG. 4, the coating layer 20 is removed up to the line 13 marking the end of the terminal portion 12.

As described above, even if the cap 30 is placed on the terminal portion 12 of the bus bar 10, since the atomized powder flows to the inside of the cap 30, the terminal portion is accurately removed when the cap 30 is removed. There is a limit to the absence of the coating layer 20 up to the end of (12).

In addition, the coating layer 20 is not uniform due to a difference in thickness and material at the contact portion between the bus bar 10 and the cap 30 that is not covered by the cap 30, and the bus is removed when the cap 30 is removed. Defects may be generated in the coating layer 20 at both ends of the bar 10.

In order to solve this problem, in the present invention, as described above, the cap 30 is smaller than the size of the terminal portion 12 to be finally formed.

Therefore, in the coating removal step (S70), the coating layer 20 formed by the powder flowing into the inside of the cap 30, the bus bar 10 is not covered by the cap 30 and the cap 30 are in contact By removing the bonding coating layer 20 formed on the site with a laser, the terminal portion 12 to be finally formed can be exposed to the outside with accurate dimensions without the coating layer 20.

According to the manufacturing method of the present invention as described above, the terminal portion 12 of the correct size is exposed to the outside on both ends of the bus bar 10, and the coating layer 20 can be formed in a uniform thickness in the remaining portions.

The method of manufacturing a battery connection busbar for an electric vehicle according to the present inventors is not limited to the above-described embodiments, and can be implemented by variously changing within a range within which the technical spirit of the present invention is permitted.

The present invention can be applied to a method technology for manufacturing a connecting busbar for an electric vehicle battery, and thus has industrial applicability.

Claims (6)

In the manufacturing method of the bus bar to electrically connect the battery of the electric vehicle, A cutting step of cutting the metal plate by punching it into a bus bar shape with a press; A burr removing step of removing burrs formed at corner portions of the bus bar in the cutting step; A masking step of covering and masking a cap on terminal portions formed at both ends of the bus bar; A coating step of forming an insulating coating layer on the outer circumferential surface of the bus bar with both ends masked; A masking removal step of removing the caps on both ends of the bus bar; After removing the cap, a coating removal step of removing a portion of the coating layer adjacent to the cap; a method of manufacturing a battery connection busbar for an electric vehicle, comprising: The method according to claim 1, In the deburring step, a method of manufacturing a battery-connected busbar for an electric vehicle, wherein the burr is removed by pressing after placing the corner portion of the busbar in the rounding groove of the die. The method according to claim 1, In the masking step, a cap of heat-resistant material is put on both ends of the bus bar, In the coating step, a method of manufacturing a battery-connected busbar for an electric vehicle, wherein the coating layer is formed by heating the busbar and attaching a powder-form paint to the surface of the busbar. The method according to claim 3, The coating step, A preheating step of heating the bus bar; A dipping step of putting the heated bus bar into a powder-form paint; After removing the bus bar from the paint in powder form, heating the bus bar to melt the powder adhering to the outside of the bus bar to harden it to form the coating layer. Method of manufacturing a bus bar. The method according to claim 4, In the masking step, a cap having a size smaller than the line indicating the end portion of the terminal portion to be finally formed is covered at both ends of the bus bar, and a portion of the terminal portion including the line marking the end portion of the terminal portion is exposed to the outside, In the coating removal step, after removing the cap, a method of manufacturing a battery-connected busbar for an electric vehicle, characterized in that a coating layer covering a part of the terminal portion is removed with a laser to a line marking the end of the terminal portion. The method according to claim 1, The metal plate is made of copper, Between the deburring step and the masking step, the plating step of nickel plating on the surface of the bus bar to prevent oxidation of the bus bar made of copper; manufacturing of a battery connection bus bar for an electric vehicle, characterized in that further comprises Way.

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