KR102502722B1 - reinforcement structure for insulation level of Battery pack - Google Patents

Abstract

The insulation performance reinforcement structure of the battery pack of the present invention is reinforced to simultaneously satisfy the robustness structure and insulation structure of the end plate, a pair of left and right support bars, and the base plate for supporting a plurality of battery module assemblies in a box shape. By improving the clearance distance and creepage distance for each nominal voltage, insulation breakdown in the lateral and vertical directions can be prevented, and at the same time, insulation breakdown along the sensing connector wire path can be prevented in case of moisture condensation.

Description

Reinforcement structure for insulation level of Battery pack}

The present invention relates to a structure for reinforcing insulation performance of a battery pack, and more particularly, to a battery capable of simultaneously enhancing robustness and insulation by improving a space distance and a creeping distance for each battery pack nominal voltage. It relates to a structure for reinforcing the insulation performance of a pack.

Battery packs go through several tests during the development stage. In particular, since the battery pack serves to store electricity, the level at which the stored electricity is leaked to the outside becomes a criterion for evaluation.

As shown in FIG. 1, a conventional battery pack 1 includes a base plate 20 and an end plate in which a battery module assembly (BMA) 10 composed of a plurality of battery cells is manufactured as a press product. A robust structure is applied to be supported by a box shape by a combination of various parts such as (30) and support bar (40).

At this time, the base plate 20 installed on the bottom, the end plate 30 installed on the side, and the support bar 40 installed on the top are made of a single steel material made of a pressed product.

In particular, since the end plate 30 made of steel is heavy with a weight of 342 g and has a short creepage distance of 46.8 mm, it provides a cause for insulation destruction in the lateral direction, and the support bar 40 made of steel has a creepage Since the distance is installed as short as 73.2 mm, it provides a cause of destroying insulation in the vertical direction.

In this way, when the base plate 20, the end plate 30, and the support bar 40, which provide the cause of insulation breakdown, are left in a high temperature and high humidity environment around the battery cell for a long time, a current path other than the cable is generated from the battery cell. , Since the occurrence of such a current path is a part that does not satisfy the performance of the battery pack 1, there is a problem that not only rework for safety reasons, but also modification of the mold in some cases has occurred.

Therefore, insulation performance is a criterion for the clearance and creepage distance for each battery pack nominal voltage, and the longer the clearance and creepage distance, the better the insulation performance. and a reinforced insulation structure has been required as an important factor.

Domestic Patent No. 10-1769820 (2017.08.14)

An object of the present invention is proposed to solve the problem in view of the existing problems, and improves durability and insulation by improving the creepage distance by changing the material of the end plate, support bar, and base plate by plastic or a combination of plastic and steel. It is to provide a structure for reinforcing the insulation performance of a battery pack that can simultaneously enhance the.

In order to solve the above technical problem, a structure for reinforcing insulation performance of a battery pack according to an embodiment of the present invention is a battery supporting several battery module assemblies in a box shape by a combination of several parts including an end plate, a support bar, and a base plate. In the pack, the end plate is installed on the side surface of the plurality of battery module assemblies and is made of a synthetic resin material to increase creepage distance while simultaneously enhancing robustness and insulation, and the support bar is formed on the upper surface of the plurality of battery module assemblies. It is made of a combination of a first support member made of metal and a second support member made of synthetic resin to increase the creepage distance while simultaneously enhancing robustness and insulation.
The end plate is characterized by being hot stacked or heterogeneously injected using a heterogeneous synthetic resin material having high tensile strength at the edges and low tensile strength at the center to increase the surface pressure reaction speed.

As another embodiment, the end plate of the present invention is characterized in that it is plastic.

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As another embodiment, the end plate of the present invention is characterized in that the creepage distance between the battery cell of the battery module assembly and the end plate is 102.7 mm or more.

As another embodiment, the support bar of the present invention is characterized in that the creepage distance between the battery cells of the battery module assembly and the support bar is 101.3 mm or more.

As another embodiment, the first support member of the present invention is press-processed from steel, and the second support member is injection-molded from plastic.

As another embodiment, the first support member and the second support member of the present invention are coupled by insert injection molding or bolts.

On the other hand, in order to solve the above technical problem, a structure for reinforcing insulation performance of a battery pack according to another embodiment of the present invention is a box shape by a combination of several parts consisting of an end plate, a support bar, and a base plate. In the supporting battery pack, the end plate is installed on a side surface of the plurality of battery module assemblies and is made of a synthetic resin material to increase creepage distance while simultaneously enhancing robustness and insulation, and the base plate is made of a synthetic resin material. It is installed on the lower surface of the assembly and is composed of a combination of a first base member made of metal and a second base member made of synthetic resin to increase creepage distance while simultaneously enhancing robustness and insulation. The base plate is connected to the sensing connector of the battery module assembly. It is characterized in that the creepage distance between the base plates is 52.2 mm or more.

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As another embodiment, the first base member of the present invention is press-worked with steel, and the second base member is injection-molded with plastic.

As another embodiment, the first base member and the second base member of the present invention are coupled by insert injection molding or bolts.

As another embodiment, the second base member of the present invention is characterized in that it is made of a thin plate and coupled to the upper surface of the first base member by hot melt adhesion.

The insulation performance reinforcement structure of the battery pack of the present invention is reinforced to simultaneously satisfy the robustness structure and insulation structure of the end plate, a pair of left and right support bars, and the base plate for supporting a plurality of battery module assemblies in a box shape. By improving the clearance distance and creepage distance for each nominal voltage, insulation breakdown in the lateral and vertical directions can be prevented in advance, and at the same time, insulation breakdown along the sensing connector wire path when moisture is condensed can be prevented in advance. there is.

1 is a perspective view showing a battery pack to which a conventional end plate and a support bar are applied;
2 is a perspective view showing a battery pack to which an end plate and a support bar according to the present invention are applied;
3 is a perspective view showing a battery pack to which a base plate according to the present invention is applied;
4 and 5 are detailed views showing a base plate structure according to the present invention.

In order to fully understand the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the examples described in detail below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shapes of elements in the drawings may be exaggerated to emphasize a clearer description. It should be noted that in each drawing, the same configuration may be indicated by the same reference numerals. Detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention are omitted.

Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 2 to 5 in the accompanying drawings.

2 is a perspective view showing a battery pack to which an end plate and a support bar according to the present invention are applied, FIG. 3 is a perspective view showing a battery pack to which a base plate according to the present invention is applied, and FIGS. 4 and 5 are according to the present invention It is a detailed view showing the base plate structure.

As shown in the drawing, the insulation performance enhancing structure of the battery pack 100 of the present invention is installed on the side of several battery module assemblies 110 to simultaneously enhance robustness and insulation while increasing the creepage distance. A pair of left and right support bars 130 made of a combination of a metal material and a synthetic resin material installed on the upper surface of the end plate 120 and the plurality of battery module assemblies 110 to simultaneously enhance robustness and insulation while increasing creepage distance, A base plate 140 made of a combination of a metal material and a synthetic resin material is installed on the lower surface of the plurality of battery module assemblies 110 to increase creepage distance while simultaneously enhancing robustness and insulation.

That is, the end plate 120 is made of any one selected from plastic, PA66 (POLYAMIDE 66) series, and PP (POLYPROPYLENE) series, and the creepage distance between the battery cell of the battery module assembly 110 and the end plate 120 is It is preferable to configure with 102.7 mm or more.

In addition, the end plate 120 is hot stacked using heterogeneous synthetic resin materials having high tensile strength at the edges and low tensile strength at the center so as to increase the surface pressure reaction speed when the overcharge switch (not shown) is operated. Alternatively, it may be configured to be integrated by heterogeneous injection.

In addition, it is preferable that the pair of left and right support bars 130 have a creepage distance between the battery cells of the battery module assembly 110 and the support bar 130 of 101.3 mm or more.

In addition, the left and right pair of support bars 130 are connected to the left and right sides of the upper surfaces of the plurality of battery module assemblies 110, respectively, to increase robustness. A first support member 132 press-processed from steel, It is composed of a second support member 134 injection-molded with plastic to be coupled to the upper surface of the first support member 132 to increase insulation.

At this time, the first support member 132 and the second support member 134 are preferably configured to be coupled by insert injection molding or bolts.

Meanwhile, the base plate 140 preferably has a creepage distance between the sensing connector 112 of the battery module assembly 110 and the base plate 140 of 52.2 mm or more.

In addition, the base plate 140 is connected to the lower surfaces of the plurality of battery module assemblies 110 and includes a first base member 142 pressed with steel to increase robustness, and the first base member 142. It is composed of a second base member 144 injection-molded with plastic to be coupled to the upper surface of the base member 144 to increase insulation.

At this time, the first base member 142 and the second base member 144 are preferably configured to be coupled by insert injection molding or bolts.

The second base member 144 may be made of a thin plate and may be coupled to the upper surface of the first base member 142 by hot melt adhesion.

The insulation performance reinforcement structure of the battery pack of the present invention configured as described above is composed of an end plate 120 supporting a plurality of battery module assemblies 110 in a box shape, a pair of left and right support bars 130, and a base plate 140. By reinforcing the robustness structure and the insulation structure to simultaneously satisfy, it is possible to prevent insulation breakdown in the lateral and vertical directions in advance by improving the clearance and creepage distance for each nominal voltage of the battery pack 100 in advance, and at the same time, sensing when moisture is condensed Insulation breakdown along the wire path of the connector 112 can be prevented in advance.

That is, when the end plate 120 is applied as an injection-molded plastic, it is lighter than the conventional end plate pressed with steel, and can be strengthened to simultaneously satisfy the strength and insulation properties as well as the weight reduction effect, and the creepage distance is increased by 219% to 102.7 Since it can be increased to more than mm, there is an advantage in that insulation breakdown in the lateral direction can be prevented in advance and assembling ability can be improved so that the counterpart does not rotate.

In addition, when a pair of left and right support bars 130 are applied as a combination of a first support member 132 made of steel and a second support member 134 made of plastic, a conventional support bar made of a single steel material is pressed. Since the creepage distance can be increased to more than 101.3mm, which is an increase of 138%, while it can be reinforced to satisfy more robustness and insulation at the same time, not only can insulation breakdown in the vertical direction be prevented in advance, but also it is easy to be compatible with peripheral parts and at the same time It has the advantage of improving confidentiality and assemblability.

In addition, when the base plate 140 is applied as a combination of the first base member 142 made of steel and the second base member 144 made of plastic, it has more robustness and insulation than the conventional base plate pressed from a single steel material. Since the creepage distance between the sensing connector 112 of the plurality of battery module assemblies 110 and the base plate 140 can be increased to 52.2 mm or more while being able to simultaneously satisfy It has the advantage of being able to prevent insulation breakdown along the path in advance.

On the other hand, the present invention is not limited to the above-described embodiments, but can be practiced with modifications and variations within the scope of the present invention, and the technical idea to which such modifications and variations are applied also falls within the scope of the following claims. Must see.

100: battery pack 110: battery module assembly
120: end plate 130: support bar
132: first support member 134: second support member
140: base plate 142: first base member
144: second base member

Claims (12)

In a battery pack supporting a plurality of battery module assemblies in a box shape by a combination of several parts consisting of an end plate, a support bar, and a base plate,
The end plate is installed on the side surface of the plurality of battery module assemblies and is made of a synthetic resin material to increase creepage distance while simultaneously enhancing robustness and insulation.
The support bar is installed on the upper surface of the plurality of battery module assemblies and is composed of a combination of a first support member made of metal and a second support member made of synthetic resin to increase creepage distance while simultaneously enhancing robustness and insulation,
The end plate is a battery pack insulation performance reinforcement structure, characterized in that the edges are hot stacked or heterogeneous injection using a heterogeneous synthetic resin material having a high tensile strength and a center having a low tensile strength to increase the surface pressure reaction speed. The method of claim 1,
The insulation performance reinforcement structure of the battery pack, characterized in that the end plate is plastic. delete The method of claim 1,
The end plate is a structure for reinforcing insulation performance of a battery pack, characterized in that the creepage distance between the battery cell and the end plate of the battery module assembly is 102.7 mm or more. The method of claim 1,
The support bar is a structure for reinforcing insulation performance of a battery pack, characterized in that the creepage distance between the battery cell and the support bar of the battery module assembly is 101.3 mm or more. The method of claim 1,
The first support member is pressed from steel,
The second support member is a structure for reinforcing insulation performance of a battery pack, characterized in that injection molded plastic. The method of claim 1,
The insulation performance reinforcement structure of the battery pack, characterized in that the first support member and the second support member are coupled by insert injection or bolts. In a battery pack supporting a plurality of battery module assemblies in a box shape by a combination of several parts consisting of an end plate, a support bar, and a base plate,
The end plate is installed on the side surface of the plurality of battery module assemblies and is made of a synthetic resin material to increase creepage distance while simultaneously enhancing robustness and insulation.
The base plate is installed on the lower surface of the plurality of battery module assemblies and is made of a combination of a first base member made of metal and a second base member made of synthetic resin to increase creepage distance while simultaneously enhancing robustness and insulation.
The base plate has an insulating performance reinforcement structure of a battery pack, characterized in that the creepage distance between the sensing connector of the battery module assembly and the base plate is 52.2 mm or more. delete The method of claim 8,
The first base member is pressed from steel,
The second base member is an insulating performance reinforcement structure of a battery pack, characterized in that injection molded plastic. The method of claim 8,
The insulation performance reinforcement structure of the battery pack, characterized in that the first base member and the second base member are coupled by insert injection or bolts. The method of claim 8,
The structure for reinforcing insulation performance of a battery pack, characterized in that the second base member is made of a thin plate and coupled to the upper surface of the first base member by hot melt adhesion.

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