DE102021109282B4 - Battery module for a motor vehicle - Google Patents

Abstract

Battery module (100) for a motor vehicle, comprising a cell stack (102) with a plurality of battery cells, a housing (101) with an insertion opening and a seal (103; 104), the battery cells being connected to one another, the cell stack (102) inside the Housing (101) is arranged, wherein the seal (103; 104) is arranged between the cell stack (102) and the housing (101) and surrounds and seals an area (107), the seal (103; 104) having a first sealing element (103) and a second sealing element (104), characterized in that the first sealing element (103) has a lower bulk modulus than the second sealing element (104), wherein the first sealing element (103) is attached to the cell stack (102), wherein the second sealing member (104) is fixed to the first sealing member (103) with the first sealing member (103) being compressed such that an elastic restoring force of the first sealing member (103) presses the second sealing member (104) against the housing (101).

Description

The present invention relates to a battery module for a motor vehicle according to the preamble of claim 1.

Battery modules with a cell stack with a plurality of battery cells are known from the prior art, in which the cell stack is pushed into a housing during production. To cool the battery cells, the cell stack is connected to the housing via a thermally conductive medium.

Out of DE 10 2014 226 249 A1 a battery module with several battery cells in one housing is known. The battery cells are thermally connected to the housing via a heat-conducting paste.

In contrast, the object of the present invention is to reduce the amount of heat-conducting medium required.

This object is achieved by a battery module according to claim 1, a motor vehicle according to claim 9 and a method according to claim 10. Embodiments of the invention are given in the dependent claims.

The battery module includes a cell stack with multiple battery cells, a housing with an insertion opening, and a seal. The battery cells are connected to each other. The cell stack is arranged inside the housing. The seal is arranged between the cell stack and the housing. The gasket surrounds and seals an area. In the context of this description, this means in particular that a heat-conducting medium arranged in the area, for example, cannot escape from the area. It is also possible for the gasket to surround and seal multiple areas. The areas can also be separated from one another by the seal.

The seal includes first and second sealing members. The first sealing element has a lower bulk modulus than the second sealing element. For example, the first sealing element can consist of an elastically deformable plastic. The first sealing element is attached to the cell stack, in particular directly. The second sealing element is attached to the first sealing element, for example with an adhesive connection. The first sealing member is compressed so that an elastic restoring force of the first sealing member presses the second sealing member against the housing. For example, a partial section of the second sealing element lying against the housing can form a closed line. The first sealing element can be designed as cut foam, for example.

Because the area is sealed off by the seal, the amount of heat-conducting medium required for the battery module can be reduced by the heat-conducting medium being arranged exclusively in the area.

The configuration of the seal with the first and the second sealing element is particularly advantageous in the manufacture of the battery module. It enables the cell stack to be inserted with the seal attached. When pushed in, the first sealing element is then elastically compressed. The second sealing element slides along the housing, which is compressed little or not at all, thus enabling insertion with little force and without damaging the seal. This applies in particular if the partial section of the second sealing element which rests against the housing forms a closed line. In this case, when the cell stack is pushed into the housing, the seal is pushed in at least partially along the sealing line.

According to one embodiment of the invention, the battery module can include a thermally conductive medium. The thermally conductive medium can have a higher thermal conductivity than air. In particular, the thermal conductivity of the thermally conductive medium can be greater than 3.5 W/(m*K). The thermally conductive medium can be in the form of thermally conductive paste, for example.

According to one embodiment of the invention, the second sealing element can be plate-shaped. In the context of this description, this means in particular that the second sealing element has a length and a width that is more than twice, for example more than five times, the thickness of the second sealing element. Here, the thickness is the direction in which the first sealing member is spaced apart from the housing.

For example, the second sealing element can be in the form of a metal sheet that is in particular cut or stamped. However, the configuration of the second sealing element is preferably made of a plastic that is harder than the material of the first sealing element.

According to one embodiment of the invention, the area can be limited by the seal, the cell stack and the housing. In this way, the thermally conductive medium comes into direct contact with the housing and the cell stack.

According to an embodiment of the invention, the second sealing element may have a first portion which delimits the area and which is free from direct contact with the first sealing element. This first section can be pressed against the housing by the thermally conductive medium, so that the sealing effect is improved.

According to an embodiment of the invention, the second sealing element can have a second section which projects away from the first sealing element in a direction pointing away from the insertion opening and from the region. The second portion may be at least partially spaced from the housing. The first sealing element can be arranged, for example, between the second section and the insertion opening. In particular, it is possible that an end of the second section that is furthest away from the insertion opening is spaced furthest away from the housing.

This second section is advantageous when the cell stack with the seal attached is pushed into the housing. For example, the second section can also be referred to as an insertion bevel. Due to the spacing of the second section from the housing, the probability of the end of the second sealing element facing the insertion opening before being pushed in contacting an outer edge of the housing is reduced. Such contact could damage the seal and/or increase the insertion force required.

According to one embodiment of the invention, the first sealing element can be attached to the cell stack in a materially bonded manner, in particular with an adhesive bond. For example, the first sealing element can have been applied to the cell stack as a paste, the paste then having dried and having formed an integral connection with the cell stack.

The motor vehicle according to claim 9 comprises a battery module according to an embodiment of the invention.

The method according to claim 10 is used to produce a battery module according to an embodiment of the invention. The housing, cell stack and gasket are provided. The first sealing element is attached to the cell stack and the second sealing element to the first sealing element.

The first sealing element is compressed. The cell stack is pushed into the housing with the seal while the first sealing element is compressed. The compression of the first sealing element can take place, for example, as a result of being pushed in.

Then the thermally conductive medium is filled into the area.

• 1 eine schematische Schnittansicht eines Batteriemoduls nach einer Ausführungsform der Erfindung; und
• 2 eine schematische Schnittansicht orthogonal zur Schnittebene aus 1 des Batteriemoduls aus 1.

Further features and advantages of the present invention become clear from the following description of preferred exemplary embodiments with reference to the attached figures. The same reference symbols are used for the same or similar components and for components with the same or similar functions. while showing

• 1 a schematic sectional view of a battery module according to an embodiment of the invention; and
• 2 a schematic sectional view orthogonal to the sectional plane 1 of the battery module 1 .

The battery module 100 includes a housing 101, a cell stack 102 with a plurality of battery cells, a first sealing element 103 and a second sealing element 104. The first sealing element 103 and the second sealing element 104 form a seal which surrounds areas 107 and seals each. The areas 107 are each delimited by the cell stack 102 , the seal and the housing 101 . The areas 107 are separated from one another.

The first sealing member 103 is compressed. An elastic restoring force of the first sealing element 103 therefore presses the second sealing element 104 along a sealing line against the housing 101. The second sealing element 104 is plate-shaped and has a lower compression modulus than the first sealing element 103.

A thermally conductive paste is arranged in the areas 107 so that heat generated in the cell stack 102 is conducted particularly well to the housing 101 . The seal prevents the thermally conductive paste from escaping from areas 107 . This has the advantage that relatively little thermal paste is required.

During production of the battery module 100, the cell stack 102 with the seal attached to the cell stack 102 is pushed into an insertion opening in the housing 101. The insertion direction is in 1 shown with an arrow. During this push-in movement, the seal is at least partially displaced along the sealing line relative to the housing 101 and at the same time presses against the housing 101. It is therefore during the push-in movement It is particularly advantageous that the second sealing element 104 has a lower bulk modulus than the first sealing element 103 and is plate-shaped. In this way, a relatively small force is required during the insertion process. In addition, the risk of damage to the seal is reduced.

The second sealing element 104 has a first section 106 which is free from direct contact with the first sealing element 103 and is pressed against the housing 101 by the thermally conductive medium. This increases the tightness of the seal.

In addition, the second sealing element 104 has a second section 105 which projects away from the first sealing element 103 in the direction of insertion in the direction of an end of the housing 101 which is arranged opposite the insertion opening. At least part of this second section 105 is spaced from the housing 101 . In this case, the end of the second section 105 which is furthest away from the first sealing element 103 is spaced furthest from the housing 101 . This second section 105 can also be referred to as an insertion bevel since it simplifies the insertion of the cell stack 102 with the seal into the housing 101 .

When the cell stack 102 with the seal is pushed into the housing 101, the second section 105 reduces the probability of the foremost end of the seal coming into contact with the border of the push-in opening. Less precision is therefore required to insert the cell stack 102 with the seal into the housing 101 without folding the second sealing element 104 over in the process.

Claims (10)

Battery module (100) for a motor vehicle, comprising a cell stack (102) with a plurality of battery cells, a housing (101) with an insertion opening and a seal (103; 104), the battery cells being connected to one another, the cell stack (102) inside the Housing (101) is arranged, wherein the seal (103; 104) is arranged between the cell stack (102) and the housing (101) and surrounds and seals an area (107), the seal (103; 104) having a first sealing element (103) and a second sealing element (104), characterized in that the first sealing element (103) has a lower bulk modulus than the second sealing element (104), wherein the first sealing element (103) is attached to the cell stack (102), wherein the second sealing member (104) is fixed to the first sealing member (103) with the first sealing member (103) being compressed such that an elastic restoring force of the first sealing member (103) presses the second sealing member (104) against the housing (101). Battery module (100) after claim 1 , characterized in that the battery module (100) comprises a thermally conductive medium, wherein the thermally conductive medium is arranged in the region (107). Battery module (100) according to one of the preceding claims, characterized in that the second sealing element (104) is plate-shaped. Battery module (100) according to one of the preceding claims, characterized in that the first sealing element (103) is thicker than the second sealing element (104). Battery module (100) according to one of the preceding claims, characterized in that the area (107) is delimited by the seal (103; 104), the cell stack (102) and the housing (101). Battery module (100) according to one of the preceding claims, characterized in that the second sealing element (104) has a first section (106) which delimits the region (107) and which is free of direct contact with the first sealing element (103). . Battery module (100) according to one of the preceding claims, characterized in that the second sealing element (104) has a second section (105) which protrudes away from the first sealing element (103) in a direction away from the insertion opening and from the region (107 ) points away, wherein the second portion (105) is at least partially spaced from the housing (101). Battery module (100) according to one of the preceding claims, characterized in that the first sealing element (103) is materially attached to the cell stack (102). Motor vehicle, comprising a battery module (100) according to one of Claims 1 until 8th . Method for producing a battery module (100) according to one of claims 2 until 7 , comprising the following steps: - providing the housing (101), the cell stack (102) and the seal (103; 104); - Attaching the first sealing element (103) to the cell stack (102); - Fastening the second sealing element (104) to the first sealing element (103); - Compression of the first sealing element (103); - Sliding the cell stack (102) with the seal (103; 104) into the housing (101), while the first sealing element (103) is compressed; - Filling of the thermally conductive medium in the area (107).

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