EP4193419A1

EP4193419A1 - Housing for a battery module for receiving battery cells

Info

Publication number: EP4193419A1
Application number: EP21755739.6A
Authority: EP
Inventors: Mario Meyer; Jochen Haussmann
Original assignee: Webasto SE
Current assignee: Webasto SE
Priority date: 2020-08-04
Filing date: 2021-08-04
Publication date: 2023-06-14
Also published as: KR20230042120A; DE202020104503U1; CN216750111U; US20230282909A1; WO2022029175A1

Abstract

The invention relates to a housing (12) for a battery module (10) for receiving battery cells (10a-n), comprising at least one end plate (12a), which comprises an inner profile element (122) and an outer profile element (120), the inner profile element (122) being shaped and designed such that, within a first deformation path (S1), it provides a first elastic bias on battery cells (10a-n) arranged in the housing (12), and the inner profile element (122) and the outer profile element (120) being shaped and designed such that the inner profile element (122), once the first deformation path (S1) has been passed through, cooperates with the outer profile element (120) to exert a second elastic bias on battery cells (10a-n) arranged in the housing (12).

Description

Housing for a battery module for accommodating battery cells

technical field

The present invention relates to a housing for a battery module for accommodating battery cells. The present invention also relates to a traction battery for a motor vehicle, preferably for a passenger vehicle, a bus and/or a truck.

State of the art

In the course of the electrification of vehicles, the optimization of the housing for the traction batteries installed in the vehicle is important. The aim is to achieve the highest possible capacity of the traction batteries in order to provide a long range.

Battery cells are usually combined in a housing for a battery module. A plurality of battery cells are usually mounted in the housing and electrically connected to one another.

Furthermore, it is desirable to improve the functionality, performance and service life of the battery cells installed in the battery module. It is known that when battery cells are charged/discharged, swelling forces arise that lead to so-called “cell breathing”. In other words, the battery cells can swell and swell during charging and discharging. In addition, there can be a steady increase in size over the lifetime of the cells.

This can be observed in particular with prismatic cells and pouch cells. In the case of prismatic cells, care must also be taken to ensure that the swelling forces do not destroy the thin shells of the cells. Therefore, prismatic cells are often built into rigid housings, which limit the swelling of the cells and therefore counteract rupture of the cell membranes.

Accordingly, it is known to provide battery cells in a housing, each with a rigid end plate to clamp the battery cells of the battery mod u Is. However, this has the disadvantage that the swelling forces of the cells are not optimally absorbed, since the battery cell cannot expand or "breathe". As a result, the forces in the battery cells of the battery module continue to increase over the service life. This can lead to an impairment of the functioning of the battery cells, in particular to a reduced capacity and/or service life.

Presentation of the invention

Proceeding from the known prior art, it is an object of the present invention to specify an improved solution for a housing for a battery module, which improves the performance and service life of the battery cells.

This object is achieved by a housing for a battery module for accommodating battery cells with the features of claim 1. Advantageous developments result from the dependent claims, the present description and the figures.

Accordingly, a housing for a battery module for accommodating battery cells is proposed, which comprises at least one end plate, which comprises an inner profile element and an outer profile element, the inner profile element being shaped and designed in such a way that, within a first deformation path, there is a first elastic prestress on im Provides battery cells arranged in the housing and wherein the inner profile element and the outer profile element are shaped and designed in such a way that the inner profile element interacts with the outer profile element to exert a second elastic prestress on battery cells arranged in the housing when the first deformation path is exceeded.

The two-part solution consisting of the inner profile element and the outer profile element of the at least one end plate allows the rigidity of the end plate and thus a desired prestress on the battery cells to be better adjusted depending on an expansion of the battery cells. Until a first deformation path is reached, the prestress on the battery cells is set accordingly via the inner profile element.

After the first deformation path has been exceeded, the inner and outer profile elements interact in such a way that the rigidity of the end plate is increased. Accordingly, a second bias voltage acts on the battery cells in this area. The bias voltage acting on the battery cells is thus adjusted in two stages in an optimized manner, at least as a result of the two-part solution. In other words, the battery cells while maintaining a expand preload. This improves the functioning of the battery cells and increases the service life of the battery module.

Furthermore, the two-part solution makes it possible to define an individual and desired ratio of prestress to the expansion of the battery cell, which can be tailored to the specific cell requirements installed.

The housing preferably has an end plate according to the invention on the two end sides, which are formed opposite one another. In other words, the battery cells are clamped between the two end plates. The battery cells are thus preloaded or clamped by the opposing end plates with a desired preload to ensure improved functionality.

The deformation path describes the expansion of the inner profile element and the outer profile element in a direction perpendicular to the plane defined by the end plate. During operation, the deformation path corresponds to the expansion of the battery cells in the longitudinal direction of the battery module in the direction of the end plates.

Bias refers to a bias that the end plate applies to the battery cells. In this case, the battery cells are preferably prestressed with a prestress FO in an initial state, i.e. in a state in which they are installed for the first time in the housing. In the further course, the swelling forces of the battery cells occurring during operation of the battery module, which cause the battery cells to expand in the longitudinal direction of the battery module, are absorbed by the end plate in such a way that the expansion of the battery cells is absorbed, but a desired prestress continues to act on the battery cells, whereby a critical for the performance of the battery cell bias voltage is not exceeded.

A desired course of prestressing depending on the expansion of the battery cells can be defined by the shape and configuration of the end plate, in particular of the inner profile element and the outer profile element. Due to the two-part design of the end plate, i.e. with an inner profile element and an outer profile element, different preload profiles can be configured. As a result, a housing for a wide variety of battery module configurations can be provided in a simple and flexible manner.

According to a preferred embodiment, the inner profile element and the outer profile element work together in such a way that when the first deformation path is exceeded, the inner one Profile element with which the outer profile element comes into contact essentially in the middle of the end plate and increases the rigidity of the end plate and applies the second prestress, which is increased compared to the first prestress, to the battery cells.

By "switching on" the outer profile element after the first deformation path has been exceeded, a different, in particular higher, stiffness of the end plate can be achieved. This connection causes the bias voltage on the battery cells to behave in a different ratio depending on the expansion. In other words, the prestress changes as a function of the expansion of the battery cells within the first deformation path along a first prestress/expansion curve. Once the first deformation path is exceeded, i.e. for a second deformation path, the prestress changes depending on the expansion of the battery cells within the second deformation path along a second prestress-expansion curve. This is advantageous because once the first deformation path is exceeded, the second prestress curve on the battery cells can be increased disproportionately compared to the first prestress curve depending on the expansion within the first deformation path, which improves or increases the functionality and service life of the battery module.

According to a further embodiment, the inner profile element has a first modulus of elasticity and the outer profile element has a second modulus of elasticity, the first modulus of elasticity of the inner profile element setting the desired prestress on the battery cells within the first deformation path. The first modulus of elasticity of the inner profile element in combination with the second modulus of elasticity determines the desired prestress on the battery cells within a second deformation path, i.e. outside the first deformation path.

By selecting the modulus of elasticity of the inner and the outer profile element, a wide variety of prestress profiles can be configured in relation to the expansion. In one example, the first modulus of elasticity may be less than the second modulus of elasticity. In another example, the first modulus of elasticity and the second modulus of elasticity may be equal.

Depending on the battery module configuration, the swelling forces can be different, so the expansion of the battery cells can be different. By means of the end plate proposed here, the inner profile element and the outer profile element can Their moduli of elasticity can be adjusted to meet the different requirements of battery module configurations.

According to one embodiment, the inner profile element and/or the outer profile element are adapted to different battery module configurations and/or desired prestresses by adjusting the moduli of elasticity of the inner profile element and the outer profile element, in particular by adjusting the wall thicknesses and/or the material and/or the size of the first Deformation path and/or shape adjustable.

In one example, the extent of the first deformation path can be adjusted via the shape of the inner profile element. In another example, the rigidity can be increased by changing the wall thickness and thus the course of the prestress can be adjusted depending on the expansion.

Such constructive possibilities for adapting the shape and design of the profile elements are advantageous because they allow quick, flexible and simple adaptation to different battery configurations with different requirements for prestressing or expansion.

According to one embodiment, the inner profile element and/or the outer profile element are roll-profiled sheet metal plates.

The shaping and configuration of the inner and outer profile element by roll profiling is advantageous since the inner and outer profile element can be designed quickly, flexibly, reliably and inexpensively in this way. In addition, large quantities can be provided in a cost-effective manner.

The outer profile element is preferably designed in one piece and particularly preferably in the form of a leaf spring. As a result, a first desired pre-voltage curve can be defined as a function of the expansion of the battery cells. The leaf spring is configured in such a way to apply a prestress to the battery cells in the initial state and to ensure expansion during the operation of the battery module, with the battery cells continuing to be clamped by the outer profile element. Within the second

Deformation path is thus defined by the leaf spring a second bias curve depending on the expansion of the battery cells. According to a further embodiment, the inner profile element is in one piece and is designed as an arcuate or U-shaped structure. This provides a stiffer profile element, ie with a higher modulus of elasticity. Within the first deformation path, a first course of prestressing is defined as a function of the expansion of the battery cells by switching on the inner profile element.

According to a further embodiment, an outer side of the inner profile element is partially connected to an inner side of the outer profile element, wherein the inner profile element partially encases the outer profile element, and wherein the outer side of the outer profile element is the outer side of the housing.

According to a further embodiment, the inner profile element and the outer profile element are connected to one another by an integral or non-positive connection. As a result, the at least one end plate can be formed from the inner profile element and the outer profile element without further fastening elements.

According to a further embodiment, the housing is essentially adapted to the installation space for accommodating a large number of battery cells.

According to a further embodiment, the housing has two substantially perpendicular side walls with respect to the end plates.

The end plates can be connected to the side walls using a non-positive connection, e.g. snap & click or screw connections. This has the advantage that the housing can be assembled according to a modular principle depending on the battery module configuration. For example, depending on the number and size of the battery cells used in a battery module, housings with different lengths of side walls with different widths of end plates can be formed. Different housing interior volumes can thus be assembled quickly and easily.

In a further example, the housing may have a substantially planar underside, the plane of the underside being perpendicular to the plane of the side walls and perpendicular to the plane of the end plate, thus forming the housing interior downwards.

In a further example, the housing can have a substantially flat upper side, the plane of the upper side being perpendicular to the plane of the side walls and perpendicular to the plane of the end plate and thus covering the inner space of the housing upwards. According to a further aspect, a traction battery for a motor vehicle is proposed, comprising at least one battery module with the housing described above.

The housing that can be used flexibly as described above allows traction batteries with different specifications and for different purposes to be designed in a flexible and efficient manner.

According to one embodiment, the at least one battery module is connected to a vehicle structure via the housing.

In one example, attachment areas are integrated into the housing to attach the battery module to the vehicle structure. This means that battery modules can also be provided in a preassembled form, so that the traction battery can be constructed efficiently and in a manner equalized in terms of location and time. Furthermore, efficient and reliable assembly of a traction battery from battery modules can be achieved as a result.

Brief description of the figures

Preferred further embodiments of the invention are explained in more detail by the following description of the figures. show:

FIG. 1 shows a schematic view of a housing for a battery module for accommodating battery cells which are clamped between two opposite end plates of a housing according to an exemplary embodiment,

FIG. 2 shows a schematic sectional view of an end plate according to one embodiment;

Figure 3 is a schematic perspective view of the end plate of Figure 2 according to a

embodiment; and

FIG. 4 shows an exemplary exponential voltage curve as a function of the expansion of the battery cells according to one embodiment.

Detailed description of preferred exemplary embodiments

Preferred exemplary embodiments are described below with reference to the figures. The same, similar or equivalent elements are included in the different figures Identical reference numerals are provided, and a repeated description of these elements is partially dispensed with in order to avoid redundancies.

A housing 12 for a battery module 10 for accommodating battery cells 10a-n is shown schematically in FIG. The plurality of battery cells 10a-n can be arranged side by side within the housing 12 along a longitudinal direction L of the housing.

The battery cells 10a-n can accordingly preferably be prismatic cells or pouch cells, which enable the battery module 10 to be constructed in a particularly space-saving and therefore efficient manner.

Prismatic cells usually have a rigid, cubic housing, whereas pouch cells are usually encased in a flexible metal foil.

As shown here by way of example, the housing 12 comprises at least one end plate, here two opposite end plates 12a, 12b, between which the battery cells 10a-n are arranged.

In the exemplary embodiment shown, each of the end plates 12a, 12b comprises an inner profile element 122 and an outer profile element 120 (see FIG. 2). The end plates 12a, 12b are configured such that they counteract an expansion of the battery cells 10a-n perpendicular to the plane formed by the end plates 12a, 12b, i.e. in the longitudinal direction of the housing L (see arrows along the longitudinal direction L).

The housing 12 is preferably essentially adapted to the installation space for accommodating a multiplicity of battery cells 10a-n. The housing 12 has at least two essentially perpendicular side walls 12c, 12d with respect to the end plates 12a, 12b.

As shown in the sectional view of an end plate 12a in Figure 2, the inner profile element 122 is shaped and designed in such a way that within a first deformation path S1 there is a first elastic prestress (see arrows) on battery cells 10a-n arranged in the housing 12, here for example on the battery cell 10a arranged on the end plate 12a.

As shown by way of example, an inside of the outer profile element 120 is in press contact with an outside of a battery cell via the inner profile element 122, ie in an initial state the outer profile element 120 is arranged in such a way that a prestress directly and/or indirectly on the battery cells 10a-n, here directly via the battery cell 10a.

The inner profile element 122 and the outer profile element 120 are shaped and designed such that the inner profile element 122 interacts with the outer profile element 120 to exert a second elastic prestress on battery cells 10a-n arranged in the housing 12 when the first deformation path S1 is exceeded.

The two-part solution consisting of the inner profile element 122 and the outer profile element 120 of the at least one end plate 12a, 12b allows the rigidity of the end plate and thus a desired preload on the battery cells to be better adjusted depending on a desired expansion of the battery cells. The elastic prestressing is controlled via the inner profile element 122 until a first deformation path S1 is reached (as indicated by a dashed area of the inner profile element). After the first deformation path S1 has been exceeded, the inner profile element 122 comes into contact with the outer profile element 120 essentially in the center thereof, so that over the further deformation path the inner profile element 122 interacts with the outer profile element 120 and accordingly provides a combined prestress. The prestress exerted on the battery cells 10a-n within the first deformation path S1 can thus have a lower value than the prestress which is exerted on the battery cells 10a-n when the first deformation path S1 is exceeded.

In other words, the inner profile element 122 and the outer profile element 120 interact in such a way that the rigidity is increased after the first deformation path S1 has been exceeded. The expansion of the battery cells and the bias voltage thus acting on the battery cells is thus controlled in two stages in an optimized manner, at least by the two-part solution. In other words, the battery cells can expand while maintaining a bias voltage. This improves the functioning of the battery cells and increases the service life of the battery module.

In other words, the battery cells can expand, with a desired bias voltage always acting on the battery cells in order to improve the functioning of the battery cells and increase their service life.

As shown in Figure 2, the inner profile element 122 and the outer profile element 120 can interact in such a way that when the first deformation path S1 is exceeded (as well as through the dashed area of the inner profile element in Figure 2) the inner profile element 122 comes into contact with the outer profile element 120 essentially in the middle of the end plate 12a.

After contacting, the profile elements 120, 122 cooperate and thus increase the rigidity of the end plate 12a. As a result, a second bias voltage that is higher than the first bias voltage is applied to the battery cells 10a. At the same time, the expansion along a second deformation path S2 (as also indicated by the dashed area of the outer profile element 120) is determined via the combination of the inner profile element 122 and the outer profile element 120.

Inner profile element 122 preferably has a first modulus of elasticity and outer profile element 120 has a second modulus of elasticity, with the first modulus of elasticity of inner profile element 122 setting the desired prestress on battery cells 10a-10n within the first deformation path S1, and with the first modulus of elasticity of the outer Profile element 120 in combination with the second modulus of elasticity of the inner profile element 122 sets the desired prestress on the battery cells 10a-10n within the second deformation path S2.

In an exemplary embodiment shown in FIG. 2, the outer profile element 120 is configured in one piece and more or less in the form of a leaf spring. In this case, the outer profile element 122 has two elevations which are arranged mirror-symmetrically with respect to a center line M of the end plate 12a.

Furthermore, by way of example, the outer profile element 120 is flanged on the outer sides. The flanging creates a stiffer construction.

Furthermore, as in an exemplary embodiment shown in FIG. 2, the inner profile element 122 can be configured in one piece and as an arcuate or U-shaped structure. This provides a structure which is stiffer than the outer profile element 120, i.e. a structure with a higher modulus of elasticity. As a result, within the first deformation path, a first course of prestressing is defined as a function of the expansion of the battery cells by the activation of the inner profile element 122 .

FIG. 3 shows the at least one end plate 12a and the inner profile element 122 and the outer profile element 120 in a partially sectioned perspective view. Those are the inside Profile element 122 and the outer profile element 120 are shown as roll-profiled sheet metal plates, which extend along a height direction H and a transverse direction Q of the end plate 12, which essentially corresponds to the height of the battery cells 10a-n, around the battery cells 10a-n in the longitudinal direction L of the housing or the battery module 10 clamp.

The inner profile element 122 and/or the outer profile element 120 are adapted to different battery module configurations and/or desired prestresses by adjusting the moduli of elasticity of the inner profile element 122 and the outer profile element 120, in particular by adjusting the wall thicknesses and/or the material and/or the size the first deformation path S1, S2 and / or the shape adjustable.

As shown by way of example in Figures 2 and 3, an outside of inner profile element 122 is partially connected to an inside of outer profile element 120, with inner profile element 122 encasing outer profile element 120, and with the outside of outer profile element 120 covering the outside of housing 12 is or trains.

The inner profile element 122 and the outer profile element 120 are preferably connected to one another by an integral or non-positive connection.

The proposed housing 12 for accommodating a large number of battery cells 10a-n forms the battery module 10.

FIG. 4 shows, by way of example, the course of the prestress F over the deformation path S and thus also over the deformation or the expansion of the battery cells.

In the initial state, the battery cells can be clamped with a bias voltage F0. The battery cells expand during operation. The inner profile element 122 ensures an expansion of the battery cells with a first prestress within a first deformation path S1 of the battery cells. In this case, the prestress exerted on the battery cells is controlled only via the inner profile element 122 within the first deformation path S1.

Upon reaching the end of the first deformation path S1, a force F1 that is greater than F0 is exerted on the battery cells by the inner profile element 122. After the first deformation path S1 has been exceeded, the course of the prestressing F is determined by the interaction of the inner profile element 122 and the outer profile element 120. For example, the inner profile element 122 and the outer profile element 120 together bring about a prestress F2 that is greater than F1 on the battery cells. Beyond S2, the prestress exerted by the inner and outer profile element is so great that further expansion of the battery cells is hardly possible.

By “switching on” the outer profile element 120 after the first deformation path S1 has been exceeded, a different, in particular higher, rigidity of the end plate 12a can be achieved.

This connection causes the bias voltage on the battery cells to behave in a different ratio depending on the expansion. In other words, the prestress changes as a function of the expansion of the battery cells within the first deformation path along a first prestress (F)-expansion (S) curve.

Once the first deformation path S1 is exceeded, i.e. for a second deformation path S2, the preload changes depending on the expansion of the battery cells within the second deformation path S2 along a second preload-expansion curve. This is advantageous because once the first deformation path S1 has been exceeded, the second prestress curve (F1 to F2) on the battery cells can be increased disproportionately compared to the first prestress curve (F0-F1) depending on the expansion within the first deformation path, which affects the functionality and improves or increases the service life of the battery module.

As shown in FIG. 4, the inner profile element 122 and the outer profile element 120 can be shaped and designed in such a way that the prestress F on the battery cells in relation to the deformation path S or the expansion runs along a non-linear, preferably exponential, function. Due to the two-part design of the end plate, i.e. with an inner profile element 122 and an outer profile element 120, other preload profiles can alternatively be configured.

According to an aspect that is not shown, a traction battery for a motor vehicle can have at least one battery module with such a housing 12 for accommodating battery cells.

As far as applicable, all individual features that are presented in the exemplary embodiments can be combined with one another and/or exchanged without departing from the scope of the invention. Reference character list

10 battery module

10a-n battery cells

12 housing 12a, 12b end plate

12c, 12d side wall

120 outer profile element

122 inner profile element

S1 first deformation path S2 second deformation path

F preload

Claims

Expectations

1. Housing (12) for a battery module (10) for accommodating battery cells (10a-n), comprising at least one end plate (12a) which comprises an inner profile element (122) and an outer profile element (120), the inner profile element (122). ) are shaped and designed in such a way that the inner profile element (122) interacts with the outer profile element (120) to exert a second elastic prestress on battery cells (10a-n) arranged in the housing (12) when the first deformation path (S1) is exceeded.

2. Housing (12) according to claim 1, characterized in that the inner profile element (122) and the outer profile element (120) interact in such a way that when the first deformation path (S1) is exceeded, the inner profile element (122) with the outer profile element ( 120) makes contact.

3. Housing (12) according to claim 1 or 2, characterized in that the inner profile element (122) comes into contact with the outer profile element (120) substantially in the middle thereof.

4. Housing (12) according to one of the preceding claims, characterized in that the inner profile element (122) has a first modulus of elasticity and the outer profile element (120) has a second modulus of elasticity, the first modulus of elasticity of the inner profile element having the first elastic prestress sets the battery cells (10a-10n) within the first deformation path (S1) and wherein the first modulus of elasticity of the inner profile element (122) in combination with the second modulus of elasticity exerts a second elastic prestress on the battery cells (10a-10n) within a second deformation path (S2 ) sets.

5. Housing (12) according to one of the preceding claims, characterized in that the inner profile element (122) and/or the outer profile element (120) can be adapted to different battery module configurations and/or desired prestresses by adapting the moduli of elasticity of the inner profile element (122) and of the outer Profile elements (120), in particular by adjusting the wall thickness and / or the material and / or the shape are adjusted. Housing (12) according to one of the preceding claims, characterized in that the inner profile element (122) and/or the outer profile element (120) are roll-profiled sheet metal plates. Housing (12) according to one of the preceding claims, characterized in that the outer profile element (120) is in one piece and is preferably designed as a leaf spring. Housing (12) according to any of the preceding claims, characterized in that the inner profile element (122) is in one piece and is preferably designed as an arcuate or U-shaped structure. Housing (12) according to one of the preceding claims, characterized in that an inner side of the outer profile element (120) is connected in sections to an outer side of the inner profile element (122), the inner profile element (122) preferring the outer profile element (120). partially sheathed. Housing (12) according to any one of the preceding claims, characterized in that the outside of the outer profile element (120) is the outside of the housing (12). Housing (12) according to one of the preceding claims, characterized in that the inner profile element (120) and the outer profile element (122) are connected to one another in sections by an integral or non-positive connection. Housing (12) according to one of the preceding claims, characterized in that at least two opposite end plates (12a, 12b) each having an inner profile element (120) and an outer profile element (122) are provided, the end plates (12a) having an elastic Apply bias to interposed battery cells (10a-10n). Housing (12) according to Claim 12, characterized in that the housing (12) has two substantially perpendicular side walls (12c, 12d) with respect to the end plates (12a, 12b). 16 battery module (10) with a housing (12) according to any one of the preceding claims and at least one with the inner profile element (122) in operative connection battery cell (10a-10n), preferably a prismatic cell or a pouch cell.