WO2023056998A1 - Connection device, battery module, and method for producing a battery module - Google Patents

Abstract

A connection device (7) for at least two battery cells (2) for forming a battery module (1) is disclosed. The connection device (7) comprises at least one connection plate (6), for electrically connecting the at least two battery cells (2), and at least one guide device (24), wherein the at least one connection plate (6) is movably assigned at least intermittently to the guide device (24). Also described are a battery module (1), comprising a battery cell stack (3), which is formed of at least two battery cells (2), and a connection device (7), and also a method for producing a battery module (1).

Description

Connection device, battery module and method for manufacturing a battery module

The present invention relates to a connecting device, a battery module and a method for producing a battery module having the features of the independent claims.

State of the art

It is known from the prior art to connect a plurality of battery cells to form a battery module.

Utility model DE 20 2021 004059 U1 describes a cell connection system for a vehicle battery. The cell connection system creates an electrically conductive connection between a large number of battery cells and comprises a number of cell connection elements, with at least one cell connection element being designed for the electrical connection of at least two battery cells.

The published application WO 2019/214824 A1 describes a battery module that consists of several secondary (battery) cells, the interconnection of which can be flexibly configured between the module connections by means of an internal configuration circuit, if required, so that module voltages are available at the module connections for and/or during a Charging or discharging can be set. The battery modules are structurally almost standardized and can be mass-produced in any number without any problems. A traction battery can be constructed from multiple battery modules, with the multiple battery modules being connected in series in a specific embodiment.

The published application DE 10 2016 104 176 A1 discloses a module for a traction battery and a corresponding traction battery. An advantage of the arrangement described here is the possibility of tapping the voltage of the individual cells via so-called connector plates.

The patent specification DE 102012 202 694 B4 relates to a modular traction battery with a plurality of electrochemical cells

confirmation copy are arranged in a housing and are connected to one another via at least one busbar.

Description

An object of the present invention is to provide an optimized system for connecting battery cells.

The above object is achieved by a connection device for at least two battery cells, a battery module and a method for producing a battery module, which include the features in the independent claims. Further advantageous configurations are described by the dependent claims.

To form a battery module from at least two battery cells, these are combined at least via a connecting device and electrically connected to one another.

The connection device comprises at least one connection plate for electrically connecting the at least two battery cells and at least one guide device. In particular, each connection device comprises a plurality of connection plates for electrically connecting a multiplicity of battery cells within a battery module.

It is provided here that the at least one connecting plate is movably assigned to the guide device at least at times.

In particular, the connecting plate is movably assigned to the guide device in an assembled state. Furthermore, an operating state is provided in which the connecting plate is connected to battery poles of the at least two battery cells. In particular, the connecting plate can be connected to the respectively different battery poles of two adjacent battery cells.

The at least two or more battery cells are preferably arranged in a stack one behind the other or one above the other to form a battery cell stack.

The battery cells can be cuboid, for example. However, the individual battery cells can also have a cylindrical shape or another suitable shape. The battery cells each have a positive battery pole and a negative battery pole. The battery poles of a battery cell are preferably formed on opposite end faces of the battery cell.

Alternatively, the battery poles can both be formed on one side of the battery cell.

Within the formed battery cell stack, the battery poles of directly adjacent battery cells are preferably arranged in polarity such that a positive battery pole of a first battery cell and a negative battery pole of a directly adjacent second battery cell alternately point to the same side of the battery cell stack.

A large number of battery cells are preferably combined to form a battery module. In this case, a plurality of connecting devices is provided, which connecting devices are each movably assigned at least temporarily to at least one guide device.

A preferred embodiment provides that the battery module includes a carrier element. The carrier element can form part of the connecting device or be formed by a separate component. The at least one guide device of the connecting device is preferably arranged or formed on the carrier element.

The carrier element is designed, for example, as an extruded profile made from an insulating polymer material.

The at least one guide device is preferably formed by at least one guide profile in the form of a channel or channel open on one side, in which guide profile at least areas of the at least one connecting plate can be accommodated and guided in a sliding or sliding manner.

The connection plate is guided to a correct end position within the battery module and relative to the battery cells by moving it within or along the guide device, at which end position the connection plate in particular contacts the adjacent battery poles of two directly adjacent battery cells. In particular, provision is made for a sufficient number of connecting plates to be arranged in the corresponding end position on the guide device in accordance with the number of battery cells in the battery cell stack.

One embodiment provides that two parallel guide devices are provided, between which two guide devices the connecting plates are arranged.

After setting the end position, the connection plates are connected to the corresponding battery poles, which creates an active electrical connection between adjacent battery cells.

The connecting plate can be connected to the battery poles by welding, for example.

Even before connecting, it can be expedient to limit the play of connecting plates within the guide device not only in two dimensions, but also along the stacking direction. The first dimension is formed perpendicular to the plane of the battery cell stack, the second dimension is formed along the longitudinal axes of the battery cells. For example, one or two points or zones can be provided for each connecting plate, through which the guide device and/or the carrier element is/are locally blocked. This can be done, for example, by punching points, whereby the treated part is permanently deformed by the punching points. The punching points can be introduced selectively, for example using a pen or another tool. In particular, the punching points are locally limited. In this way, the play of the respective connection plate is limited to a certain area along the guide device and/or the carrier element in order to provide the connection plate pre-positioned on the respective battery pole.

One embodiment provides that the connection plate comprises a connection area and at least one locking area. In particular, the connection area is an electrical connection area which, after positioning the connection plate in the end position, extends on and between two battery poles to be connected. In particular, it is provided that the connection area in each case makes contact with a negative battery pole of a battery cell and a positive battery pole of a directly adjacent battery cell and thus electrically connects them. One embodiment can provide that the connection area forms a connection level and that the at least one locking area forms a locking level that deviates from the connection level at least in some areas.

The connection level and the locking level are preferably formed parallel to one another.

For example, the connection plate can include at least two locking sections that form the locking area. The locking sections can in particular be stored guided within the guide devices.

For example, the at least one connecting plate is arranged between two guide devices. The guide devices can be arranged or formed on a carrier element. The connection area of the connection plate is aligned parallel to a plane formed by the guide devices or by the carrier element. One embodiment provides that at least one locking section faces one of the two guide devices and protrudes at least partially into the respective groove or channel of the guide device.

Preferably, all areas of the connection plate, i.e. the connection area and the locking area, are made of the same material. A suitable material is in particular an aluminum alloy, an iron alloy or a copper alloy.

Furthermore, the battery module can include at least one tensioning device, which tensioning device holds the battery cells together in the battery module.

A suitable clamping device can be formed by a tension rod. The pull rod consists, for example, of a tensile and preferably pressure-resistant material, e.g. steel or aluminum. For example, the longitudinal axis of the pull rod is aligned parallel to the stacking direction of the battery cells.

The at least one tensioning device is preferably arranged at a distance from the battery poles of the battery cells. In addition, it can be provided that the tensioning device is arranged on the battery cells, preferably in an electrically insulated manner. One embodiment provides that the tensioning device and the connecting device are arranged on the carrier element or are assigned to the carrier element.

In particular, it is provided that the tension rods forming the clamping device are each arranged inserted into an area of the extruded profile of the carrier element, in particular in an area of the carrier element, which area is arranged along the battery module. In this way, the tensioners are secured along the length of the battery module and are electrically isolated from the connection plates and the battery posts.

The tension rods are preferably arranged closer to the battery cells than the locking area of the connecting plates, at least in sections. This is particularly advantageous since the connection area of the connection plates is thereby better accessible for connection to the battery poles, in particular for welding.

Furthermore, a method for forming a battery module is described, in particular a method for forming a battery module as described above. In the method, at least two battery cells are connected to one another via a connecting device. The procedure includes the steps:

• forming a battery cell stack,

• arranging at least one guide device on the battery cell stack,

• arranging at least one connecting plate on the guide device and moving the connecting plate along the guide device into an end position on the battery cell stack,

• Connect the connecting plate to the battery poles of at least two directly adjacent battery cells.

It should be expressly mentioned at this point that all aspects and design variants that have been explained in connection with the device according to the invention equally relate to or can be partial aspects of the method according to the invention. Therefore, if certain aspects and/or connections and/or effects are mentioned at a point in the description or also in the definition of claims for the device according to the invention, this applies equally for the method according to the invention. The same applies in reverse, so that all aspects and design variants that have been explained in connection with the method according to the invention equally relate to or can be partial aspects of the device according to the invention. Therefore, if certain aspects and/or connections and/or effects are mentioned at one point in the description or also in the claim definitions for the method according to the invention, this applies equally to the device according to the invention.

In the following, exemplary embodiments are intended to explain the invention and its advantages in more detail with reference to the attached figures. The proportions of the individual elements to one another in the figures do not always correspond to the real proportions, since some forms are shown in simplified form and other forms are shown enlarged in relation to other elements for better illustration.

fiqure description

FIG. 1 schematically shows the structure of a battery module.

FIG. 2 shows a further embodiment of a battery module with a connection device according to the invention.

Identical reference symbols are used for elements of the invention that are the same or have the same effect. Furthermore, for the sake of clarity, only reference symbols are shown in the individual figures that are necessary for the description of the respective figure. The illustrated embodiments only represent examples of how the invention can be configured and do not represent any final limitation.

The embodiments, examples and variants of the preceding paragraphs, the claims or the following description and figures, including their different views or respective individual features, can be used independently of one another or in any combination. Features described in connection with one embodiment are applicable to all embodiments unless the features are incompatible.

Figure 1 shows schematically the structure of a battery module 1 and Figure 2 shows a further embodiment of a battery module 1 with a connection device 7 according to the invention. The battery module 1 comprises a plurality of individual battery cells 2, 2a to 2d, which are arranged in a stack one behind the other to form a battery cell stack 3. For example, the battery cells 2 can each be cuboid. However, the individual battery cells 2 can also have a cylindrical shape or another suitable shape.

The battery cells 2 each have battery poles 22 on their end faces.

Each battery cell 2a to 2d has at least two battery poles 22, a positive battery pole 22p and a negative battery pole 22n. In this case, the battery poles 22 are arranged in pairs, for example, on opposite sides of the battery cell 2 . The polarity of the battery poles 22 of adjacent battery cells 2a, 2b, 2c, 2d of the battery module 1 is arranged in such a way that a positive battery pole 22p of a first battery cell 2a and a negative battery pole 22n of a second battery cell 2b are alternately on the same side of the battery module 1 point (compare Figure 1).

Alternatively (not shown), the battery poles 22 can also all be arranged on one side of the battery cells 2 and thus on one side of the battery module 1 .

In order to connect the individual battery cells 2a, 2b, 2c, 2d to form a battery module 1, a first clamping device 5a and a second clamping device 5b can be provided.

Such a clamping device 5 preferably has at least one pull rod 4, 4a, 4b. This consists, for example, of a tensile and preferably pressure-resistant material, e.g. steel or aluminum. The longitudinal axis L of the tension rod 4, shown as an example in FIG. 1, is aligned parallel to the stacking direction of the battery cells 2, 2a to 2d. The clamping device 5 is spaced apart from the battery poles 22 of the battery cells 2 and is preferably electrically insulated.

In order to electrically connect the battery cells 2, 2a to 2d (FIG. 1) or 2a to 2c (FIG. 2) to one another, a first connecting device 7, 7a and a second connecting device 7, 7b are provided. In both examples, the connecting devices 7a, 7b are assigned to the mutually opposite sides of the battery module 1, on which sides the battery poles 22 are arranged.

Each connecting device 7 comprises at least one connecting plate 6 for electrically connecting battery cells 2 within a battery module 1 . In particular, each connecting device 7 comprises a plurality of connecting plates 6 for electrically connecting battery cells 2 within a battery module 1 .

For example, in a battery module 1 shown in FIG. 1 with four battery cells 2a to 2d, two connecting plates 6 are provided in the first connecting device 7a. A first connecting plate 6-1 of the first connecting device 7a connects the negative battery pole 22n of the battery cell 2a to the positive battery pole 22p of the adjacent battery cell 2b. A second connecting plate 6-2 of the first connecting device 7a connects the negative battery pole 22n of the battery cell 2c to the positive battery pole 22n of the adjacent battery cell 2d. In the case of the second connecting device 7b, on the other hand, only one connecting plate 6 is provided, which connects the negative battery pole 22n of the battery cell 2b to the positive battery pole 22p of the battery cell 2c.

Only one connecting device 7 with a connecting plate 6 is visible in FIG.

The features of the connecting device 7 are described in particular in connection with the exemplary embodiment in FIG. In this case, the connecting device 7 comprises a carrier 14 or is assigned to the carrier 14 . The carrier 14 can be designed, for example, as an extruded profile made of an insulating polymer material.

The carrier 14 has one or more guide devices 24 or one or more guide devices 24 are arranged on the carrier 14 . The guide devices 24 are provided for the connection plates 6 to be guided therein. The guide devices 24 are preferably designed as grooves or channels open on one side, into which grooves or channels such a connecting plate 6 can be inserted. The connecting plate 6 is preferably guided in a displaceable manner within the guide devices 24 .

The connecting plate 6 is guided to a correct end position by moving within or along the guide devices 24, at which end position the connecting plate 6 in particular makes contact with the adjacent battery poles 22 of two directly adjacent battery cells 2. In particular, it is provided that a sufficient number of connecting plates 6 are arranged in the corresponding end position on the guide devices 24 in each case.

The necessary connection plates 6 can all be used in the guide devices 14 and transported together. A connection plate 6 can also be adjusted before it is connected to the battery poles 22 and moved to compensate for tolerances in the battery module 1 .

The connecting plate 6 can be connected to the battery poles 22 by welding, for example.

Even before the connection, it can be expedient to limit the play of connection plates 6 within the guide device 24 not only in two dimensions, but also along the stacking direction. In this case, the first dimension is formed perpendicularly to the stack plane, and the second dimension is formed along the longitudinal axes of the battery cells 2 . For this purpose, one or two points or zones can be provided for each connecting plate 6, through which the carrier 14 or one of the guide device 24 is blocked locally. This can be done, for example, by punching points (not shown), at which punching points the treated part is permanently deformed. The punching points can be introduced e.g. with a pen or another tool. In particular, the punching points are locally limited. In this way, the play of the respective connection plate 6 is limited to a certain area along the guide device 24 or the carrier 14 in order to have it pre-positioned immediately in the vicinity of the respective battery pole 22 .

As shown in the exemplary embodiment in FIG. 2, the at least one connecting plate 6 is preferably arranged between two guide devices 24 formed on a carrier 14 . A connection area 8 of the connection plate 6 is aligned parallel to a plane formed by the carrier 14 .

The connection plate 6 has an electrical connection area 8 . The connection area 8 is designed in such a way that it extends on and between two battery poles 22 to be connected.

The connection plate 6 may include locking portions 16 which

Locking sections 16 are guided in particular within the guide devices 24 be stored. In particular, a connecting plate 6 has at least two locking sections 16, 16a, 16b, 16c. One embodiment provides that at least one locking section 16 faces one of the two guide devices 24 and protrudes at least partially into the respective groove or channel of the guide device 24 .

Preferably, all areas of the connection plate 6, i.e. connection area 8 and locking portions 16, are made of the same material, in particular an aluminum alloy, an iron alloy or a copper alloy.

An embodiment can provide that the connection area 8 forms a connection level and that the locking areas form, at least in some areas, a locking level that deviates from the connection level.

The connection level and the locking level are preferably formed parallel to one another.

An embodiment can provide that the connecting plate is formed in one piece and that the spacing between the connecting plane and the locking plane is produced by reshaping the locking sections 16 .

One embodiment provides that both the tensioning device 5 and the connecting device 7 are arranged on the carrier 14 or are assigned to the carrier 14 .

In particular, it is provided that the tension rods 4 forming the clamping device 5 can each be arranged inserted into an area of the extruded profile of the carrier 14 , in particular in an area which extends along the battery cell stack 3 . In this way, the clamping devices 5 are fastened along the battery module 1 and are electrically insulated from the connection plates 6 and the battery poles 22 .

The tension rods 4 are preferably arranged at least in sections closer to the battery cells 2 than the locking sections 16 of the connecting plates 6. This is particularly advantageous since the respective connecting region 8 of the connecting plates 6 is more accessible for connecting, in particular for welding. A concluding note is given at this point to the descriptions of embodiment variants of the invention, with these description passages referring to the accompanying drawings. If "schematic" representations and views are generally referred to in connection with the figures and their descriptions, this in no way means that the representations of the figures and their description are to be of secondary importance with regard to the disclosure of the invention. The person skilled in the art is quite capable of extracting enough information from the diagrammatic and abstract drawings to make it easier for him to understand the invention, without his understanding being impaired in any way by the drawn and possibly not exactly true-to-scale proportions . The figures thus enable the person skilled in the art as a reader to derive a better understanding of the inventive concept formulated more generally and/or more abstractly in the claims and in the general part of the description on the basis of the more specifically explained implementations of the method according to the invention and the more specifically explained mode of operation of the device according to the invention.

The invention has been described with reference to a preferred embodiment. However, it will be apparent to a person skilled in the art that modifications or variations can be made to the invention without departing from the scope of the following claims.

reference list

1 battery module

2, 2a-2d battery cell

3 battery cell stacks

4, 4a, 4b tension rod

5, 5a, 5b clamping device

6, 6-1 , 6-2 connecting plate

7, 7a, 7b connecting device

8 connection area

14 brackets 16, 16a, 16b, 16c locking portion

22 battery poles

22n negative battery pole

22p positive battery pole

24 guiding device

L longitudinal axis

Claims

Claims connecting device (7) for at least two battery cells (2) to form a battery module (1), comprising

• at least one connecting plate (6) for electrically connecting the at least two battery cells (2),

• at least one guide device (24),

• the at least one connecting plate (6) being movably assigned to the guide device (24) at least at times. Connecting device (7) according to Claim 1 for at least a large number of battery cells (2) to form a battery module (1), comprising a plurality of connecting devices (7), which connecting devices (7) are each at least temporarily associated with the guide device (24) in a movable manner. Connecting device (7) according to claim 1 or 2, wherein the connecting device (7) comprises a carrier element (14), on which carrier element (14) the at least one guide device (24) is arranged or formed, in particular wherein the carrier element (14) is an extruded profile is, in particular wherein the carrier element (14) consists of an insulating polymer material. Connecting device (7) according to one of the preceding claims, two parallel guide devices (24) being provided, between which two guide devices (24) the at least one connecting plate (6) is arranged. Connecting device (7) according to one of the preceding claims, wherein the connecting plate (6) comprises a connecting area (8) and at least one locking area (16). Connecting device (7) according to claim 5, wherein the connecting region (8) connects a negative battery pole (22n) of a battery cell (2) and a positive battery pole (22p) of a directly adjacent battery cell (2). Connecting device (7) according to Claim 5, in which the at least one locking region (16) connects the connecting plate (6) to the guide device (24). Connecting device (7) according to Claim 5, in which the connecting plate (6) has a connecting plane and a locking plane, the connecting plane and the locking plane forming spaced-apart parallel planes. Battery module (1) comprising a battery cell stack (3) formed from at least two battery cells (2) and a connecting device (7) for the at least two battery cells (2), the connecting device (7) comprising

• at least one connecting plate (6) for electrically connecting the at least two battery cells (2),

• at least one guide device (24),

• the at least one connecting plate (6) being movably assigned to the guide device (24) at least temporarily.

• in particular comprising a connecting device (7) according to one of Claims 1 to 8. Battery module (1) according to Claim 9, comprising a carrier element (14), which carrier element (14) is part of the connecting device (7) or on which carrier element (14 ) the at least one guide device (24) is arranged. Battery module (1) according to claim 9 or 10 comprising at least one clamping device (5), wherein the clamping device (5) to battery poles (22) of the battery cells (2) is arranged spaced and / or electrically insulated. Battery module (1) according to claim 11, wherein the at least one tensioning device (5) comprises a tension rod (4) made of a tensile and/or pressure-resistant material and/or wherein the at least one tensioning device (5) is parallel to a stacking direction of the battery cell stack (3) is aligned. - 16 -

13. Battery module (1) according to claim 10 and 11, wherein the clamping device (5) is arranged on the carrier element (14), in particular wherein the carrier element (14) is formed by an extruded profile and wherein the clamping device (5) is at least partially within the Extrusion profile is arranged. 14. A method for producing a battery module (1), wherein at least two

Battery cells (2) are connected to one another via a connecting device (7), comprising the steps

• forming a battery cell stack (3) from at least two battery cells (2),

• arranging at least one guide device (24) on the battery cell stack (3),

• arranging at least one connecting plate (6) on the guide device (24) and moving the connecting plate (6) along the guide device (24) into an end position on the battery cell stack (3),

• Connecting the connection plate (6) to battery poles (22) of at least two directly adjacent battery cells (2) of the battery cell stack.