DE102011083469A1 - Battery module comprising a plurality of battery cells and motor vehicle - Google Patents

Abstract

The invention relates to a battery module (2) comprising a plurality of battery cells (1) whose poles (4) are connected in series or in series via cell connectors (5). Characteristically, at least one freely accessible surface of a cell connector (5) has a hydrophobic coating (7). Furthermore, a motor vehicle comprising the battery module is proposed.

Description

The present invention relates to a battery module comprising a plurality of battery cells whose poles are connected in series or in series via cell connectors. Furthermore, the invention relates to a motor vehicle which has such a battery module.

State of the art

It is becoming apparent that in the future, both in stationary applications such as wind turbines, in vehicles such as hybrid and electric vehicles as well as in electronic devices such as laptops and mobile phones, more new battery systems will be used to the very high demands in terms of reliability, performance and service life.

Individual battery cells become modules and these in turn are combined into batteries. 1 shows like individual battery cells 1 by parallel or serial connection to battery modules 2 and then to batteries 3 can be interconnected. There are by definition a battery module 2 or a battery 3 from at least two battery cells 1 ,

As in 2 it can be seen, the interconnection of the battery cells takes place 1 at the poles 4 with the help of so-called cell connectors 5 , The cell connectors 5 For example, as shown by means of washers 9 and nuts 10 be attached, or even cohesively via a welded joint with the poles 4 be connected. The cell connectors 5 connect the positive pole in serial connection 4 with the negative pole 4 the next battery cell 1 , the positive pole 4 this battery cell 1 with the negative pole 4 the one after the next and so on.

In the case of lithium-ion battery cells, one of the poles is typically made of an aluminum material, whereas the other pole is made of a copper material. The cell connectors are also made of aluminum or copper sheet strips.

Copper and aluminum have a different electrochemical potential. When these two metals come into contact, a wetting of the joint by a conductive medium (moisture in a battery module) forms a so-called electrochemical local element, which is to be regarded as a battery. The ions transport ions through the water, the solids conduct the electrons. As a result, the less noble metal is dissolved, the nobler remains unchanged. This corrosive process can lead to an increase in the contact resistance at the contacts due to the formation of oxide deposits. In the worst case, there is a resolution of the connection point and thus to a failure of the battery system. The presence of moisture is hard to prevent in a battery pack. In addition to the above-mentioned corrosion process, hydrogen is also released during the corrosion.

The DE 10 2008 059 970 A1 describes a battery having a plurality of battery cells that are electrically interconnected via a cell connector board having cell connectors thereon. To compensate for differences in level of the individual poles, the cell connectors are flexible and arranged on a rigid cell connector board. However, a solution for reducing corrosion is not disclosed.

Disclosure of the invention

According to the invention, a battery module comprising a plurality of battery cells whose poles are connected in series or in series via cell connectors is provided. At least one freely accessible surface of a cell connector has a hydrophobic coating. Under a freely accessible surface can be understood in this state, each surface of the cell connector, which can be wetted by the installation of the module of water or water vapor.

The division of a surface of a body as hydrophobic or hydrophilic according to their contact angle with respect to water. The contact angle refers to that angle which a drop of liquid forms on the surface of a solid to this surface in a boundary point of air, water and solid. In principle, the contact angle is not limited to a system consisting of a solid, air and water, but the system may for example consist of a solid and two immiscible fluids. The determination of the contact angle via a contact angle goniometer. Physical quantities are usually determined at room temperature, ie 20 ° Celsius. Furthermore, the shape of a drop can be determined by means of the Young's equation, the contact angle representing a boundary condition.

If this contact angle with respect to water were smaller than 90 °, the surface would be described as hydrophilic, with complete contact wetting at a contact angle of 0 °. From a contact angle of a surface to water of greater than 90 ° is called a hydrophobic surface - the body is not or only very incompletely wetted. The limit value of the contact angle of 180 ° only describes one punctiform wetting point and thus an absolute non-wettability.

Due to the hydrophobic coating of the cell connector, it can only be wetted insufficiently or not at all on the coated surfaces of moisture. If the surfaces adjacent to the battery poles or adjacent to the fastening elements attached thereto are preferably provided with the hydrophobic coating, the formation of an electrochemical local element is wholly or at least largely prevented. As a result, corrosion processes between the cell connector and adjacent components in pairs of copper and aluminum are prevented or at least reduced. This results in an increased life of the module.

According to a preferred embodiment of the invention it is provided that the hydrophobic coating of the cell connector has a contact angle to water of at least 110 °. Particularly preferably, the coating has a contact angle to water of at least 120 °, which corresponds to a preferred coating of the cell connector with PTFE (polytetrafluoroethylene).

Further preferably, the cell connector has a contact angle to water of at least 150 °. Particularly preferably, the coating has a contact angle to water of at least 160 °, resulting in a lotus effect. In order to be able to realize such high contact angles, the coated surface of the cell connector has a preferred well-defined nanostructuring of the surface, which manifests itself as roughness of the surface. With such a roughness, the moisture does not penetrate to the bottom of the roughness, but only up to the tips of the roughness. As a result, the drop does not slide on its liquid film at an inclination of the surface but rolls off.

Preferably, the hydrophobic coating or surface of the cell connector has been mechanically produced. Depending on the size of the surface structuring, it may also have been etched using an etching process and thus be an etched surface. Furthermore, the coating can be a sputtered coating, as can be produced by means of sputtering and in particular laser sputtering. Methods for producing a hydrophobic surface are described, for example, in the document DE 10 2004 026 344_B4 described.

According to a further preferred embodiment of the invention, it is provided that the hydrophobic coating of the cell connector is a lacquer layer. This generally refers to a coating that is applied by means of a spraying or dipping process.

The coating can in particular be applied only after the connection of the battery cells to a battery module. In this subsequent application necessarily adjacent components such as the poles, or connecting elements are co-coated for fixing the cell connector, which also have these hydrophobic properties. The hydrophobic properties inhibit the formation of a continuous liquid film, thereby preventing the occurrence of undesirable leakage currents.

It is further preferred if the coating is a film. This foliation is preferably applied to the cell connector prior to mounting the battery module.

The entire freely accessible surface of the cell connector may have the hydrophobic coating. By this configuration, the formation of leakage currents can be counteracted via the surface of the cell connector. In addition, it is ensured that in places where different materials touch, for example, a copper cell connector and fasteners made of aluminum, can not form an electrochemical local element.

It is furthermore preferred if the entire surface of the cell connector has the hydrophobic coating. However, this is only possible if the coating is not an electrical insulator. As a result of this configuration, the cell connector can be coated in a particularly simple manner by means of a spraying or dipping method before assembly.

According to a further preferred embodiment of the invention, it is provided that the cell connector has a basic body of metal, particularly preferably of aluminum, copper or their alloys, on which the hydrophobic coating is applied. These materials are characterized by high electrical conductivity, making them particularly suitable as a cell connector material. Further preferably, the base body may be coated with tin, for example.

According to a further preferred embodiment of the invention it is provided that the hydrophobic coating comprise materials from the group of glasses.

Preferably, the battery cells of the battery module are lithium-ion secondary cells. By using the lithium ions Technology, particularly high energy storage densities can be achieved, which leads to other advantages, especially in the field of electric mobility.

Furthermore, a motor vehicle is provided with the battery module according to the invention, wherein the battery module is generally provided for feeding an electric drive system of the vehicle.

Advantageous developments of the invention are specified in the dependent claims or refer to the description.

drawings

Embodiments of the invention will be explained in more detail with reference to the accompanying drawings and the description below. Show it:

1 Interconnections of battery cells (prior art),

2 Battery cells with cell connectors (prior art),

3 a cell connector according to the invention having a hydrophobic coating,

4 a module according to the invention, and

5 a second embodiment of the module according to the invention.

On 1 and 2 has already been discussed to explain the state of the art.

3 shows a cell connector according to the invention 5 with a hydrophobic coating 7 , The cell connector 5 In the example shown, it comprises two openings 8th , which in the electrical interconnection of two battery cells 1 as a recording of the poles 4 serve.

4 shows the side view of two battery cells 1 whose poles 4 by means of a cell connector 5 , to a battery module according to the invention 2 electrically connected. The fixation of the cell connector 5 at the poles 4 can as shown by means of washers 9 and nuts 10 done, which on thread of the poles 4 are screwed. Also common is a cohesive connection by means of welding, or a riveted joint, ie mechanical deformation. To clarify the structure of the cell connector 5 this is shown cut. The cell connector according to the invention 5 includes a hydrophobic coating 7 which is on a basic body 6 is applied. The main body 6 can, as known from the prior art, be made of an aluminum or copper material. The coating 7 is either a lacquer layer or a foil and must have sufficient electrical conductivity in the example shown in order not to hinder the flow of current to the poles.

If, for example, it is an electrically poorly or non-conductive coating, then the contact surfaces of cell connectors 5 to the washers 9 , the nuts 10 and the poles 4 from the coating 7 be omitted - see in 5 , Also conceivable are, for example, pointed elevations on the upper side of the lower nuts 10 or at the bottom of the upper washers 9 , which during assembly the coating 7 penetrate and thus ensure sufficient conductivity. coatings 7 with preferably high contact angle with respect to water of for example 150 ° and more are achieved by a defined roughness of the surface in the nanometer range. Accordingly, care must be taken when mounting the battery module 2 be done in order not to destroy the fine surface structure of the freely accessible areas.

During operation of the battery module 2 For example, in a motor vehicle, the penetration of moisture into the battery module 2 difficult to prevent. For example, a drop of water forms at the transition A between the cell connector 5 and the washer 9 so this may be due to the hydrophobic coating 7 the cell connector 5 Do not or only slightly wetting, whereby the formation of an electro-chemical local element is at least partially prevented. In addition, it can be assumed that the drop through the hydrophobic coating 7 can not permanently hold at transition A. Rather, he will roll off, for example, when cornering. As a result, the interconnection of the two battery cells 1 not disturbed by corrosion, the electric current flow remains unhindered.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102008059970 A1 [0007]
• DE 102004026344 B4 [0014]

Claims (10)

Battery module ( 2 ) comprising a plurality of battery cells ( 1 ) whose poles ( 4 ) via cell connectors ( 5 ) are connected in series or in series, characterized in that at least one freely accessible surface of a cell connector ( 5 ) a hydrophobic coating ( 7 ) having. Battery module ( 2 ) according to claim 1, wherein the hydrophobic coating ( 7 ) of the cell connector ( 5 ) has a contact angle to water of at least 110 °. Battery module ( 2 ) according to claim 2, wherein the hydrophobic coating ( 7 ) of the cell connector ( 5 ) has a contact angle to water of at least 150 °. Battery module ( 2 ) according to one of the preceding claims, wherein the entire freely accessible surface of the cell connector ( 5 ) the hydrophobic coating ( 7 ) having. Battery module ( 2 ) according to any one of the preceding claims, wherein the hydrophobic coating ( 7 ) of the cell connector ( 5 ) is a sputtered coating, in particular a laser-sputtered coating. Battery module ( 2 ) according to any one of the preceding claims, wherein the hydrophobic coating ( 7 ) of the cell connector ( 5 ) is a lacquer layer. Battery module ( 2 ) according to any one of the preceding claims, wherein the hydrophobic coating ( 7 ) is a foliation. Battery module ( 2 ) according to any one of the preceding claims, wherein the cell connector ( 5 ) a basic body ( 6 ) made of aluminum, copper or their alloys, on which the hydrophobic coating ( 7 ) is applied. Battery module ( 2 ) according to one of the preceding claims, wherein the battery cells ( 1 ) of the battery module ( 2 ) Are lithium-ion secondary cells. Motor vehicle with a battery module according to one of claims 1 to 9.

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