DE102014219353A1 - Method for producing a motor vehicle battery module and motor vehicle battery module - Google Patents

Abstract

In a method for producing a motor vehicle battery module (10), in particular for an electric or hybrid vehicle, at least two battery cells (12) and two pressure plates (20, 22) made of an electrically insulating material and two tie rods (24, 26) provided. The battery cells (12) are placed between the pressure plates (20, 22) and compressed. To the pressure plates (20, 22), the tie rods (24, 26) are attached to connect the pressure plates (20, 22) together and maintain the compressed state. Furthermore, a motor vehicle battery module (10) is described.

Description

The invention relates to a method for producing a motor vehicle battery module, in particular for an electric or a hybrid vehicle, as well as a motor vehicle battery module.

Electric or hybrid vehicles are increasingly in demand, as people now have a stronger awareness of Okology. Such motor vehicles have as a single or additional drive at least one motor vehicle battery module that provides the drive energy electrically. Typically, a motor vehicle battery module consists of a plurality of battery cells, in particular prismatic or prismatic battery cells. In the production, the battery cells are usually driven away or force-monitored and clamped by a circumferential aluminum frame, so that they are kept in a defined shape. This compressed arrangement of the battery cells is also referred to as a battery pack. Subsequently, the battery pack and surrounding the battery pack aluminum frame are surrounded by an insulating jacket to ensure the required high-voltage insulation of the battery cells or the motor vehicle battery module.

The aluminum frame for the battery pack is usually formed of two pressure plates and two tie rods that hold the individual battery cells pressed. Both the pressure plates and the tie rods are made of aluminum and must be welded at a total of four points, the corner areas, to form the closed aluminum frame, which ensures the permanent pressing of the battery cells. The printing plates and tie rods have typically been manufactured in an extrusion molding process in the prior art.

It has proved to be disadvantageous that motor vehicle battery modules produced in this way have a high weight and, in addition, their production is expensive. This is mainly due to the fact that the raw material aluminum in recent years has become more expensive and also high capital investment must be made to provide and maintain an extrusion press. Furthermore, it has been found to be a disadvantage that the manufacturing has many individual steps to provide the electrically isolated automotive battery module, which is why the production is also expensive.

The object of the invention is to provide a method for producing a motor vehicle battery module, as well as a motor vehicle battery module, which can be carried out and produced simply and inexpensively.

• a) Bereitstellen von wenigstens zwei Batteriezellen und zwei Druckplatten aus einem elektrisch isolierenden Material sowie zwei Zugankern,
• b) Anordnen der Batteriezellen zwischen den Druckplatten,
• c) Zusammendrücken der Batteriezellen und der Druckplatten, und
• d) Befestigen der Zuganker an den Druckplatten, um die Druckplatten miteinander zu verbinden und den zusammengepressten Zustand aufrecht zu erhalten.

The object is achieved by a method for producing a motor vehicle battery module, in particular for an electric or a hybrid vehicle, with the following steps:

• a) providing at least two battery cells and two pressure plates of an electrically insulating material and two tie rods,
• b) arranging the battery cells between the printing plates,
• c) compressing the battery cells and the pressure plates, and
• d) Attach the tie rods to the pressure plates to connect the pressure plates together and maintain the compressed state.

The basic idea of the invention is to save manufacturing steps as well as components and thereby to accelerate the production. According to the invention, a continuous aluminum frame is no longer needed in order to keep the individual battery cells pressed together. The printing plates themselves are made of an electrically insulating material, whereby the previously necessary manufacturing step can be omitted, to coat the printing plates with an insulating material. As a result, the costs are reduced, among other things, by the fact that an additional insulation component is not needed.

One aspect of the invention provides that the compression in step c) is path-controlled and / or force-controlled or path-controlled and / or force-controlled. This ensures that the force acting on the battery cells is defined so that a battery pack comprising the battery cells has a predefined shape.

In particular, the printing plates are produced before step a) in a plastic-forming production process, in particular an injection molding process. As a result, the high capital investment for an extrusion press can be saved, whereby the production of printing plates is cheaper in high quantities. In addition, a permanent tool for injection molding can be used, which has a longer service life compared to an extrusion tool. Further, the printing plates may be formed of a lighter material than aluminum.

According to a further embodiment, the tie rods are produced before step a) in plastics-forming manufacturing processes, in particular a plastic injection molding process. The tie rods can thus also be formed of an electrically insulating material and do not have to be subsequently encased with an insulating material. In addition, the weight of the motor vehicle battery module can be further reduced.

According to a further aspect of the invention, the printing plates and the tie rods are glued or welded together. As a result, the frame can be produced in a particularly simple manner, which surrounds the battery pack or the battery cells. In general, the production of the motor vehicle battery module thus has a higher degree of freedom.

The object of the invention is further achieved by a motor vehicle battery module, in particular for an electric or a hybrid vehicle, with at least two battery cells and two pressure plates, wherein the at least two battery cells are arranged between the two pressure plates and the pressure plates of an electrically insulating material , in particular of a plastic, are produced. As a result, a motor vehicle battery module is created, which is cheaper compared to the automotive battery modules known from the prior art, since no additional insulation component is needed. In addition, it has a smaller space requirement.

Another aspect of the invention provides that the printing plates are plastic injection molded parts. As a result, the motor vehicle battery module has greater variability. Furthermore, weight can be saved, with the stability of the motor vehicle battery module even increasing or being able to transmit a higher force, since the motor vehicle battery module has a higher flexural strength. As a result, the space requirement of the motor vehicle battery module can be further reduced.

In particular, tie rods are provided, which are each connected to the two pressure plates and arranged on opposite sides of the battery cells to form with the two pressure plates a at least two battery cells substantially enclosing housing or the at least two battery cells substantially enclosing frame. About the thus formed frame ensures that the battery cells are kept in their compressed state, so that the battery pack formed from the battery pack retains its predefined shape.

In particular, the tie rods are made of an electrically insulating material, preferably of a plastic. As a result, the tie rods already form an electrical insulation.

Furthermore, the tie rods are plate-shaped parts. The motor vehicle battery module thereby has a particularly compact shape.

Another aspect of the invention provides that the tie rods are welded or glued to the pressure plates. The connection ensures that the forces occurring during operation of the motor vehicle battery module can be absorbed by the tie rods and pressure plates in order to hold the battery pack in the predefined form. Furthermore, a faster and cheaper connection is possible due to the formation of the tie rods and the pressure plates. For example, can be dispensed with an expensive laser system, whereby the investment is much lower. In general, alternative connection methods can be used due to the design of the printing plates and tie rods.

Further advantages and features of the invention will become apparent from the following description and the single figure, to which reference is made.

In the figure is an inventive motor vehicle battery module 10 shown as a drive source or part of a drive source for a motor vehicle, in particular for an electric or hybrid vehicle. The motor vehicle battery module 10 comprises several adjacent, in particular prismatic battery cells 12 that has a battery pack 14 form.

The battery pack 14 has a first formed as a contact surface page 16 and a second formed as a contact surface page 18 on that to the first page 16 is opposite. At the first page 16 lies a first pressure plate 20 whereas on the second page 18 a second pressure plate 22 so that the battery pack 14 from the printing plates 20 . 22 is limited laterally.

The printing plates 20 . 22 thus lie on the outer battery cells 12 of the battery pack 14 and on their long side surfaces.

In the manufacture of the motor vehicle battery module 10 be the two printing plates 20 . 22 weg- and / or force-controlled or weg- and / or force-controlled compressed to the individual battery cells 12 squeeze so that they experience a defined pressure and the battery pack 14 form with a predefined shape.

The two printing plates 20 . 22 In particular, they lie completely on the respective side 16 . 18 , whereby a homogeneous pressure force on the battery pack 14 is exercised. In general, the pressure of the battery cells 12 to the so-called cellular respiration during operation of the motor vehicle battery module 10 counteract, so their thermal and electrical conditional expansion.

The motor vehicle battery module 10 also has a first tie rod 24 and a second tie rod 26 on, which are each plate-shaped. The tie rods 24 . 26 are on opposite ends of the elongated battery cells 12 arranged and connect the two printing plates 20 . 22 each with each other. The tie rods 24 . 26 thus extend over all the battery pack 14 forming battery cells 12 in each case on opposite end faces of the battery cells 12 issue.

The two printing plates 20 . 22 as well as the two tie rods 24 . 26 make up the battery pack 14 essentially enclosing framework 28 off, the battery cells 12 as well as the battery pack 14 in the predefined form. The battery pack 14 is therefore not out of the frame.

Generally the printing plates 20 . 22 made of an electrically insulating material, so that the pressure plates 20 . 22 even form the electrical insulation. The printing plates 20 . 22 can be produced in a plastic injection molding process and thus particularly favorable.

Similarly, the two tie rods 24 . 26 be made of an electrically insulating material, whereby the tie rods 24 . 26 itself form an electrical insulation. As well as the printing plates 20 . 22 can the tie rods 24 . 26 have been produced in a plastic injection molding process.

Around the surrounding frame 28 train the battery pack 14 in its defined form, the printing plates become 20 . 22 as well as the tie rods 24 . 26 at their joints 30 , ie the adjoining corners, welded or glued together.

Depending on the expected forces can thus a correspondingly sufficient connection between the tie rods 24 . 26 and the printing plates 20 . 22 be provided, which increases the degrees of freedom in the production of the motor vehicle battery module 10 increase. If expected low forces, for example, a cost-effective connection method can be selected, which is easier to implement and cheaper to perform, making the motor vehicle battery module 10 even cheaper can be made.

Generally has such a manufactured automotive battery module 10 a lower weight, as the pressure plates 20 . 22 and optionally the tie rods 24 . 26 may be formed of a lightweight material, such as an electrically insulating plastic. Despite the lighter weight, the automotive battery module can 10 transmit more power because it has a higher flexural strength.

The manufactured motor vehicle battery module 10 In addition, it is more cost-effective to manufacture, since a permanent tool can be used for the manufacture which has a long service life. Furthermore, the printing plates 20 . 22 and the tie rods 24 . 26 less expensive than with a laser welding system connected to each other.

Claims (14)

Method for producing a motor vehicle battery module ( 10 ), in particular for an electric or a hybrid vehicle, comprising the following steps: Providing at least two battery cells ( 12 ), two printing plates ( 20 . 22 ) of an electrically insulating material and two tie rods ( 24 . 26 ) Arranging the battery cells ( 12 ) between the printing plates ( 20 . 22 ) Squeezing the battery cells ( 12 ) and the printing plates ( 20 . 22 ), and Attaching the tie rods ( 24 . 26 ) on the printing plates ( 20 . 22 ) to the printing plates ( 20 . 22 ) and maintain the compressed state. A method according to claim 1, characterized in that the compression in step c) running away and / or force controlled or weg- and / or force-controlled. Method according to claim 1 or 2, characterized in that the printing plates ( 20 . 22 ) and / or the tie rods ( 24 . 26 ) are produced before step a) in a plastic molding manufacturing process, in particular injection molding. Method according to one of the preceding claims, characterized in that the printing plates ( 20 . 22 ) and the tie rods ( 24 . 26 ) are glued or welded together. Automotive battery module ( 10 ), in particular for an electric or a hybrid vehicle, with at least two battery cells ( 12 ) and two printing plates ( 20 . 22 ) arranged such that the at least two battery cells ( 12 ) between the two printing plates ( 20 . 22 ) are arranged, wherein the pressure plates ( 20 . 22 ) are made of an electrically insulating material, in particular of a plastic. Automotive battery module ( 10 ) according to claim 5, characterized in that the pressure plates ( 20 . 22 ) Injection molded parts are. Automotive battery module ( 10 ) according to one of claims 5 and 6, characterized in that tie rods ( 24 . 26 ) are provided, each with the two pressure plates ( 20 . 22 ) and on opposite sides of the battery cells ( 12 ) are arranged and with the two pressure plates ( 20 . 22 ) the at least two battery cells ( 12 ) substantially enclosing housing or substantially enclosing frame ( 28 ) train. Automotive battery module ( 10 ) according to claim 7, characterized in that the tie rods ( 24 . 26 ) are made of an electrically insulating material, in particular of a plastic. Automotive battery module ( 10 ) according to claim 7 or 8, characterized in that the tie rods ( 24 . 26 ) are plate-shaped parts. Automotive battery module ( 10 ) according to one of claims 7 to 9, characterized in that the tie rods ( 24 . 26 ) with the printing plates ( 20 . 22 ) are welded or glued.

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