DE212011100153U1 - Electric battery module - Google Patents

Abstract

Electric battery module having electrochemical plate cells (1) arranged in a housing (15) between thermally conductive partition plates (7) contacting a side wall of the housing (15), wherein band electrodes (4, 5) of adjacent electrochemical cells (1) a connecting terminal comprising a supporting and forming element (2) and a covering and forming element (3), characterized in that the supporting and forming element (2) is mounted on the thermally conductive separating plate (7) between the connected band electrodes (4, 5) of the cells (1) is fixed by means of a longitudinally directed fastening slot (11) which is embodied in a bottom of the element, wherein the thermally conductive partition plate (7) slidably in the longitudinally directed mounting slot (7) 11) of the supporting and forming element (2) is inserted.

Description

This invention relates to an electric battery module, the module having flat electrochemical cells disposed in a housing between thermally conductive separator plates and configured to power vehicles having an electric or hybrid drive unit.

Both terminals of the cells used in the modules of this type are designed as band electrodes, which are guided from one body of a cell as two thin metal sheets, the first of aluminum and the second of copper. Such a pole construction creates a problem of effective electrical connection between the two electrochemical cells that are closest to each other in a battery module. It results from the fact that the distances between the cells are small and the materials making up the band electrodes have different electrochemical properties and that an electrochemical cell is produced in their contact point in the presence of moisture, the cell being a starting point of Corrosion and an increase in the resistance of the connection is. This increased resistance of the connected poles generates energy losses and increases the heat energy generated at the site of the connection. This increased heat energy causes the rapid oxidation of the aluminum part of the compound and the even greater increase in resistance. For this reason, in the known solution concepts cell poles are connected by means of supporting and covering mold-forming elements.

Out US 2008/0124617 For example, a module of batteries is known in which the ends of electrodes that are connected are clamped for better utilization of the space by means of supporting and covering and forming elements. In addition, the ends of electrodes which are connected are separated by a plate made of an electrically non-conductive material, the plate having two rows of longitudinal guide openings which ensure the proper arrangement of connected electrodes before being electrically connected and clamped ,

Furthermore, it is off WO 2010/071463 a module of electric batteries is known in which flat electrochemical cells are arranged in a housing between thermally conductive partition plates, which touch the side wall of the housing. In this known solution concept, the ends of electrodes which are connected are also separated from each other by means of a plate consisting of an electrically non-conductive material, the plate having two rows of longitudinal guide openings.

It is an object of this invention to provide a connector. which is constructed such that band electrodes are reliably and stably connected to each other on a large area to obtain a permanent electrical connection characterized by a small resistance, thereby ensuring better utilization of the space, and easy installation of the cells into modules, as well as making them less likely to engage in random short circuits.

An electric battery module having flat electrochemical cells disposed in a housing between thermally conductive separator plates contacting a sidewall of the housing in which band electrodes of neighboring cells are connected by a terminal comprising a supporting and mold forming member and a covering and mold forming member , characterized in that the supporting and mold-forming member is mounted on the thermally conductive partition plate placed between the connected band electrodes of the cells.

The supporting and forming element is advantageously mounted on the thermally conductive partition plate by means of a longitudinally directed mounting slot formed in a bottom of the element.

The thermally conductive partition plate is advantageously used slidably in a longitudinally directed attachment slot of the supporting and forming element.

The supporting and forming element is advantageously connected by thermocompression bonding with the thermally conductive partition plate.

The supporting and forming element is advantageously adhered to the thermally conductive partition plate.

The supporting and forming element and the covering and forming element advantageously have curved shaping surfaces.

In an advantageous embodiment, a supporting and forming element and / or a covering and forming element made of plastic.

In a further advantageous embodiment, a module has a high-current terminal and a measuring terminal.

As a result of eliminating a plate of electrically nonconductive material having lead openings of electrode ends and replacing it with a supporting and forming element fixed on the thermally conductive separator plate, the space has been better utilized and the terminals at the electrode ends can be joined together more easily.

In this specification, the term "forming element" refers to any element having a voluminous profile surface other than a flat surface, which element provides an arc profile of the ribbon electrodes when connected by clamping.

Embodiments of this invention are illustrated in the drawing, in which:

1 shows a connector of band electrodes of electrochemical cells in a perspective view before clamping;

2 shows a similar connector in a perspective view after clamping;

3 shows a supporting and forming element in a perspective view;

4 shows a covering and forming element in a perspective view;

5 shows an example of a high current terminal in a perspective view;

6 shows a battery module in a partial section through screws which clamp a supporting and forming element and a covering and forming element;

7 shows a cross section through an assembled battery module; and

8th shows a single battery module in an exploded perspective view from the connector side.

Before connecting the band electrodes of the electrochemical cells 1 has a connector, as in 1 is shown, a supporting and forming element 2 on a thermally conductive partition plate 7 is attached, and a covering and forming element 3 with band electrodes 4 . 5 from these two adjacent electrochemical cells 1 on which are located between the elements, these band electrodes 4 . 5 have an electrical contact with each other and on the supporting and forming element 2 wrapped and using clamping elements that act as screws 6 are executed, by the covering shape-forming element 3 be pressed. The supporting form-forming element 2 as well as the covering and forming element 3 , in the 1 are shown, have curved mold-forming surfaces.

In 2 is another connector for band electrodes of electrochemical cells 1 represented in which the supporting and forming element 2 by thermocompression bonding on the thermally conductive separator plate 7 is attached.

In other embodiments of this invention, the supporting and forming element is 2 by sticking on the thermally conductive separating plate 7 attached.

In 3 is an embodiment of the supporting and forming element 2 shown having an outer curved mold-forming surface. This form-forming and supporting element 2 has a slot 11 and openings 8th for the screws 6 while a length of the shape-forming member is adjusted to be approximately in accordance with a width of the band electrodes 4 . 5 is. To reduce the likelihood of accidental shorts both when mounting a connector and during operation, the supporting and forming element becomes 2 by means of the slot 11 on the thermally conductive partition plate 7 attached, and it is made of plastic, z. B. polypropylene.

In 4 is the covering and forming element 3 represented along with its inner arched forming surface. This covering and forming element 3 has openings 9 for the screws 6 on. A length of this covering and forming element 3 fits the length of the supporting and forming element 2 that with the covering and forming element 3 interacts. The covering and forming element 3 exists for similar reasons as the supporting and forming element 2 made of plastic, such. B. polypropylene.

In order to incorporate adjacent battery modules into the set of modules, according to the invention, the first connector designed to be connected to a positive band electrode of a cell that is uppermost in the battery module and the last connector designed to be connected to a negative band electrode To be connected to a cell that is the lowest in the battery module, in addition to high current terminals 12 equipped. An example of the shape of the high current terminal 12 is in 5 shown.

In 6 is a part of the battery module in a section through the clamping screws and by the supporting and forming element 2 as well as the covering and forming element 3 shown. As in 6 is shown, are the electrochemical cells 1 stacked and thermally through the thermally conductive separator plates 7 separated mechanically with a housing 15 the module are connected, and the band electrodes 4 . 5 the electrochemical cells 1 are the form-forming and supporting elements 2 wrapped on the thermally conductive separator plates 7 are fastened, and are protected by the covering and forming elements 3 pressed. In the illustrated embodiment, the screws act 6 as elements that are the supporting and form-forming element 2 as well as the covering and forming element 3 Clamp. In addition, the battery module has measuring terminals 10 and the high current terminals 12 on.

In 7 is a cross section of the assembled battery module 13 shown. The module 13 shows the case 15 with a stack of eight flat electrochemical cells 1 on in the housing between the thermally conductive separator plates 7 in mechanical contact with walls of the housing 15 are arranged. In this module are the band electrodes 1 and 2 the neighboring cells connected to each other by a clamp connector. The clamp connectors have the supporting and forming elements 2 placed on the thermally conductive separating plates 7 are attached, and the covering and forming elements 3 put on them by the clamping screws 6 be pressed.

In 8th is a single battery module 13 shown in an exploded view from the side of the connector ago. To the electrochemical cells 1 of the battery module 13 connect, the band electrodes 4 . 5 in pairs around the supporting and form-forming elements 2 placed and with the help of screws 6 through the covering and forming elements 3 pressed. After that, an electronics board 14 attached, which is the voltage from all Meßklemmanschlüssen 10 the electrochemical cells 1 and then this board is connected to a battery monitoring system. In addition, outermost connectors of the tape electrodes used in the cells, that is, connectors at the top left and bottom right, are in addition to the high current clamp terminals 12 intended.

The above examples do not cover all possibilities for a beneficial utilization of the invention. They are only embodiments relating to the construction of the module of flat electrochemical cells arranged in a housing between thermally conductive partition plates designed for vehicles having an electric or hybrid drive unit.

LIST OF REFERENCE NUMBERS

1

electrochemical cell

2

supporting and forming element

3

covering and forming element

4

Band electrode (+)

5

Band electrode (-)

6

mounting screws

7

thermally conductive partition plate

8th

Openings for a fastening screw made in a supporting and forming element 2

9

Openings for a fastening screw made in a covering and forming element 3

10

Measuring terminal

11

Slot executed in a supporting and forming element

12

High current terminal

13

battery module

14

electronic board

15

Housing of the module

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

• US 2008/0124617 [0003]
• WO 2010/071463 [0004]

Claims (8)

Electric battery module with electrochemical plate cells ( 1 ) housed in a housing ( 15 ) between thermally conductive separating plates ( 7 ) are arranged, which has a side wall of the housing ( 15 ), whereby band electrodes ( 4 . 5 ) of adjacent electrochemical cells ( 1 ) by a terminal, which is a supporting and forming element ( 2 ) as well as a covering and forming element ( 3 ), characterized in that the supporting and forming element ( 2 ) on the thermally conductive separating plate ( 7 ) between the connected band electrodes ( 4 . 5 ) of the cells ( 1 ) is placed by means of a longitudinal attachment slot ( 11 ), which is carried out in a bottom of the element, wherein the thermally conductive separating plate ( 7 ) slidable in the longitudinally directed mounting slot ( 11 ) of the supporting and forming element ( 2 ) is used. Module according to claim 1, characterized in that the supporting and forming element ( 2 ) by thermocompression bonding with the thermally conductive separation plate ( 7 ) connected is. Module according to claim 1, characterized in that the supporting and forming element is thermally attached to the thermally conductive separating plate ( 7 ) is glued. Module according to claim 1 or 2 or 3, characterized in that the supporting and forming element ( 2 ) as well as the covering and forming element ( 3 ) have curved shaping surfaces. Module according to claim 1 or 2 or 3, characterized in that the supporting and forming element ( 2 ) is made of plastic. Module according to claim 1 or 2 or 3, characterized in that the covering and forming element ( 3 ) is made of plastic. Module according to claim 1, characterized in that it has a high current terminal ( 12 ) having. Module according to claim 1, characterized in that it has a measuring terminal ( 10 ) having.

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