AT522004B1 - Contacting device for parallel and serial contacting of battery cells assembled into a module - Google Patents

Abstract

A contacting device for parallel and serial contacting of battery cells (1) assembled into a module, which have an end face (3) with a ground connection (5) surrounding a cell pole (4) on the circumference, with contact conductors (2) connected to form a current path. described. In order to specify a contacting device of the type described at the beginning, which, despite low production costs, enables both reliable serial and parallel contacting of battery cells, in particular with a cell pole on the end face and a jacket that can be contacted to ground, with a compact design of the module, it is proposed that the individual contact conductors (2nd ) an annular support (6) for a ground connection (5) of a battery cell (1) and a pole contact (9) connected to the support (6) via a connecting web (8) for the material connection to the cell pole (4) of an adjacent battery cell (1) have.

Description

description

The invention relates to a contacting device for parallel and serial contacting of battery cells assembled into a module, which have an end face with a ground connection surrounding a cell pole on the circumference, with contact conductors connected to form a current path, the individual contact conductors having an annular support for have a ground connection of a battery cell and a pole contact, connected to the support via a connecting web, for the material connection to the cell pole of an adjacent battery cell.

For parallel contacting of battery cells assembled into a module, it is known to connect the individual cell poles in the same direction to one another via a contact plate, thus enabling equipotential bonding.

In order to make serial contact with battery cells of a module, which each have two cell poles of different polarity arranged directly next to one another on their end faces, it has already been proposed (DE 102008034873 A1) to provide electrically conductive cell connectors welded to the cell poles, with the cell connectors each having a cell pole of a Connect the battery to the opposite cell pole of an adjacent battery cell. Although it is possible to contact individual battery cells in parallel, in that the cell connector connects one cell pole of one battery to the cell pole of the same direction of an adjacent battery cell, only two adjacent battery cells can be connected to each other, with crossing the current paths of opposite polarity alone constructively prevented.

Apart from the fact that such contacting devices can only use battery cells whose respective positive and negative poles are designed as contact points that jointly protrude over the end face of the battery cell in the longitudinal direction of the cell, there is the disadvantage that sensible parallel contacting of the cell assembly is only possible via additional constructive measures, such as the above-mentioned contact plate for connecting cell poles of the same direction, could be achieved, which would, on the one hand, significantly increase the manufacturing costs and / or space requirements of the module and, on the other hand, the risk of short circuits, especially in the case of cell poles of different polarity arranged close to one another short creepage or air gaps.

[0005] Further devices for serial contacting of several battery cells are known, for example, from US 2010/015519 A1 and from US 2002/022022178 A1. US 2010/015519 A1 provides contact conductors for battery cells assembled into a module. In this case, a contact conductor comprises an annular support for a connection point of a battery cell and a pole contact connected to the support for the integral connection to the cell pole of an adjacent battery cell. In the case of US 2002/022022178 A1, contact conductors used in a circuit board are provided for serial contacting of a plurality of battery cells, with the contact conductors being formed from a plurality of individual components.

The invention is therefore based on the object of specifying a contacting device of the type described at the outset which, despite low production costs, enables both reliable serial and parallel contacting of battery cells, in particular with a cell pole on the end face and a casing that can be contacted to ground, with a compact design of the module .

The invention solves the problem in that the ring-shaped supports are connected via parallel connectors to form a continuous current path.

As a result of these measures, a serial connection between two battery cells can be produced with a contact conductor that is simple to manufacture in terms of design, with a parallel connection for potential equalization being achieved in that the ring-shaped supports of a contacting device are connected to form a continuous current path via parallel connectors provided for this purpose. Due to the fact that the modules are combined

If battery cells have to have the highest possible packing density for reasons of energy efficiency in practice, the features according to the invention result in only short line lengths both between the battery cells connected to one another in parallel via the annular supports and via the battery cells connected to one another in series via the connecting webs, which a low overall electrical resistance and thus leads to fewer line losses through the contacting device. Particularly favorable production conditions result when the contacting device is designed in one piece, because the contact conductors according to the invention, which are connected via the parallel connectors, can be cut out of an electrically conductive contact sheet using a suitable cutting process.

In order to avoid damage to adjacent battery cells in the module in the event of a fault in individual battery cells, it is proposed that the connecting web form a safety fuse for protecting individual cells. In addition or as an alternative to this, the parallel connectors can also have safety fuses. With regard to favorable manufacturing conditions and good mechanical stability of the connecting web, the safety fuse can be formed by material cutouts in the connecting web. As a result, the support webs of the fuse link formed in this way can also be partially severed after the connecting webs have been bent back and the pole contact has been firmly connected to the cell pole, resulting in an S-shaped meandering structure. In this way, the mechanical stability of the connecting web can be maintained during the assembly process.

Due to the fact that in conventional round cells the jacket that can be contacted with ground is folded over onto the end face that has the cell pole, the annular support provided according to the invention can be broken through by an opening for the connecting web of an adjacent contacting device, because electrical contact can be made over the entire remaining arc length of the support is made possible. In this case, however, just as in the case of a continuous ring-shaped support, a corresponding spacing must be provided between the connecting web and the jacket that can be contacted with ground or the ring-shaped support for insulation between the connecting web and the electrical ground, which may also be covered by an electrical insulator can be filled out.

In order to avoid an electrical connection between the connecting bridge and the ground contact of an adjacent battery cell, the connecting bridge can be attached to the ring inside of the support and bent back over the support to the pole contact for the cell pole. The consequence of this is that the bent-back connecting web has, due to its material stress, a bending radius that is at least large enough for the connecting web to form a bridge spanning the annular support of an adjacent battery cell at a distance.

In order to enable the production of a contacting device according to the invention from a contact plate with minimal use of material and high processing speed, it is proposed that the inner diameter of the annular support corresponds to at least three times the support width. In this case, namely, the connecting web can be cut out of the material located within the annular support. In order to form the pole contact, part of the ring-shaped support can also be cut out, which then either has a reduced support width or is broken through by an opening for the connecting web of an adjacent contacting device.

To connect several battery cells distributed in a longitudinal and a transverse direction to form a battery module, several contacting devices according to the invention can be provided in a contact plane, with the connecting webs of the contact conductors of a contacting device overlapping the annular supports of the contact conductors of an adjacent contacting device.

The battery cells can thus be connected in parallel in the longitudinal direction of a contacting device according to the invention, while the battery cells which are adjacent in the transverse direction normal to this longitudinal direction are serially connected to one another via the individual connections.

binding bridges are contacted.

[0015] Although the annular supports can be overlapped by the connecting webs with the necessary insulation without further measures, the overall height is particularly low if the contacting devices are embedded in a common circuit board designed, for example, as a contacting foil. Depending on the embodiment described above, the individual current paths run in a manner known to those skilled in the art in one or more levels of the circuit board and are separated from one another by a suitable insulating substrate.

In the drawing, the subject of the invention is shown for example. Show it

1 shows a top view of several contacting devices in a first embodiment, which connect individual battery cells to form a module,

Figure 2 is a larger-scale, oblique view of a representation substantially corresponding to Figure 1;

[0019] FIG. 3 shows an oblique view of an alternative embodiment of contacting devices arranged next to one another with a plurality of connected battery cells.

A contacting device according to the invention for parallel and serial contacting of battery cells 1 assembled into a module has contact conductors 2 connected to form a current path. The battery cells 1 comprise an end face 3 with a cell pole 4 and a ground connection 5 surrounding the cell pole 4 on the circumference. The individual contact conductors 2 each have ring-shaped supports 6 that make electrical contact with the ground connections 5, with a parallel connection for potential equalization via the ring-shaped supports 6 to form a continuous current path connecting parallel connector 7 takes place. A serial connection between two battery cells 1 takes place via connecting webs 8 connected to the annular supports 6. The connecting webs 8 have pole contacts 9 which are materially connected to the cell pole 4 of an adjacent battery cell 1, forming an electrical contact point.

The contacting device can be designed in one piece, with the inventive contact conductors 2 connected via the parallel connectors 7 being able to be cut out of an electrically conductive contact sheet by a suitable cutting process. To form the pole contact 9, part of the ring-shaped support 6 can also be cut out, as is indicated by way of example in FIGS.

In order to also avoid an electrical connection between the connecting web 8 and the ground contact of an adjacent battery cell 1, the connecting web 8 can be attached, for example, to the ring inside of the support 6 and bent back over the support 6 to the pole contact 9 for the cell pole 4. In this case, the bent-back connecting web 8 has a bending radius that is at least large enough for the connecting web 8 to form a bridge spanning the annular support 6 of an adjacent battery cell 1 at a distance, as can be seen from FIG. 2 . The distance that forms between the connecting web 8 and the annular support 6 of an adjacent battery cell 1 can remain free, as shown in FIG. 2, or can also be additionally filled with an electrical insulator.

In order to enable production of a contacting device according to the invention with minimal use of material and high processing speed, the inner diameter of the annular support 6 can correspond to at least three times the width of the support.

As can be seen from FIGS. 1 and 2, the connecting webs 8 can form a safety fuse 10 for protecting individual cells. Although in principle the most varied design variants of the fuse 10 are conceivable, the fuse 10 can be formed by material cutouts in the connection web 8 with regard to favorable production conditions and good mechanical stability of the connection web 8 . In this case, after the connecting webs 8 have been bent back and the pole contact 9 has been bonded to the cell pole 4, the supporting webs shown in FIGS. 1 and 2 can also be partially

be severed, resulting in an S-shaped meander structure. This has the advantage that the mechanical stability of the connecting web 8 is retained during the assembly process.

1 and 2, several battery cells distributed in a longitudinal and a transverse direction can be connected to form a battery module, it is advisable to provide several contacting devices according to the invention arranged next to one another in a contact plane. The connecting webs 8 of the contact conductors 2 of a contacting device can overlap the annular supports 6 of the contact conductors 2 of an adjacent contacting device by the connecting webs 8 spanning the annular supports 6 of adjacent battery cells 1 like a bridge at a distance.

In order to achieve a particularly low overall height, the contacting devices can be arranged in a common circuit board 11, which is designed, for example, in FIG. 3 as a contacting film. The current paths of the respective contacting devices can advantageously be electrically isolated from one another via a suitable insulating substrate of the circuit board 11 .

Claims (7)

patent claims 1. Contacting device for parallel and serial contacting of battery cells (1) assembled into a module, which have an end face (3) with a ground connection (5) surrounding a cell pole (4) on the circumference, with contact conductors (2) connected to form a current path, the individual contact conductors (2) have an annular support (6) for a ground connection (5) of a battery cell (1) and a pole contact (9) connected to the support (6) via a connecting web (8) for materially bonded connection to the cell pole (4) of an adjacent battery cell (1), characterized in that the ring-shaped supports (6) are connected via parallel connectors (7) to form a continuous current path. 2. Contacting device according to claim 1, characterized in that the connecting web (8) forms a safety fuse (10) for protecting individual cells. 3. Contacting device according to one of claims 1 or 2, characterized in that the annular support (6) is broken through by an opening for the connecting web (8) of an adjacent contacting device. 4. Contacting device according to one of claims 1 to 3, characterized in that the connecting web (8) is attached to the ring inside of the support (6) and bent back over the support (6) to the pole contact (9) for the cell pole (4). 5. Contacting device according to one of claims 1 to 4, characterized in that the inner diameter of the annular support (6) corresponds to at least three times the support width. 6. Battery module, characterized by contacting devices arranged next to one another in a contact plane according to one of claims 1 to 5, characterized in that the connecting webs (8) of the contact conductors (2) of a contacting device, the annular supports (6) of the contact conductors (2) of an adjacent contacting device encroach. 7. Battery module according to claim 6, characterized in that the contacting devices are embedded in a common circuit board (11). 3 sheets of drawings