AT16081U1 - accumulator - Google Patents

Abstract

The invention relates to an accumulator (1) having a plurality of memory modules (2) for electrical current, wherein a respective cooling device (4) for cooling the memory modules (2) is arranged between the memory modules (2), each of which has at least one first sheet metal element (7). and a second sheet metal element (8) connected thereto, between which at least one coolant channel (11) is formed, and wherein the cooling device (4) has a coolant inlet (12) and a coolant outlet (13). The first sheet metal element (7) is connected to the second sheet metal element (8) by means of electromagnetic pulse welding or by gluing.

Description

The invention relates to an accumulator with a plurality of memory modules for electric power, wherein between the memory modules in each case a cooling device for cooling the memory modules is arranged, each having at least a first sheet metal element and a second sheet metal element connected therewith, between which at least one coolant channel formed and wherein the cooling device comprises a coolant inlet and a coolant outlet.

The invention further relates to a method for producing a cooling device for an accumulator having a plurality of memory modules for electrical energy, between each of which a cooling device for cooling the memory modules is arranged, after which a first sheet metal element and a second sheet metal element are provided and interconnected.

The life and the effectiveness as well as the safety of a rechargeable battery for the so-called e-mobility depend inter alia on the temperature during operation. For this reason, various concepts have already been proposed for the cooling or temperature control of the accumulators. In essence, the concepts can be divided into two types, namely air cooling and water cooling or generally cooling with liquids.

For the water cooling heat sinks are used, in which at least one coolant channel is formed. These heat sinks are placed between the individual modules of the accumulator. A module is an independent unit of the accumulator, so not necessarily only one cell.

Such a heat sink is known for example from DE 10 2012 218 724 A1. This publication describes an arrangement for controlling the temperature of at least one energy store, comprising two cover plates and an intermediate plate arranged between these cover plates, wherein the arrangement comprises a plurality of extending between the cover plates channels for guiding a fluid medium, wherein at least one of the cover plates on an intermediate plate facing away from the outside Cover plate has a contact surface over which this cover plate with an outer surface of the energy storage thermally conductive is connected, wherein the intermediate plate has a plurality of slots and the slots laterally delimiting intermediate webs, wherein each of the intermediate webs on both cover plates areal adjacent, so that each of the slots in each case by both cover plates is covered, each of the channels is one of these slots.

The present invention has for its object to provide an improved, operable with egg ner coolant liquid cooling device for a rechargeable battery or the accumulator equipped for e-mobility.

This object is achieved in the accumulator mentioned above in that the first sheet metal element is connected to the second sheet metal element by means of electromagnetic pulse welding or by gluing.

Further, the object is achieved with the aforementioned method, according to which it is provided that the two sheet metal elements are connected by means of electromagnetic pulse welding or by gluing.

The advantage here is that the two sheet metal elements can be easily connected to each other circumferentially, with no additional heat is introduced into the two sheet metal elements. This in turn is advantageous in terms of the flatness of the cooling device and subsequently to the installation of the cooling device to the respective memory module. With the improved system, the efficiency of the cooling can be improved, with additional balancing weights for the compensation of unevenness in the adjoining areas of the cooling device and memory module are not necessary. Due to the strong acceleration of a sheet metal element when connecting to the second sheet metal element, the tightness of the connection can be improved. The advantage here is that no additional

Material is required so that there is no tension due to different thermal expansion of different materials in the connection area. In addition, the connection of the two sheet metal elements takes place within a very short time, whereby corresponding cost advantages in the production of the cooling device can be realized.

According to a variant of the accumulator can be provided that the coolant channel is formed in at least one of the two sheet metal elements. It can thus be reduced, the number of individual components of the cooling device, which subsequently the robustness of the cooling device can be improved.

But it can also be provided that between the first and the second sheet metal element another sheet metal element is arranged. By this sheet metal element, the coolant channel can be divided and thus the length of the flow path of the coolant can be increased in the cooling device. This, in turn, is advantageous in terms of the efficiency of the cooling device.

On the other hand, to increase the cooling capacity of the cooling device but also be provided that in the further sheet metal element openings are formed, which form part of the at least one coolant channel. It can thus be increased, the cross section of the coolant channel without the two sheet metal elements must be subjected to excessive deformation to form the coolant channel.

According to another embodiment of the accumulator can be provided that in the coolant inlet and in the coolant outlet, a distance sealing element is used. It can thus improve the tightness of these areas.

For a better understanding of the invention, this will be explained in more detail with reference to the following figures.

In a simplified, schematic representation: [0016] FIG. 1 shows a detail of an accumulator; FIG. 2 shows a cooling device in oblique view; FIG. Fig. 3 is an exploded view of the cooling device of Figure 2 in an oblique view. FIG. 4 shows a spacer sealing element. FIG.

Introductoryly it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals or the same component names, the revelations contained in the entire description can be mutatis mutandis transferred to like parts with the same reference numerals or the same component names. Also, the location information chosen in the description, such as top, bottom, side, etc. related to the immediately described and illustrated figure and these position information in a change in position mutatis mutandis to transfer to the new location.

In Fig. 1, an accumulator 1, i. a rechargeable battery, partially shown in an oblique view. The accumulator 1 comprises a plurality of memory modules 2 for electrical energy. The memory modules 2 are connected to one another via at least one busbar 3. Between the memory modules 2 are applied to these adjacent cooling devices 4. The memory modules 2 can be arranged on holding devices 5, which are arranged below the memory modules 2. The holding devices 5 may be connected to connecting elements 6 to form memory module rows.

Since the basic structure of such accumulators 1 for e-mobility from the relevant prior art is known, reference is made to avoid repetition. The following description is therefore limited to the cooling of the accumulator. 1

It should further be noted that the term "cooling" in the context of the invention, the temperature of the accumulator 1 is understood.

FIGS. 2 and 3 show an alternative embodiment of the cooling device 4 in an oblique view or an exploded view. The cooling device 4 has a first sheet metal element 7 and a second sheet metal element 8 connected thereto.

The two sheet metal elements 7, 8 are at least approximately plate-shaped.

The connection of the two sheet metal elements 7, 8 takes place by means of electromagnetic pulse welding. For this purpose, one of the two sheet metal elements 7, 8 is held stationary and the other sheet metal element 7, 8 is accelerated in the sequence against the stationary sheet metal element 7, 8. In principle, electromagnetic pulse welding is known from the relevant prior art. Reference should therefore be made to this for further details of this method.

Alternatively, the two sheet metal elements 7,8 are also glued together.

The connection of the two sheet metal elements 7, 8 takes place in the region of edges 9 of the sheet metal elements 7.8 fully.

The sheet metal elements 7, 8 have openings 10 in the region of the lower edge. These openings 10 serve to receive the connecting elements 6, as can be seen from Fig. 1.

In the cooling device 4, at least one coolant channel 11 is formed between the sheet metal elements 7, 8, which emerges in the embodiment of the cooling device 4 according to FIGS. 1 to 3 on the surface of the sheet metal element 8. In this embodiment, the at least one coolant channel 11 is formed in the sheet metal element 8, for example by deep drawing or by means of a stamping process. The other sheet metal element 7 is executed completely flat in the technical understanding.

However, there is also the possibility that the at least one coolant channel 1 is partially formed both by the sheet metal element 7 and by the sheet metal element 8, for example, each half, by corresponding deformation thereof.

Of course, also forms in the embodiment of the cooling device according to FIGS. 2 and 3, the sheet metal element 7 a part of the coolant channel 11, since it forms the cover on one side for the coolant channel 11, but in this "undeformed", So even state.

In principle, a plurality of coolant channels 11 may be disposed within the cooling device 4. For this purpose, for example, the two sheet metal elements 7, 8 can also be connected to one another in areas between the edges 9, that is, for example, a middle seam can be formed.

But there is also the possibility that, according to another embodiment, between the two sheet metal elements 7, 8 arranged a further sheet metal element and optionally connected to the sheet metal element 7 and / or the sheet metal element 8, being used as a connection method again the electromagnetic pulse welding comes. The volume between the two sheet metal elements 7, 8 is divided in this embodiment variant with the other sheet metal element into two sub-volumes.

The further sheet metal element may be at least approximately or exactly as large in area as the sheet metal element 7 and the sheet metal element 8. By at least approximately is meant that it is only so much smaller than space is needed to the two Sheet metal elements 7, 8 along the edges 9 to connect together. The further sheet metal element is thus completely spaced from the edges 9 of the sheet metal element 7, 8 is formed.

However, it can also be provided according to another embodiment of the cooling device 4, that in the further sheet metal element openings are formed, which form at least a portion of the at least one coolant channel 11. It is thus achieved in this embodiment of the cooling device 4 by the arrangement of the further sheet metal element, a greater spacing of the two sheet metal elements 7, 8 in the region of the coolant channel 11, whereby the volume of the at least one coolant channel 11 can be increased.

In Fig. 1 to 3 can be seen, the coolant channel 11 may be arranged meandering extending in the cooling device 4. However, other courses of the at least one coolant channel 11 are also possible.

As a coolant, from which the cooling device 4 is flowed through, a liquid is used, for example a water-glycol mixture.

The coolant channel 11 extends from a coolant inlet 12 to a coolant outlet 13 of the cooling device 4. If there are several coolant channels 11 per cooling device 4, more than one coolant inlet 12 and / or more than one coolant outlet 13 can also be provided.

The coolant inlet 12 and the coolant outlet 13 may be formed as simple recesses in the sheet metal elements 7, 8, which are sealed accordingly.

In the preferred embodiment of the cooling device 4, however, it may be provided that in the sheet metal elements 7, 8 corresponding openings 14 are provided, and that in these openings 14 each have a spacer sealing element 15 is inserted. A variant of this distance sealing element 15 is shown in Fig. 4.

In the context of the invention, a spacer sealing element 15 is understood to mean an element which on the one hand enables both a sealing of the coolant inlet 12 and the coolant outlet 13, and on the other hand also a spaced arrangement of the two sheet metal elements 7, 8 in the region of the coolant inlet 12 or of the coolant outlet 13.

The distance sealing element 15 may have a circumferential, brim-shaped edge 16, with which it rests flat against the sheet metal elements 7, 8. Extending orthogonally thereto from this edge 16 is a circumferential, closed web 17, which projects into the opening 14 (FIG. 3) of the sheet-metal element 8 (FIG. 2). On the opposite side of the edge 16, such a web 17 is also formed, which, however, can not be seen in Fig. 4, since it protrudes into the opening 14 of the sheet metal element 7.

The web 17 encloses an opening 18, via which the coolant from the distance sealing element 15 can flow into the coolant channel 11 and can flow out.

It should be noted that the concretely illustrated in Fig. 4, elongated shape of the spacer sealing element 15 is to be understood as preferred but not limiting.

The distance sealing elements 15 can also be used to connect the cooling devices 4 to the coolant system of the accumulator 1. The forwarding of the coolant from a cooling device 4 in the next cooling device 4 can be done via the holding devices 5, to which they may also have openings 19, as can be seen from Fig. 1. The geometry of these openings 19 corresponds to the geometry of the apertures 14 in the sheet metal elements 7, 8. If the webs 17 of the distance sealing elements 15 are made so wide that they protrude through the sheet metal elements 7, 8, they can protrude into the openings 19 of the holding devices 5 and thus also the fluid-tight connection of the cooling devices 4 to the holding devices 5.

The spacer sealing element 15 is in particular made of a plastic, such as e.g. POM, PA, PA6, PA66.

The embodiments show possible embodiments of the accumulator 1 and the cooling device 4, wherein it should be noted at this point that combinations of the individual variants are possible with each other.

For the sake of order, it should finally be pointed out that for a better understanding of the construction of the accumulator 1 or the cooling device 4, these were not necessarily represented to scale.

REFERENCE LIST 1 accumulator 2 storage module 3 busbar 4 cooling device 5 holding device 6 connecting element 7 sheet metal element 8 sheet metal element 9 edge 10 breakthrough 11 coolant channel 12 coolant inlet 13 coolant outlet 14 breakthrough 15 spacer sealing element 16 edge 17 web 18 breakthrough 19 breakthrough

Claims (6)

claims 1. accumulator (1) with a plurality of memory modules (2) for electric power, wherein between the memory modules (2) each have a cooling device (4) for cooling the memory modules (2) is arranged, each at least a first sheet metal element (7) and a connected thereto second sheet metal element (8), between which at least one coolant channel (11) is formed, and wherein the cooling device (4) has a coolant inlet (12) and a coolant outlet (13), characterized in that the first sheet metal element (7 ) is connected to the second sheet metal element (8) by means of electromagnetic pulse welding or by gluing. Second accumulator (1) according to claim 1, characterized in that the coolant channel (11) in at least one of the two sheet metal elements (7, 8) is formed. 3. Accumulator (1) according to claim 1 or 2, characterized in that between the first and the second sheet metal element (7, 8), a further sheet metal element is arranged. 4. Accumulator (1) according to claim 3, characterized in that in the further sheet metal element openings are formed, which form part of the at least one coolant channel (11). 5. Accumulator (1) according to one of claims 1 to 4, characterized in that in the coolant inlet (12) and in the coolant outlet (13) has a spacer sealing element (15) is inserted. 6. A method for producing a cooling device (4) for an accumulator (1) comprising a plurality of memory modules (2) for electrical energy, between each of which a cooling device (4) for cooling the memory modules (2) is arranged, after which a first sheet metal element ( 7) and a second sheet metal element (8) are provided and interconnected, characterized in that the two sheet metal elements (7, 8) are connected by means of electromagnetic pulse welding or by gluing. For this 2 sheets of drawings