DE102016203773B4 - Device for holding and cooling at least one electrical energy storage device, energy storage device - Google Patents

Abstract

Device (3) for holding and cooling at least one electrical energy store (2), with a cooling plate (4) on which at least one pair (7) of two holding walls (8) is held at one end in a first distance (A1), between which the at least one energy store (2) can be arranged in such a way that it is in surface contact contact at least with the retaining walls (8), the retaining walls (8) being pressed / pressed against the energy store (2) by spring force to ensure contact contact, wherein the retaining walls (8) are at least partially elastically deformable and / or elastically mounted on the cooling plate (4), and that the retaining walls (8) in their relaxed state at the other end a second distance (A2) to each other, which is smaller than the first Distance.

Description

The invention relates to a device for holding and cooling of at least one electrical energy storage, with a cooling plate, which are held at one end at a first distance to each other at least in a pair of two retaining walls, between which the at least one energy storage can be arranged such that it is in planar Touch contact is at least with the retaining walls, wherein the retaining walls to ensure the contact contact by spring force against the energy storage are pressed / pressed.

Furthermore, the invention relates to an energy storage arrangement having at least one energy store and with a device for holding and cooling the at least one energy store.

Devices and arrangements of the type mentioned are known from the prior art. With the increasing electrification of drive devices of motor vehicles, the requirements for the cooling of electrical energy storage devices are also increasing. Not only must it be ensured that the energy storage devices do not exceed a maximum temperature in order not to be damaged, but rather it must be ensured that the temperature of the energy storage device moves in a favorable range in order to ensure optimum utilization of the electrical energy stored therein can. The performance of such energy storage is highly dependent on temperature, which is why it is also of interest to keep it in the presence of a plurality of energy storage as possible at the same operating temperature value. For example, the patent discloses this EP 2 200 109 B1 a holding and cooling device for an energy store, in which two holding elements are arranged on a cooling plate for each energy storage, between which the energy storage can be arranged. In this case, a pressure on the holding elements to be exercised, which urges the holding elements against the energy storage, so that a contact between energy storage and holding element for dissipating the heat of the energy storage is ensured in the holding element and thus in the cooling plate even with vibration or the like. The pressure is applied by spring force of a spring band, which surrounds the holding elements outside and thus pushes together or in the direction of the energy storage.

From the publication DE 28 25 126 B1 For example, there is known a tension member for holding lead acid battery packs for assembly into a block assembly in which the tension member is comprised of two closely spaced, preformed leaf springs. From the publication US 2005/0016894 A1 Further, a clamping cartridge for releasably clamping a plurality of plate-shaped elements in a substantially parallel and spaced apart manner.

The invention has for its object to improve a device of the type mentioned in such a way that a simple installation of or the energy storage is guaranteed to the device without increasing the cost or production cost of the device.

The problem underlying the invention is achieved by a device having the features of claim 1. This has the advantage that the energy storage can be easily inserted into the device, with a subsequent or additional attachment of a spring element to ensure the surface touch contact omitted. As a result, both the number of parts and the production costs are reduced. The inventive device is characterized in that the retaining walls are at least partially elastically deformable and / or elastically displaceable on the cooling plate, and that the retaining walls in their relaxed state anderendig have a second distance from each other, which is smaller than the first distance. Thus, the retaining walls are closer to each other at their ends remote from the cooling plate than to the cooling plate. In a side view, the retaining walls are thus arranged in the manner of an inverted V on the retaining plate. Now, if the energy storage is pushed between the retaining walls, they are bent apart at their free ends under elastic deformation of the retaining walls themselves and / or the elastic mounting, so that the energy storage between the retaining walls can be inserted. Due to the elastic deformation while the retaining walls are resiliently biased so that a spring force is generated, which acts in each case in the direction of the energy storage. As a result, the retaining walls during insertion of the energy storage are pressed laterally against the energy storage, whereby the surface contact contact is ensured in a simple and cost-effective manner.

According to a preferred embodiment of the invention it is provided that the retaining walls are formed flat and inclined in its relaxed position held on the cooling plate. Thus, the retaining walls are structurally simple in an advantageous manner and in particular may be identical, so that the production cost is further reduced. Due to the planar design also the insertion of the energy storage between the two retaining walls of the pair is facilitated because no complicating the insertion Projections or the like are formed on the retaining walls.

Furthermore, it is preferably provided that the first distance corresponds to a width of the energy store. If the energy store is thus completely inserted between the pair of retaining walls, in particular so that the energy store abuts one-end between the retaining walls on the cooling plate, the retaining walls are aligned perpendicular to the cooling plate.

The prerequisite for this is, of course, that the energy store has parallel side walls. In the region of the cooling plate thus no or an extremely small spring force is exerted on the energy storage, while at the other end a correspondingly high spring force acts between the retaining walls on the energy storage. Because the first distance corresponds at least to the width of the energy store, it is ensured that the energy store can be pushed up to the cooling plate. As a result, a further touch contact is ensured, which improves the heat dissipation from the energy storage.

According to a preferred embodiment of the invention, it is provided that the height of the retaining walls at least substantially equal to the height of the energy storage: Thus, the retaining walls over the entire height of the energy storage and possibly beyond, so that the greatest possible contact between the energy storage and retaining walls is guaranteed.

Furthermore, it is preferably provided that the retaining walls are made of a thermally conductive material. Thus, the heat is advantageously transferred from the retaining walls in the cooling plate. In particular, the retaining walls are made of plastic or metal.

Furthermore, it is preferably provided that a plurality of pairs of retaining walls are arranged side by side on the cooling plate. As a result, a plurality of energy stores can be arranged on the cooling plate as described above and can be thermally connected. This results in the simple advantage that the pairs of retaining plates can be arranged close to each other, without coming into conflict with each other, and that thereby the number of energy storage is arbitrarily scalable.

Furthermore, it is preferably provided that the adjacent retaining walls of two pairs are arranged V-shaped on the cooling plate in the relaxed state. Due to the V-shaped arrangement, there is the advantage that the retaining walls can easily be pushed outward during the insertion of the energy store between a respective pair of retaining walls. It is particularly preferred that in the prestressed state, ie when an energy store or an energy store is used in the two adjacent pairs, a distance between the adjacent retaining walls remains, whereby manufacturing tolerances compensated and the insertion of multiple energy storage is facilitated in adjacent pairs.

According to an advantageous development of the invention, provision is made for a respective thermally insulating layer to be arranged between the adjacent retaining walls of two pairs. As a result, the advantage is achieved that the temperatures of the adjacent energy storage do not influence each other through the retaining walls. Rather, this ensures that the heat is dissipated by the respective energy storage by standing in contact with the holding wall in the cooling plate. This ensures the connection of the respective energy store to the cooling plate or the heat dissipation into the cooling plate. In particular, in a case of damage, for example in the case of an internal short circuit of an energy store, the thermal load of an adjacent energy store is thus reduced.

In particular, it is provided that the thermally insulating layer is formed by at least one arranged between the V-shaped retaining walls film. The film is simple and inexpensive to produce and can be arranged during assembly between the adjacent retaining walls. For example, the foil is attached to one of the two retaining walls, so that when energy stores are inserted into the adjacent pairs of retaining walls, the foil rests against both the one and the other retaining wall between the adjacent pairs of retaining walls. Optionally, each of the adjacent retaining walls of the two pairs can each be assigned a corresponding foil. Conveniently, the respective film extends over the entire width and height of the respective retaining wall. In particular, it is provided that the respective film is designed to be flexible, so that it can be mitverformt in a deformation of the retaining wall and in particular does not hinder the deformation of the respective retaining wall.

According to an advantageous development of the invention it is additionally provided that the cooling plate and / or the retaining walls each have at least one coolant channel for a conveyable coolant. As a result, active heat dissipation from the energy store (s) is ensured. In particular, it is provided that at least the cooling plate is provided with one or more coolant channels, so that the dissipated by the retaining walls in the cooling plate heat safely can be removed. As a result, the performance of the energy storage is increased overall.

The energy storage device according to the invention with the features of claim 11 is characterized by the inventive design of the device for holding and cooling of the energy storage or. This results in the already mentioned advantages. Further advantages and preferred features and combinations of features emerge in particular from the previously described and from the claims.

• 1 eine Energiespeicheranordnung mit einem Energiespeicher und einer Einrichtung zum Halten und Kühlen des Energiespeichers und
• 2 die Energiespeicheranordnung mit dem durch die Einrichtung gehaltenen Energiespeicher.

In the following, the invention will be discussed with reference to the drawing. Show this

• 1 an energy storage device having an energy storage device and a device for holding and cooling the energy storage device and
• 2 the energy storage device with the held by the device energy storage.

1 shows in a simplified representation of an energy storage device 1 with an electrical energy storage 2 and a facility 3 for holding and cooling the energy storage 2 , The energy storage arrangement 1 is for example designed to be used in a motor vehicle with an electric drive. In order to operate the energy storage 2 to be able to keep at an advantageous operating temperature, is the device 3 provided, which the energy storage 2 On the one hand locked in the vehicle and on the other hand in an advantageous manner would be from the energy storage 2 dissipates.

The device 3 has a cooling plate 4 on, the one or more coolant channels 5 has, through which a particular liquid coolant is conveyed through, such as by an arrow 6 displayed.

At the cooling plate 4 are several couples 7 of retaining walls 8th , in particular holding plates arranged. Einendig are the retaining walls 8th on the cooling plate 4 held. In particular, the retaining walls 8th positive and / or cohesive with the cooling plate 4 connected. The retaining walls 8th are each formed elastically deformable and are in their relaxed, in 1 shown state, even. The retaining walls 8th are doing so on the cooling plate 4 arranged so that they are inclined to this at an angle not equal to 90 °. Here are the retaining walls 8th a couple 7 each inclined to each other so that the retaining walls 8th a couple 7 at her the cooling plate 4 facing end a first distance A1 to each other, and on the other of the cooling plate 4 opposite end a second distance A2 which is smaller than the first distance A1 ,

The couple 7 are arranged so close to each other that the adjacent retaining walls 8th the neighboring couples 7 V-shaped are arranged to each other. At her the cooling plate 4 facing end are the adjacent retaining walls 8th the neighboring couples 7 in particular to each other, as in 1 shown.

The first distance A1 corresponds to a width B of the energy storage 2 , The energy storage 2 is mounted by placing it between the retaining walls 8th a couple 7 is inserted. These are the retaining walls 8th of the couple 7 at her the cooling plate 4 the opposite end elastically pushed outward or bent, so that the distance A2 enlarged until he at least the width B of the energy store 2 matches, so that this between the retaining walls 8th can be inserted, as by an arrow 9 shown. Because the first distance A1 the width B corresponds, the energy storage 2 with his face 10 to the cooling plate 4 between the retaining walls 8th be pushed in, so he with the end face 10 on the cooling plate 4 and with its side surfaces respectively on the holding walls 8th of the couple 7 is in touch.

2 shows the mounted position or the installation situation of the energy storage 2 between the one pair 7 of retaining walls 8th , Due to the favorable choice of distances A1 and A2 , which in particular by the orientation of the retaining walls 8th be achieved, it is achieved that the elastically bent retaining walls 8th now by their inherent elasticity with a spring force against the side walls of the energy storage 2 be urged. The energy storage 2 is thus between the holding walls 8th of the couple 7 braced and thus in particular frictionally engaged between the retaining walls 8th locked. At the same time is achieved due to the advantageous embodiment that the retaining walls 8th each flat on the side walls of the energy storage 2 abutment, so that a surface touch contact is ensured, by which heat from the energy storage in an advantageous manner 2 in the respective retaining wall 8th can be transferred. The energy storage 2 is thus between the retaining walls 8th of the couple 7 clamped, whereby by the spring force or bias a good thermal connection of the energy storage 2 to the cooling system or the cooling plate 4 is guaranteed.

The retaining walls 8th are made in particular of a thermally conductive material, such as plastic and / or metal, through which the heat advantageous to the cooling plate 4 is dissipated. The retaining walls 8th and / or their connection to the cooling plate 4 are suitably designed such that the retaining walls 8th from the in 1 shown inclined position in a direction perpendicular to the cooling plate 4 aligned position, as in 2 shown to be elastically displaceable / deformable when an energy store 2 between the retaining walls 8th a couple 7 is plugged in, as in 2 shown.

Optionally, it is provided that between the adjacent retaining walls 8th from two adjacent pairs 7 in each case at least one thermally insulating layer 11 is introduced, in particular before the energy storage 2 between two retaining walls 8th a couple 7 is inserted. The thermally insulating layers 11 are doing in the V-shaped space between two adjacent retaining walls 8th from two adjacent pairs 7 used as in 1 and 2 shown by way of example. The layers 11 are formed in particular by thermally insulating and optionally also electrically insulating films, in particular to one of the retaining walls 8th be applied or applied. Will between the holding walls 8th from two adjacent pairs 7 one energy store each 2 used, then the thermally insulating layer 11 each between the adjacent walls 8th the neighboring couples 7 strained, so the layer 11 prevents heat from an energy store 2 through the retaining walls 8th in the neighboring energy storage 2 can go over. Through the thermally insulating layers 11 ensures that the heat by means of retaining walls 8th the cooling plate 4 is added. This ensures that the heat from the energy storage arrangement 1 safely in the cooling plate 8th is passed to there by means of the coolant from the energy storage device 1 to be dissipated. A thermal load of neighboring energy storage 2 one another is thus prevented.

LIST OF REFERENCE NUMBERS

1

Energy storage device

2

energy storage

3

Facility

4

cooling plate

5

Coolant channel

6

arrow

7

Pair

8th

retaining wall

9

arrow

10

face

11

layer

Claims (11)

Device (3) for holding and cooling at least one electrical energy store (2), with a cooling plate (4) on which at least one pair (7) of two holding walls (8) is held at one end in a first distance (A1), between which the at least one energy store (2) can be arranged in such a way that it is in surface contact contact at least with the retaining walls (8), the retaining walls (8) being pressed / pressed against the energy store (2) by spring force to ensure contact contact, wherein the retaining walls (8) are at least partially elastically deformable and / or elastically mounted on the cooling plate (4), and that the retaining walls (8) in their relaxed state at the other end a second distance (A2) to each other, which is smaller than the first Distance. Setup after Claim 1 , characterized in that the retaining walls (8) formed flat and inclined in its relaxed position on the cooling plate (4) are held. Device according to one of the preceding claims, characterized in that the first distance (A1) corresponds to a width (B) of the energy store (2). Device according to one of the preceding claims, characterized in that the height of the retaining walls (8) at least equal to the height of the energy store (2). Device according to one of the preceding claims, characterized in that the retaining walls (8) are made of a thermally conductive material. Device according to one of the preceding claims, characterized in that a plurality of pairs (7) of retaining walls (8) on the cooling plate (4) are arranged side by side. Device according to one of the preceding claims, characterized in that adjacent retaining walls (8) of two adjacent pairs (7) are arranged in a V-shape relative to one another on the cooling plate (4). Device according to one of the preceding claims, characterized in that between two adjacent retaining walls (8) of two adjacent pairs (7) in each case at least one thermally insulating layer (11) is arranged. Device according to one of the preceding claims, characterized in that the thermally insulating layer (11) by an intermediate the V-shaped arranged retaining walls (8) arranged film is formed. Device according to one of the preceding claims, characterized in that the cooling plate (4) and / or the retaining walls (8) each have at least one coolant channel (5) for a conveyable coolant. Energy storage arrangement (1) with at least one energy store (2) and with a device (3) for holding and cooling the energy store (2), characterized by the formation of the device according to one of Claims 1 to 10 ,

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