DE102012215446A1 - Storage cell for energy storage unit of e.g. hybrid car, has contact region for attaching housing to cooling element, and insulation layer applied outside housing in sections of connection region supplementary to contact region - Google Patents

Abstract

The cell (1) has an electrochemical or electrostatic storage element (8) arranged in an outer housing, and two terminals (9, 10) for connecting a load with that storage element. Side surfaces (4, 5) of the outer housing are formed as a contact region for attaching the housing to a cooling element. The housing has a connection region in which the housing comprises an assembly seam/surface (7) for closing the housing. An insulation layer is applied outside the housing in sections of the connection region supplementary to the contact region. An independent claim is also included for an energy storage unit.

Description

The invention relates to a memory cell for an energy store for a hybrid or electric vehicle, to a method for producing a memory cell, and to an energy store having a memory cell.

Various memory cells are known in the prior art. For example, it is known to form memory cells around with a lid and a housing. The lid is usually connected by a weld with the rest of the housing. The lid and the housing are made of metal e.g. made of aluminium. In the housing, a storage element is arranged, through which the energy is stored. Also known are prismatic memory cells, which have a relatively small thickness compared to the total size of the cell. Due to the small thickness such cells can be cooled very evenly. As a result, the temperature across the memory cell varies only by less than 5K, or even by less than 3K, thereby increasing the life of the cell.

In addition, prismatic memory cells are known, which instead of a solid housing an outer shell of a composite foil, e.g. an aluminum composite foil having. Such memory cells are also known as "soft packs".

In the aforementioned variants of memory cells, it would be desirable to increase the energy density with which electrical energy can be stored in the memory cell. In the case of the previously known memory cells, however, distances between adjacent cells are usually necessary in order to achieve a sufficient dielectric strength (up to 4 kV).

It is also, e.g. of films of softpacks known to form the cells with an insulating layer. However, the insulation is not sufficiently reliable, because in particular at joints of different film or housing parts can lead to voltage breakdowns. Although the reliability can be improved by thicker insulating layers, but thereby the cooling of the memory cell is deteriorated, since the insulating layers usually have a relatively poor heat conduction.

The object of the invention is to propose a memory cell for an energy storage device for a hybrid or electric vehicle, which allows storage of energy with high energy density and at the same time can be cooled as efficiently as possible. Further objects of the invention are to propose a method for producing a memory cell and an energy store with a memory cell.

This object is achieved by a memory cell, by a method and by an energy store according to the independent claims. Advantageous developments and refinements emerge with the features of the subclaims.

As is known from the prior art, memory cells according to the invention comprise an outer shell, at least one storage element arranged in the outer shell, and at least two terminals for connecting a consumer to the at least one storage element. The outer shell further includes a contact area for connection to a cooling element and a connection area in which the outer shell has a connection seam or surface for closing the outer shell.

According to the invention, at least on parts of the connection region, an insulation layer which is additional in comparison to the contact region is applied externally to the outer shell. By means of this additional insulation layer it is prevented that a dielectric strength of the insulation of the memory cell is reduced by the connecting seam or surface. At the same time, cooling of the memory cell is not complicated because the additional insulation layer is not arranged in the contact region to the heat sink.

Particularly preferably, the additional insulating layer compared to the contact area completely covers the connecting seam or an end of the connecting surface facing the outside of the outer shell.

The storage element may optionally be an electrochemical storage element (e.g., a lithium-ion cell, lead-acid battery, nickel-metal hybrid, or nickel-zinc cell) or an electrostatic storage (e.g., a double-layer capacitor).

In one embodiment of the invention, the storage element is designed to extend flat in one plane. By this is meant that a dimension of the memory element within the plane is at least five times, preferably at least ten times and more preferably at least twenty times as large as a dimension in the direction orthogonal to the plane. In embodiments having such a flat storage element, the contact region of the outer shell to the plane has substantially parallel side faces for attachment to a heat sink. The connection region may preferably at least partially circulate the contact region in such embodiments.

In such a planar design of the memory element, the memory cell may be preferably formed prismatic.

In an alternative embodiment, the outer shell is cylindrical. At least one of the base surfaces of the cylinder is in this case designed as a housing part which is separate from a jacket surface of the cylinder, this separate housing part being connected (preferably welded) by the connecting region to the jacket surface.

In prismatic cells in the embodiment of the housing as a soft pack, the outer shell may comprise a film, in particular a composite film and particularly preferably an aluminum composite film. The composite film may have, for example, a first plastic layer as the first layer, a metal layer (for example aluminum layer) as a middle layer, and a second plastic layer as a third layer facing the inside of the memory cell. The first layer may in particular be made of nylon (polyamide) and the third layer in particular of PP (polypropylene). In embodiments with an outer shell formed from foil, the foil may be connected, for example, along a peripheral edge. Thus, two films can be applied to one another, the storage element being arranged between the two films, and the two film layers being connected to one another in an edge region surrounding the storage element.

The outer shell may also consist of a rigid material. The outer shell may comprise a lid and a vessel. The lid may be particularly preferably welded to the vessel.

The additional insulation layer is preferably made of a material with high dielectric strength. In particular, the dielectric strength can be greater than 10 kV / mm. Particularly suitable as materials for the insulating layer are plastics such as polyurethane or polypropylene. The insulating layer may also include a filler such as alumina, alumina particles, plastic and especially polymer particles, ceramic particles or nanoparticles. The filler may also be an oxide or nitride, in particular a metal oxide or metal nitride. The filler is electrically insulating.

In a method for producing a memory cell, the insulation layer may particularly preferably be connected in a materially bonded manner to the connection region of the outer shell. For this purpose, the insulating layer can be glued, for example, by means of an adhesive layer or melted by heating to the connection region.

In further embodiments, the insulating layer is sprayed or produced by immersing the connecting region of the memory cell in a material forming the insulating layer. Likewise, the outer shell of the memory cell can be completely immersed in the insulating layer forming material, wherein the contact portion of the outer shell is protected by suitable means, such as an applied protective layer, from sticking to the insulating layer forming material.

In a particularly preferred embodiment, the insulating layer is formed so that it has another function in addition to its insulating effect. For example, the insulating layer may be formed integrally with a fastening element for attaching the memory cell to a heat sink.

An energy store according to the invention comprises at least one memory cell as described above and at least one heat sink. The memory cell is applied to the contact area on the heat sink. Between the memory cell and the heat sink, a heat conducting pad, thermal paste and / or mica can be arranged.

Particularly preferably, the energy store can be designed to provide a maximum power of at least 10 kW.

The energy store is preferably used as part of a hybrid or electric vehicle. Accordingly, the invention also relates to a drive train for a hybrid or electric vehicle with a previously designed as energy storage.

Embodiments of the invention are explained below with reference to the figures. It shows

1 a perspective view of an embodiment of a memory cell prior to the application of an additional insulating layer in the connection region between the lid and the housing,

2 a perspective view of the memory cell 1 after applying the additional insulating layer,

3 an embodiment of a round cell before the application of the additional insulating layer,

4 the round cell 3 after applying the additional insulating layer,

5 a designed as a prismatic soft pack memory cell with applied insulating layer in front and side view,

6 a side view of a section of an energy storage with the memory cell 5 .

7 a side view of a section of an energy storage device with a further embodiment of a memory cell and

8th a sectional view through the edge region of a memory cell according to one of 5 to 7 ,

In 1 is a memory cell 1 shown in prismatic design, which has an outer shell with a cell housing 2 and a lid 3 includes. Both the cell case 2 as well as the lid 3 consist of an insulating coated sheet. faces 4 . 5 of the housing 2 serve as a contact area for attachment to a heat sink. In addition, the housing has 2 a waisted area 6 on.

The housing 2 and the lid 3 are along one the lid 3 circumferential weld 7 connected with each other. In the case 2 is a cell wrap 8th arranged from a wound electrode pair and separator. The cell wrap 8th is with arresters 9 . 10 connected, which pass through the lid by means of an insulating bushing.

In such cells, as they are already known from the prior art, forms the weld 7 a weak point in the isolation of the cell, which increases the risk of voltage breakdown. If the cell housing and the lid consist, for example, of insulating coated metal sheets, the insulating coating can be damaged during welding in the region of the weld seam.

To remedy this vulnerability, in this embodiment, the weld 7 with a coating 11 covered, like this in 2 is shown. To produce the coating 11 In the present embodiment, a two-component mixture of a plastic material is applied, which is then cured. Voltage breakdown along the weld 7 are thus reliably avoided.

In the 3 and 4 is a cylindrical memory cell 12 shown. The memory cell 12 has an outer shell consisting of a housing 13 and a lid 14 on. Also in this embodiment, the lid 14 with the housing 13 through a weld 15 connected. As in 4 can be seen, in this embodiment, the entire lid and the weld with a coating 16 covered. To produce the coating 16 a lacquer is applied, which then polymerizes or otherwise hardens. The paint used is added as a filler alumina. The cooling of the memory cell 12 takes place over the lateral surface 17 of the cylindrically shaped housing 13 , As in the previous embodiment, an electrode coil is also in the housing here 18 arranged with separator, which with through the lid 16 passed through arresters 19 connected is.

In 5 is a trained as a soft pack cell 20 shown in front view (left) and side view (right). The memory cell 20 comprises two composite film layers 21 . 22 between which an electrode stack with separator which can not be recognized in the figure is arranged. The two foil layers 21 . 22 consist of an aluminum composite foil having at least one insulating layer and an aluminum layer. The two layers 21 . 22 are in a peripheral region, which surrounds the region of the electrode stack, not shown, arranged flat on each other and connected to each other by means of an adhesive bond. To avoid being along cutting edges 23 on the edge of the layers 21 . 22 There is an increased risk of voltage breakdowns along the outer edges of the laminar connection between the two layers 21 . 22 an insulating layer 24 applied.

In 6 is a section of an energy store 25 represented the cell 20 and a heat sink 26 having. The memory cell 20 lies with its front surface on the heat sink 26 at. The additional insulating layer 24 is thus only in one area of the memory cell 20 arranged, which is not on the heat sink 26 is applied and thus does not contribute significantly to the cooling. Of course, larger energy storage from a variety of heat sinks 26 and cells 20 be assembled. The cells 20 can then optionally only one side or on both sides of a heat sink 26 issue.

A section of a modified variant of an energy storage 27 is in 7 shown. This variant of the energy storage differs from the energy storage 6 in that the insulating layer 28 the memory cell 29 integral with a fastener for attachment to the heat sink 30 is trained. The fastener 31 has a passage opening 32 on, in the one shaping 33 of the heat sink 30 engages, thereby forming a positive connection, ie a connection by engaging behind between the cell 29 and the heat sink 30 is formed.

In the in 8th illustrated sectional view in which a section through the edge of one of the memory cells from the 5 to 7 2, it can be seen that the memory cell comprises two composite foils, each consisting of a middle layer 34 made of aluminum and two outer polymer layers 35 consist. The two composite films are at the outer edge by means of an adhesive layer 36 connected and with the insulating layer 28 coated. In addition, in the figure, the electrode set is arranged between the composite foils 37 to recognize with separators on average.

Claims (11)

Memory cell ( 1 ; 12 ; 20 ; 29 ) for an energy store ( 25 ; 27 ) for a hybrid or electric vehicle, comprising an outer shell, at least one outer or outer electrochemical or electrostatic storage element ( 8th ; 18 ) and at least two ports ( 9 . 10 ; 19 ) for connecting a consumer to the at least one memory element ( 8th ; 18 ), wherein the outer shell has a contact area ( 4 . 5 ; 17 ) for connection to a cooling element and a connection region, in which the outer shell is a connecting seam or surface ( 7 ; 15 ; 23 ) for closing the outer shell, characterized in that, at least in parts of the connection area, a 4 . 5 ; 17 ) additional insulation layer ( 11 ; 16 ; 24 ; 28 ) is applied externally to the outer shell. Memory cell ( 1 ; 12 ; 20 ; 29 ) according to claim 1, characterized in that the memory element ( 8th ; 18 ) is formed extending flat in a plane and the contact area ( 4 . 5 ) of the outer shell to the plane substantially parallel side surfaces ( 4 . 5 ) for attachment to a heat sink, wherein the connection region at least partially surrounds the contact region. Memory cell ( 1 ; 12 ; 20 ; 29 ) according to claim 2, characterized in that the outer shell is formed substantially prism-shaped. Memory cell ( 1 ; 12 ; 20 ; 29 ) according to claim 1, characterized in that the outer shell is cylindrical, wherein at least one base surface is formed separately from a lateral surface of the outer shell and wherein the separately formed base surface is connected by the connecting portion with the lateral surface. Memory cell ( 1 ; 12 ; 20 ; 29 ) according to one of the preceding claims, characterized in that the outer shell consists at least partially of a composite foil, preferably aluminum composite foil. Memory cell ( 1 ; 12 ; 20 ; 29 ) according to one of the preceding claims, characterized in that the outer shell of a plurality of assembled individual parts, such as a lid and a vessel or a plurality of assembled films is constructed. Memory cell ( 1 ; 12 ; 20 ; 29 ) according to one of the preceding claims, characterized in that the additional insulation layer ( 11 ; 16 ; 24 ; 28 ) has a material with a dielectric strength of more than 10 kV / mm, preferably a plastic such as polyurethane or polypropylene. Memory cell ( 1 ; 12 ; 20 ; 29 ) according to one of the preceding claims, characterized in that the insulating layer ( 11 ; 16 ; 24 ; 28 ) is materially connected to the connection region. Memory cell ( 1 ; 12 ; 20 ; 29 ) according to one of the preceding claims, characterized in that the insulating layer ( 28 ) in one piece with a fastening element ( 31 ) for mounting the memory cell ( 1 ; 12 ; 20 ; 29 ) is formed on a heat sink. Method for producing a memory cell ( 1 ; 12 ; 20 ; 29 ) according to one of the preceding claims, characterized in that the insulating layer is glued as a finished layer or that the insulating layer is sprayed or that the insulating layer is produced by at least partial immersion of the edge region in a material forming the insulating layer. Energy storage ( 25 ; 27 ) for a hybrid or electric vehicle comprising at least one memory cell ( 1 ; 12 ; 20 ; 29 ) according to one of claims 1 to 9 and at least one heat sink, wherein the contact region of the memory cell ( 1 ; 12 ; 20 ; 29 ) is attached fitting to the heat sink.

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