DE102013201887A1 - Battery for supplying electrical driving devices of e.g. electric vehicle with power, has galvanic cell comprising electrode, where physical and electrically conductive contact is obtained between housing and electrode in normal condition - Google Patents

Abstract

The battery (1) has a galvanic cell (3) whose electrode (6) is electrically insulated from a partially electrically conductive housing (2) in a normal condition of the battery by an electrical insulation (7) to obtain direct physical and electrically conductive contact between the housing and the electrode in the normal condition of the battery. The electrical insulation is molded by plastic deformation of the housing and resulting force caused by simultaneous physical contact of the electrical insulation with the housing.

Description

State of the art

Accumulators are used in different areas. For example, the mobile use of accumulators in electrically powered motor vehicles, in particular electric motor vehicles and hybrid electric vehicles, is known, in order to supply electrical power to the accumulators with electric drive devices of the motor vehicles. Furthermore, mobile applications of accumulators are known, inter alia, in the consumer sector, for example in laptops, mobile telephones and the like. In addition, accumulators are also used stationary, for example in wind turbines. For these non-exhaustive applications very high demands are placed on batteries in terms of their reliability, performance and service life.

An accumulator has a housing in which a galvanic cell is arranged. The galvanic cell is usually isolated by electrically non-conductive support elements (so-called "retainer") relative to the housing, wherein the galvanic cell can be supported at the same time on the support elements against the housing. Such a support element may be formed, for example, of plastic.

A housing of a rechargeable battery comprises, for example, a receiving body accommodating the galvanic cell (so-called "can") made of aluminum or steel sheet and a metal lid closing the receiving body (so-called "cap plate"), the cover usually being airtight in the production of a corresponding rechargeable battery is welded to the receiving body. Such a housing is dimensionally stable under low mechanical loads, which means that, for example, it can withstand minor impacts without plastic deformation.

It is known to connect at least one electrode of the galvanic cell via an electrical fuse to the housing of the accumulator. In the case of a short circuit between the electrodes of the galvanic cell, the electrical fuse serves to prevent the housing of the accumulator from being put under electrical voltage.

Disclosure of the invention

The invention relates to an accumulator with an at least partially electrically conductive housing and a housing arranged in the galvanic cell, wherein an electrode of the galvanic cell is electrically connected via an electrical fuse to the housing and another electrode of the galvanic cell whose polarity opposite to the polarity of the electrically conductively connected to the housing electrode is electrically isolated from the housing in a normal state of the accumulator via an electrical insulation, characterized in that the shape of the electrical insulation in a plastic deformation of the housing and a consequent Applying force to the electrical insulation by simultaneous physical contacts with the housing and in the normal state of the accumulator electrically insulated from the housing electrode such that an immediate k rperlicher and electrically conductive contact between the housing and the electrically insulated relative to the housing in the normal state of the battery electrode can be formed.

Under the normal state of the accumulator should be understood in particular a state in which the housing of the accumulator is not plastically deformed by external mechanical force.

Basically, it should not be ruled out that the shape of the electrical insulation changes even with an elastic deformation of the housing due to a mechanical force of a certain magnitude such that a direct physical and electrically conductive contact between the housing and in the normal state of the battery electrically opposite to the Housing insulated electrode can be formed. It is essential, however, that the shape of the electrical insulation changes at least in a plastic deformation of the housing of the accumulator accordingly.

If plastic deformation of the housing of the rechargeable battery according to the invention results in direct physical and electrically conductive contact between the housing and the electrode electrically insulated from the housing in the normal state of the rechargeable battery, the electrodes of the rechargeable cell of the rechargeable battery are short-circuited via the housing. As a result, the electrical fuse of the accumulator, via which an electrode of the galvanic cell in the normal state of the accumulator is electrically conductively connected to the housing, triggered, whereby this electrode is electrically separated from the housing. Thus, the short circuit between the electrodes of the galvanic cell can be eliminated.

In accordance with the invention, in the case of a plastic deformation of the housing of a rechargeable battery, the electrical fuse can thus be targeted of the accumulator to prevent the housing of the accumulator is placed under electrical voltage. In this way, it can be prevented, in particular, that further components of a suitably equipped motor vehicle are subjected to electrical voltage when, for example, they come into physical contact with the accumulator whose housing has been plastically deformed, for example, in the case of an accident of a suitably equipped motor vehicle. Thus, the invention protects the occupants of a suitably equipped motor vehicle in the event of an accident from life-threatening electric shock. Rescuers working at the scene of the accident and fitters involved in the repair of the damaged motor vehicle are also protected from life-threatening electric shocks by the invention.

If the electrical insulation in a plastic deformation of the housing of the accumulator does not change its shape accordingly, the formation of an immediate physical and electrically conductive contact between the housing and in the normal state of the accumulator electrically insulated from the housing electrode would not specifically possible, causing the electrical fuse of the accumulator would most likely not be triggered. Thus, it can not be ruled out in such a rechargeable battery that the housing of the rechargeable battery is put under electrical tension when the housing is plastically deformed.

According to an advantageous embodiment, the electrical insulation comprises at least one insulating element, which is at least partially disposed between at least one adjacent to the in the normal state of the battery relative to the housing electrically insulated electrode disposed housing portion and this electrode. The insulation element can simultaneously serve to support the galvanic cell against the housing.

According to a further advantageous embodiment, the insulation element is rigid. Alternatively, the isolation element could also be flexible.

A further advantageous embodiment provides that at least one predetermined breaking point is formed on the insulating element. In particular, it is provided that the insulating element breaks in a plastic deformation of the housing of the accumulator at the predetermined breaking point, whereby the shape of the electrical insulation changes such that a direct physical and electrically conductive contact between the housing and in the normal state of the accumulator electrically opposite the housing insulated electrode can be formed. The predetermined breaking point can be formed by a material taper. The number of existing predetermined breaking points and the shape of the respective predetermined breaking point can be adapted to the respective technical conditions and requirements.

According to a further advantageous embodiment, at least one projection is arranged on the side of the housing section facing the galvanic cell and / or on the side of the galvanic cell facing the housing section, wherein the projection is subjected to the predetermined breaking point during plastic deformation of the housing and / or wherein the predetermined breaking point is acted upon by plastic deformation of the housing with force against the projection. By the cooperation of projection or projections and predetermined breaking point can be reliably ensured that it comes in a plastic deformation of the housing of the accumulator to a desired change in the shape of the electrical insulation. The number of existing projections and their shape are preferably adapted to the particular technical conditions and requirements.

According to a further advantageous embodiment, the insulating element is designed such that it is at least divided into two parts in the case of plastic deformation of the housing by direct physical contact with the housing section and the galvanic cell. The division into two forms a way of changing the shape of the electrical insulation, which in a simple manner enables direct physical contact and thus electrically conductive contact between the housing and the electrode electrically insulated from the housing in the normal state of the accumulator, in particular because it is possible is that the two parts of the insulating element are displaced after their separation from each other to release at least one gap relative to each other.

In the following, the invention will be explained by way of example with reference to the attached figures with reference to preferred exemplary embodiments, wherein the features illustrated below may represent an aspect of the invention both individually and in various combinations with one another. Show it

1 : a schematic representation of an embodiment of the accumulator according to the invention,

2a a schematic partial representation of a horizontal cross section through a further embodiment of the accumulator according to the invention in a normal state, and

2 B FIG. 2: a schematic partial representation of a cross section of the in. FIG 2 shown accumulator after plastic deformation of the housing of the accumulator.

1 shows a schematic representation of an embodiment of the accumulator according to the invention 1 , The accumulator 1 has an electrically conductive housing 2 made of aluminum or steel. Furthermore, the accumulator 1 one in the case 2 arranged galvanic cell 3 on. An electrode 4 namely, the positive electrode, the galvanic cell 3 is about an electrical fuse 5 electrically conductive with the housing 2 connected. Another electrode 6 That is, the negative electrode, the galvanic cell, is in the normal state of the accumulator shown 1 via an electrical insulation 7 and an electrically insulating gasket 13 opposite the housing 2 electrically isolated.

The electrical insulation 7 comprises a rigidly formed insulation element 8th which at least partially between the electrode 6 and the housing portion arranged adjacent thereto 9 of the housing 2 is arranged.

2a shows a schematic partial representation of a cross section through a further embodiment of the accumulator according to the invention 1 in a normal state of the accumulator, that is, in a state in which the housing 2 not plastically deformed. The isolation element 8th has one to the center of the insulation element 8th increasing material taper, over at least a portion of the perpendicular to the plane of the longitudinal extension of the insulating element 8th runs. By this material taper is on the isolation element 8th a breaking point 10 educated. At the housing section 9 facing side of the galvanic cell 3 or the electrode 6 the galvanic cell 3 is a lead 11 arranged. The lead 11 is complementary to that on the insulating element 8th arranged material taper formed.

2 B shows a schematic partial view of a cross section of the in 2 shown accumulator 1 with plastically deformed housing 2 , The lead 11 is during the plastic deformation of the housing 2 with force against the breaking point 9 been charged. At the same time, the predetermined breaking point 9 in the plastic deformation of the housing 2 with force against the lead 11 have been charged. This depends on the nature of the respective plastic deformation of the housing 2 from or from where on the housing 2 the plastic deformation is done. Due to the immediate physical contact of the insulating element occurring during the plastic deformation 8th with the housing section 9 and the galvanic cell 3 is the isolation element 8th along the predetermined breaking point 9 in two parts 12 and 14 been shared. The shape of the insulation element 8th and thus the electrical insulation 7 has consequently in the plastic deformation of the housing 2 changed so that a direct physical and electrically conductive contact between the housing 2 and the electrode 6 can be trained.

Claims (6)

Accumulator ( 1 ) with an at least partially electrically conductive housing ( 2 ) and one in the housing ( 2 ) arranged galvanic cell ( 3 ), one electrode ( 4 ) of the galvanic cell ( 3 ) via an electrical fuse ( 5 ) electrically conductive with the housing ( 2 ) and another electrode ( 6 ) of the galvanic cell ( 3 ) whose polarity is opposite to the polarity of the electrically conductive with the housing ( 2 ) connected electrode ( 4 ), in a normal state of the accumulator ( 1 ) via an electrical insulation ( 7 ) opposite the housing ( 2 ) is electrically insulated, characterized in that the shape of the electrical insulation ( 7 ) at a plastic deformation of the housing ( 2 ) and a consequent force application of electrical insulation ( 7 ) by simultaneous physical contact with the housing ( 2 ) and in the normal state of the accumulator ( 1 ) electrically opposite the housing ( 2 ) isolated electrode ( 6 ) such that a direct physical and electrically conductive contact between the housing ( 2 ) and in the normal state of the accumulator ( 1 ) electrically opposite the housing ( 2 ) isolated electrode ( 6 ) can be formed. Accumulator ( 1 ) according to claim 1, characterized in that the electrical insulation ( 7 ) at least one isolation element ( 8th ), which is at least partially adjacent to that in the normal state of the accumulator ( 1 ) opposite the housing ( 2 ) electrically isolated electrode ( 6 ) arranged housing section ( 9 ) and this electrode ( 6 ) is arranged. Accumulator ( 1 ) according to claim 2, characterized in that the insulating element ( 8th ) is rigid. Accumulator ( 1 ) according to claim 2 or 3, characterized in that on the insulating element ( 8th ) at least one predetermined breaking point ( 10 ) is trained. Accumulator ( 1 ) according to claim 4, characterized in that on the galvanic cell ( 3 ) facing side of the housing portion ( 9 ) and / or on the housing section ( 9 ) facing side of the galvanic cell ( 3 ) at least one projection ( 11 ), wherein the projection ( 11 ) with plastic deformation of the housing ( 2 ) with force against the predetermined breaking point ( 10 ) is applied and / or wherein the predetermined breaking point ( 10 ) with plastic deformation of the housing ( 2 ) with force against the projection ( 11 ) is applied. Accumulator ( 1 ) according to one of claims 2 to 5, characterized in that the insulating element ( 8th ) is designed such that when plastic deformation of the housing ( 2 ) by a direct physical contact with the housing section ( 9 ) and the galvanic cell ( 3 ) at least divided into two.

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