DE102018209186A1 - Battery unit with a plurality of battery cells and use of such a battery unit - Google Patents

Abstract

The invention relates to a battery unit comprising a plurality of battery cells (2) which are completely accommodated in a housing (3) of the battery unit (1), which is designed to thermally insulate the plurality of battery cells (2), a first housing wall ( 31) of the housing (3) is designed as a vacuum insulation panel element (310) and that a second housing wall (32) of the housing (3) is designed as a supported vacuum insulation element (320).

Description

State of the art

The invention relates to a battery unit having a plurality of battery cells according to the preamble of the independent claim.

Furthermore, the invention also relates to the use of such a battery unit.

From the prior art it is known that battery modules can consist of a plurality of individual battery cells, which can be interconnected in series and / or in parallel in an electrically conductive manner.

Furthermore, a plurality of battery modules are arranged together to form a higher-order unit of the battery pack.

Such a battery pack may include other components such as a battery management system or a thermal management system.

In particular, battery cells with a solid electrolyte are operated at an operating temperature with a value in the range between 50 ° C and 80 ° C.

For such battery cells, which are also called medium-temperature battery cells, to be able to achieve optimum performance with a solid electrolyte, they should be correspondingly insulated or heated in order to achieve a working temperature of 50.degree. C. to 80.degree.

For this purpose, it is known from the prior art that battery modules or battery packs may further comprise a thermal insulation or an external heating element or an external cooling element, which may be arranged on the level of the battery pack or on the battery module level.

In particular, to maintain the working temperature between 50 ° C and 80 ° C appropriately sized insulation advantageous.

Disclosure of the invention

A battery unit with the features of the independent claim offers the advantage that a reliably thermally insulated battery unit can be provided, which in particular also has a small or minimized number of thermal bridges to an environment of the battery unit.

For this purpose, a battery unit is provided, which has a plurality of battery cells.

The plurality of battery cells is completely accommodated in a housing of the battery unit.

The housing of the battery unit is formed to a thermal insulation of the plurality of battery cells.

According to the invention, a first housing wall of the housing is designed as a vacuum insulation panel element and a second housing wall of the housing is designed as a supported vacuum insulation element.

The measures listed in the dependent claims advantageous refinements and improvements of the independent claim device are possible.

Battery enclosures comprising thermal insulations usually have the disadvantage that the greatest amount of heat is transferred from the interior of the housing to the environment via the surface of pure insulation, and the next largest proportion of heat is transmitted via mechanical and / or electrical feedthroughs from inside the housing Housing is transferred to the environment.

By means of a battery unit according to the invention, it is possible to provide reliable insulation by the combination of the first housing walls designed as a vacuum insulation panel element and the second housing walls in the form of a supported vacuum insulation element.

A vacuum insulation panel element is to be understood here as an insulation element and in particular an insulation board element within which a vacuum is arranged, so that a comparable high insulation effect can be formed.

In particular, vacuum insulation panel elements comprise a core and a shell enclosing the core, and often additionally a so-called getter.

The core is usually formed as a porous or loose material and serves as a support for the vacuum and can be formed, for example, as an open-cell plastic foam, microfiber material, perlite or fumed silica.

The sheath further serves to prevent gas from entering the vacuum insulation panel element can reach, so that the vacuum is maintained and can be formed, for example, as an aluminum composite film, metallized plastic film or vaporized aluminum.

The getter can be designed as an additional component and serve to bind hydrogen or other gas molecules in order to maintain the vacuum can.

Under a supported vacuum insulation element is to be understood at this point an insulating element and in particular an insulation panel member within which a vacuum is arranged, so that a comparatively high insulation effect can be formed.

Such a supported vacuum insulation element comprises in particular a core and a shell enclosing the core.

It is possible that the core, like the vacuum insulation panel element, also includes such fillers.

The shell is designed to hold the vacuum upright.

The difference with the vacuum insulation panel member is that the supported vacuum insulation member is formed to be comparatively mechanically stable.

For this example, the shell may be formed of a mechanically comparable stable material or the supported vacuum insulation element may further comprise additional mechanical support elements.

For example, the supported vacuum insulation element may be formed from two half-shells, which are interconnected to form a vacuum.

It should be noted at this point that a vacuum insulation panel element has the advantage that such elements can have a comparatively low weight and a comparatively small wall thickness.

As a result, vacuum insulation panel elements form in particular only comparably small thermal bridges.

Vakuumisolationspaneelelement are usually not mechanically resilient, so that mechanical feedthroughs are required for holding elements to connect the battery unit, for example, with the underbody of a vehicle, whereby additional thermal bridges are formed.

It should be noted at this point that a supported vacuum insulation element has the advantage that such elements are comparable mechanically strong.

Supported vacuum insulation element further offer the advantage that, for example, can be dispensed with mechanical feedthroughs for a holder, for example on a vehicle, since the insulation element itself is mechanically strong, and thus can be clamped against an underbody of a vehicle.

In comparison to Vakuumisolationspaneelelement supported vacuum insulation elements usually have a higher weight and are also more expensive.

A battery unit according to the invention, which has both a vacuum insulation panel element and a supported vacuum insulation element, can thus overcome the respective disadvantages and combine the advantages.

In particular, while the weight of the battery unit can be reduced and the insulation effect can be improved.

Advantageously, the vacuum insulation panel element comprises a shell which is formed of aluminum and has a wall thickness of less than 200 micrometers.

For example, the shell of the vacuum insulation panel element may be formed from a composite of aluminum foils and have a wall thickness of in particular 100 micrometers.

The casing of the vacuum insulation panel element is preferably designed as a film.

Furthermore, it is also possible that the vacuum insulation panel element is formed with aluminum vapor-deposited or coated.

Thereby, it is advantageously possible to form a vacuum insulation panel element which forms only a comparatively small thermal bridge between the battery cells in the interior of the housing and an environment of the battery unit.

Conveniently, the supported vacuum insulation element comprises a shell formed of stainless steel with a wall thickness between 0.5 millimeters and 1 millimeter.

This makes it reliably possible to form a mechanically stable supported vacuum insulation element.

According to an advantageous aspect of the invention, the supported vacuum insulation element may further be designed for attachment to a vehicle.

Furthermore, the supported vacuum insulation element may also comprise a holding element designed for attachment to a vehicle.

This makes it possible to dispense largely with bushings for holding elements by the respective insulation element.

It is possible, for example, that the battery unit can be connected to a subfloor of a vehicle.

It is expedient if the plurality of battery cells is prismatic in each case.

Prismatic battery cells offer the advantage that they can be arranged comparably tight and compact.

In this case, the prismatic battery cells are preferably arranged adjacent to one another in a longitudinal direction of the battery unit.

Furthermore, it is also possible to form the battery cells as so-called bag cells, which may also be referred to as "pouch cells" to English.

In this case, the bag cells are preferably arranged adjacent to one another in a longitudinal direction of the battery unit.

Expediently, the first housing wall formed as a vacuum insulation panel element is arranged on one of the plurality of battery cells jointly formed largest side surface.

This offers the advantage that the largest side surface formed jointly by the plurality of battery cells can be reliably isolated, as a result of which comparatively little heat is transferred to the environment via this largest side surface.

Furthermore, it is also expedient if the first housing wall designed as a vacuum insulation panel element is arranged on a largest side surface of a battery cell.

For example, such an arrangement is advantageous if the plurality of battery cells in a longitudinal direction of the battery unit is respectively arranged adjacent to each other with their largest side surfaces, which comparatively little heat is transmitted to the environment over such a largest side surfaces of the battery cell.

Advantageously, the second housing wall formed as a supported vacuum insulation element is arranged on one of the plurality of battery cells jointly formed smallest side surface.

This offers the advantage that the supported vacuum insulation element can be mounted on the smallest possible side surface, whereby heat losses can be reduced.

In other words, this means that supported on the smallest side surfaces which are formed by the battery cells together or even by a battery cell, supported vacuum insulation elements to connect the battery unit, for example, with a vehicle and vacuum insulation panel elements are arranged on the remaining side surfaces to provide sufficient insulation.

Furthermore, this has the advantage that the respective larger or largest side surfaces can be covered with the comparatively lighter vacuum insulation panel elements.

Expediently, the housing in each case comprises a plurality of first housing walls and a plurality of second housing walls, in order thus to ensure reliable insulation and at the same time to enable a mechanical connection, for example to a vehicle.

The battery unit can be designed as a battery module.

A battery module comprises a plurality of electrically series-connected and / or parallel-connected battery cells.

Furthermore, the battery unit can also be designed as a battery pack. A battery pack comprises a plurality of electrically interconnected battery modules and optionally monitoring and control systems or tempering.

According to a particularly preferred aspect of the invention, the battery cells are each formed as medium temperature battery cells. Medium temperature battery cells usually comprise a solid electrolyte and, as already described, an optimum operating temperature between 50 ° C and 80 ° C on.

With a battery unit according to the invention, it is possible to operate such medium-temperature battery cells in an optimum temperature range.

The present invention also provides the use of a battery unit just described, wherein the battery cells are operated at a temperature of 50 ° C to 80 ° C.

list of figures

Embodiments of the invention are illustrated in the drawings and explained in more detail in the following description.

• 1 schematisch in einer Explosionsdarstellung eine Ausführungsform einer erfindungsgemäßen Batterieeinheit.

It shows:

• 1 schematically an exploded view of an embodiment of a battery unit according to the invention.

The 1 shows schematically in an exploded view an embodiment of a battery unit according to the invention 1 ,

The battery unit 1 has a plurality of battery cells 2 on which in the 1 are shown together as a cuboid for simplified representation. The battery cells 2 are preferred as medium temperature battery cells 20 educated.

In particular, it should be noted at this point that the cuboid in this case on the one hand a plurality of electrically conductive interconnected battery cells 2 can describe when the battery unit 1 is formed as a battery module or that the cuboid while on the other hand also a plurality of electrically conductively interconnected battery modules having in each case a plurality of battery cells 2 can describe.

Furthermore, the battery unit 1 a housing 3 on.

Here is the majority of battery cells 2 completely in the case 3 the battery unit 1 added.

The housing 3 the battery unit 1 is doing to a thermal insulation of the plurality of battery cells 2 educated.

This includes the housing 3 the battery unit 1 a first housing wall 31 serving as a vacuum insulation panel element 310 is trained.

Furthermore, the housing comprises 3 the battery unit 1 to a second housing wall 32 , which serves as a supported vacuum insulation element 320 is trained.

This shows the 1 that the case 3 in each case a plurality of first housing walls 31 and a plurality of second housing wall 32 includes.

In particular, the vacuum insulation panel element comprises 310 while a shell formed of aluminum 311 ,

The case 311 has a wall thickness 312 less than 200 microns. Furthermore, the shell 311 the vacuum insulation panel element 310 as a foil 313 be formed or vapor-deposited aluminum 314 include.

Preferably, the supported vacuum insulation element comprises 320 while a shell formed of stainless steel 321 ,

The case 321 has a wall thickness 322 between 0.5 mm and 1 mm.

Like from the 1 can be seen, the supported vacuum insulation element 320 be designed for attachment to a vehicle, wherein in the embodiment according to 1 the supported vacuum insulation element 320 to a holding element 325 which can be used to attach the battery unit 1 is formed on a vehicle.

Furthermore, the shows 1 also, that as a vacuum insulation panel element 310 trained first housing wall 31 at one of the plurality of battery cells 2 jointly formed largest side surface 21 is arranged.

Furthermore, the vacuum insulation panel element 310 also on a largest side surface 22 a single battery cell 2 be arranged.

In particular, the figure also shows that as a supported vacuum insulation element 320 trained second housing wall 32 at one of the plurality of battery cells 2 jointly formed smallest side surface 23 is arranged. This smallest side surface 23 For example, even from just one battery cell 2 be formed.

Claims (12)

Battery unit comprising a plurality of battery cells (2) which are completely accommodated in a housing (3) of the battery unit (1), which leads to a thermal insulation of the plurality is formed on battery cells (2), characterized in that a first housing wall (31) of the housing (3) as a Vakuumisolationspaneelelement (310) is formed and that a second housing wall (32) of the housing (3) as a supported vacuum insulation element (320 ) is trained. Battery unit after the previous one Claim 1 , characterized in that the vacuum insulation panel member (310) comprises a sheath (311) formed of aluminum having a wall thickness (312) smaller than 200 micrometers. Battery unit after the previous one Claim 2 characterized in that the shell (311) of the vacuum insulation panel element (310) is formed as a foil (313) or comprises vapor deposited aluminum (314). Battery unit according to one of the previous Claims 1 to 3 , characterized in that the supported vacuum insulation element (320) comprises a shell (321) made of stainless steel with a wall thickness (322) between 0.5 and 1 millimeter. Battery unit according to one of the previous Claims 1 to 4 characterized in that the supported vacuum insulation element (320) is further adapted for attachment to a vehicle or that the supported vacuum insulation element (320) comprises a support member (325) adapted for attachment of the battery unit (1) to a vehicle. Battery unit according to one of the previous Claims 1 to 5 , characterized in that the plurality of battery cells (2) are each formed prismatic. Battery unit according to one of the previous Claims 1 to 6 , Characterized in that or formed as Vakuumisolationspaneelelement (310) first housing wall (31) is arranged on one of the plurality of battery cells (2) together are formed the largest side face (21) disposed at a largest side face (22) of a battery cell (2) is. Battery unit according to one of the previous Claims 1 to 7 , characterized in that the second housing wall (32) formed as a supported vacuum insulation element (320) is arranged on one of the plurality of battery cells (2) co-formed smallest side surface (23). Battery unit according to one of the previous Claims 1 to 8th , characterized in that the housing (3) each comprise a plurality of first housing walls (31) and a plurality of second housing walls (32). Battery unit according to one of the previous Claims 1 to 9 , characterized in that the battery cells (2) are each formed as medium temperature battery cells (20). Battery unit according to one of the previous Claims 1 to 10 , characterized in that the battery unit (1) is a battery module or a battery pack. Use of a battery unit according to one of Claims 1 to 11 , characterized in that the battery cells (2) are operated at a temperature of 50 ° C to 80 ° C.

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