DE102017206989A1 - Method for producing a cell housing of an electrochemical battery cell and electrochemical battery cell and battery module - Google Patents

Abstract

The invention relates to a method for producing a cell housing (22) of an electrochemical battery cell (20), having a housing pot (24) and a housing cover (26) which closes it, wherein the housing pot (24) is integrally formed from a sheet steel (28). especially deep-drawn, will.

Description

The invention relates to a method for producing a cell housing of an electrochemical battery cell, comprising a housing pot and a housing cover which closes it. The invention further relates to an electrochemical battery cell with such a cell housing and a battery module for an electric motor driven or driven motor vehicle with a number of such battery cells.

Electric (electric motor driven) motor vehicles, such as electric or hybrid vehicles, usually include an electric motor with which one or both vehicle axles are drivable. For the purpose of supplying electrical energy, the electric motor is typically coupled to an in-vehicle (high-voltage) battery as an electrical energy store. Such batteries are embodied, for example, as accumulators, with a plurality of individual batteries typically being connected in a modular manner to form a common battery system in order to generate a sufficiently high operating voltage.

The individual battery modules usually comprise a number of electrochemical (thin) layer cells, hereinafter also referred to as battery cells, which are lined up or stacked within a respective battery or cell housing along a stack or row direction to form a cell stack or cell stack.

The battery cells have, for example, a layered structure with a cathode layer and with an anode layer and with a separator layer introduced therebetween. These components are permeated by a liquid electrolyte (liquid electrolyte) which produces an ionic compound of the components. The ionic line is usually based on lithium ions.

Also conceivable, for example, battery cells with a solid electrolyte, hereinafter also referred to as solid-state cells, which have a much higher energy storage density than battery cells with liquid electrolytes with the same construction weight.

Cell enclosures of battery cells are typically formed from a cell compartment or housing pot, also referred to as a can or can, and a cell or housing cover closing it. In general, both the housing pot and the housing cover are made of an aluminum material and materially joined, in particular by means of welding, together. Due to the large number of battery cells in a cell stack, the battery module formed thereby has a comparatively large construction volume and a high structural weight due to the many lined cell housing, which adversely affects the range of the electromotive drive.

To reduce the structural weight and the volume of construction, it is conceivable, for example, to reduce the wall thickness or wall thickness of the cell housing. The resulting material savings causes both a cost savings and a weight saving.

The housing pot of such a cell housing is usually produced in a deep-drawing process. In the case of such cell housings made of aluminum, only a minimum wall thickness of approximately 0.4 mm can be realized due to the material. By thus predetermined minimum size or minimum wall thickness, both the energy storage density and the degree of filling or filling factor of the active material of the battery cell are adversely limited.

The invention has for its object to provide a particularly suitable method for producing a cell housing of an electrochemical battery cell, in which in particular a particularly thin-walled housing pot can be realized. The invention is further based on the object of specifying an electrochemical battery cell with such a cell housing. Furthermore, the invention has for its object to provide a battery module for a motor driven motor vehicle with a number of such battery cells.

With regard to the method, the object with the features of claim 1 and in terms of the electrochemical battery cell with the features of claim 5 and in terms of the battery module with the features of claim 9 is achieved according to the invention. Advantageous embodiments and further developments are the subject of the respective subclaims.

The method according to the invention is suitable and designed for producing a cell housing of an electrochemical battery cell. The cell housing is in this case particularly suitable for use in automotive applications, preferably in electric or electric motor driven motor vehicles, suitable and furnished.

The cell housing has a housing pot (Can), in which at least one layer system of the battery cell can be used. The housing pot is covered and sealed in the joining state of the cell housing by means of a housing cover.

According to the method it is provided that the housing pot integrally, so one-piece or monolithic, formed from a steel sheet, in particular deep-drawn, is. In other words, the housing pot is preferably formed in a thermoforming process from a stamped sheet steel, for example. As a result, a particularly suitable method for producing a cell housing is realized.

Instead of a deep drawing process, for example, an extrusion process, in particular a cold extrusion process, for forming the steel sheet is conceivable.

In contrast to the prior art, a steel sheet is thus used instead of an aluminum material. The steel material has improved mechanical properties compared to the aluminum material. In particular, it is thus possible to produce a housing pot with a reduced compared to a housing made of aluminum housing wall thickness. As a result, higher energy storage densities and filling levels of the battery cells are made possible. In other words, a larger space for the layer system of the battery cell is generated at the same size of the housing pot.

The invention is based on the finding that although steel has a higher density than aluminum, but due to the much lower feasible wall thicknesses of the housing pots a significant weight savings compared to conventional cell casings is possible. Furthermore, steel has a higher temperature resistance and a higher mechanical strength, so that a particularly stable and reliable cell housing is guaranteed despite reduced wall thickness.

The housing pot takes on the (thin) layer system of the battery cell in the assembly or joining state, and is covered with a housing cover of the cell housing and sealed. The layer system of the battery cell is in this case designed, for example, with a liquid electrolyte. Also conceivable are configurations of the battery cell as a solid state cell with a solid electrolyte.

The housing cover has, for example, an integrated bursting membrane or rupture disk in order to effect a pressure compensation in the case of volume changes of the recorded layer system of the battery cell.

In an advantageous embodiment, the deep-drawn housing pot has a wall thickness or wall thickness less than 0.4 mm, in particular less than 0.2 mm. Preferably, the wall thickness is about 0.1 mm. As a result, a particularly suitable cell housing is formed. The reduced wall thickness corresponds to a material saving, whereby the manufacturing cost of the cell housing can be reduced. Furthermore, a reduction of the building weight and the volume of construction is effected.

In a suitable development, a tin-plated steel sheet, in particular a tinplate, is used to deep-draw the housing pot. By tin coating corrosion protection of the cell housing is realized. However, it is also conceivable, for example, a subsequent tinning of the deep-drawn steel sheet.

In an advantageous further development form, the tinned steel sheet or the housing pot is additionally provided with a polyurethane protective layer. As a result, the corrosion protection of the cell housing is further improved. The protective layer is in this case in particular on the housing side, that is applied to an inner wall of the housing pot, so that a reliable corrosion protection against a liquid electrolyte of the battery cell is realized. This allows a particularly robust housing pot. Thus, the life of the cell case is improved.

In a preferred embodiment, the housing pot is deep-drawn in a prismatic housing form. The prismatic package shape is, for example, a PHEV cell format (PHEV: Plug-in Hybrid Electric Vehicle), in particular a PHEV2 cell format. As a result, a particularly suitable housing shape of the battery cell for automotive applications, in particular in an electric or hybrid vehicle realized.

The electrochemical battery cell according to the invention is particularly suitable and suitable for use in an electrically driven motor vehicle. The battery cell has a cell housing produced by the method described above with a prismatic housing pot in particular and with a housing cover.

In a suitable development of the housing pot is closed by means of a housing cover made of an aluminum material. In other words, the housing cover of the cell housing is made of an aluminum material. As a result, on the one hand a low-cost battery cell is realized. On the other hand, using the aluminum housing cover ensures a sorted joining with common cell connectors of battery modules.

In a preferred embodiment, the housing pot and the housing cover are positively joined together. Preferably, the housing pot and the housing cover by means of a Forming process, in particular by means of flanging, joined. In other words, the housing cover and the housing pot are not materially connected to one another, in particular not welded together. As a result, a cost-effective and easy to produce connection between the housing pot and the housing cover is formed, whereby a particularly stable and dense cell housing is formed. In particular, a reliable and reliable connection between the housing pot made of sheet steel and the housing cover made of aluminum is realized.

In an advantageous embodiment of the housing cover of the housing pot opposite housing base is designed with a projecting into the housing interior or retracted curvature or crowning. On the one hand, the pressure stability of the cell housing is increased by the inwardly arched or domed housing bottom. On the other hand, a particularly flat and stable support of the cell housing is thus formed by the peripheral edge region of the housing bottom, whereby an arrangement and storage of multiple battery cells is simplified.

In a preferred embodiment, the curvature of the housing bottom is designed in terms of pressure equalization in the event of overpressure of the battery or solid state cell occurring. This makes it possible, for example, to use the housing bottom of the housing pot by deformation of the curvature outwards for pressure equalization and thus, for example, to make the housing cover with a simpler bursting membrane, or to save them completely. As a result, a particularly cost-reduced battery cell can be realized.

In a preferred application, a number of electrochemical battery cells according to the invention are arranged along a stacking direction to form a battery cell stack or a cell block of a battery module. To form the battery module, for example, more than ten, in particular more than 100, preferably more than 500, battery cells are lined up. Since each battery cell preferably has a reduced structural weight due to the deep-drawn steel sheet housing pot, thus a significant weight saving of the battery module is realized in comparison to the prior art. This allows a particularly weight-reduced battery module with a particularly high energy storage density. In this case, the battery module is suitable and set up, in particular, for use in a motor vehicle that can be driven by an electric motor.

The battery module is in this case, for example, part of a (high-voltage) battery system, which is arranged as an in-vehicle energy storage in an electric motor driven motor vehicle. The battery system is designed, for example, for the electrical supply of the vehicle drive of the motor vehicle designed in particular as an electric or hybrid vehicle. Due to the deep-drawn steel sheets as housing pots in this case a particularly suitable and construction weight reduced battery system is formed, which is improved in particular in terms of performance and range.

• 1 in einer schematischen und vereinfachten Darstellung ein Hybridfahrzeug mit einem fahrzeuginternen Hochvolt-Batteriesystem,
• 2 ausschnittsweise in perspektivischer Darstellung ein Batteriemodul des Batteriesystems, mit einer Anzahl von Batteriezellen,
• 3 in Perspektive eine Batteriezelle,
• 4 in perspektivischer Darstellung einen Gehäusetopf der Batteriezelle, und
• 5 in schematischer und vereinfachter Darstellung einen Schnitt durch den Gehäusetopf gemäß der Linie V-V in 4.

Embodiments of the invention are explained in more detail with reference to a drawing. Show:

• 1 in a schematic and simplified representation of a hybrid vehicle with an in-vehicle high-voltage battery system,
• 2 a perspective view of a battery module of the battery system, with a number of battery cells,
• 3 in perspective a battery cell,
• 4 in perspective view of a housing pot of the battery cell, and
• 5 in a schematic and simplified representation of a section through the housing pot according to the line VV in 4 ,

Corresponding parts and sizes are always provided with the same reference numerals in all figures.

In 1 is a highly simplified and schematic representation of an electric or electric motor driven motor vehicle in the form of a hybrid vehicle 2 shown. The hybrid vehicle 2 has an in-vehicle high-voltage energy storage in the form of a (high-voltage) battery system 4. The battery system 4 is by means of a DC-DC converter 6 to a DC link 8th coupled to which an inverter 10 for supplying an electric motor 12 connected.

The battery system 4 has at least one battery module 14 which is controlled and / or regulated in operation, for example, by means of a controller (not shown in detail) (Battery Management System, BMS). To generate a sufficiently high operating voltage, the battery module 14 one in 2 fragmentary cell stack or cell packet 16 on. The cell stack 16 has a number of along a stacking direction 18 lined up battery cells 20 on, in 2 exemplarily only four battery cells 20 are shown. In the 2 are the battery cells 20 merely exemplified with reference numerals.

The battery cells 20 For example, they are designed as accumulators, which are modular to the common battery module 14 are interconnected. In the 3 individually illustrated battery cell 20 here has a cell housing 22 for receiving a layer system, not shown.

The layer system of the battery cell 20 has, for example, a cathode layer and an anode layer and with a separator layer introduced therebetween, which are penetrated by a liquid electrolyte (liquid electrolyte). It is also conceivable, for example, a solid-state layer system with a solid electrolyte.

The cell case 22 has a housing system receiving the housing cup 24 and a housing cover closing this 26 on. The deep-drawn housing pot 24 is made of a particular tinned sheet steel 28 produced. The steel sheet 28 is here in particular designed as a tinplate, wherein additionally, in particular on the inside of the housing, a protective layer of polyurethane (PU) is applied.

The steel sheet 28 is as a stamped part by means of a deep-drawing process in one piece in the housing pot 24 reshaped. The housing pot 24 the battery cell 20 in this case has a prismatic housing shape. In a suitable dimensioning is the housing pot 24 produced in a PHEV2 cell format.

The housing cover made of an aluminum material 26 has two electrical connections in the form of a positive pole in the area of the narrow sides 30 and a negative pole 32 on, by means of which the battery cells 20 in the composite of the battery module 14 be connected in parallel to each other. Between the positive pole 30 and the negative pole 32 is a rupture disk 34 intended. The housing cover 26 is in the assembly or joining state by means of a forming process, in particular by means of crimping, a form-fitting to a cover-side collar region 36 of the housing pot 24 attached.

As in particular in the sectional view of 5 it can be seen, the housing pot 24 a caseback 38 on, which in the assembled state opposite to the housing cover 26 is arranged. The caseback 38 is here with a curvature or crowning 40 executed, which projects into the housing interior or is drawn into this.

The deep-drawn housing pot 24 here has a wall thickness or wall thickness 42 which is preferably less than 0.4 mm, in particular less than 0.2 mm. Preferably, the wall thickness 42 equal to 0.1 mm.

The invention is not limited to the embodiments described above. Rather, other variants of the invention can be derived therefrom by the person skilled in the art without departing from the subject matter of the invention. In particular, all the individual features described in connection with the exemplary embodiments can also be combined with one another in other ways, without departing from the subject matter of the invention.

LIST OF REFERENCE NUMBERS

2

Motor vehicle / hybrid vehicle

4

battery system

6

DC converter

8th

DC

10

inverter

12

electric motor

14

battery module

16

cell stack

18

stacking direction

20

battery cell

22

cell case

24

housing pot

26

housing cover

28

sheet steel

30

positive pole

32

minuspol

34

rupture disc

36

collar region

38

caseback

40

Buckle / crown

42

wall thickness

Claims (9)

Method for producing a cell housing (22) of an electrochemical battery cell (20), comprising a housing pot (24) and a housing cover (26) closing it, characterized in that the housing pot (24) is integrally formed from a sheet steel (28), in particular deep-drawn, will. Method according to Claim 1 characterized by a deep-drawn housing pot (24) with a wall thickness (42) less than 0.4 mm, in particular less than 0.2 mm. Method according to Claim 1 or 2 , characterized in that a tinned steel sheet (28) is used. Method according to one of Claims 1 to 3 , characterized in that the housing pot (24) is deep-drawn in a prismatic housing shape. Electrochemical battery cell (20) with a according to a method according to any one of Claims 1 to 4 manufactured cell housing (22). Electrochemical battery cell (20) according to Claim 5 , characterized in that the housing pot (24) is closed by means of a housing cover (26) made of an aluminum material. Electrochemical battery cell (20) according to Claim 5 or 6 , characterized in that the housing pot (24) and the housing cover (26) are positively joined together. Electrochemical battery cell (20) according to one of Claims 5 to 7 , characterized in that the housing pot (24) has a housing cover (26) opposite housing bottom (38), which is designed with a protruding into the housing interior buckle (40). Battery module (14) for an electric motor driven motor vehicle (2) with a cell stack (16) comprising a number of along a stacking direction (18) stacked electrochemical battery cells (20) according to one of Claims 5 to 8th ,

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