DE102012220386A1 - Battery cell with housing cover plate with riveted filler opening - Google Patents

Abstract

A battery cell, in particular a lithium-ion battery cell, is proposed in which a winding element, two current collectors and electrolyte are accommodated in a housing. The housing consists of a container and a lid assembly. The cover arrangement includes, inter alia, a cover plate which is firmly connected to the container after internal components of the battery cell have been introduced. According to the invention, a filling opening (25) provided in the cover plate (23), through which electrolyte can be filled into the interior of the housing, is closed with the aid of a rivet (31).

Description

Field of the invention

The present invention relates to a battery cell, in particular a lithium-ion battery cell. The invention further relates to a motor vehicle with such a battery cell.

State of the art

Battery cells, sometimes referred to as accumulator cells, are used for the chemical storage of electrically provided energy. Even today, battery cells are used to power a variety of mobile devices. In the future, battery cells are to be used inter alia for supplying energy to mobile electric vehicles or hybrid vehicles, on land as well as to water, or for stationary intermediate storage of electrical energy originating from alternative energy sources.

For this purpose, a plurality of battery cells is usually assembled into battery packs. In order to exploit an available package volume as efficiently as possible, primarily battery cells with a prismatic, for example, a cuboid-like shape are used for such purposes.

Because of their possible high energy density, thermal stability and lack of memory effect is usually used for demanding applications such as storage solutions for motor vehicles, a lithium-ion battery technology, which is currently being intensively developed due to the high economic importance of future electromobility.

There are already many different types of battery cells, in particular lithium-ion battery cells, and further in particular battery cells with prismatic shape. However, such conventional battery cells usually have a complex structure in which a large number of different individual parts is used to assemble the entire battery cell. In particular, in assembling the individual parts, elaborate manufacturing processes such as e.g. Welding methods are used which are both costly and energy intensive. All of this can add to the increased cost of manufacturing the battery cell.

Disclosure of the invention

By means of embodiments of the present invention, among other things, a cost for the assembly of a battery cell and associated costs can be reduced.

It is proposed a battery cell, in particular a lithium-ion battery cell having at least one winding element, an electrolyte, two current collector and a housing. The winding element consists of a wound stack of a first foil coated with anode material, for example of copper, a second foil coated with cathode material, for example of aluminum, and two plastic foils serving as diaphragms. Instead of wound versions and stacked arrangements of film and plastic layers are possible. One of the current collector is electrically conductively connected, for example welded, to the first foil of the winding element. The second current collector is electrically conductively connected to the second foil of the winding element. The housing has a container and a lid assembly. The container has an opening through which the winding element and the two current collectors can be introduced into the housing during the manufacture of the battery cell. The lid assembly is adapted to complete the opening of the container gas-tight and pressure-tight. For this purpose, the lid assembly, inter alia, a cover plate which can largely close the opening in the container and which can be connected for hermetic sealing of the housing with the container, for example by a weld. The cover plate has, inter alia, a filling opening, through which electrolyte can be filled into the housing. The proposed battery cell is characterized in that the filling opening is closed with a rivet.

Embodiments of the battery cells according to the invention are based inter alia on the following findings and ideas:
When assembling a battery cell usually the winding element is first introduced with the current collectors mounted therein in the still open-topped container of the housing and then hermetically sealed the opening of the container using the lid assembly. When attaching the lid assembly, the cover plate is first connected to the container, for example by welding. The filling opening provided in the cover plate then charges electrolyte into the container so that it can wet the winding element received therein. Then the filling opening must be hermetically sealed and sealed against the electrolyte.

For this purpose, an existing example of metal or plastic ball is pressed onto the filling opening in conventional battery cells and welded directly or via a metallic plate with the edge of the filling opening. However, a welding process is a complex process and can be expensive among other things Require welding robots and welding processes. Thus, a laser welding process often requires a large number of work steps and is therefore comparatively complex and cost-intensive. In addition, a thermal stress is exerted during welding, which can be problematic in the desired thin-walled lid designs.

It is therefore proposed to close the filling opening without the use of welding operations.

For this purpose, the filling opening is closed with a rivet. For this purpose, a standardized, commercially available rivet can be used.

The rivet must be arranged so that a shaft of the rivet extends through the filling opening. In this case, the radial diameter of the expansion of the rivet at a first or upper end of the shaft must be greater than the diameter of the filling opening. The same applies to the arranged on the other side of the cover plate expansion of the rivet. This overlapping of the rivet formed as a riveting head over the edge of the filling opening should ensure sufficient overlap between the expansion or the rivet head and the surface of the cover plate. The higher the contact force of the rivet head to the surface of the cover plate and the larger the overlapping surface or contact surface between the two elements, the better the possible sealing effect.

An advantage of the rivet lies in the simplicity of the method and the wide spread of this joining technique and the resulting relatively low cost.

The peculiarity of this is that it is not as usual the connection of two parts in the foreground, but the sealing effect of a rivet when it is in the cross section of an opening. The rivet must be such that it allows a gas-tight and pressure-tight closing of the filling opening. Various types of rivets are available for this purpose. Through the widespread use and standardization of riveting, the use of standardized and therefore cost-effective tools is possible.

Another advantage of the rivet is that the riveting of the filler opening can be done without the application of force on the cover plate. Since the cover plates used can only have a very small thickness of the order of 1 mm or less and, in addition, materials with low strength can be used, only closure methods are applicable in which no or only very small forces act on the cover plate during closing.

In one embodiment of the invention, at least one sealing ring is interposed between a widening of a shank of the rivet and the cover plate for sealing the filling opening.

A sealing ring can be understood here as an additional element for increasing the sealing effect of the gap between the expansion of the rivet shank and the surface of the cover plate. Advantage of the use of a sealing ring is a further improved sealing effect to prevent leakage of electrolyte from the battery cell. The sealing ring can be designed so that the inner diameter of the sealing ring is smaller than the diameter of the expansion and typically slightly larger than the diameter of the shaft, so that the sealing ring can be pressed by the expansion of the rivet on the surface of the cover plate. The sealing ring and the shaft are preferably arranged concentrically. In a typical embodiment, the sealing ring is pushed onto the shank of the rivet before the rivet is introduced into the filling opening. For this it is necessary that the diameter of the sealing ring is larger than the diameter of the shaft.

In one embodiment according to the invention, the sealing ring, the rivet and the cover plate made of the same material.

The advantage lies in the fact that galvanic or electrochemical processes and reactions can be avoided, which lead to corrosion or the emergence of unwanted electrical voltages at the contact surfaces between different materials. This means that, for example, the same alloy is used for the components mentioned. This prevents corrosion effects through additional galvanic elements, which are caused by the direct contact of different metals.

In one embodiment according to the invention, the rivet is made of an electrolyte-resistant plastic.

The advantage of using a plastic is that it can be a cost-effective and low-weight alternative to metallic materials when used for battery cells, since the described electrochemical effects and corrosion effects can be avoided by galvanic elements.

According to an embodiment according to the present invention, the sealing ring is made of an electrolyte-resistant plastic.

In particular, electrolyte-resistant elastomers can be used here. Such an elastomer may contain, for example, a fluoropolymer. For example, the Dupont company markets an elastomer resistant to many electrolytes under the brand name Viton, sometimes with the addition FKM.

It should be noted that in each case a sealing ring can be located on both sides of the cover plate at the widenings of the rivet. In this way, the sealing effect can be increased again. Also, instead of a single sealing ring several sealing rings can be combined to increase the sealing effect. The sealing ring may be designed to be elastic and thereby in the unstretched state before being pushed onto the shank of the rivet have the same or slightly smaller inner diameter than the shank of the rivet.

According to one embodiment of the invention, the rivet is a blind rivet. Advantage of a blind rivet is that the riveting of only one side of the component to be riveted can be done without a tool on the other side of the rivet must be recognized. In practice, this is often a special blind rivet used.

It is also advantageous that no residual parts or chips during Vernietvorgang arise, which can then get into the housing interior and there trigger mechanical damage or chemical reactions. Both rivets and the tools used are widely available and inexpensive.

In one embodiment of the invention, the blind rivet is a cup rivet. A cup rivet is to be understood as a special embodiment of the blind rivet in which the lower end of the shaft of the rivet is closed and therefore forms the shape of a cup.

An advantage of using a cup rivet for the battery cell proposed herein is that the rivet is closed at the side facing the container interior and thereby can close the inlet opening gas-tight and pressure-tight. Compared to other rivet forms, it also offers the advantage that the riveting process leaves no waste or residual parts inside the housing and thus does not cause undesired reactions or impairments of the battery function.

Furthermore, a method for sealing a battery housing of a battery cell is specified. The battery cell has a winding element of a wound stack of a first film coated with anode material, a second film coated with cathode material and two plastic films serving as diaphragms. The battery cell furthermore has an electrolyte, two current collectors, one of which is electrically conductively connected to the first film and one to the second film. The battery cell furthermore has a housing with a container and a lid arrangement, wherein the container has an opening through which the winding element and the two current collectors can be introduced into the housing during the production of the battery cell. In this case, the cover assembly is designed for gas-tight and pressure-tight sealing of the opening of the container and has a cover plate. The cover plate has a filling opening for filling electrolyte into the housing. The method comprises the step of gas-tight and pressure-tight sealing of the filling opening by riveting.

According to one embodiment of the invention, the riveting comprises the following steps:
The shank of a rivet is inserted into the filling opening, wherein the rivet in the inserted state at a first end of the shank on a side facing away from the container side of the cover plate has a widening whose radial diameter is greater than the diameter of the filling opening. The diameter of the shank of the rivet is smaller than the diameter of the filling opening.

In other words, a Rohniet having a rivet head in the form of a widening on one side of the shaft, with the shaft inserted into the filling opening, so that the rivet head or the widening comes into contact with the surface of the cover plate. When using a sealing ring, for example, this is previously pushed onto the shank of the rivet, in order then to be located between the widening of the rivet and the surface of the cover plate.

In a next step, a second end of the shank is widened on a side of the cover plate facing the container so that the widening of the first end of the shank, together with the widening of the second end of the shank and the shank, closes the filling opening in a gastight and pressure-tight manner. In this case, the radial diameter of the second expansion is greater than the diameter of the filling opening.

According to a further aspect of the invention, a motor vehicle has a battery cell according to the present invention.

In principle, the battery cell according to the invention can be used for a large number of other mobile or stationary applications. These include, for example, maritime applications or e-bikes as well as other sports or leisure equipment in the mobile sector.

It should be noted that possible features and advantages of a battery cell according to the invention are described herein with reference to different embodiments. A person skilled in the art understands that the individual features can be suitably combined or exchanged with one another in order to arrive at further embodiments and possibly synergy effects in this way.

Brief description of the drawings

Hereinafter, embodiments of the invention will be described with reference to the accompanying drawings, wherein neither the description nor the drawings are to be construed as limiting the invention.

1 shows an exploded view of a lithium-ion battery cell.

2 shows a filling opening with a rivet and a sealing ring before riveting a battery cell according to an embodiment of the invention in cross section.

3 shows a filling opening with a rivet and a sealing ring after riveting a battery cell according to an embodiment of the invention in cross section.

4 shows a filling opening with a rivet and a arranged on the inside of the cover plate sealing ring after riveting a battery cell according to an embodiment of the invention in cross section.

5 shows a filling opening with a rivet without sealing ring after riveting a battery cell according to an embodiment of the invention in cross section.

6 shows a motor vehicle with a battery according to an embodiment of the present invention.

The figures are only schematic and not to scale. Like reference numerals designate the same or similar features in the figures.

Embodiments of the invention

1 shows a conventional lithium-ion battery cell in an exploded view. It can be seen that the battery cell consists of a large number of individual components. Only the components necessary for the understanding of embodiments of the invention and their features are described herein, a description of the remaining components of the battery cell is omitted.

The battery cell 1 has at least one winding element 3 with a wrapped stack 5 of a copper foil coated with anode material and an aluminum foil coated with cathode material, and intervening plastic foils serving as diaphragms.

For electrical contacting, the copper foil and the aluminum foil are stacked slightly offset one above the other in the opposite direction so that the copper foil on a narrow side and the aluminum foil on an opposite narrow side project slightly beyond a respective edge of the winding element. To a projecting area 4 the copper foil becomes a current collector made of copper 7 welded, so that this pantograph is electrically connected to the anode of the winding element. At an opposite projecting portion of the aluminum foil is a second current collector made of aluminum 9 welded to make electrical contact with the cathode of the winding element 3 manufacture.

That with the two pantographs 7 . 9 provided winding element 3 is then in an upwardly open, cuboid container 13 through an opening 14 brought in. The container 13 is then with a lid assembly 15 in addition to a cover plate 23 still several other components includes, closed. The cover plate 23 is welded with its edge to an inner surface of the container. The container 13 as well as the cover plate 23 are made of sheet metal to withstand, among other things, the chemically aggressive electrolyte can.

The cover plate 23 has, among other things, a filling opening 25 on, through the electrolyte into the interior of the container 13 and the lid assembly 15 formed housing 11 can be filled after the cover plate 23 on the container 13 was attached. The filling opening 25 may for example be formed with a round cross-section and have a diameter of about 5 mm.

In conventional battery cells, the filling opening 25 using a ball 26 closed, which is a slightly larger diameter than the filling hole 25 having. The ball 26 is doing in the filling hole 25 pressed in and then revolving with the cover plate 23 welded.

In 2 and 3 is a rivet / seal assembly 30 for a tight closure of a filler opening of a battery cell according to an exemplary embodiment of the invention. In a filling opening 25 is a shaft 35 a rivet 31 added. The rivet 31 has an expansion on its top 32 that have an investment area 49 which has a sealing ring 34 with a surface of the cover plate 23 in contact. The rivet, as in 2 shown, has only an expansion before riveting 32 , The other end of the rivet can be used as an extension of the shaft 35 be seen. This allows insertion of the rivet into the opening prior to riveting.

Furthermore, the rivet has an elongated cavity 36 on, which runs in the axial direction through the interior of the rivet. In the case of the cup rivet shown here, the second end of the rivet, shown below, is closed on its front side. The cavity 36 is thus not continuous, but only at one upper end open and closed at a lower end.

At its lower end, the cavity 36 a broadening 44 on. This broadening 44 serves to accommodate a widened end 40 a thorn 38 passing through the elongated cavity 36 passed through. This thorn 38 points at the point 42 a breaking point on. Is in the process of riveting the mandrel 38 with a force 46 , which is directed away from the cover plate, from the cavity 36 pulled out, the widened part pulls 40 of the thorn the lower part of the rivet 31 in the in 3 illustrated form of a second expansion. Upon further withdrawal of the spine 38 from the cavity 36 the counterforce increases in such a way that the spike is in place 42 breaks and the widened part 40 of the thorn 38 remains in the resulting expansion. This has the advantage that the riveting of only one side of the cover plate is possible, but also that no residual parts arise from the riveting and could fall into the container later.

In 3 is the cover plate and the rivet / seal assembly 30 presented after riveting. The rivet closes over the contact surfaces 49 and 48 and over the sealing ring 34 the opening 25 in the cover plate 23 , In the opening 36 is located after riveting only the separated widened end 40 of the thorn that is in place 42 from the thorn 38 was separated. After riveting, the rivet points 32 now a second expansion 33 on inside a broadening of the bore 44 for receiving the widened end of the spine 40 contains. The two expansions 32 and 33 are under tension over the shaft 35 , which is guided through the opening, connected to each other.

As can be seen from the illustration, the sealing effect can be influenced by the fact that the most dense and contiguous contact between the contact surfaces 49 and 48 as well as the sealing ring 34 and the cover plate 23 is created. This leads to the gas-tight and pressure-tight closure of the opening, in particular through the closed surface of the second expansion 33 ,

Instead of the variant of the cup rivet shown here, further riveting methods and variants are possible, for example a hammer rivet, in which the mandrel is driven into the rivet and remains there. As a result, a closure of the opening is achieved. Also possible is a Zugdornniet in which a protruding at the rivet mandrel is compressed by train and breaks off at a predetermined breaking point. Again, the compressed end of the mandrel closes the bore or opening of the rivet to achieve a gas-tight and pressure-tight seal.

In 4 a further exemplary embodiment of the invention is shown in which the sealing ring 34 on the inner or lower side of the cover plate 23 between the lower widening 33 of the rivet 31 , in particular the investment area 48 , and the cover plate 23 is arranged. In this case, the upper widening is 32 , in particular the investment area 49 , in direct mechanical contact with the surface of the cover plate 23 ,

In addition, embodiments are with a rivet 31 conceivable in which two or more sealing rings are arranged such that they are between the contact surfaces 49 respectively. 48 and the cover plate 23 on the upper or lower side of the cover plate 23 are located.

5 shows an inventive exemplary embodiment in which the rivet 31 without sealing ring with its respective widenings 32 and 33 , in particular with the contact surfaces 49 and 48 , in direct contact with the cover plate 23 are located.

6 shows a motor vehicle 100 with a battery 102 consisting of several of the battery cells described above 1 is composed.

Claims (10)

Battery cell ( 1 ), in particular lithium-ion battery cell, comprising: a winding element ( 3 ) from a wound stack ( 5 ) comprising a first film coated with anode material, a second film coated with cathode material and two plastic films serving as diaphragms, an electrolyte, two current collectors ( 7 . 9 ), one of which is electrically conductively connected to the first film and one to the second film, a housing ( 11 ) with a container ( 13 ) and a lid assembly ( 15 ), the container ( 13 ) an opening ( 14 ), through which the winding element ( 3 ) and the two current collectors ( 7 . 9 ) during manufacture of the battery cell ( 1 ) in the housing ( 11 ) can be introduced, wherein the lid assembly ( 15 ) a cover plate ( 23 ) and the opening ( 14 ) of the container ( 13 ) gas-tight and pressure-tight, with the cover plate ( 23 ) a filling opening ( 25 ) for filling electrolyte in the housing ( 11 ), characterized in that the filling opening with a rivet ( 31 ) is closed. Battery cell according to claim 1, wherein between a widening of a shaft ( 35 ) of the rivet and the cover plate at least one sealing ring ( 34 ) is interposed for sealing the filling opening.  Battery cell according to claim 1 or 2, wherein the sealing ring, the rivet and the cover plate made of the same material.  Battery cell according to one of the preceding claims, wherein the rivet consists of an electrolyte-resistant plastic.  Battery cell according to claim 2 or 3, wherein the sealing ring consists of an electrolyte-resistant plastic.  Battery cell according to one of the preceding claims, wherein the rivet is a blind rivet.  A battery cell according to claim 6, wherein the blind rivet is a cup rivet. Method for sealing a battery housing of a battery cell, the battery cell comprising: a winding element ( 3 ) from a wound stack ( 5 ) comprising a first film coated with anode material, a second film coated with cathode material and two plastic films serving as diaphragms, an electrolyte, two current collectors ( 7 . 9 ), one of which is electrically conductively connected to the first film and one to the second film, a housing ( 11 ) with a container ( 13 ) and a lid assembly ( 15 ), the container ( 13 ) an opening ( 14 ), through which the winding element ( 3 ) and the two current collectors ( 7 . 9 ) during manufacture of the battery cell ( 1 ) in the housing ( 11 ) can be introduced, wherein the lid assembly ( 15 ) is formed for gas-tight and pressure-tight sealing of the opening of the container and a cover plate ( 23 ), wherein the cover plate ( 23 ) a filling opening ( 25 ) for filling electrolyte in the housing ( 11 ) having; the method comprising the step: gas-tight and pressure-tight closing of the filling opening by riveting. The method of claim 8, wherein riveting comprises the steps of: inserting a stem ( 35 ) of a rivet ( 31 ) in the filling opening; wherein the rivet in the inserted state at a first end of the shaft at a side facing away from the container side of the cover plate, a widening ( 32 ), whose radial diameter is greater than the diameter of the filling opening; and wherein the diameter of the shank of the rivet is smaller than the diameter of the filling opening; Expansion of a second end ( 33 ) of the shank on a side of the cover plate facing the container such that the widening of the first end of the shank together with the widening of the second end of the shank and the shank closes the filling opening in a gastight and pressure-tight manner; wherein the radial diameter of the second expansion is greater than the diameter of the filling opening. Motor vehicle ( 100 ) comprising a battery cell ( 1 ) according to one of claims 1 to 9.

Images