WO2014040789A1 - Battery cell having a housing cover plate with an adhesively bonded sealing stopper - Google Patents

Abstract

Proposed is a battery cell, in particular a lithium-ion battery cell, in which a winding element, two current collectors and electrolyte are accommodated in a housing. The housing consists of a metal container and a cover arrangement. The cover arrangement comprises, inter alia, a cover plate which is fixedly connected to the container after interior components of the battery cell have been introduced. According to the invention, a filling opening (25) provided in the cover plate (23), through which opening electrolyte can be filled into the interior of the housing, is sealed by means of a sealing stopper (27). The sealing stopper is held in the filling opening (25) by means of an adhesive (31). A sealing arrangement (35) prevents electrolyte that is filled in the housing from coming into contact with and chemically attacking the adhesive (31).

Description

 description

title

 Battery cell with housing cover plate with glued-in sealing plug 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 will be used, among other things, to supply energy to mobile devices

Electric vehicles or hybrid vehicles, both on land and on water, or for stationary intermediate storage of electricity derived from alternative energy sources.

For this purpose, a plurality of battery cells is usually assembled into battery packs. In order to utilize an available package volume as efficiently as possible, primarily battery cells with a prismatic,

used for example a cuboid-like shape.

Because of their possible high energy density, thermal stability and lack of memory effect is used for demanding applications such as

Storage solutions for motor vehicles usually used a lithium-ion battery technology, which is currently being intensively developed due to the high economic importance of a future electric mobility. 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 for assembling the entire battery cell a plurality

different items is used. 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. One of the current collectors is electrically conductively connected, for example welded, to the first foil of the wetting element. The second current collector is electrically conductively connected to the second foil of the winding element. The housing has a metallic container and a largely metallic 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 the

To close the container opening gas-tight and pressure-tight. For this purpose, the

Cover assembly, inter alia, a cover plate which can largely close the opening in the container and which for hermetically closing the

Housing can be connected to 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 sealing plug, wherein the sealing plug is held in the filling opening by means of an adhesive and a sealing arrangement prevents the electrolyte filled into the housing from coming into contact with the adhesive. Embodiments of the battery cells according to the invention are based inter alia on the following findings and ideas:

When assembling a battery cell is usually first the winding element with the current collector mounted therein in the still open top of the

Housing introduced 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. Subsequently, the filling opening must be hermetically sealed and resistant to the electrolyte

be closed.

For this purpose, in conventional battery cells, a metal ball is pressed onto the filling opening and welded to the edge of the filling opening. However, hire one

 Welding process a complex work process and may require, inter alia, expensive welding robot. In addition, a thermal stress is exerted during welding. It is therefore proposed to close the filling opening without the use of welding operations. For this purpose, a suitably shaped sealing plug in the

Introduced filling. An adhesive is provided between the sealing plug and an adjacent surface of the cover plate in the region of the filling opening. After curing, this adhesive ensures that the sealing plug in the filling opening is mechanically held. The adhesive fixes the closure plug within the filling opening so tightly that even with an increased internal pressure within the battery cell housing of, for example, more than 6000 hPa, there is no danger that the closure plug will come off the filling opening. However, it has been observed that most of the adhesives are chemically attacked by the electrolyte filled in the housing. Therefore, it is additionally provided that the battery cell has an additional sealing arrangement, which prevents the adhesive from coming into contact with the electrolyte. The sealing arrangement can be realized in different ways. In order to achieve a sufficiently stable adhesive bond between the cover plate and the sealing plug, the cover plate at the filling opening may have a projecting into the housing projection and the closure plug may be inserted into this projection, wherein the closure plug at a first portion of a lateral surface with an inner surface of the Projection can be glued.

 This results in a large-area bonding between the plug and the cover plate.

In order to reliably protect the bond against the attack of electrolyte, the sealing plug in a second portion, which is located closer to the interior of the housing of the battery cell, based on the first portion of the lateral surface, which is glued to the inner surface of the projection, a sealing bead exhibit. This sealing bead can, for example, surround the sealing plug in an annular manner and ensure a reliable sealing between the sealing plug and a further inner region of the projection of the cover plate in the region of the filling opening.

The sealing arrangement, in particular the sealing bead described above, can be designed with an elastomer resistant to the electrolyte. Such an elastomer may contain, for example, a fluoropolymer. For example, from the company DuPont a against many electrolytes resistant elastomer under the

Brand names Viton®, partly with the addition FKM, distributed.

In an alternative embodiment, a sealing arrangement can be produced by providing a lower end of the in the region of the filling opening on the cover plate

Projection so bent towards the middle of the opening, that it is with the

 Sealing plug in a second portion, which is relative to the first portion of the lateral surface, which is adhesively bonded to the inner surface of the projection, closer to the interior of the housing comes into abutment. The lower end of the

Projection can form, for example, a sharp edge, which closely conforms to a lateral surface of the sealing plug accommodated in the projection and thereby prevents electrolyte from reaching the bond arranged above it.

The sealing plug can be at the lower end below the second

Subarea have a Einführfase. The Einführfase can at the lower end of the sealing plug form a downwardly tapered area, using which can be successively pressed outwardly during insertion of the sealing plug into the projection of the inwardly bent portion of the projection. The inwardly bent portion of the projection, whose cross section may be slightly smaller than the cross section of the sealing plug in the second portion, can thus be widened by the Einführfase so that it conforms under mechanical tension to the lateral surface of the sealing plug.

Both the filling opening and the sealing plug can be a round

Have cross-section, wherein the closure plug may then be at least partially cylindrical. Due to the rotational symmetry, such filling openings and sealing plugs can be produced easily.

Outside the housing, the stopper may have a laterally projecting beyond the opening collar. This covenant may occur when inserting the

Closing plug into the filling hole serve as a mechanical stop, to prevent the plug is inserted too deeply into the filling opening or even pushed through the filling opening into the interior of the battery cell.

The adhesive used to bond the sealing plug to the cover plate may be a microencapsulated adhesive. Such microencapsulated adhesives contain tiny capsules filled with an adhesive substance. The microencapsulated adhesive can even before mounting the battery cell on surfaces to be bonded to the

Sealing plug and / or the cover plate are applied. When fitting the sealing plug into the filling opening, the microencapsulation is destroyed, so that the adhesive is released and after curing, the surfaces to be bonded mechanically stable. Microencapsulated adhesives are also used, for example, to secure screwed connections

independent loosening used. An example of a microencapsulated adhesive is sold under the trademark Loctite®.

The described possible features of the battery cell and configurations of the components of the battery cell, in particular the design of the cover plate and the sealing plug, are particularly suitable for use in battery cells whose housing has a prismatic shape. It should be noted that possible features and advantages of a battery cell according to the invention herein with respect to different

Embodiments are described. A person skilled in the art will understand that the individual features can be suitably combined or exchanged with one another, thus leading to further embodiments and possibly

To achieve synergy effects.

Brief Description of the Drawings Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings, wherein neither the description nor the description of the present invention will be described

Drawings are to be construed as limiting the invention.

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

FIG. 2 shows a cross-section of a sealing plug for a battery cell inserted into a filling opening of a cover plate according to an embodiment of the present invention. FIG. 3 shows a cross section of a sealing plug for a battery cell inserted into a filling opening of a cover plate according to another embodiment of the present invention.

FIG. 4 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

Fig. 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 wound stack 5 of a copper foil, which is coated with anode material, and a

Aluminum foil, which is coated with cathode material, and intervening plastic films, which serve as diaphragms on.

For electrical contacting, the copper foil and the aluminum foil along the winding axis in the opposite direction slightly staggered stacked, so that the copper foil on a narrow side and the aluminum foil on a

slightly overhanging the opposite narrow side over a respective edge of the Wckelelements. To a protruding portion 4 of the copper foil, a current collector 7 made of copper is welded, so that this current collector is electrically connected to the anode of Wckelelements. To an opposite projecting portion of the aluminum foil, a second current collector 9 made of aluminum is welded to make electrical contact with the cathode of the winding element 3.

The winding element 3 provided with the two current collectors 7, 9 is then introduced through an opening 14 into an upwardly open, cuboidal container 13. The container 13 is then provided with a lid assembly 15 in addition to a cover plate

23 still includes several other components, 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 formed of sheet metal to withstand, inter alia, the chemically aggressive electrolyte can.

The cover plate 23 has, among other things, a filling opening 25, through which electrolyte can be filled into the interior of the housing 1 formed by the container 13 and the lid assembly 15, after the cover plate 23 has been fastened to the container 13. The filling opening 25 may be formed, for example, with a round cross section and have a diameter of about 5 mm.

In conventional battery cells, the filling opening 25 is closed by means of a ball 26, which has a slightly larger diameter than the filling opening 25. The ball 26 is thereby pressed into the filling opening 25 and then welded circumferentially with the cover plate 23. FIGS. 2 and 3 show alternative ways of closing the filling opening 25 of a battery cell according to embodiments of the present invention

described. An inner edge of the filling opening 25 of the cover plate 23 is bent downward, for example, by a bending process, a deep-drawing process or an embossing process, so that a protrusion 29 projecting inwards into the housing 11 forms. This projection 29 may preferably have a round cross section, so that an inner surface 30 of the projection 29 has a cylindrical geometry. The projection can be, for example, 3 mm to 5 mm in the interior of the housing

protrude.

In the projection 29, a sealing plug 27 is inserted after the filling of the electrolyte. The closure plug 27 has an outer contour that corresponds approximately to the inner contour of the projection 29. In the case of a cylindrical projection 29, the sealing plug 27 has a likewise cylindrical shank 26 whose diameter is at most slightly smaller than an inner diameter of the projection 29. The sealing plug 27 has at its upper end, that is, the end remaining outside the housing 11 laterally over the filling opening 25 projecting collar 39.

On an outer surface 28 of the shaft 26 of the sealing plug 27, an adhesive 31, preferably a microencapsulated adhesive, is provided. A thickness of one

 Adhesive layer or the dimensions of the shaft 26 and the

Projection 29 are dimensioned so that the adhesive 31 comes into contact with the inner surface 30 of the projection 29 during insertion of the sealing plug 27 and optionally a microencapsulation is opened. After hardening of the adhesive 31, this thus ensures a stable fixation of the sealing plug 27 within the projection 29 of the filling opening 25.

In order to protect the adhesive 31 from attack by aggressive electrolyte, a sealing arrangement 35 is provided below the adhesive 31, that is, closer to the interior of the housing 11. In the example shown in FIG. 2, this sealing arrangement 35 is formed by means of an elastomer which surrounds the shaft in a ring-shaped manner and forms a sealing bead 33. This elastomer is on the one hand chemically resistant to the electrolyte and on the other hand has sufficient elasticity to provide a reliable seal between the inner surface 30 of the projection 29 and the lateral surface 28 of the shaft 26 of the sealing plug 27. The elastomer can be received in a groove 37, for example in the form of an O-ring and thus against an axial

Be slipped. For manufacturing the sealing plug 27, automatic turning can be used. As a fit between the sealing plug 27 and the filling opening 25, for example H7 / r6 can be selected, which corresponds to a slight pressure. The sealing bead 33 may, for example, 0.03 mm with a tolerance of 0.01 mm in

Have diameter.

FIG. 3 shows an alternative embodiment for closing the filling opening 25 with the aid of a sealing plug 27. Instead of a sealing bead 33, a seal between the projection 29 and the shaft 26 of the sealing plug 27 is accomplished here directly via a suitable configuration of the projection 29. A lower end 41 of the projection 29 is bent toward the center of the filling opening 25 such that the inner diameter of the projection 29 in this area is slightly smaller than the outer diameter of the shaft 26 of the sealing plug 27 before it is inserted into the projection 29. At a lower end of the shaft 26, a taper in the form of a cylinder-stump-like Einführfase 45 is provided. By means of this insertion chamfer 45, the inwardly bent edge region 41 of the projection 29 can be widened outwards during the insertion of the sealing plug 27 into the filling opening 25. In this case, an edge 43 at the lower end 41 of the projection 29 as a sealing arrangement 35 against the electrolyte seal against the shaft 26 of the sealing plug 27 create.

In this embodiment of the sealing plug 27 can be used for manufacturing, for example, a cold striking. As a fit again H7 / r6 can be selected. By means of embodiments of the present invention can be dispensed with consuming welding processes for closing the filling opening 25. Instead, you can the closure stopper is simply pressed into the filling opening 25 and held in the filling opening 25 by means of the possibly microencapsulated adhesive 31, which may have been previously applied, if possible. The sealing arrangement 25 prevents the adhesive 31 from being contacted and attacked by the electrolyte.

4 shows a motor vehicle 100 with a battery 102, which is composed of several of the battery cells 1 described above.

Claims

claims

 1. battery cell (1), in particular lithium-ion battery cell, comprising:

a winding element (3) consisting of a wound stack (5) of 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 foil and one to the second foil,

a housing (11) having a metallic container (13) and a cover assembly (15), the container (13) having an opening (14) through which the wedge element (3) and the two current collectors (7, 9) travel during the Production of the battery cell (1) in the housing (1 1) can be introduced

wherein the lid assembly (15) has a cover plate (23) and the opening (14) of the container (13) gas-tight and pressure-sealed,

the cover plate (23) having a filling opening (25) for filling electrolyte into the housing (11),

characterized in that

the filling opening (25) is closed with a sealing plug (27), wherein the sealing plug (27) is held in the filling opening (25) by means of an adhesive (31) and wherein a sealing arrangement (35) prevents the housing (11 ) filled electrolyte in contact with the adhesive (31) passes.

2. Battery cell according to claim 1, wherein the cover plate (23) at the filling opening (25) in the housing (11) protruding projection (29) and wherein the

Closing plug (27) is inserted into the projection (29) and wherein the

Closing plug (27) at a first portion of a lateral surface (28) with an inner surface (30) of the projection (29) is glued.

3. Battery cell according to claim 2, wherein the sealing plug (27) in a second

Partial region, which is arranged closer to the interior of the housing (1 1) relative to the first subregion of the lateral surface (28), which is glued to the inner surface (30) of the projection (29), a sealing bead (33) as a sealing arrangement (35 ) having.

4. Battery cell according to one of claims 1 to 3, wherein the sealing arrangement (35) is designed with an elastomer resistant to the electrolyte.

5. Battery cell according to claim 2, wherein a lower end (41) of the projection (29) is bent towards the center of the filling opening (25), that it with the

Closing plug (27) in a second portion, based on the first

Part of the lateral surface (28), which is glued to the inner surface (30) of the projection (29), closer to the interior of the housing (1 1) is arranged, comes into contact and acts as a sealing arrangement (35).

6. Battery cell according to claim 5, wherein the closure plug (27) at its lower end below the second portion of a Einführfase (45).

7. Battery cell according to one of claims 1 to 6, wherein the filling opening (25) has a round cross-section and the closure plug (27) is at least partially cylindrical.

8. Battery cell according to one of claims 1 to 7, wherein the closure plug (27) outside the housing (11) has a laterally beyond the filling opening (25) projecting collar (39).

9. Battery cell according to one of claims 1 to 8, wherein the adhesive (31) is microencapsulated.

10 motor vehicle (100) comprising a battery cell (1) according to one of claims 1 to 9.