WO2013064205A1 - Production method for an energy storage apparatus, and an energy storage apparatus which is produced by means of this method - Google Patents

Abstract

Method for producing an energy storage apparatus which has a dimensionally rigid housing device (3), an electrode assembly (2) and an electrode assembly foil device (1), wherein this electrode assembly (2) has at least a positive electrode and a negative electrode, and wherein this electrode assembly foil device (1) has a first (7a), a second (7b) and a third (7c) spatial extent, wherein this third spatial extent (7c) is low compared to this first (7a) and this second (b) extent, and wherein this electrode assembly foil device (1) can be moved from a first to a second state by means of a change in pressure, wherein this first and this second state differ from one another by virtue of a change in this third spatial extent (7c).

Description

 Manufacturing method for an energy storage device and an energy storage device produced by this method

description

Hereby, the entire contents of the priority application DE 10 201 1 1 17 471.4 by reference is part of the present application.

The present invention relates to a production method for

Energy storage devices and a device produced by this method.

In the following, the invention will be described with reference to the production of a

Energy storage device described which at least one

An electrode assembly, wherein an electrode assembly has at least one positive and one negative electrode, which are intended to convert electrical energy into chemically bonded energy during charging and chemically bonded into electrical energy during discharge. As a rule, these electrodes are at least partially surrounded by an envelope, wherein the envelope is usually of a form-elastic nature. This elasticity of the shape allows a certain size change of the electrode assembly without significant forces being exerted on the electrodes or on the cladding. Such a change in size is often caused by thermal and chemical processes and is in the operation of the

Energy storage device usually indispensable. Often are in known

Energy storage devices one or more of these electrode assemblies received in a usually dimensionally stable housing device, wherein only individual sections of the housing device can be dimensionally stable and other form-elastic. On the one hand, this housing device enables the energy storage device to be securely received and fastened; on the other hand, a planned force can be exerted on the electrode assemblies by means of this housing device, thus counteracting their excessive expansion during operation.

For applying the force to the electrode assembly, the

Housing device often an elastic deformable element, which is supported on this. Frequently, an elastic element is used which has substantially the same base area as the

Electrode assembly, since as the largest possible force on the electrode assembly can be achieved. This area is to be understood as the area between the two larger spatial areas

Extensions of the electrode assembly is clamped. In order to achieve a high power density of the energy storage device, this elastic element usually has a small size in its third spatial extent. This has the consequence that the elastic element is often designed as a film-like element, therefore often has little dimensional stability and thus is usually difficult to handle during assembly.

US4269907A and US5328778A each show sheet-like elastic members which are inserted between or in the electrode assemblies to exert a force on the electrode assemblies, especially when they expand.

The US20101 19927A shows a dimensionally stable housing in which a plurality of electrode assemblies are introduced. These electrode assemblies are surrounded by one or more elastic members, which exert a force on the electrode assemblies, particularly when the electrode assemblies are due to thermal or chemical processes expand. The elastic elements for applying the force effect can have a foam-like material.

An object of the present invention is to provide an improved

Production method and one produced by this manufacturing method

To provide energy storage device.

The object is achieved with a method according to claim 1, an energy storage device according to claim 7 and a

Energy storage device according to claim 13. Preferred developments of the invention are subject of the dependent claims.

In the inventive method for producing a

Energy storage device, an energy storage device is manufactured, which comprises a housing device, an electrode assembly and a

 Electrode assembly foil device has. The housing device is designed as a dimensionally stable housing device. The

Electrode assembly has at least one positive electrode and one negative electrode. In particular for generating a force effect on at least one electrode assembly, the energy storage device has an electrode assembly foil device. These

Electrode assembly foil means has first, second and third spatial extents. This third spatial extent is small compared to this first and second extension. Preferably, the first and second extents of the electrode assembly foil means substantially correspond to the two major spatial ones

Extensions of the electrode assembly. The electrode assembly foil device can be converted from a first to a second state by means of a pressure change. This first and second state differed from each other at least by a change in this third spatial extent. The method of making this Energy storage device has a sequence of operations.

At least this sequence has the steps:

• Insert the electrode assembly foil device into the

 Housing means,

 • changing a foil pressure, which is within the

 Electrode assembly foil device prevails, or changing a housing internal pressure, this at least within the

 Housing device prevails and

 That the housing device (3) after inserting one or

 several electrode assemblies (2) is closed.

First, the electrode assembly foil device is inserted into the housing device in a first step. Preferably, the housing device is dimensionally stable, in which case the term "dimensionally stable" in the sense of the invention means, in particular, that the housing device does not substantially deform under the action of significant forces. In particular on the preferably dimensionally stable housing device, a preferably elastically deformable device, in particular an electrode assembly foil device, can be supported and thus a force effect on the

Apply electrode assembly.

In a further working step, a pressure ratio between a foil pressure, wherein this prevails within the electrode assembly foil device, and a housing internal pressure, wherein this prevails at least within the housing device, is changed. For the purposes of the invention is to be understood by a ratio of the quotient of this film pressure and this housing internal pressure, wherein either the film pressure or the housing internal pressure can be in the numerator of the pressure ratio.

By changing this pressure ratio tends the

Electrode assembly foil device to expand, such Expansion is particularly in the direction of preferably dimensionally stable

Housing device essentially not possible and the

Electrode assembly foil device accordingly preferably exerts on the electrode assembly a force effect, preferably in the form of a surface load.

In particular, by changing this pressure ratio after inserting the electrode assembly film device in the

Housing device is a particularly simple insertion of this

or the electrode assembly in the housing device allows. This is achieved by the fact that the electrode assembly foil device has a smaller extension in at least one spatial direction before the change in this pressure ratio than after, the underlying object is achieved.

In particular, the fact that the size change and thus also the force effect of the electrode assembly foil device on the

Electrode assembly preferably on the degree of change of

Pressure ratio depends, it is possible that with otherwise identical components different electrode assemblies can be constructed. In particular, it is possible to vary the number of electrode assemblies and / or their thickness when used in the same housing device, and the changed thickness by different pressure conditions in the

Electrode assembly foil device to take into account. Thus, it is possible to use a higher number of identical parts or to make the production process flexible, since only the pressure ratio for different energy storage devices is changed, but not their housing device and so the underlying problem is solved. Optionally, the method according to the invention may have further work steps. An electrode assembly in the sense of the invention means a device which is used in particular for providing electrical energy. For this purpose, the electrode assembly has at least two electrodes

different polarity, wherein the electrodes are criticized by a separator. The electrode assembly is dischargeable and rechargeable, with ions of a conductive salt of an electrolyte migrating through the separator. When charging energy storage device takes place in the electrode assembly, a conversion of supplied electrical energy into chemical energy. At the

Discharging chemical energy in the electrode assembly is converted into electrical energy. The electrode assembly has at least one so-called.

On lateral surface, wherein the lateral surface of the electrode assembly for

Surrounded or limited to a housing device out.

In the context of the invention, a housing device is to be understood as meaning a device which serves in particular to accommodate at least one, but preferably a plurality of electrode assemblies. For this purpose, the

Housing device usually one or more dimensionally stable

Housing elements on. For the purposes of the invention, the term dimensionally stable means that such a housing element is essentially not deformed even under a significant force, in contrast to form-elastic elements, such as e.g. a plastic film, which is considerably deformable in certain spatial directions, even under the slightest force. Dimensionally stable housing elements have as one component in particular metallic materials, plastic or fiber-reinforced materials. Furthermore, the housing device preferably serves to at least partially prevent environmental influences such as external forces from the electrode assembly (s). Furthermore, the housing device serves in particular for a possibility of attachment of the energy storage device to other

Machine elements, in particular frame, carrier or

To provide plate elements. In the context of the invention, an electrode assembly foil device is to be understood as meaning a device which, by means of the modification of a

Pressure ratio of a first, in particular a compressed, in a second, in particular decompressed, state is convertible. In this case, these first and second states differ in particular in a change of at least one spatial extent of the

Electrode assemblies-foil device. In particular, the spatial

Extension in the second state greater than in the first state. The printing ratio is formed, in particular, from a film printing which prevails within at least one part of the electrode assembly film device, whereby this interior of the electrode assembly film device can initially also be completely evacuated and further from a housing internal pressure. This housing internal pressure initially prevails at least within the housing device. Preferably by a change in the pressure ratio, ie by increasing the film pressure relative to the housing internal pressure or by lowering the internal pressure of the housing relative to the film pressure or a combination of both

Measures, the electrode assembly foil device is transferred from this first in this second state. The transfer of this first into this second state is therefore according to the

Executed air mattress principle, with this principle by the

Change in the pressure ratio, between air pressure inside the foil-like air mattress and the air pressure outside of it, one

Changes in size of the air mattress is effected. Next is one

For the purposes of the invention, electrode assembly film device should be understood as an open-pored or closed-pored film device.

Open porous is to be understood in the sense of the invention that the

Electrode assembly film device having cavities, said cavities are at least partially closed not gas-tight and so gas exchange between cavities with each other or with the environment surrounding the electrode assembly foil device is enabled.

By closed-cell, on the other hand, in the sense of the invention is to be understood that the electrode assembly foil device has cavities, these cavities being substantially gas-tightly closed, in particular with the environment surrounding the electrode assembly foil device no gas exchange takes place. In a preferred embodiment, the housing device is closed in a further step. Here, the closing of the

Housing device happen before or after changing the pressure ratio. The closing of the housing device is preferably to be understood as meaning the positive, non-positive or cohesive closing of the housing device. Further preferably, under the

closing the housing means to understand the attachment of a cover device on the housing means. This cover device can preferably be connected to the housing device. Preferably, this cover device, in the case of a cohesive connection, glued or welded, in the case of a positive or non-positive connection, screwed, riveted, verklippt or pressed.

Preferably, an anaerobic adhesive is used to close the housing means. Such an adhesive is to be understood as meaning an adhesive which cures with completion of the supply of air. Further

Preferably, other adhesives are conceivable. However, an adhesive of the aforementioned type has the advantage that it hardens only or the curing only significantly accelerated when the cover device is placed on the housing device, since in particular only at this time enters the air termination. In contrast, one would

conventional adhesive already begin to cure at the time of application. When using an anaerobic adhesive can Adhesive surpluses are easily removed from the housing as they do not cure, thus providing an improved manufacturing process.

Also preferred is the use of a multi-component

Adhesive conceivable, preferably a first component of

 Adhesive adheres to the housing device and adheres a second component of the adhesive of the lid device. It is preferably also conceivable that a first and a second component of this adhesive are applied to only one component (housing device, cover device) and activated by the joining of these two components. This can be achieved in an advantageous manner in that one of these two adhesive components is introduced into a pressure-sensitive packaging, which package releases its contents when a pressure is applied, as occurs when joining the two components mentioned. Such a two-component adhesive also offers the advantage over conventional adhesives that the curing of the adhesive does not begin until the housing device is closed. By using a multi-component adhesive, the application of the adhesive to the Zufügenden component from the rest

Production process, at least locally, be separated thereby can reduce unwanted impurities and it is an improved

Manufacturing method provided.

In a preferred embodiment, the sequence of operations for manufacturing the energy storage device is arranged such that first the electrode assembly foil device is inserted into the housing device and subsequently the at least one electrode assemblies. In a further preferred embodiment, the sequence of operations is arranged in such a way that first the electrode assembly in the

Housing device is used and subsequently the

Electrode assemblies-foil device. Further preferably, the

Electrode assembly foil device together with the

Electrode assembly can be used in the housing device. The The first-mentioned sequence of working steps offers the advantage that in particular the hard-to-handle electrode assembly foil device (high flexibility) can be inserted particularly easily into the housing device and thus a faster assembly of the energy storage device is made possible. In the second-mentioned sequence of operations offers the advantage that the electrode assembly, which is sensitive to external influences, such as force effects, can be used very early in the production process in the protective housing device, thus becomes a

Manufacturing method with low probability of error provided. In the latter common use of the electrode assembly foil device with the electrode assembly in the housing means, the electrode assembly foil means forms a kind of protective sheath for the electrode assembly as long as it is outside the housing means. A package of electrode assembly foil device and

Electrode assemblies can be particularly easily used in the housing device, thus an improved Hers is part process provided.

In a preferred embodiment, after insertion of the

Electrode assembly foil device in the housing device of

Foil pressure increased. In particular, by this pressure increase, the electrode assembly film device expands and this preferably leads to the electrode assembly foil device at the

Housing device supports and a force on the

Applying electrode assemblies. Preferably by increasing the

Foil printing after inserting the electrode assembly foil device in the housing means on the one hand facilitates insertion, including the electrode assembly, and on the other hand by the advantageous

Force action of the electrode assembly foil device on the

Electrode assembly has improved functions of

Energy storage device achieved. An advantage of the pressure increase within the electrode assembly foil device is that this device normally has a low volume and thus only a small amount Energy input is necessary to increase the pressure. By the action of force on the electrode assembly, the individual electrodes are preferably pressed together flat, here by the detachment of the electrodes is counteracted by thermal or chemical processes and enables an improved function of the energy storage device.

 In a preferred embodiment, after insertion of the

Electrode assembly foil device reduces the housing internal pressure. In particular, by this pressure reduction, the expands

Electrode assembly foil device, this preferably leads to the electrode assembly foil device at the

Housing device supports and a force on the

Apply electrode assembly. Preferably, by reducing the internal pressure of the housing after inserting the electrode assembly foil device into the housing device, on the one hand a simplified introduction of the electrode assemblies into the housing device is made possible and on the other hand an improved function of the energy storage device is achieved by the advantageous force effect of the electrode assembly foil device on the electrode assemblies. An advantage of the pressure reduction is in particular that the cover device by the outside of the

Housing device prevailing, compared to the housing internal pressure higher, air pressure is pressed onto the housing device and thus an additional sealing effect of the housing device can be achieved.

A produced by means of the production process according to the invention

Energy storage device has at least one preferably dimensionally stable housing device, an electrode assemblies and at least one

Electrode assembly foil device on.

In a preferred embodiment, the electrode assembly foil device has a base, which is substantially the same

Base area of the electrode assembly corresponds. Preferably, the electrode assembly has a substantially rectangular base body. Further preferably, the electrode assembly also in the

Have substantially cylindrical body with preferably circular or elliptical cross-sectional area. In the case of a cylindrical base body, the electrodes of the electrode assembly are preferably wound around a cylinder axis. In this case, the decisive base area for the electrode assembly foil device is the base surface which these electrodes have before winding, or the lateral surface of this cylindrical base body. By adapting the

Electrode assembly foil means to the footprint of at least one electrode enables a preferably uniform pressure to be applied to a large area of the electrode assembly, which often has a positive effect on performance, particularly in the case of current removal and feed, thus providing an improved energy storage device. Further preferably, the electrode assembly foil means comprises a dimensionally stable element for uniform pressure distribution. This dimensionally stable element may preferably be used as a kind of intermediate plate between the electrode assembly foil device and the

Electrode assembly understood. By the uniform

Pressure distribution on the electrode assembly is an improved function of the energy storage device achievable because the individual electrodes are pressed flat against each other.

In a preferred embodiment, the electrode assembly foil device has an open-pore structure. Preferably, the

Electrode assembly foil device to a material, wherein this has a foam-like structure and is elastically deformable. Materials with an open-pore structure generally have a preferably good elastic deformability and are suitable for high degrees of deformation. By a high degree of deformation, which describes the relationship between deformed and undeformed state, it is possible for the electrode assembly to be easily inserted into the housing device when the electrode assembly foil device is deformed. In a further preferred embodiment, the

Electrode assembly foil device has a closed-pore structure. Preferably, the closed pores of such a structure are filled with a compressible medium, preferably with a gas, more preferably with air. Further preferably, the filling of these pores is provided with a non-flammable, preferably with a reaction-inhibiting gas. By a high ambient pressure, the individual cavities of the closed-pore structure and the medium absorbed therein

compressed and reduces the dimensions of the electrode assembly foil device. The resulting at least a reduced dimension of the electrode assembly foil device resulting from this compression results in ease of insertion, both of the

Electrode assembly foil device as well as the electrode assembly is made possible in the housing device. Further preferably, by means of the closed-pored structure reactants, such as

non-combustible gases or other reaction-inhibiting substances into which

Housing device are introduced. In the event of danger, these media are regularly pressed out of the closed-pore structure, since in such a case either the electrode assembly can expand considerably or the housing device can be deformed. By this pressing out the reactants are distributed in the housing device and can develop a good effect. Preferably by these non-combustible or reaction-inhibiting media is thus in the case of

Damage to the electrode assembly an unwanted reaction of ingredients this already within the housing device reduced, braked or inhibited and thus provided an improved energy storage device. In a preferred embodiment, the electrode assembly foil device is received within the electrode assembly.

Preferably, the electrode assembly foil device is within the Electrode assembly included if this has a cylindrical basic shape. Preferably, the electrode assembly foil device is wound around the cylinder axis, around which the electrodes of the

Electrode assembly are wound. Preferably, the

Electrode assembly foil means disposed inside or outside a sheath of the electrode assembly. By introducing the

Electrode assembly foil device in the electrode assembly is a particularly simple and space-saving design of the energy storage device allows and thus an improved energy storage device for

Provided.

 Other features, advantages and embodiments of the present invention will become apparent from the following description of the accompanying drawings.

Showing:

1 shows a section through an energy storage device with several

 FIG. 2 shows a section through an energy storage device with a rectangular cross-sectional area and two electrode assembly foil devices;

 cylindrical electrode assembly having a circular cross-sectional area and an electrode assembly foil device,

3 shows an energy storage device before the electrode assemblies with electrode assembly foil device are inserted into the housing device.

Fig. 1 shows a section through an energy storage device. These

The energy storage device has two electrode assembly foil devices 1, a plurality of electrode assemblies 2, a housing 3 and a cover device 4. The electrode assembly film device 1 is supported on the one hand on the housing device 3 and exerts on the Electrode assemblies 2 from a force effect. By means of this force effect, the function of the electrode assemblies is improved because a detachment of the

Electrodes (not shown) is avoided. Next, the

Housing device 3 stiffening ribs 5 on. By means of these stiffening ribs, on the one hand, the rigidity of the housing device 3 is increased, on the other hand the surface area of the latter is increased and thus improved heat dissipation from the housing device 3 is achieved. In a warming of

Electrode assemblies, as typically occurs when energy is stored and expelled, usually expand the electrode assemblies, this expansion can in extreme cases to a separation of the

Electrodes within the electrode assemblies come. With increased expansion of the electrode assemblies 2, the force effect that the electrode assembly film device 1 on the

Electrode assemblies 2 exerts, thus the function of the

Energy storage device further improved.

2 shows a section through a cylindrical energy storage device, wherein the electrode assembly 2 here has a circular cross-sectional area, radially outside the electrode assembly 2 is the

Electrode assembly foil device 1 is arranged. The

Electrode assembly foil device 1 is supported on the

Housing device 3 and generates a force on the

Electrode Assembly 2. The electrode assembly 2 is wound around the cylinder axis 6.

3 shows a plurality of electrode assemblies 2 arranged laterally

Electrode assembly film devices 1 before they are used together in the housing device 3. In the present case, the film pressure PEBF, that is to say the pressure within the electrode assembly film device, is lower than the ambient pressure PU G, the ambient pressure also prevailing within the housing device. Due to the greater ambient pressure, the electrode assembly foil device is compressed, especially in its third spatial extension 7c. The first spatial extent 7a and the second spatial extent 7b of the electrode assembly foil device largely correspond to the first 8a and second 8b spatial extent of the electrode assembly. After inserting the electrode assemblies 2 with the electrode assembly film devices 1 into the housing device 3, the pressure ratio between the pressure within the electrode assembly film device PEBF and the pressure within the housing device 3 is changed so that the spatial extent 7c of the electrode assembly film device changes so that that this is a force on the

Applying electrode assemblies.

LIST OF REFERENCE NUMBERS

1 electrode assembly foil device

 2 electrode assembly

 3 housing device

 4 lid device

 5 stiffening rib

 6 cylinder axis

 7a first spatial extent of the electrode assembly foil device

 7b second spatial extent of the electrode assembly foil device

 7c third spatial extent of the electrode assembly foil device

 8a first spatial extent of the electrode assembly

 8b Second spatial extension of the electrode assembly

 PUMG ambient pressure

 PEBF pressure within the electrode assembly foil device, foil pressure

Claims

Godfather testing

Method for producing an energy storage device,

 which a dimensionally stable housing device (3), a

 Electrode assembly (2) and an electrode assembly foil device (1),

 said electrode assembly (2) having at least a positive electrode and a negative electrode, and

 said electrode assembly foil means (1) having a first (7a), a second (7b) and a third (7c) spatial extent, said third spatial extent (7c) being small relative to said first (7a) and second (7b ) Extension and where

 this electrode assembly foil device (1) by means of a

 Pressure change from a first to a second state

 can be converted, with this first and this second state by a change of this third spatial extent (7c) differ from each other, characterized by

 the work steps

 Inserting the electrode assembly foil device (1) into the housing device (3),

 • changing a pressure ratio, this being

 Pressure ratio has a film pressure, wherein this prevails within the electrode assembly film device (1) and has a housing internal pressure, wherein this at least within the housing device (3) prevails and

• that the housing device (3) after the insertion of one or more electrode assemblies (2) is closed. 2. A method for producing an energy storage device according to one of claims 1, characterized in that

the electrode assembly foil device (1) together with the Electrode assembly (2) is inserted into the housing device (3).

A method for producing an energy storage device according to at least one of claims 1 or 2, characterized in that

before the electrode assembly foil device (1) in the

Housing device (3) is inserted, the electrode assembly (2) is inserted into this or vice versa.

Method for producing an energy storage device according to one of claims 1 to 3, characterized in that

after the insertion of the electrode assembly foil device (1) into the housing device (3), the foil pressure is increased.

Method for producing an energy storage device according to one of claims 1 to 3, characterized in that

after inserting the electrode assembly foil device (1) into the housing device (3), the housing internal pressure is reduced.

Energy storage device, produced by a method according to one of claims 1 to 5, wherein said energy storage device is dimensionally stable housing means (3),

an electrode assembly (2) and

an electrode assembly foil device (1).

Energy storage device according to claim 6, characterized in that

this electrode assembly foil device (1) has a base area (7a × 7b) which essentially corresponds to the base area (8a × 8b) of this electrode assembly (2). Energy storage device according to one of claims 6 to 7, characterized in that

 the housing device (3) stiffening ribs (5).

Energy storage device according to one of claims 6 to 8, characterized in that

 the electrode assembly foil device (1) has an open-pored structure.

Energy storage device according to one of claims 6 to 8, characterized in that

 the electrode assembly foil device (1) has a closed-pore structure.

Energy storage device according to one of claims 6 to 10, characterized in that

 the electrode assembly foil device (1) within the

 Electrode assembly (2) is received. 12. Energy supply system, characterized by

 at least one energy storage device according to the invention, preferably a plurality of these energy storage devices.