DE102013002152A1 - Electrical storage cell for use in electrical storage module of vehicle, has electrical non-conductive insulating jacket including electrical non-conductive cell cover that covers top surface of cell case along boundary to cell case - Google Patents

Abstract

The cell (100) has a large extent prismatic cell case (101) comprising a cell cladding part (102), a top face (103) and an bottom part (104). Electrical cell terminals (105, 106) are arranged at the top face of the prismatic cell case. An electrical non conductive insulating jacket (107) i.e. heat shrink sleeve, encloses the cell cladding part and includes an electrical non conductive cell cover (109) that covers the top surface of the cell case along a boundary (108) of the cell case. A cell bottom part is provided with a heat conducting element. An independent claim is also included for a method for manufacturing an electrical storage cell.

Description

The invention relates to an electrical storage cell. The invention further relates to an electrical storage module. The invention also relates to a method for producing an electrical storage cell.

State of the art

From the DE 10 2009 042 270 A1 are known an insulation device for an electrochemical energy storage unit and a method for producing such an insulation device, wherein the insulation unit comprises a cooling plate, which is designed for thermal contacting with the electrochemical energy storage unit, wherein the cooling plate has at least one opening. Furthermore, the insulation device comprises a contact rail, which is designed to dissipate heat. Also, the isolation device has a holding element for fixing an arrangement between the cooling plate and the contact rail, wherein the holding element has a shaft which extends through the opening of the cooling plate. In this case, a first intermediate space is defined by a distance between a wall of the opening and the shaft and / or a second intermediate space defined by a distance between an edge of the contact rail and the shaft. Finally, the insulating device comprises a connecting element having a surface which comprises an electrically insulating material, wherein the connecting element is arranged between a main surface of the cooling plate and a surface of the contact rail and further comprises a partial region which projects into the first and / or second intermediate space.

The known isolation device is geared to cooling an electrochemical energy storage unit or an electrochemical energy storage cell via their electrical arresters, ie their connections or contacts. This will, as in the WO 2009 006 998 A1 is described in more detail, in a plurality of flat formed energy storage cells, which are arranged with their flat side parallel to each other and form a cell stack, led out a surge arrester via an end face of the energy storage cell and electrically and mechanically contacted via a connecting element with a surge arrester another energy storage cell. The connecting element is U-shaped and provided with openings, which serve as a receptacle for rivet mandrels. By Nietdorne, which are preferably made of plastic, a mechanical connection between the connecting element and a heat sink is ensured. Between the heat sink and the connecting element, a heat-conducting foil is arranged. On the one hand, the heat-conducting foil serves to release the heat from the connecting element to the heat sink and, on the other hand, to avoid a short circuit of the individual cells via the heat sink. Such, so-called Ableiterkühlung makes it possible to derive the heat directly from the energy storage cell, but it should be ensured a secure electrical insulation.

To get out of the WO 2009 006 998 A1 known electrochemical energy storage unit to provide an improved isolation device, is in the DE 10 2009 042 270 A1 proposed an extension of a Kriechstromwegs for carrying out a mandrel or rivet pin called retaining pin by a contact rail and a cooling plate, wherein the cooling plate and the contact rail are separated by an electrically insulating heat conducting foil. The heat-conducting foil has a partial region which optionally projects into the intermediate space between a wall of the opening of the cooling plate and the shank of the holding journal and / or into the intermediate space between the contact rail and the shank of the holding journal. Thereby, the path of a possibly occurring leakage current between the cooling plate and the contact rail is extended and thereby improves the electrical insulation between the contact rail and the cooling plate.

From the DE 10 2010 020 065 A1 For example, an energy storage module comprising a plurality of prismatic storage cells and a method for producing such an energy storage module are known. The memory cell described in this document typically consists of one or more individual electrochemical cells. On a front side, the memory cell has a first polarity connection terminal and a second polarity connection terminal. On the back of the memory cell no connection terminals are provided. One of the connection terminals, typically the positive pole of the memory cell, may be electrically connected to a housing of the memory cell.

The prismatic memory cells are arranged in the energy storage module stacked at least one row behind the other. Therefore, at least opposing major surfaces of the memory cells are provided with an electrically insulating material. As an example, the application of an adhesive film or an electrically insulating adhesive to the main surfaces or the use of a shrink tube, which is applied to the glued main surfaces is described. In addition to inhibiting the movement of the memory cells relative to one another, this additionally provides voltage isolation protection between the adjacent memory cells. This allows the direct stacking of the memory cells z. B. even if a respective coat of Memory cells represents a voltage-carrying component of the memory cells.

The adhesive film or the alternatives mentioned must be in accordance with the description of DE 10 2010 020 065 A1 provide only a low voltage isolation to provide isolation to the adjacent memory cell of a memory cell array. The use of an adhesive layer on an adhesive film or a heat-shrinkable tube applied to the memory cell for the production of the insulation also allows a compact arrangement of the memory cells in succession, so that the energy storage module can be provided in a space-optimized manner.

In order to form the energy storage module, the prismatic storage cells, which are arranged stacked one behind another in at least one row, are tensioned between two end plates via tie rods. In addition to the mechanical fixing of the modules to one another, the end plates and tie rods forming a module frame serve, in particular, to counteract deformation due to gas pressure changes which occur during operation in the electrochemical cells arranged in the interior of the modules. Within the module, a respective memory cell row is separated from the end plates and the tie rods by a multi-part insulating jacket with electrical insulation properties completely surrounding the memory cell row. The task of the insulation sheath is to provide a high-voltage insulation. The electrical insulation properties of a respective insulation jacket are such that it provides contact protection with respect to a voltage obtained by the serial connection of all the memory cells of the energy storage module. Since this voltage can be above the Berührschutzgrenze, a protection for the assembler performing assembly is provided by the insulation coats. The provision of the insulation sheath thus ensures that the pressure frame formed from the end plates and the tie rod is electrically insulated.

It has been shown in practice that the electrical insulation achieved by this construction between the sheaths of the memory cells on the one hand and the module frame on the other hand is not sufficient in the operation of the memory cells.

DESCRIPTION OF THE INVENTION: Problem, Solution, Advantages

The invention has the object to improve the insulation of the cell housing to the module frame in a memory cell and an energy storage module of the type described.

This object is achieved by an electrical storage cell having an at least substantially prismatic cell housing, which comprises a cell casing, an upper side and a lower side, wherein electrical cell terminals are arranged on the upper side of the cell casing, wherein the storage cell further comprises a cell casing at least substantially enclosing the entire surface, comprises electrically non-conductive insulating jacket and a top of the memory cell at least along its boundary to the cell cladding covering and at least substantially form-fitting manner adjacent to the insulating, electrically non-conductive cell cover.

In this case, a prismatic body is in the definition customary in mathematics, as in the publication retrievable via the Internet http://de.wikipedia.org/wiki/Prisma_(Geometrie) can be seen, a geometric body having a polygon as a base and the side edges are parallel and equal length. A prism is created by parallel displacement of a plane polygon along a line in space that is not in this plane. If the parallel shift of the polygon is perpendicular to the base, a straight prism is created. The other, congruent to the base and parallel boundary surface forms the top surface of the prism. The totality of all other boundary surfaces is referred to as a lateral surface, which consists of a straight prism of rectangles.

Thereafter, the cell housing is preferably designed at least substantially as a straight prism, wherein the base of the prism, the underside of the cell housing, the top surface of the prism, the top of the cell housing and the lateral surface of the prism forms the cell casing. Further preferably, but not necessarily, the underside and the top of the cell housing are at least substantially formed as rectangles, more preferably as rectangles with a width substantially greater length. In one embodiment, the bottom and top of the cell housing may have a length that is about 5-6 times the width.

In the case of the electrical storage cell according to the invention, the cell lid is arranged on the upper side of the cell housing having electrical cell connections. In order to gain access to the electrical cell terminals even when the cell lid is mounted, the cell lid preferably has recesses through which the electrical cell terminals on the top side of the cell housing so that electrical connections of the cell terminals can be made outside the cell lid.

The cell jacket at least substantially enclosing the entire surface, electrically non-conductive insulating jacket is preferably made of an electrically insulating film. For a simplification of the attachment, this film is particularly preferably self-adhesive, ie provided with a self-adhesive coating. The electrically insulating film may simply be wound around the cell casing, ie the cell casing. According to another preferred embodiment of the insulating jacket is formed of a tubular insulating material, ie a shrink tube which is shrunk onto the cell jacket.

The invention is based on the finding that the existing in the known memory cells and energy storage modules creepage distances of electrical currents between the module frame of the energy storage module and the cell jacket of the individual memory cells are insufficient, especially if the energy storage module and the individual memory cells are exposed to the ongoing influence of dirt and moisture , It has been found that this disadvantage is not alone, at least not reliably repairable by attaching an insulating jacket. On the one hand, a sole insulation with such an insulating jacket, in particular in the form of a foil or a heat-shrinkable tube, can not yet reliably protect all live components of an electrical storage cell against leakage currents or voltage flashovers. On the other hand, it is found that the design of such an insulating jacket in manufacturing is subject to high tolerances, so that the design of creepage distances is subjected to such strong fluctuations by such insulating only in practice and thus given no sufficient security of the electrical storage cell against leakage currents or voltage flashovers is.

The invention now makes it possible in a simple manner to reliably isolate the individual electrical storage cells from each other and from a module frame when installed in an energy storage module, since a reliable design of sufficiently long creepage distances in close manufacturing tolerances is achieved by simple means. In addition, the cell lid offers the possibility of positioning the memory cells in the module frame by means of the cell cover, preferably by means of a preferably at least substantially rigid configuration, in particular in the case of memory cells that are mechanically elastic within certain limits due to their internal structure. This offers further advantages explained in the context of the following description in the context of the present invention.

Preferred and advantageous embodiments of the invention are characterized in the subclaims.

In a preferred development of the electrical storage cell according to the invention, the cell cover is materially connected to it along its at least largely positive abutment against the insulating jacket. This reliably avoids possible gaps between the cell lid and the insulating jacket, which arise during a period of operation of the electric storage cell along said abutment and could form undesirable creepage distances, in particular in connection with penetrating dirt or moisture. As a result, the creepage distances are extended effectively and reliably by this development and thus increases the safety against voltage flashovers.

According to an advantageous embodiment of this in addition to the mere adjacency of the materials of these two construction elements of the electrical storage cells, namely the cell cover and the insulating jacket, executed material connection of the cell cover is glued along its at least largely positive abutment of the insulating jacket with this and / or welded and / or shed. An adhesive bond between cell cover and insulating jacket can preferably be effected by a self-adhesive coating of the insulating jacket. Advantageously, however, an adhesive can also be applied along the boundary of the insulating jacket to the cell lid for an adhesive seam. This is particularly the case when the insulating sheath is shrunk from a tubular insulating material. Furthermore, the connection can also be produced by a potting compound, which is preferably introduced into a formation along a boundary of the cell cover, wherein the boundary of the cell cover and thus the shape along the boundary of the top of the memory cell comes to lie to the cell cladding. Preferably, the molding together with an adjacent boundary of the insulating jacket forms a groove into which the potting compound is filled.

Depending on the materials selected for the cell cover and the insulating jacket, both can also be welded together along the delimitation of the upper side of the storage cell to the cell jacket, eg. B. by plastic welding.

According to another embodiment of the electric storage cell according to the invention, the latter has a cell bottom which covers the underside of the storage cell at least along its demarcation from the cell casing and at least substantially in a form-fitting manner adjacent to the insulating casing. The cell bottom allows in a for Cell cover corresponding manner an electrically insulating termination of the electric storage cell, in particular the underside of the memory cell, compared to a module frame when installed in an energy storage module and thus a well-defined training there creepage distances occurring. In addition, the cell bottom protects the electrical storage cell from damage, the z. B. may occur when installed in an energy storage module, and in the handling of such an energy storage module.

In a preferred embodiment of the electrical storage cell according to the invention are cell terminals exclusively at the top of the memory cell and the cell bottom covers the underside of the memory cell over the entire surface, whereby a very good electrical insulation is obtained. More preferably, the cell bottom is adhered to the underside of the memory cell, wherein an adhesive used for this purpose advantageously has electrically insulating properties.

According to a further embodiment of the electrical storage cell, the cell bottom is materially connected along its at least largely positive abutment against the insulating jacket. Such a connection may be made according to the above-described connection between the cell cover and the insulating jacket. Thus, in addition to adjoining the materials of the cell bottom and the insulating jacket are connected to each other here. This connection can again be carried out in such a way that the cell bottom is adhesively bonded and / or welded and / or sealed along its at least largely positive abutment against the insulating jacket.

According to another development of the electric storage cell according to the invention, the cell bottom comprises a substantially flat, heat-conducting element, of which at least parts are in heat-conducting connection with the underside of the prismatic cell housing. In this case, the heat-conducting element of the cell bottom and the underside of the prismatic cell housing are preferably electrically insulated from one another.

In such a configuration of the electrical storage cell according to the invention, in which all electrical cell connections are preferably arranged on the upper side of the cell housing of the storage cell, the storage cell is advantageously cooled via the underside of the cell housing and the cell bottom. As a result, a mutual obstruction of the cooling at the bottom of the cell housing of the memory cell on the one hand and the electrical connections on the upper side of the cell housing of the memory cell on the other hand is excluded.

In an advantageous development of the electrical storage cell according to the invention, the cell bottom is formed with a metal plate which is at least partially enveloped by insulating material. This represents a particularly simple and inexpensive to manufacture embodiment of the heat-conducting, but electrically insulating element in the cell bottom. Preferably, the metallic plate is formed as an aluminum plate, which is injected into an electrically insulating plastic and arranged by means of which electrically insulated against the bottom of the cell housing of the memory cell ,

According to another embodiment of the electrical storage cell according to the invention, the cell cover and / or the cell bottom are each formed with a peripheral edge that runs around the insulating jacket at least largely along its abutment, which serves as a template for shaping a boundary of the insulating jacket adjoining the cell cover or the cell bottom , In particular, this cutting edge serves as a simple and precise template for a quick and accurate trimming of the insulating jacket and thus a cost-effective in tight manufacturing tolerances possible shaping of the boundary of the insulating jacket.

In another development of the electrical storage cell according to the invention, the cell lid is formed with a positioning aid for positionally accurate positioning of the storage cell in a module frame. A cell cover designed in this way forms the possibility of positioning the memory cells in the module frame in a defined manner, particularly in the case of memory cells which are mechanically elastic within certain limits due to their internal structure. The positioning aid preferably forms a stop of the individual electrical storage cell with respect to the module frame. This allows the memory cell in a defined position against a cooling device, for. B. a cooling plate on which the memory cell is applied to the cell bottom pressed. There is thus provided a defined, close heat-conducting contact from the underside of the cell housing via the cell bottom to the cooling device, whereby the efficiency of the cooling device is improved and a defined, uniform cooling of the memory cells in the module frame is obtained.

In addition, the prescribed design of the cell cover allows secure, stable and protected against damage mounting the individual electrical storage cells in the module frame. Injuries, in particular of the insulating jacket can be prevented.

According to yet another refinement of the electrical storage cell according to the invention, the cell cover is designed with a contacting aid for connecting at least one electrical connection element to at least one of the electrical cell connections in a manner that confuses with certainty. The contacting aid preferably comprises a spatial configuration of at least one part of the cell cover for the positive, confusion-proof connection of the at least one electrical connection element to the at least one of the electrical cell connections. The spatial configuration of the at least one part of the cell cover provided as a contacting aid is thus associated with the at least one connecting element, preferably positively, suitably shaped such that a confusion of the electrical cell terminals and thus a reversal of polarity of the electrical memory cell during connection is reliably avoided, because a certain Connecting element fits only to a predetermined cell connection and can be mounted only on this.

Such a contacting aid can be advantageously used both for contacting a single electrical memory cell designed according to the invention and, in particular, for contacting an entire energy storage module comprising a plurality of such electrical memory cells.

The above-mentioned object is further achieved by an electrical storage module, in particular for a vehicle, comprising at least one electrical storage cell of the type described above. In such an electrical storage module, here also designated by the term energy storage module, preferably several of the electrical storage cells are combined in a module frame and are characterized by this in a compact assembly for handling and installation, for. As in a vehicle, held together and protected against damage. The design of the electric storage cells with cell covers ensures a simple and secure arrangement of the storage cells within the module frame, since the storage cells can preferably be aligned and fixed to one another and to the module frame by means of the cell cover and possibly additionally the cell bottoms. In this case, the cell lid and cell bottoms also provide protection against damage to the electrical storage cells during the installation process in the storage module.

In an electrical memory module having a plurality of electrical memory cells, electrical connection elements for connecting to electrical cell terminals of the electrical memory cells can be combined to form a common assembly contacting unit and the contacting unit can form-locking elements for positive connection for connecting to the electrical cell connections, confusion-safe assembly of the contacting unit the Kontaktierhilfen the cell cover of the electric storage cells.

The contacting unit as a common assembly allows a quick and confusion-safe contacting of memory modules with a larger number of memory cells, the Kontaktierhilfen the cell cover by their training with particular geometric elements for torsionally secure mounting of the contacting serve with respect to the memory cells. Conversely, the contacting unit can be used in the manner of a template for the unmistakable assembly of the individual electrical memory cells to the memory module.

Thus, in this way, the cell cover can be equipped with a form-locking system on which the contacting unit is attached. In particular, the contacting unit can be locked on such a positive locking system.

The above-mentioned object is also achieved by a method for producing an electrical memory cell formed in the manner described above, comprising the following method steps: fixing, preferably gluing, a cell cover on an upper side of a cell housing of the electrical memory cell and at least substantially full-surface application, preferably gluing, an electrically non-conductive insulating jacket on a cell jacket, wherein the insulating jacket with its boundary adjoins an edge of the boundary of the upper side of the memory cell to cell shell coming edge of the cell cover at least substantially positive fit. In this case, the cell lid is thus first glued to the top of the cell case, so that for the subsequent attachment of the insulating jacket on the cell casing a boundary is specified up to which the insulating jacket should extend. The insulating jacket is then applied in a single step on the cell jacket and at the same time on the edge of the cell cover, preferably glued.

An advantageous development of the method according to the invention is characterized by a further, before the application of the insulating takes place process step: attaching, preferably bonding, in particular at least almost full-surface bonding of a cell bottom on a bottom of the cell housing. Through the cell bottom is for subsequent attachment of the Insulating sheath on the cell casing given a further boundary, up to which the insulating jacket should extend. An at least largely form-fitting joining of the insulating jacket to the further boundary formed by the cell bottom is obtained in the same working step in which the insulating jacket is applied to the cell jacket. Overall, an all-round electrical insulation of the electrical storage cell.

The insulating jacket can be applied for example as a self-adhesive film. In the simplest case, a self-adhesive configuration of the insulating jacket at the same time also produces a not only positive, but also material connection to the edges of the cell lid and the cell bottom, without requiring a further work step. In a modification of this method, this connection is made by an additional adhesive seam by connecting the insulating jacket to the cell lid and / or the cell bottom by applying a seam formed of an adhesive. The adhesive is introduced separately as a seam, preferably in a correspondingly formed in the cell cover along the boundary of the top of the memory cell to the cell shell coming edge shaped groove. A corresponding connection of the insulating jacket takes place on the bottom of the cell on the underside of the cell housing. This modification of the method is preferably used when the insulating jacket without self-adhesive design z. B. is formed by a shrink tubing.

According to another development of the method according to the invention is carried out as a further step after applying the insulating forming a forming of the cell cover or the cell bottom boundary of the insulating jacket by separating the insulating jacket along cut edges, at least substantially along the cell cover and / or cell bottom their adjacencies are formed circumferentially on the insulating jacket and thereby serve as templates for the molding of the adjacent to the cell cover or the cell bottom boundary of the insulating jacket.

Accordingly, the insulating jacket is applied to the cell housing in such a way that, with its borders adjacent to the cell lid or the cell bottom, it first projects beyond adjoining edges of the cell lid or the cell bottom. These boundaries of the cell lid or the cell bottom are formed with the cut edges. The insulating sheath thus initially protrudes beyond these cut edges. Subsequently, a trimming of the insulating jacket along the cut edges is made. For this purpose, it is only necessary to guide a cutting tool, in particular a knife-like cutting tool, once around the contour of the cell lid or the cell bottom at the cut edges. The cut edges thereby effect a precise shaping of final edgings of the insulating jacket produced in this way.

The described trimming of the insulating jacket forms a final manufacturing step, in particular, when a material connection to the cell cover and cell bottom takes place only by self-adhesive bonding of the insulating jacket. If, however, the insulating z. B. formed as a shrink tube, the trimming is preferably carried out prior to producing the adhesive seam, which takes place in particular by introducing a separate adhesive into the grooves described in the cell cover or cell bottom or by potting these grooves. In a modification of the method, it is also possible to first introduce the adhesive into the groove and then to wrap the insulating jacket around the cell housing.

For producing an electrical storage module from a plurality of electrical storage cells of the type described, these storage cells are inserted into a module frame and aligned in their position relative to one another and to the module frame by means of their cell covers. Preferably, the memory cells are then pressed in the module frame. By the cell lid is thereby achieved that the individual memory cells remain in their defined position. As a result, the electrical cell connections in the finished compressed memory module remain in a precisely defined position relative to each other and to the module frame. This facilitates a subsequent attachment of a contacting unit, in which preferably all electrical connection elements for connection to the electrical cell terminals of the electrical storage cells are combined to form a common assembly, since the cell cover tight manufacturing tolerances for the positions of the cell connections are met, the electrical connection elements within the contacting thus can also be arranged at fixed positions.

Brief description of the drawings

Embodiments of the invention are illustrated in the drawings and will be described in more detail below. Show it:

1 an example of an inventive electrical storage cell in a perspective view,

2 a side view and an end view of the electric storage cell according to 1 .

3 a plan view of the electric storage cell after 1 .

4 a bottom view of the electrical storage cell after 1 .

5 a sectional view of the electric storage cell according to 1 along a in the in 2 reproduced side view of the electrical storage cell registered section line AA,

6 a section B from the in 5 reproduced representation of the electric storage cell according to 1 in a first state of manufacture,

7 a section D from the in 6 reproduced representation of the electric storage cell according to 1 .

8th the detail B from the in 5 reproduced representation of the electric storage cell according to 1 in a second state of manufacture,

9 the detail B from the in 5 reproduced representation of the electric storage cell according to 1 in a third state of manufacture,

10 the detail B from the in 5 reproduced representation of the electric storage cell according to 1 in a fourth state of manufacture,

11 the detail B from the in 5 reproduced representation of the electric storage cell according to 1 in a fifth state of manufacture,

12 a section of the in 11 reproduced representation of the electric storage cell according to 1 .

13 a section C from the in 5 reproduced representation of the electric storage cell according to 1 , and

14 a section of the in 13 reproduced representation of the electric storage cell according to 1 ,

In this case, matching elements in the different figures are provided with the same reference numerals, with a repeated description of these elements being omitted.

Preferred embodiment of the invention

In 1 is with the reference numeral 100 an example of an inventive electrical storage cell referred to, with an at least substantially prismatic cell housing 101 is trained. The cell case 101 includes a cell sheath 102 , a top 103 and a bottom 104 , The electric storage cell 100 is in 1 in a perspective view of the cell casing 102 and the top 103 shown. In the illustrated embodiment, the cell housing is prismatic shaped with a rectangular-elongated base and top surface, the z. B. 5-6 times as long as it is wide, resulting in the cell housing 101 a flat cuboid shape results. The electric storage cells 100 can then be conveniently with the large surfaces of their cell coats 102 along a longer of the edges of the top 103 for forming a memory module from a plurality of electrical memory cells 100 together layers.

At the top 103 of the cell case 101 two electrical cell connections are arranged, one plus pole 105 and a negative pole 106 , both of which are designed as threaded bolts in this example. An embodiment as z. B. substantially flat contact lugs or sheets is also possible in a modification of the illustrated embodiment.

The electric storage cell 100 also has a cell sheath 102 at least substantially over the entire surface enclosing, electrically non-conductive insulating jacket 107 as well as the top 103 at least along their demarcation 108 to the cell jacket 102 covering and form-fitting to the insulating jacket 107 adjacent, electrically non-conductive cell cover 109 on. In the cell lid 109 are two recesses 110 . 111 for performing the electrical cell connections 105 respectively. 106 trained, otherwise the cell lid 109 In this exemplary embodiment, the surface is designed to be closed in a closed manner in order to achieve as complete electrical isolation of the electrical storage cell as possible 100 to ensure.

The cell lid 109 the electric storage cell 100 to 1 is further formed with a positioning aid for positionally accurate positioning of the memory cell in a module frame, not shown. This positioning aid consists in the illustrated embodiment, each one of the cell cover 109 along its shorter edges molded stop bar 112 ,

The electric storage cell 100 to 1 points at the cell lid 109 in the region of the recess 110 for the positive pole 105 a molded Kontaktierhilfe 113 on for unmistakably connecting an unillustrated electrical connection element to the positive pole 105 , This contacting aid 113 is as z. B. cylindrically shaped projection formed, the surrounding surface parts of the cell cover 109 surmounted. The connecting element is then designed in a complementary shape, z. B. with a contact for help 113 corresponding recess, that it fits only to the positive pole 105 can be put on. Conversely, then one with the negative pole 106 connecting element to be connected no recess and can not be on the positive pole 105 put on, as the contact aid 113 this is blocked. Advantageously, the connecting elements for positive pole 105 and negative pole 106 summarized by an electrically insulating member together to form a common assembly contacting unit, whereby the confusion safety when connecting the connecting elements further increases and the assembly is simplified and accelerated.

2 shows again the embodiment of the electrical memory cell 100 and their construction elements 1 This time in a side view on the large area of the sides of the cell wall 102 in the left part of the 2 and in a front view on the smaller of the sides of the cell wall 102 in the right part of the 2 ,

3 shows a top view of the embodiment of the electrical storage cell 100 and their construction elements 1 , and 4 shows a bottom view of the electrical storage cell 100 to 1 , In 4 is additionally a cell bottom 114 shown the bottom 104 the memory cell 100 at least along a boundary 115 the bottom 104 to the cell jacket 102 covered and at least largely positive fit to the insulating jacket 107 borders. The cell bottom 114 is also provided with a metal plate at least partially enveloped by insulating material, preferably an aluminum plate 116 formed, which is preferably injected in plastic and thereby against the bottom 104 the memory cell 100 is mounted electrically isolated. In particular, the aluminum plate 116 with their edges of demarcation 115 the bottom 104 to the cell jacket 102 spaced apart to ensure the required electrical insulation. For a more stable mechanical connection between the aluminum plate 116 and the plastic of the cell bottom 114 has the aluminum plate 116 advantageously arranged in rows along their boundary openings 117 on, in which the plastic of the cell bottom upon injection of the aluminum plate 116 is injected with.

5 shows a sectional view of the electric storage cell 100 and their construction elements 1 along a in the in 2 reproduced side view of the electrical storage cell 100 registered section line AA, the internal design of the electric storage cell 100 is not reproduced. Also in this illustration are the areas around the cell lid 109 and the cell bottom 114 simplified drawn. In 5 is shown that the cell case 101 with top 103 , Cell coat 102 and bottom 104 with one of the electrical cell connections, here the negative pole 106 is electrically connected. This highlights the need for effective and reliable electrical isolation of the cell housing 101 to create his environment.

6 shows a section B from the in 5 reproduced sectional view of the electric storage cell 100 and their construction elements 1 , In this case, a first manufacturing state is reproduced, as it is after applying a cell sheath 102 enveloping insulating jacket 107 but without one on top 103 the electric storage cell 100 attached cell lid 109 would result. In the area of demarcation 108 the top 103 to the cell jacket 102 stands the insulating jacket 107 over a local edge of the cell mantle 102 above. Due to the elasticity of the material of the insulating jacket formed by an electrically insulating film or a shrink tube 107 and the manufacturing tolerances when cutting and applying the insulating jacket 107 This supernatant is designed largely undefined.

7 shows to further illustrate these facts a section D of the in 6 reproduced representation of the electrical memory cell 100 and their construction elements 1 , Additionally is in 7 a room area 118 shown in the embodiment shown in the drawing a tolerance compensation of manufacturing tolerances between the top 103 or the cell connection 105 respectively. 106 on the one hand and the cell jacket 102 on the other hand serves and in particular in a later manufacturing state is preferably filled with adhesive.

8th shows the detail B from the in 5 reproduced sectional view of the electric storage cell 100 and their construction elements 1 , In this case, a second manufacturing state is reproduced, as it turns out, after first on the top 103 the electric storage cell 100 a cell lid 109 is attached, preferably by gluing to the top 103 , and then a cell jacket 102 enveloping insulating jacket 107 is applied. In a modification, the attachment of the cell cover 109 also exclusively by shrinking the insulating jacket 107 respectively.

In the area of demarcation 108 the top 103 to the cell jacket 102 closes the insulating jacket 107 now to a local boundary of the cell cover 109 form fit and is now the insulating jacket 107 dimensioned during manufacture such that it over this boundary of the cell cover 109 survives. For this supernatant 119 is a compliance with tight manufacturing tolerances when cutting and applying the insulating jacket 107 not mandatory; the supernatant 119 can be designed largely undefined.

The cell lid 109 is with a along its adjoining to the insulating jacket 107 , ie along its boundary in the area of the demarcation 108 the top 103 of the cell case 101 to the cell jacket 102 , circumferential cutting edge 120 shaped as a template for a molding of the cell cover 109 adjoining edge of the insulating jacket 107 serves. For this purpose, the insulating jacket 107 Simply with a knife or a similar tool, which runs along the cutting edge 120 Once around the circumference of the cell cover is guided, accurately separated. Shows a third manufacturing state achieved thereby 9 , in which also the detail B from the in 5 reproduced representation of the electrical memory cell 100 to 1 is shown.

As below 14 is explained in a comparable way for the same purpose, the cell bottom 114 advantageous with a corresponding cutting edge 121 educated.

10 shows the detail B from the in 5 reproduced sectional view of the electric storage cell 100 and their construction elements 1 , In this case, a fourth manufacturing state is reproduced, as it results when, in addition to the described manufacturing steps, in which on the top 103 the electric storage cell 100 a cell lid 109 is attached, preferably by gluing to the top 103 , and then a cell jacket 102 enveloping insulating jacket 107 is applied, the cell lid 109 glued or potted along its positive boundary to the insulating jacket 107 for bonding or potting this positive boundary by a special seam of adhesive.

In the illustrated embodiment, the adhesive is after application of the insulating jacket 107 and its trimming along the cutting edge 120 as a seam separately into a corresponding in the cell lid 109 along its along the boundary 108 the top 103 the memory cell 100 to the cell jacket 102 Bound contoured groove 122 introduced and thereby a hermetically sealed closure between the cell cover 109 and the insulating jacket 107 receive. In 11 , in turn, the detail B from the in 5 reproduced sectional view of the electric storage cell 100 and their construction elements 1 is shown, the result obtained by the bonding is shown as the fifth state of manufacture. The particular seam of adhesive is shown schematically and with the reference numeral 123 designated. The seam 123 here borders directly on the cutting edge 120 ,

In a modification of the embodiment described above, a changed production sequence is observed. Thereafter, the cell cover is first again 109 glued on and then the glue for the seam 123 in the groove 122 introduced, z. B. as adhesive bead. Subsequently, the insulating jacket 107 wrapped or slipped over and shrunk, at the same time the adhesive bead on the insulating jacket 107 connects and makes the bond to the cell cover. The adhesive bead is preferred 123 made of hot melt adhesive and the insulating jacket 107 formed by a shrink tube. When shrinking the insulating jacket then the hot melt adhesive is melted at the same time and so are the cell cover 109 and the insulating jacket 107 glued together.

12 shows to further clarify this situation one of 7 corresponding section D from the in 11 reproduced representation of the electrical memory cell 100 and their construction elements 1 ,

Similarly, in a manner not shown in the figures for the same purpose, the cell bottom 114 advantageous with a corresponding adhesive seam to the insulating jacket 107 connected.

13 shows a section C from the in 5 reproduced sectional view of the electric storage cell 100 and their construction elements 1 , The cell bottom 114 with the embedded, plastic-coated aluminum plate 116 is by means of a layer applied adhesive 124 with the bottom 104 of the cell case 101 bonded. The insulating jacket 107 envelops the cell wall 102 and a subsequent boundary of the cell bottom 114 and is glued along this boundary to the cell bottom.

In the area of the boundary of the cell mantle 102 to the bottom 104 forms the cell bottom 114 the above-mentioned cutting edge 121 , as a template for separating the insulating jacket 107 at its adjoining to the cell floor 114 and thus for convenient, dimensionally accurate forms of Boundary of the insulating jacket 107 by trimming in this area is used.

14 shows for further clarification of these circumstances an enlarged section E from in 13 reproduced representation of the electrical memory cell 100 and their construction elements 1 ,

In one in the 13 and 14 illustrated dimensioning example, the insulating jacket 107 a thickness of 0.1 mm and the cell bottom 114 a thickness of 1.1 mm.

LIST OF REFERENCE NUMBERS

100

Electric storage cell

101

cell case

102

Cell jacket of 101

103

Top of 101

104

Bottom of 101

105

Positive pole electrical cell connections

106

Negative pole electrical cell connections

107

insulating jacket 102 circumaural

108

Demarcation of 103 to 102

109

cell cover

110

Recess in 109 For 105

111

Recess in 109 For 106

112

Stop bar (positioning aid) on 109

113

Contacting aid on 109

114

cell floor

115

Demarcation of 104 to 102

116

Aluminum plate in 114

117

Breakthroughs in 116

118

Room area at 108

119

Supernatant of 107 over the edge of 109

120

Cutting edge at edge of 109

121

Cutting edge at edge of 114

122

Nut at edge of 109 In the range of 108

123

Adhesive or sealing seam

124

layered adhesive between 114 and 104

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102009042270 A1 [0002, 0004]
• WO 2009006998 A1 [0003, 0004]
• DE 102010020065 A1 [0005, 0007]

Cited non-patent literature

• http://en.wikipedia.org/wiki/Prisma_(Geometry) [0012]

Claims (14)

Electric storage cell ( 100 ) with an at least largely prismatic cell housing ( 101 ), which has a cell jacket ( 102 ), a top ( 103 ) and a bottom ( 104 ), wherein electrical cell connections ( 105 . 106 ) at the top ( 103 ) of the cell housing ( 101 ) are arranged, wherein the memory cell ( 100 ) further comprises a cell sheath ( 102 ) at least substantially over the entire surface enclosing, electrically non-conductive insulating jacket ( 107 ) as well as the top ( 103 ) of the memory cell ( 100 ) at least along its boundary ( 108 ) to the cell jacket ( 102 ) covering and at least largely positive fit to the insulating jacket ( 107 ) adjacent, electrically non-conductive cell lid ( 109 ). Electric storage cell ( 100 ) according to claim 1, characterized by the underside ( 104 ) of the memory cell ( 100 ) at least along its boundary ( 115 ) to the cell jacket ( 102 ) covering and at least largely positive fit to the insulating jacket ( 107 ) adjacent cell floor ( 114 ). Electric storage cell ( 100 ) according to claim 1 or 2, characterized in that the cell lid ( 109 ) and / or the cell bottom ( 114 ) along its at least largely positive abutment against the insulating jacket ( 107 ) is materially connected to this. Electric storage cell ( 100 ) according to claim 3, characterized in that the cell lid ( 109 ) and / or the cell bottom ( 114 ) along its at least largely positive abutment against the insulating jacket ( 107 ) is glued thereto and / or welded and / or potted. Electric storage cell ( 100 ) according to claim 2, 3 or 4, characterized in that the cell bottom ( 114 ) a substantially flat, heat-conducting element ( 116 ), of which at least parts in heat-conducting connection with the underside ( 104 ) of the prismatic cell housing ( 101 ) stand. Electric storage cell ( 100 ) according to claim 5, characterized in that the cell bottom ( 114 ) with an at least partially enveloped by insulating metallic plate ( 116 ) is trained. Electric storage cell ( 100 ) according to one or more of claims 1 to 6, characterized in that the cell lid ( 109 ) and / or the cell bottom ( 114 ) with one each at least largely along its adjacency to the insulating jacket ( 107 ) circumferential cutting edge ( 120 . 121 ) are formed as a template for molding a to the cell cover ( 109 ) or the cell bottom ( 114 ) adjacent boundary of the insulating jacket ( 107 ) serves. Electric storage cell ( 100 ) according to one of the preceding claims, characterized in that the cell lid ( 109 ) with a positioning aid ( 112 ) is formed for positionally accurate positioning of the memory cell ( 100 ) in a module frame. Electric storage cell ( 100 ) according to one of the preceding claims, characterized in that the cell lid ( 109 ) with a contacting aid ( 113 ) is designed for the unmistakable connection of at least one electrical connection element to at least one of the electrical cell connections ( 105 . 106 ). Electrical storage module, in particular for a vehicle, comprising at least one electric storage cell ( 100 ) according to any one of the preceding claims. Method for producing an electrical memory cell (according to one of Claims 1 to 9) ( 100 ), comprising the following method steps: fixing, preferably gluing, a cell lid ( 109 ) on a top side ( 103 ) of a cell casing ( 101 ) of the electrical storage cell ( 100 ) and at least substantially full-surface application, preferably bonding, of an electrically non-conductive insulating jacket ( 107 ) on a cell jacket ( 102 ), wherein the insulating jacket ( 107 ) with its boundary to one along a boundary ( 108 ) of the top side ( 103 ) of the memory cell ( 100 ) to the cell jacket ( 102 ) bordering the cell lid ( 109 ) bordered at least largely positive fit. A method according to claim 11, characterized by a further, before the application of the insulating jacket ( 107 ) process step: fixing, preferably bonding, in particular at least almost full-surface bonding of a cell bottom ( 114 ) on a lower side ( 104 ) of the cell housing ( 101 ). A method according to claim 11 or 12, characterized in that the insulating jacket ( 107 ) to the cell lid ( 109 ) and / or the cell bottom ( 114 ) is connected by applying a seam formed from an adhesive. A method according to claim 11, 12 or 13, characterized by a further, after the application of the insulating jacket ( 107 ) process step: molding one to the cell lid ( 109 ) or the cell bottom ( 114 ) adjacent boundary of the insulating jacket ( 107 ) by separating of the insulating jacket ( 107 ) along cut edges ( 120 . 121 ) attached to the cell lid ( 109 ) and / or cell bottom ( 114 ) depending at least largely along their adjacencies to the insulating jacket ( 107 ) are formed circumferentially and thereby as templates for the molding of the cell cover ( 109 ) or the cell bottom ( 114 ) adjacent boundary of the insulating jacket ( 107 ) serve.

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