DE102015105326B4 - Energy storage device and method for producing an energy storage device - Google Patents

Abstract

Energy storage device (100) with a plurality of mechanically interconnected energy storage modules (1), each energy storage module (1) having a battery cell receiving module (10), the battery cell receiving modules (10) each having a base body (11) which has a base body top side (12). , a base body underside (14), a lateral surface (16) extending between the base body top side (12) and the base body underside (14) and a plurality of through holes (18) from the base body top side (12) to Base body underside (14), wherein the through holes (18) are designed such that a battery cell (20) can be inserted into them and the base body (11) is designed such that each battery cell (20), if is inserted into a through hole (18), is enclosed over its entire length by the base body (11), with battery cells (20) being inserted into the through holes (18) in each battery cell receiving module (10) and with an electrically conductive adhesive layer (40) electrically connects at least two first cover plates (30) and/or at least two second cover plates (32) of the energy storage modules (1) to one another.

Description

The present invention relates to an energy storage device and a method for producing an energy storage device.

Energy storage devices are known from the prior art, in which battery cells are permanently installed with a battery cell receiving module. Such energy storage devices have the disadvantage that the entire energy storage device must be replaced after the battery cells have deteriorated over time. Furthermore, battery cell receiving modules for receiving a plurality of battery cells are known in the prior art, in which the individual battery cells can be replaced.

For example, this is disclosed DE 10 2012 110 644 A1 an energy storage device with a plurality of battery cells, with a first cell holder for fixing the battery cells on the pole side, which comprises a contact part with contact sections for electrically contacting the poles of the battery cells, a second cell holder for fixing the battery cells on the opposite pole side and an unlockable locking means for mechanically connecting the first cell holder to the second cell holder, which extends between adjacent battery cells and which is intended for pressing the contact sections onto the poles of the battery cells. Disadvantageous with the DE 10 2012 110 644 A1 is that the energy storage device disclosed there or the associated battery cell receiving module consists of a large number of individual parts, which means that the assembly of the energy storage device is complex. Another disadvantage in the DE 10 2012 110 644 A1 disclosed energy storage device is that only the end regions of the battery cells received are enclosed by the battery cell receiving device. As a result, the battery cell receiving module does not offer any mechanical protection function in the middle areas of the battery cells.

Further energy storage systems are being developed in the DE 9 404 070 U1 , the WO 2014 / 079 507 A1 , the US 2006 / 0 113 965 A1 , the US 2009 / 0 111 015 A1 and the DE 198 29 293 A1 described.

It is therefore the object of the present invention to at least partially avoid the disadvantages described above in an energy storage device and a method for producing the energy storage device. In particular, the object of the present invention is to create an energy storage device by means of which a simple exchange of battery cells and at the same time a reliably functioning energy storage device that is safe to use and manufacture can be realized. Therefore, a method for producing such an energy storage device should also be shown.

The above object is achieved by an energy storage device and a method for producing the energy storage device with the features of claims 1 and 12.

Further features of the invention emerge from the subclaims, the description and the drawings. Features and details that are described in connection with the energy storage device naturally also apply in connection with the method according to the invention for producing the energy storage device and vice versa, so that reference is or can always be made to each other with regard to the disclosure of the individual aspects of the invention.

According to a first aspect of the present invention, an energy storage device with a plurality of mechanically interconnected energy storage modules is proposed, each energy storage module having a battery cell receiving module. The battery cell receiving modules each comprise a base body which has a base body top, a base body underside, a lateral surface extending between the base body top and the base body underside, and a plurality of through holes from the base body top to the base body underside, whereby the through holes are designed such that a battery cell can be inserted into each of them and the base body is designed such that each battery cell, when inserted into a through hole, is enclosed by the base body over its entire length. Battery cells are inserted into the through holes in each battery cell receiving module. An electrically conductive adhesive layer electrically connects at least two first cover plates and/or at least two second cover plates of the energy storage modules to one another.

This can ensure a reliable electrical connection between the individual energy storage modules. An adhesive layer connects at least two first cover plates and/or an adhesive layer electrically connects at least two second cover plates to one another. It is preferred if the energy storage modules are always connected to one another in pairs. This makes energy storage modules particularly easy to replace. It is particularly preferred if the individual energy storage modules are electrically connected to each other alternately in pairs via the first and second cover plates. That is, an adhesive layer connects, for example, a first and a second energy storage module by connecting the first cover plate of the first energy storage module to the first cover plate of the second energy storage module. A further adhesive layer then connects the second energy storage module to a third energy storage module such that the second cover plate of the second energy storage module is connected to the second cover plate of the third energy storage module. A further adhesive layer then connects the third energy storage module to a fourth energy storage module such that the first cover plate of the third energy storage module is connected to the first cover plate of the fourth energy storage module, etc. However, the present invention is not limited to connecting the cover plates in pairs. It is also conceivable that more than two or all of the first cover plates are electrically connected to one another with a single layer of adhesive and more than two or all of the second cover plates are electrically connected to one another with a further layer of adhesive.

A quick and uncomplicated replacement of battery cells can be realized in the battery cell receiving module, since the individual battery cells can simply be pushed into the through holes and removed from them again. Because the through holes are designed in such a way that a battery cell can be inserted into them and the base body is designed in such a way that each battery cell, when inserted into a through hole, is enclosed by the base body over its entire length, a compact and secure accommodation for the individual battery cells can be created. The individual battery cells are ideally protected from external influences in the associated through holes. The battery cell receiving module is also particularly inexpensive and easy to manufacture. It can, for example, be produced as a one-piece or monolithic molded part.

The battery cell receiving module is particularly suitable for use in an energy storage device. The material for the base body preferably comprises metal, for example aluminum, and/or a plastic, for example polypropylene and/or epoxy resin.

The fact that the base body is designed in such a way that each battery cell, when inserted into a through hole, is enclosed by the base body over its entire length means that each battery cell inserted into the base body, for example a cylindrical battery cell, is separated from the base body with respect to its lateral surface is enclosed. This means that the base body is preferably designed in such a way that the top and bottom of the battery cell, when inserted into the base body, are not enclosed by the base body. This ensures that the battery cells can be easily inserted into the base body and removed from it again.

The through holes are preferably cylindrical, but are not limited to this. The through holes are particularly preferably designed to correspond to the outer contour of the battery cells to be inserted therein. For example, the through holes are designed in such a way that the lateral surface of a battery cell inserted therein lies opposite a surface of a through hole at least partially, preferably over the entire length of the battery cell. It can be advantageous here if the through holes are designed in such a way that each battery cell inserted therein can be contacted over the entire length of the battery cell via at least one contact surface or at least one contact edge between the battery cell and the associated through hole.

The lateral surface, which extends around the entire base body, is preferably formed without gaps between the top side of the base body and the underside of the base body. This means that the lateral surface has no holes or openings through which air, for example, could penetrate. However, the present invention is not limited to this. A perforated lateral surface is also conceivable, which has through openings which extend, for example, from the lateral surface to the through holes.

According to a further development, the lateral surface has at least part of a connecting device, via which the battery cell receiving module can be mechanically connected to a further battery cell receiving module. Because a part of a connecting device is already provided in the lateral surface of the base body, the other part of the connecting device can be designed to be smaller and less complex. As a result, costs can be saved and the assembly of a plurality of battery cell receiving modules can be simplified. The at least one part of the connecting device is preferably designed as a recess or recess in the outer peripheral region of the base body. This means that the lateral surface forms, for example, a receptacle for a part of the associated connecting device in at least one section. For example, there is a groove under a recess in the outer peripheral area or to understand an undercut that is formed as part of the lateral surface and does not interrupt it. The at least one part of the connecting device can be designed, for example, as a partially cross-shaped undercut, into which a connecting piece, for example a cross-shaped pin, can be inserted from the top of the base body to the bottom of the base body, or vice versa. In addition to the cross-shaped pin, other connecting elements, for example hooking or latching ones, are of course also conceivable. The at least one part of the connecting device is also not limited to extending from the top of the base body to the bottom of the base body. For example, it is also possible for a recess or part of a connecting device to be formed only in a section of the lateral surface between the top side of the base body and the underside of the base body, into which another part of the connecting device can engage, snap into place or adhere. This makes it possible to connect a plurality of base bodies or battery cell receiving modules to one another in a compact and space-saving manner.

Because the at least one part of the connecting device is designed in the lateral surface as a recess, for example an undercut, correspondingly designed battery cell receiving modules can be stored in a particularly space-saving manner or transported for further processing. For this purpose, the lateral surface preferably has a flat or straight surface section on at least one section, on which the battery cell receiving module can lie flush against a flat or straight storage or transport surface. It is also conceivable that the at least one part of the connecting device is a positive part of a connecting device, i.e. that protrudes from the outer circumference of the base body. It is particularly preferred here if a further battery cell receiving module, with which the one battery cell receiving module is to be connected, forms an associated negative part of the connecting device, whereby the two or a plurality of battery cell receiving modules can be put together like a puzzle. By means of the connecting device, the base bodies and thus the battery cell receiving modules can always be connected in pairs. This makes it particularly easy to replace individual battery cell receiving modules with a large number of interconnected battery cell receiving modules.

It is further advantageous if the base body has seven through holes, one of the through holes being arranged centrally in the base body and the other through holes being arranged uniformly around the central through hole. In such a development, the base body is preferably designed as a hexagonal prism or essentially as a hexagonal prism, which forms a uniform hexagon or essentially a uniform hexagon in longitudinal section. With such an arrangement of the through holes, a compact base body can be created, in which the through holes are arranged in a particularly space-saving manner. However, the number and arrangement of the through holes is not limited to this. It is also conceivable that more or fewer through holes are provided in a prism-shaped or cylindrical base body.

In addition, in a battery cell receiving module, a plane that runs through the center of the base body can form a plane of symmetry of the base body. By means of such a symmetrical design of the battery cell receiving module, a plurality of such battery cell receiving modules can be arranged particularly easily next to one another and connected to one another. It is particularly preferred if the plane of symmetry runs through the center of the base body in a longitudinal section, i.e. from the top of the base body to the bottom of the base body. It is preferred that a plurality of symmetry planes, for example six, run in longitudinal section through the center of the base body.

The base body can have a plurality of temperature control channels which extend through the base body from the top of the base body to the underside of the base body. This makes it possible to create a particularly safe and reliably functioning battery cell receiving module, since the battery cells accommodated in the base body can be heated or cooled to the desired temperature at any time. This can be a desired high temperature at a low ambient temperature or a desired low temperature at a high ambient temperature. The temperature control channels are preferably arranged in the base body in such a way that they run between at least two through holes, preferably parallel to them. The temperature control channels preferably have a smaller diameter than the through holes. The temperature control channels can also preferably be designed in such a way that they are suitable for conducting a temperature control fluid such as water, oil and/or a gaseous substance. In addition or as an alternative to the temperature control channels, the battery cell receiving module, in particular in the base body, can also have heat pipes such as heat pipes or two-phase thermosiphons, which preferably have a hermetically encapsulated volume in the form of a pipe with a working medium such as water, ammonia or a metal wire mesh inside. The heat pipes allow the battery cells accommodated in the base body to be particularly advantageously tempered.

In an exemplary development, the lateral surface can have at least one contact section and at least one mating contact section, wherein the at least one contact section can be placed flush or substantially flush with the surface on a mating contact section of an adjacent, identical battery cell receiving module. As a result, a battery cell receiving module can be created, which is particularly advantageously designed for compactly placing or assembling a plurality of battery cell receiving modules. The contact section and the mating contact section preferably have the same shape or area, i.e. are identical or essentially identical. The lateral surface can therefore always alternately form a contact section and a mating contact section.

Furthermore, it is advantageous if the lateral surface is formed completely or substantially completely by contact sections and mating contact sections, the number of contact sections corresponding to the number of mating contact sections. As a result, a particularly symmetrical battery cell receiving module can be provided, which enables a plurality of battery cell receiving modules to be optimally placed together or assembled. In a preferred embodiment, the lateral surface has three contact sections and three mating contact sections, the contact sections and the mating contact sections each having the same shape. The base body is preferably designed as a hexagonal prism or essentially as a hexagonal prism. However, the present invention is not limited to this. A base body with more or fewer contact sections and/or counter-contact sections is also conceivable. For example, a cuboid base body with two contact sections and two counter-contact sections can also be provided.

In the case of the energy storage module, it is of further advantage if a first cover plate is arranged on the top of the base body and a second cover plate on the underside of the base body and the two cover plates each have a plurality of contact areas, each of which, in particular, has a projection from the cover plates , with which the battery cells can be contacted. Such cover plates make it possible to provide a compact and easy-to-assemble energy storage module. The contact areas, which are preferably provided as a projection from the cover plates, make it possible to produce a space-saving through-hole that can be easily applied to the battery cells. The cover plate can be designed, for example, as a deep-drawn component, such as a contact plate. However, the contact sections can also be located in the same plane as a cover plate underside. This means that the contact areas do not have to be provided as a projection from the cover plates. The fact that the cover plates are arranged on the top of the base body and the bottom of the base body does not mean that they have to rest directly on them. Although it is possible for the cover plates to rest directly on the top of the base body and the bottom of the base body, they can also be slightly spaced from the top of the base body and the bottom of the base body. Furthermore, it is also conceivable that an intermediate element is arranged between the cover plates and the top side of the base body and the bottom side of the base body.

In an advantageous development, a fuse is provided between the contact areas, which form at least part of a cover plate underside, and a cover plate upper side, which melts when a melting temperature is reached, whereby a connection between a battery cell and the cover plate can be separated. Such a fuse offers inexpensive yet highly effective protection against defective battery cells. In the event of a failure of one of the battery cells, the fuse evaporates and the defective battery cell can no longer affect the energy storage module. The fuse can be provided, for example, in the form of connecting webs between the contact areas and the respective cover plate, which can melt or evaporate in the event of a defective battery cell. The connecting webs can be realized, for example, by elongated holes or recesses in an area between the respective cover plate and the associated contact areas. The recesses can be made, for example, using a laser or another cutting device.

The battery cell receiving modules or energy storage modules do not have to be connected by the connection device described above, but can also be connected by an alternative connection device.

In a preferred embodiment, the mechanical connection of the energy storage modules is established via a connecting device which has at least one recess on the respective outer circumference of the lateral surfaces to be connected and has a separate connecting piece for positive insertion into the respective recesses. Thanks to the recess on the outer circumference, the individual energy storage modules can be stored and transported in a space-saving manner. A recess or recess on the outer circumference is understood to mean, for example, a groove or an undercut that is formed as part of the lateral surface or through it. The connecting piece can, for example, have a cross-shaped pin or cross pin, which can be inserted into the associated recess from the top of the base body to the bottom of the base body, or the other way around. The connecting piece preferably has a length that corresponds or essentially corresponds to the height, i.e. a length from the top of the base body to the bottom of the base body. In addition to the cross-shaped pin, other connecting elements, for example hooking or latching ones, are of course also conceivable. The recess and/or the connecting piece are not limited to extending from the top of the base body to the bottom of the base body. For example, it is also possible for the connecting device to be formed only in a section of the lateral surface, i.e. only in a section between the top side of the base body and the underside of the base body. Using the connection device, the energy storage modules can always be connected in pairs. This makes it particularly easy to replace individual energy storage modules with a large number of energy storage modules connected to one another.

For sufficient cooling of the energy storage device, it is advantageous if a cooling plate is applied to the adhesive layer. This means that a cooling plate or a plurality of cooling plates can be applied to the adhesive layer. For easy replacement of individual energy storage modules, it is preferred if a cooling plate is applied to each adhesive layer. For example, a cooling plate that has the shape or essentially the shape of the adhesive layer can be applied to an adhesive layer that connects two energy storage modules to one another. The respective adhesive layers and/or the respective cooling plates are preferably designed such that they completely or substantially completely cover the first and second cover plates of the two or more interconnecting energy storage modules.

In addition, it is possible for the energy storage module or the energy storage device to have heat pipes, in particular heat pipes, with the heat pipes being arranged at least in sections on the contact areas, so that a respective contact area is arranged, for example, between a heat pipe section and a battery cell. It is particularly preferred if an insulation layer is arranged between the respective heat pipe sections at the contact areas. This makes it possible to achieve particularly efficient and safe cooling of the energy storage module or a corresponding energy storage device

• - Einsetzen von Batteriezellen in das vorstehend beschriebene Batteriezellenaufnahmemodul,
• - Anbringen der Deckplatten auf der Grundkörper-Oberseite und der Grundkörper-Unterseite, sodass die Deckplatten in Kontakt mit den Batteriezellen stehen und ein Energiespeichermodul gebildet wird,
• - mechanisches Verbinden einer Mehrzahl der Energiespeichermodule und
• - Aufbringen einer elektrisch leitenden Kleberschicht auf jeweils wenigstens zwei erste Deckplatten und/oder wenigstens zwei zweite Deckplatten der Energiespeichermodule zum elektrischen Verbinden der Energiespeichermodule.

According to a further aspect of the present invention, a method for producing an energy storage device is provided, comprising the steps:

• - Inserting battery cells into the battery cell receiving module described above,
• - Attaching the cover plates to the top of the base body and the bottom of the base body so that the cover plates are in contact with the battery cells and an energy storage module is formed,
• - mechanically connecting a majority of the energy storage modules and
• - Applying an electrically conductive adhesive layer to at least two first cover plates and / or at least two second cover plates of the energy storage modules for electrically connecting the energy storage modules.

Such a method can create an energy storage device with the features and advantages presented above. The modular assembly of the energy storage device can also provide a high level of safety for the worker, since no dangerously high currents can flow for the worker during the connection of the energy storage modules and in particular before the adhesive layer is applied.

Further measures improving the invention result from the following description of the invention. All features and/or advantages arising from the claims, the description or the drawing, including constructive details and spatial arrangements, can be essential to the invention, both taken alone and in the various combinations.

• 1 eine perspektivische Ansicht eines Grundkörpers gemäß einer Ausführungsform,
• 2 eine Draufsicht des Grundkörpers gemäß einer Ausführungsform,
• 3 eine Draufsicht einer Deckplatte gemäß einer Ausführungsform,
• 4 einen Teil einer Seitenansicht der Deckplatte gemäß einer Ausführungsform,
• 5 eine Explosionsdarstellung eines Energiespeichermoduls gemäß einer Ausführungsform,
• 6 eine perspektivische Ansicht eines Zusammenbaus einer Mehrzahl der Energiespeichermodule gemäß einer Ausführungsform,
• 7 eine perspektivische Ansicht des Zusammenbaus der Mehrzahl der Energiespeichermodule mit einer Kleberschicht gemäß einer Ausführungsform, und
• 8 eine perspektivische Ansicht des Zusammenbaus der Mehrzahl der Energiespeichermodule mit einer Mehrzahl von Kleberschichten und Kühlplatten gemäß einer Ausführungsform.

They show schematically:

• 1 a perspective view of a base body according to an embodiment,
• 2 a top view of the base body according to one embodiment,
• 3 a top view of a cover plate according to an embodiment,
• 4 a part of a side view of the cover plate according to an embodiment,
• 5 an exploded view of an energy storage module according to one embodiment,
• 6 a perspective view of an assembly of a plurality of the energy storage modules according to an embodiment,
• 7 a perspective view of the assembly of the plurality of energy storage modules with an adhesive layer according to an embodiment, and
• 8th a perspective view of the assembly of the plurality of energy storage modules with a plurality of adhesive layers and cooling plates according to an embodiment.

Elements with the same function and mode of operation are in the 1 until 8th each provided with the same reference number.

1 shows a base body 11, which essentially has the shape of a hexagonal prism. The base body 11 has a base body top 12, a base body underside 14 and a lateral surface 16 extending between the base body top 12 and the base body underside 14. Seven through holes 18 run from the top side of the base body 12 to the bottom side 14 of the base body, one of the through holes 18 being arranged centrally in the base body 11 and the other through holes 18 being arranged evenly around the central through hole 18. The through holes 18 are designed such that a battery cell 20 can be inserted into each of them. According to the in 1 In the embodiment shown, the through holes 18 are designed such that a cylindrical battery cell 20 can be inserted into each of them.

This means that the through holes 18 are designed as through holes. According to the in 1 In the embodiment shown, the base body 11 is designed such that each battery cell 20, when inserted into one of the through holes 18, is enclosed by the base body 11 over its entire length. For this purpose, the base body 11 is preferably provided as a one-piece or monolithic molded body.

The in 1 The base body 11 shown also has a lateral surface 16, in which or through which a plurality of recesses or depressions 17a are formed. These recesses 17a are part of a connecting device with reference to 5 and 6 is described in further detail. The fact that the lateral surface 16 has a recess or depression does not mean that the lateral surface 16 is interrupted at this point. Rather, this means that the lateral surface 16 in these sections is offset radially inwards relative to the remaining lateral surface 16 with respect to the outer circumference of the base body 11. According to the in 1 In the embodiment shown, the recess 17a is designed as a partial cross, roof or V-shaped undercut in the base body 11. The base body 11 according to in 1 The embodiment shown also has a plurality of temperature control channels 19, which extend from the top of the base body 12 to the underside of the base body 14 through the base body 11 and are each arranged between the through holes 18 and run parallel to them.

In the 1 The lateral surface 16 shown also has three contact sections 16a and three mating contact sections 16b, each of the three contact sections 16a being able to be placed flush or substantially flush with each of the three mating contact sections 16b of an adjacent, identical base body 11. The lateral surface 16 is completely or, with the exception of the recesses 17a, essentially completely formed by the contact sections 16a and mating contact sections 16b.

As in 2 shown, a plane that runs through the center of the base body 11 forms a symmetry plane 15 of the base body 11. More precisely, the base body 11 has a plurality, in the present embodiment six, of symmetry planes 15, which extend in the longitudinal direction through the Center of the base body 11 extend.

3 shows a top view of a first cover plate 30 and a second cover plate 32. The first and second cover plates 30, 32 according to the present embodiment are identical, but can also be designed differently in another embodiment. In the 3 Cover plate 30 or 32 shown has a contact area 34 and a fuse 36 formed between elongated holes 38.

As in 4 shown, the cover plate 30 or 32 designed according to the present embodiment is manufactured as a deep-drawn component. The cover plate 30 or 32 according to this embodiment has a plurality of contact areas 34, each of which can be contacted with the battery cells 20 via a projection from the cover plate 30 or 32. 4 also shows the fuse 36, which is between the contact areas 34, which is at least part of a deck plate underside 33 form, and a cover plate top 31 is provided. The fuse 36 melts when a melting temperature is reached, whereby a connection, for example an electrical and/or a mechanical connection, between a battery cell 20 and the cover plate 30, 32 can be separated. The cover plate 30 or 32 does not have to be designed as a deep-drawn component, but can also be manufactured as a completely flat stamped part.

5 shows an exploded view of an energy storage module 1 according to an embodiment with the base body 11, the battery cells 20, the cross-shaped connecting pieces 17b and a first cover plate 30 and a second cover plate 31.

6 shows a perspective view of an assembly of a plurality of the energy storage modules 1 to form an energy storage device 100 according to an embodiment. In an energy storage device 100 according to this embodiment, a plurality of energy storage modules 1 are connected to one another by the connecting pieces 17b, which are inserted or inserted in a form-fitting manner into the recesses 17a on the respective lateral surfaces 16.

7 shows a perspective view of the assembly of the majority of energy storage modules 1 to form an energy storage device 100 with an electrically conductive adhesive layer 40. The adhesive layer connects according to FIG 7 illustrated embodiment two energy storage modules 1 together.

8th shows a perspective view of the assembly of the plurality of energy storage modules 1 into an energy storage device 100 with a plurality of adhesive layers 40 and a plurality of cooling plates 50. The in 8th Adhesive layers 40 shown connect two energy storage modules 1 to each other and the in 8th The cooling plates shown are in turn applied to the respective adhesive layers 40.

With renewed reference to the 5 until 8th A method for producing an energy storage device 100 is then described. First, as for example in 5 to recognize, the battery cells 20 are inserted into a base body 11. Three connecting pieces 17b are then pushed into three of the six recesses 17a and the first and second cover plates 30, 32 are attached to the base body top 12 and the base body bottom 14 in such a way that the cover plates 30, 32 are in contact with the battery cells 20 and an energy storage module 1 is formed. Now, as in particular 6 To recognize, a plurality of the energy storage modules 1 assembled as described above are mechanically connected to one another, so that the connecting pieces 17b each engage in the recesses 17a and the contact sections 16a rest flush against the mating contact sections 16a. Then, as in 7 can be seen, an electrically conductive adhesive layer 40 is applied to two first cover plates 30 and / or at least two second cover plates 32 of the energy storage modules 1 in order to electrically connect the energy storage modules 1 to one another. The cooling plates 50 are then added, as in 8th shown, applied to the adhesive layers 40.

Reference symbol list

1

Energy storage module

10

Battery cell receiving module

11

Basic body

12

Base body top

14

Base body underside

15

symmetry plane

16

Lateral surface

16a

Contact section

16b

Counter contact section

17a

recess

17b

connector

18

through hole

19

Temperature control channel

20

Battery cell

30

first cover plate

31

Cover plate top

32

second cover plate

33

Cover plate underside

34

Contact area

36

fuse

38

Long hole

40

adhesive layer

50

cooling plate

100

Energy storage device

Claims (12)

Energy storage device (100) with a plurality of mechanically interconnected energy storage modules (1), each energy storage module (1) having a battery cell holder module (10), the battery cell receiving modules (10) each having a base body (11) which has a base body top side (12), a base body underside (14), one located between the base body top side (12) and the base body Underside (14) extending lateral surface (16) and a plurality of through holes (18) from the base body top (12) to the base body underside (14), wherein the through holes (18) are designed such that in them one battery cell (20) can be inserted in each case and the base body (11) is designed such that each battery cell (20), when inserted into a through hole (18), is enclosed by the base body (11) over its entire length, in Each battery cell receiving module (10) has battery cells (20) inserted into the through holes (18) and wherein an electrically conductive adhesive layer (40) electrically connects at least two first cover plates (30) and/or at least two second cover plates (32) of the energy storage modules (1). connects with each other. Energy storage device (100). Claim 1 , wherein the lateral surface (16) has at least part of a connecting device via which the battery cell receiving module (10) can be mechanically connected to a further battery cell receiving module (10). Energy storage device (100). Claim 1 or 2 , wherein the base body (11) has seven through holes (18), one of the through holes (18) being arranged centrally in the base body (11) and the other through holes (18) being arranged evenly around the central through hole (18). Energy storage device (100) according to one of Claims 1 until 3 , wherein a plane that runs through the center of the base body (11) forms a plane of symmetry (15) of the base body (11). Energy storage device (100) according to one of Claims 1 until 4 , wherein the base body (11) has a plurality of temperature control channels (19) which extend through the base body (11) from the top of the base body (12) to the underside of the base body (14). Energy storage device (100) according to one of Claims 1 until 5 , wherein the lateral surface (16) has at least one contact section (16a) and at least one mating contact section (16b) and the at least one contact section (16a) can be placed flush or substantially flush with the surface on a mating contact section (16b) of an adjacent, identical battery cell receiving module (10). . Energy storage device (100). Claim 6 , wherein the lateral surface (16) is formed completely or substantially completely by contact sections (16a) and mating contact sections (16b), the number of contact sections (16a) corresponding to the number of mating contact sections (16b). Energy storage device (100) according to one of Claims 1 until 7 , wherein a first cover plate (30) is arranged on the upper side of the base body (12) and a second cover plate (32) on the underside of the base body (14) and the two cover plates (30, 32) each have a plurality of contact areas (34). have, which can each be contacted with the battery cells (20), in particular via a projection from the cover plates (30, 32). Energy storage device (100). Claim 8 , wherein between the contact areas (34), which form at least part of a cover plate underside (33), and a cover plate upper side (31), a fuse (36) is provided, which melts when a melting temperature is reached, thereby creating a connection between a battery cell (20) and the cover plate (30, 32) can be separated. Energy storage device (100) according to one of Claims 1 until 9 , wherein the mechanical connection of the energy storage modules (1) is established via a connecting device which has at least one recess (17a) on the respective outer circumference of the lateral surfaces (16) to be connected and a separate connecting piece (17b) for positive insertion into the respective recesses (17a). having. Energy storage device (100) according to one of Claims 1 until 10 , wherein a cooling plate (50) is applied to the adhesive layer (40). Method for producing an energy storage device (100) according to one of the preceding claims with the steps: - inserting battery cells (20) into a battery cell receiving module (10), - attaching the cover plates (30, 32) to the top of the base body (12) and the Base body underside (14), so that the cover plates (30, 32) are in contact with the battery cells (20) and an energy storage module (1) is formed, - mechanically connecting a plurality of the energy storage modules (1) and - applying an electrically conductive adhesive layer (40) on at least two first cover plates (30) and/or at least two second cover plates (32) of the energy storage modules (1) for electrically connecting the energy storage modules (1).

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