EP4052324A1 - Shock-proof battery module, in particular for use in a submarine - Google Patents

Abstract

The invention relates to a battery module (10). The battery module (10) has at least one first battery (20) and a second battery (20), and all of the batteries (20) have a cylindrical design. All the batteries (20) have at least one electric contact (24) on a first cylinder base, and all of the batteries (20) have a bursting membrane (22) on a second cylinder base. All of the batteries (20) are arranged parallel to one another, and all of the first cylinder bases are arranged in the same direction. All of the batteries (20) are arranged in the module housing, and the module housing has a first module housing part (30) and a second module housing part (40), wherein the first module housing part (30) and the second module housing part (40) are designed to be flat and are arranged perpendicularly to the longitudinal direction of the batteries (20). The first module housing part (30) has first recesses for receiving a respective share of the batteries (20) in the region of the first cylinder base surfaces, and the first module housing part (30) has openings for feeding through the electric connections in the region of the first recesses. The second module housing part (40) has second recesses for receiving a respective share of the batteries (20) in the region of the second cylinder base surfaces, and the second module housing part (40) has bursting points (44) in the region of the second recesses. A potting compound (50) is arranged between the first module housing part (30), the second module housing part (40), and the batteries (20), and a respective cavity (60) is arranged between the bursting points (44) of the second module housing part (40) and the bursting membranes (22) of the second cylinder bases.

Description

Shock-proof battery module, especially for use in a submarine

The invention relates to a battery module, in particular for accumulators based on lithium.

Lithium-based batteries are increasingly interesting, for example because of their high energy density. However, there are two fundamental differences, for example to lead-sulfuric acid batteries, for large energy storage systems in particular. On the one hand, the individual cells cannot simply be enlarged at will. This means that a large number of accumulators are regularly combined to form a larger module. On the other hand, there is the problem of thermal runaway with these accumulators. Since a large amount of gas is also produced here, this means a great risk, especially in critical environments, as has been shown, for example, on accumulators in aircraft.

Traditionally, submarines have had large capacity batteries for underwater travel, making them a vital source of energy. Even in an emergency, it must always be ensured that energy is provided to keep the crew alive and to surface. Therefore, especially in the submarine sector, it is important that all important components are designed to be shock-proof, i.e. withstand a shock wave triggered by a detonation in the immediate vicinity and still be functional afterwards. Extremely high forces occur here for a short time.

At the same time, the safety of lithium cells in particular is much more important in a submarine than in a passenger car, for example. While people can leave the vehicle almost immediately and safely, this is impossible with a submerged submarine. To make matters worse, a submerged submarine only provides a very small breathable atmosphere, so pollutants are not released and diluted quickly.

From US 2012/0003508 A1 a battery with lithium cells with a flame-retardant filling foam between the lithium cells is known.

Confirmation copy From DE 102017214289 A1 a battery module with at least two battery cells and each with at least one safety valve is known.

From DE 102015 219 280 A1, a battery system encapsulated with a potting compound and having a plurality of battery cells is known.

From DE 102008 013 188 A1 an electrochemical accumulator with a degassing space for receiving a gas escaping from the cells in the event of an accident is known.

A solid-state secondary battery is known from JP 02 174 077 A.

From DE 10 2016 001 287 A1 a battery block with several battery cells and a potting compound is known, the battery cells being surrounded by a polyimide layer.

The object of the invention is to provide a battery module which ensures a high level of safety even when an individual accumulator runs through the heat.

This object is achieved by the battery module with the features specified in claim 1, the large battery module with the features specified in claim 11 and by the method for producing a battery module with the features specified in claim 14. Advantageous further developments result from the subclaims, the following description and the drawings.

The battery module according to the invention is a shock-resistant battery module which is particularly suitable for use in a submarine. The battery module has at least a first accumulator and a second accumulator. The battery module preferably has 20 to 500, particularly preferably 50 to 200, accumulators. All accumulators have a cylindrical design. This means that the individual accumulators are not designed as pouch cells, which can usually compensate for a larger change in volume. For that you can Accumulators in cylindrical shape can be easily produced and also connected in large numbers to form a module. All accumulators have at least two electrical contacts, preferably exactly two, one for the anode and one for the cathode. All accumulators have at least one electrical contact on a first cylinder end face. For example, the other electrical contact can be contacted via the jacket surface. Furthermore, all accumulators have a bursting membrane on a second cylinder face.

In the battery module, all of the accumulators are arranged parallel to one another, with all of the first cylinder end faces being arranged in the same direction. This allows the electrical energy to be dissipated centrally on one side. All accumulators are arranged in a module housing.

The module housing has a first module housing part and a second module housing part. The first module housing part has a flat design and is arranged perpendicular to the longitudinal direction of the accumulators. The second module housing part is also designed to be flat and is arranged perpendicular to the longitudinal direction of the accumulators.

The first module housing part has first recesses for receiving part of the accumulators in each case in the area of the first cylinder end faces. In the area of the first recesses, the first module housing part has openings for carrying out the electrical connections. This is necessary in order to be able to make electrical contact with the batteries and to be able to dissipate the power. The second module housing part has second recesses for receiving a part of the accumulators in each case in the area of the second cylinder end faces.

A potting compound is arranged between the first module housing part, the second module housing part and the accumulators. The sealing compound ensures a shock-proof positioning of the accumulators with respect to one another.

The second module housing part has bursting points in the area of the second recesses. A cavity is arranged between the bursting points of the second module housing part and the bursting membranes of the second cylinder end faces. The cavity can, for example and preferably, be gas-filled, in particular air-filled or inert gas-filled, in particular filled with nitrogen or argon.

By arranging all the accumulators in the module housing, all the accumulators are protected from the environment. If an accumulator now comes to a thermal runaway, it produces large quantities of hot gases which, in the event of direct contact, can easily lead to neighboring accumulators also becoming critical and thermal runaway themselves. However, since the accumulators are protected within the module housing, a single continuous accumulator can also make non-adjacent accumulators critical. However, a simple and complete installation would mean that the resulting pressure cannot be dissipated. If there is a thermal runaway in an individual accumulator, a pressure is created inside the accumulator, which causes the bursting membrane to burst on the second cylinder face. This increases the pressure in the cavity, which is adjacent to the accumulator. This increase in pressure leads to the bursting point also bursting in the area of the second recesses of the second module housing part, so that the gases produced are discharged to the outside and the pressure is reduced without further damage being produced.

In a further embodiment of the invention, all accumulators have at least two electrical contacts on the first cylinder end face.

In a further embodiment of the invention, a seal is arranged between the first module housing part and the accumulators. The seals mean that the accumulators cannot come into contact between the casting compound and the openings of the first recesses of the first module housing part and the electrical contacts. In particular, this prevents the openings or contacts from being closed or inaccessible by the potting compound itself and thus preventing electrical contact. In a further embodiment of the invention, one or more closures are placed on the electrical contacts leading through the openings. These serve to prevent the ingress of moisture, for example, and thus corrosion.

In a further embodiment of the invention, the distance between the second module housing part and the outer surfaces of the accumulators is 0.1 mm to 5 mm, preferably 0.2 mm to 2 mm. This gap width is optimal, since the potting compound can penetrate a little into the gap in order to establish the mechanical connection between the accumulators and the second module housing part, but not penetrate completely and thus prevent the formation of the cavity.

In a further embodiment of the invention, the electrical contacts of the accumulators protrude from the battery module through the openings of the first recesses in the first module housing part.

In a further alternative embodiment of the invention, the electrical contacts are electrically connected by means of a busbar located in the first module housing part and the power is thus dissipated from the battery module. For this purpose, the first module housing part has, for example, at least one first busbar in order to contact one of the two contacts on each accumulator. The first module housing preferably also has at least one second busbar in order to contact the other of the two contacts on each accumulator. This corresponds to an electrical parallel connection. Alternatively, the accumulators can also be connected in series in order to achieve a higher output voltage. The disadvantage here is that the failure of an accumulator would interrupt the electrical functionality. A combination of series connection and parallel connection can also be made.

In a further embodiment of the invention, contact is made with one contact in each case via a first busbar and the second contact is led out and contacted outside the battery module. In a further embodiment of the invention, the first module housing part and the second module housing part consist of a fiber-reinforced plastic, preferably a fiber-reinforced epoxy, in particular of glass fiber-reinforced epoxy.

In a further embodiment of the invention, the potting compound is a thermoset, preferably an epoxy.

The casting compound preferably has a modulus of elasticity of 25 to 200 MPa, more preferably 50 to 125 MPa, particularly preferably 60 to 90 MPa, according to ISO 527.

The casting compound preferably has a tensile strength of 2 to 20 MPa, more preferably 3 to 15 MPa, particularly preferably 4 to 9 MPa, according to ISO 527.

The potting compound preferably has a hardness of 20 to 100 Shore D according to ISO 53505, preferably from 35 to 80, particularly preferably from 50 to 75.

In a further embodiment of the invention, the accumulators are separated from the potting compound by a polyimide film, in particular a film made of a polycondensate of 1,2,4,5-benzene tetracarboxylic acid dianhydride and 4,4'-diaminodiphenyl ether. Polyimide is particularly puncture-resistant and thus leads to a further separation and thus securing of the accumulators from one another.

In a further embodiment of the invention, the thermal conductivity of the casting compound is greater than 0.03 W / (m K), preferably greater than 0.2 W / (m K), more preferably greater than 0.5 W / (m · K) ), particularly preferably greater than 0.8 W / (m K). Even if an arbitrarily high thermal conductivity would be desirable, the potting compound realistically has a thermal conductivity that is less than 20 W / (m K), more likely less than 5 W / (mK), even more likely less than 2 W / (m · K). In particular, the thermal conductivity is determined in accordance with ISO 8894-1. In a further embodiment of the invention, the distance between the bursting points of the second module housing part and the bursting membranes of the second cylinder end faces is 0.5 mm to 2 mm.

In a further embodiment of the invention, the bursting points of the second module housing part have a thickness of 0.1 mm to 0.4 mm. The bursting points of the second module housing part are particularly preferably made of the same material as the second module housing part. The bursting points are particularly preferably produced by reducing the wall thickness in this area of the second module housing part. In a further development of the embodiment, a circular groove is arranged around the bursting point.

In a further embodiment of the invention, the second module housing part has at least one first gas channel, the first gas channel having at least the bursting point of the second module housing part, which is arranged behind the first accumulator, and the bursting point of the second module housing part, which is arranged behind the second accumulator the side opposite the cavities connects to one another. Through the first gas channel, gases which arise in the event of a thermal runaway or other exothermic chemical reaction of an accumulator can thus be specifically discharged, for example discharged upwards. This is particularly preferred if several battery modules are to be set up next to one another so that the gases produced do not come into contact with the electrical contacts of another battery module, since they could damage them.

In a further embodiment of the invention, a large battery module is formed from two battery modules. The battery modules are preferably designed in accordance with one of the above embodiments. The two battery modules are arranged in the large battery module in such a way that the first cylinder end faces of all the accumulators are arranged towards the center of the large battery module and thus directly opposite one another. The distance between the battery modules is between 1/20 and 1/1 of the extent of the battery module in the direction of the longitudinal axis of the accumulators, for example between 10 cm and 20 cm. As a result, all electrical lines run in the middle, preferably mirror-symmetrically from both sides. This enables cabling that has a very low electromagnetic signature and thus reduces the probability of detection for a submarine with such a large battery module. At least the electrical contact is therefore arranged in an intermediate space between the two battery modules. Furthermore, the gap is potted with the potting compound and cured. It can be advantageous to apply a boundary around the space before the potting in order to prevent the potting compound from leaking out. The limitation can then be removed again. Although this makes it practically impossible to carry out maintenance work or repairs, it is advantageous that this stabilizes all contacts within the potting compound and is therefore shock-proof. The contacts cannot, or can hardly, become detached from the contact and the potting compound prevents a detached contact from moving freely in the space. A short circuit caused by a released contact is practically impossible.

In a further embodiment of the invention, the large battery module has a base plate, the base plate being glued and / or encapsulated to the two battery modules. The two battery modules can also be screwed together, for example for a first fixation before potting. Gluing and / or potting creates a large-area connection between the base plate and the battery modules so that the forces that occur in the event of a shock can be transmitted safely and non-destructively . For example, the connection to a guide rail can be established via the base plate.

In a further embodiment of the invention, a cooling water supply and a cooling water discharge are arranged cast in the intermediate space in the potting compound.

In a further aspect, the invention relates to a method for producing a battery module, the method having the following steps: a) Providing a first module housing part, the first module housing part having first recesses for receiving a part of the accumulators in each case in the area of the first end faces, the first module housing part having openings in the area of the first recesses for carrying out at least one electrical connection, b) providing a second Module housing part, the second module housing part having second recesses for receiving a part of the accumulators in each case in the area of the second end faces, the second module housing part having bursting points in the area of the second recesses, c) arranging the first module housing part in such a way that the first recesses are arranged upwards, wherein the openings are arranged downward, d) arranging accumulators in the first recesses, wherein the first cylinder end faces with each at least one electrical contact are arranged downward, e) arranging the second module housing Partly in such a way that the accumulators are inserted with the second end faces into the second recesses of the second module housing part, f) introduction of a mixture of epoxy resin and hardener in the area between the first module housing part and the second module housing part, g) hardening of the mixture to form the potting compound.

The mixture of epoxy resin and hardener is introduced into the area between the first module housing part and the second module housing part in such a way that gas is trapped in the area between the bursting points of the second module housing part and the bursting membrane of the accumulator.

In other words, the first module housing part is first placed in such a way that the first recesses point upwards, into which the accumulators are then inserted in such a way that the electrical contacts point downwards. The second module housing part is then placed on top of the accumulators and the area between the module housing part with a mixture of epoxy resins and hardener decays and this is then cured. This then creates the finished battery module. ok

This procedure and in particular also the spatial arrangement lead to gas inclusions being formed in the second recesses of the second module housing part during filling, which then, after the material has hardened, form desired cavities that leave parts of the accumulators uncovered. Due to the partial penetration of the epoxy material from below into the second recesses, the gas cannot escape in these areas, so that the pressure increases slowly and creates a counterforce against the penetration of the epoxy material. This prevents potting compound from penetrating between the bursting membranes and bursting points and ensures the safety of the battery module. To operate the battery module, this battery module would usually then be rotated by 90 ° so that the individual accumulators are not vertical, but are arranged horizontally. However, if the battery module were to be manufactured in this orientation, the cavities would not be formed, or at least would not be formed with the same reliability.

In a further embodiment of the invention, a sealing adhesive is introduced into the gap between the outer surfaces of the accumulators and the first module housing part between step d) and step e). The sealing adhesive is intended to prevent the liquid mixture of epoxy resins and hardener from reaching and blocking the openings of the first module housing part and / or the electrical contacts of the accumulators. Another positive side effect is that the accumulators are fixed relative to the first module housing part and thus stability is already ensured. This makes it easier to put on the second module housing part, since all the accumulators hold their relative position.

In an alternative embodiment of the invention, an O-ring is applied to each accumulator before step d), which O-ring is arranged in step d) in the gap between the outer surfaces of the accumulators and the first module housing.

In a further embodiment of the invention, a casting mold is arranged before step f) and is removed again after step g). For example and in particular, after step e), an outer lateral border is used as a casting mold for the battery module is attached, which prevents the potting compound from being brought out to the side. This shape preferably also has an introduction device for introducing the potting compound. Alternatively, a trough-shaped casting mold, for example, can be provided before step c), into which the first module housing part is then inserted in step c). This is followed by the further build-up and hardening of the mixture as well as the subsequent removal of the casting mold.

A lateral sealing of the housing is alternatively also achieved in that the module housing parts touch each other circumferentially or are temporarily closed on the side by covers, the covers being removed again after the potting.

In a further embodiment of the invention, before step d), the accumulators are wrapped with a polyimide film, in particular a film made of a polycondensate of 1,2,4,5-benzene-tetracarboxylic acid dianhydride and 4,4'-diaminodiphenyl ether.

In a further aspect, the invention relates to a method for producing a large battery module according to the invention. In addition to the steps of the method for producing a battery module, the following steps are carried out after step g): h) providing a second battery module which was produced according to method steps a) to g), i) arranging the two battery modules with the first cylinder end face to one another, so that a gap is created between the two battery modules, j) introducing a mixture of epoxy resin and hardener into the gap between the two battery modules and curing the mixture.

In a further embodiment of the invention, electrical connections are made on the contacts of the accumulators. This can take place before step h), after step i) or partially before step h) and after step i). In a further embodiment of the invention, cooling water connections are attached to the battery modules. This can take place before step h), after step i) or partially before step h) and after step i).

In a further aspect, the invention relates to an energy storage device. The energy storage device has a load output for transferring electrical energy to at least one consumer. For example, this is a busbar that collects the electrical energy from various accumulators and transfers it to the on-board network, for example of a submarine. The energy storage device has at least one first battery module according to the invention. A plurality of modules are preferably arranged grouped in strings. A plurality of strands are more preferably arranged. For example, a submarine usually has an energy storage device that has about 10 to 50 strings, each string having about 4 to 10 modules. A module can have 20 to 500 accumulators, for example.

In a further aspect, the invention relates to a watercraft with an energy storage device according to the invention. The watercraft is preferably a military watercraft. In particular, the military watercraft is selected from the group comprising submarines, aircraft carriers, helicopter carriers, cruisers, destroyers, frigates, corvettes, landing ships, mine layers, mine clearance vehicles, mine hunters, patrol boats, speed boats, escort boats, air cushion boats and reconnaissance ships. The military watercraft is particularly preferably selected from the group comprising submarines, cruisers, destroyers, frigates, corvettes, speed boats and escort boats. The military watercraft is very particularly preferably a submarine.

The battery module according to the invention is shown below using a device shown in FIG

Drawings illustrated embodiment explained in more detail.

Fig. 1 battery module

Fig. 2 battery module with seal

Fig. 3 battery module with gas duct Fig. 4 Battery module with busbar Fig. 5 Step c)

Fig. 6 step d)

Fig. 7 Application of the seal

Fig. 8 step e)

Fig. 9 Attachment of the casting mold

Fig. 10 step f)

Fig. 11 Large battery module

In Fig. 1, the battery module 10 is shown in a schematic cross section. The battery module 10 has six accumulators 20, shown by way of example. The accumulators 20 each have two electrical contacts 24 via which electrical energy can be delivered. A bursting membrane 20 of the accumulator 20 is arranged on the opposite side of the cylindrically constructed accumulators. The accumulators 20 are located in a module housing which consists of a first module housing part 30, a second module housing part 40 and a potting compound 50. The first module housing part 30 has first recesses, which can be seen in FIG. 1 as those depressions facing downwards. The accumulators 20 each protrude a little into these first recesses. The electrical contacts 24 of the accumulators 20 protrude through openings in the first recesses to the outside, so that electrical contacting of the entire battery module 10 via the individual electrical contacts 24 on one side is possible. Alternatively, the electrical contact can be made independently within the first module housing part 30 without the electrical contacts 24 protruding from the first module housing part 30 in order to provide a closed surface. In this alternative, electrical lines can then be arranged in the first module housing part 30.

The second module housing part 40 flat mirror-image recesses compared to the first module housing part 30, since both are placed on the opposite sides of the accumulators. For example, the bursting point 44 is produced by thinning out the second module housing part 40, for example when drilling out the second recesses from the second module housing part 40.

Typically, the battery module 10 would be operated rotated by 90 ° counterclockwise, for example. As a result, the accumulators 20 come into a lying position, the electrical contacts 24 can all be tapped on one side.

FIG. 2 additionally shows seals 70 between the accumulators 20 and the first module housing part 30.

In FIG. 3, the battery module 10 additionally has a gas duct 90. The gas duct 90 is arranged in such a way that it runs behind the bursting points 44 in such a way that it absorbs and discharges the escaping gases. If an accumulator 20 thermally ruptures, its rupture membrane 22 bursts. The gases produced reach the cavity 60, whereby its internal pressure rises and the burst point 44 of the second module housing part 40 also bursts, thus directing the gases produced into the gas duct 90. The gases produced are discharged via the gas duct 90. If the battery module is operated in a state rotated 90 ° counterclockwise, the gas duct 90 points upwards, which is beneficial for the discharge of hot gases through the gas duct 90. In this case, the gas channel 90 is closed on the underside and open on the upper side, closed by a valve or closed by a further closure membrane. The sealing membrane can be designed in such a way that it closes the opening and is opened when the gas escapes. It is, for example, a thin adhesive film. The closure of the gas duct 90 on both sides prevents moisture from collecting in the gas duct 90 in a damp or wet environment.

4 shows a battery module 10 with a first busbar 100. The accumulators 20 are rotated by 90 ° compared to FIGS. 1 to 3, so that the second electrical contact 24 lies behind the first. A second busbar is arranged behind the first busbar 100, so that both poles are tapped separately. The electrical contacts 24 can when introducing the Batteries 20 are electrically and mechanically connected to the busbars 100, for example by means of conductive silver adhesive.

The method for producing a battery module 10 is shown schematically in FIGS. 5 to 10. 5 shows the first module housing part 30, which is arranged horizontally so that the first recesses are arranged pointing upwards and the openings are arranged pointing downwards. In FIG. 6, the accumulators 20 are inserted into the first recesses of the first module housing part 30 in such a way that the electrical contacts 24 protrude downward through the openings. Next, a seal, in particular in the form of a sealing adhesive, is introduced into the area between the outer surface of the accumulators 20 and the first module housing part 30 in the area of the first recesses, as shown in FIG. 7. On the one hand, this ensures that the accumulators 20 are already mechanically fixed. On the other hand, it prevents the casting compound from penetrating deeper areas. After the module housing part 40 has been placed on the accumulators 20, the picture shown in FIG. 8 results. So that no casting compound gets to the outside when the inner area is filled with casting compound, a casting mold 80 is attached to the outside, as shown in FIG. 9. A mixture 52 of resin and hardener is then introduced, as shown in FIG. 10. This is hardened and, after hardening, the casting mold 80 is removed. After the casting mold 80 has been removed, the battery module 10 shown in FIG. 1 is obtained.

In Fig. 11, a large battery module 110 is shown. The large battery module 110 has two battery modules 10, which are each arranged in such a way that the first cylinder end faces of all the accumulators 20 point towards the center, where the electrical contacting 130 is arranged in the space. This gap is cast with a casting compound 50. The base plate 120 can, for example, be glued to the battery modules 10 prior to the assembly of the large battery module 110 or, when the intermediate space is cast, it can be connected to the potting compound 50 by potting compound flowing under the battery modules 10. Alternatively, the base plate 120 can also, for example, firstly be glued to the battery modules 10 at the edge and then through penetrating potting compound 50 to be further potted. In all cases, a full-area connection between the battery modules 10 and the base plate 120 is desirable.

Reference numeral 10 battery module

20 accumulator

22 bursting membrane

24 electrical contact

30 first module housing part 40 second module housing part

44 bursting point

50 casting compound

52 Mixture of resin and hardener 60 cavity 70 sealing

80 mold

90 gas duct

100 busbar

110 large battery module 120 base plate

130 electrical contact

Claims

Claims

1. Battery module (10), wherein the battery module is a shock-resistant battery module for use in a submarine, wherein the battery module (10) has at least a first accumulator (20) and a second accumulator (20), wherein all accumulators (20) one have a cylindrical design, all accumulators (20) having at least two electrical contacts (24), all accumulators (20) having at least one electrical contact (24) on a first cylindrical end face, all accumulators (20) having a bursting membrane on a second cylindrical end face (22), wherein all accumulators (20) are arranged parallel to one another, wherein all first cylinder end faces are arranged in the same direction, wherein all accumulators (20) are arranged in a module housing, the module housing having a first module housing part (30) and a second module housing part (40), wherein the first module housing part (30) is flat and perpendicular t is arranged to the longitudinal direction of the accumulators (20), the second module housing part (40) being flat and arranged perpendicular to the longitudinal direction of the accumulators (20), the first module housing part (30) having first recesses for receiving a part of the accumulators (20) ) in the area of the first cylinder end faces, the first module housing part (30) having openings for the implementation of the electrical connections in the area of the first recesses, the second module housing part (40) having second recesses for receiving a part of the accumulators (20) in the area of the having second cylinder end faces, the second module housing part (40) having bursting points (44) in the region of the second recesses, a potting compound (50) being arranged between the first module housing part (30), the second module housing part (40) and the accumulators (20) , the potting compound (50) providing a shock-proof positioning of the accumulators (20) each other, a cavity (60) being arranged between the bursting points (44) of the second module housing part (40) and the bursting membranes (22) of the second cylinder end faces.

2. Battery module (10) according to claim 1, characterized in that a seal (70) is arranged between the first module housing part (30) and the accumulators (20).

3. battery module (10) according to any one of the preceding claims, characterized in that between the second module housing part (40) and the outer surfaces of the accumulators (20) a distance of 0.1 mm to 5 mm, preferably from 0.2 mm to 2 mm, is.

4. Battery module (10) according to one of the preceding claims, characterized in that the electrical contacts (24) of the accumulators (20) protrude through the openings of the first recesses in the first module housing part (30) from the battery module (10).

5. Battery module (10) according to one of the preceding claims, characterized in that the potting compound (50) is a thermoset, preferably an epoxy resin.

6. battery module (10) according to any one of the preceding claims, characterized in that the accumulators (20) by a polyimide film, in particular a film made of a polycondensate of 1, 2,4,5-benzene tetracarboxylic dianhydride and 4,4'-diaminodiphenyl ether, at least are partially separated from the potting compound (50).

7. Battery module (10) according to one of the preceding claims, characterized in that the thermal conductivity of the potting compound (50) is greater than 0.03 W / (m K), preferably greater than 0.2 W / (m K).

8. Battery module (10) according to one of the preceding claims, characterized in that the distance between the bursting points (44) of the second module housing part (40) and the bursting membranes (22) of the second cylinder end faces is 0.5 mm to 2 mm.

9. battery module (10) according to any one of the preceding claims, characterized in that the bursting points (44) of the second module housing part (40) has a thickness of 0.1 mm to 0.4 mm.

10. Battery module (10) according to one of the preceding claims, characterized in that the second module housing part (40) has at least one first gas channel (90), the first gas channel (90) at least the bursting point (44) of the second module housing part (40) , which is arranged behind the first accumulator (20), and the bursting point (44) of the second module housing part (40) which is arranged behind the second accumulator (20) connects to one another on the side opposite the cavities.

11. Large battery module (110), wherein the large battery module (110) is formed from two battery modules (10) according to one of the preceding claims, wherein the two battery modules (10) are arranged such that the first cylinder end faces of all batteries (20) to the center of the Large battery module (110) and are thus arranged directly opposite one another, an interspace between the two battery modules (10) having at least the electrical contact (130), the interspace being encapsulated with the potting compound (50).

12. Large battery module (110) according to claim 11, characterized in that the large battery module (110) has a base plate (120), the base plate (120) being glued and / or encapsulated to the two battery modules (10).

13. Large battery module (110) according to one of claims 11 to 12, characterized in that a cooling water supply and a cooling water discharge are arranged in the intermediate space in the casting compound (50)

14. The method for producing a battery module (10) according to any one of claims 1 to 10, wherein the method comprises the following steps: a) Providing a first module housing part (30), the first module housing part (30) having first recesses for receiving a part of the accumulators (20) in the area of the first end faces, the first module housing part (30) in the area of the first recesses having openings for Having at least one electrical connection through, b) providing a second module housing part (40), the second module housing part (40) having second recesses for receiving a part of the accumulators (20) in the region of the second end faces, the second module housing part (40) has bursting points (44) in the area of the second recesses, c) arranging the first module housing part (30) such that the first recesses are arranged upwards, the openings being arranged downwards, d) arranging accumulators (20) in the first recesses , wherein the first cylinder end faces with the respective at least one electrical contact (24) according to be arranged at the bottom, e) arranging the second module housing part (40) such that the accumulators (20) are inserted with the second end faces into the second recesses of the second module housing part (40), f) introducing a mixture (52) of epoxy resin and hardener in the area between the first module housing part (30) and the second module housing part (40), g) curing of the mixture (52) to form the casting compound (50).

15. The method according to claim 14, characterized in that between step d) and step e) a sealing adhesive is introduced into the gap between the outer surfaces of the accumulators (20) and the first module housing.

16. The method according to claim 14, characterized in that before step d) an O-ring is applied to each accumulator (20), which is arranged in step d) in the gap between the outer surfaces of the accumulators (20) and the first module housing .

17. The method according to any one of claims 14 to 16, characterized in that a casting mold (80) is arranged before step f), which is removed again after step g).

18. The method according to any one of claims 14 to 17, characterized in that before step d) the accumulators (20) with a polyimide film, in particular a film made of a polycondensate of 1, 2,4,5-benzene tetracarboxylic dianhydride and 4,4'- Diaminodiphenyl ether.

19. The method for producing a large battery module according to one of claims 11 to 13, the method in addition to the method for producing a battery module according to one of claims 14 to 18, characterized in that after step g) the following steps are carried out: h) providing a second battery module which was produced according to method steps a) to g), i) arranging the two battery modules (10) with the first cylinder face to one another so that a space is created between the two battery modules, j) introducing a mixture (52) of epoxy resin and hardener in the space between the two battery modules and curing the mixture.