DE102021119206A1 - Method for sealing an intermediate space between a battery module and a battery housing, battery and motor vehicle - Google Patents

Abstract

The invention relates to a method for introducing a heat-conducting compound (20) into an intermediate space (18) between a battery module (12) and a part (10) of a battery housing (16), the battery housing (16) being provided, the battery module (12) is arranged in a receiving area (14) of the battery housing (16), a seal (22) at least partially delimiting the intermediate space (18) is provided between the battery module (12) and the part (10) of the battery housing (16), and the Thermally conductive compound (20) is introduced into the intermediate space (18). The seal (22) is provided as a sealing compound (22) that can be hardened by external activation and, in a non-activated state, moves the battery module ( 12) and the part (10) of the battery case (16) is brought into contact, and is activated when it is in the determined final position.

Description

The invention relates to a method for introducing a heat-conducting compound into an intermediate space between a battery module and part of a battery housing, the battery housing being provided, the battery module being arranged in a receiving area of the battery housing, a seal between the battery module and the intermediate space at least partially delimiting Part of the battery case is provided and the thermal compound is introduced into the gap. Furthermore, the invention also relates to a battery and a motor vehicle.

In order to be able to efficiently dissipate the heat generated in the high-voltage batteries during fast charging and when power is called up in electric vehicles, a heat-conducting paste, the so-called gap filler, which is referred to as heat-conducting compound in the context of the present invention, is used between the battery module and the cooling base. When assembling the high-voltage battery, the gap filler can, for example, be applied in the form of a caterpillar to the empty battery compartment and then slowly pressed into the surface by placing and lowering the battery module. An alternative possibility is to inject the gap filler into the space between the battery case and the module. The battery module is first placed and screwed into the empty battery compartment. The gap filler is then injected into the corresponding gap between the battery module and the bottom of the housing. Such a gap filler injection is, for example, in DE 10 2018 208 070 A1 described. The intermediate space into which the heat-conducting medium is introduced is sealed by at least one sealing element, which is arranged between the battery module and the housing element.

Such a seal is advantageous in order to outwardly delimit the surface to be wetted between the battery module and the compartment base, i.e. the part of the housing base which corresponds to a compartment assigned to the battery module. Such a seal has to meet numerous requirements. First, the seal should withstand the gap filler injection pressure during installation. Therefore, the seal must be extremely robust. On the other hand, the seal must work with the gap height tolerances that occur, which can be between 0.5 and 2.0 mm, for example. In other words, the seal should be able to compensate for such height tolerances. Therefore, a very soft seal would be an advantage. At the same time, the seal must not exert too much counter-pressure on the battery module and compartments, so as not to unnecessarily push the gap up. A seal that is as soft as possible would also be advantageous for this. Soft seals, on the other hand, fail to withstand the injection pressure mentioned above. Accordingly, such a desired seal is not available on the market due to the conflicting requirements.

Furthermore describes the DE 11 2019 002 449 T5 thermally conductive gap filler materials with controlled cure. Such a gap filler can be used between battery cells and a base plate. A pattern of gap filler that corresponds to the desired layout of the battery cells can be applied to the surface of the base plate, for example with a robot. In order to form such a layer with a discrete pattern of the thermally conductive gap filler, it must have a relatively high viscosity. However, in order to be able to introduce a thermally conductive compound into the intermediate space using an injection method described above, the thermally conductive compound should have the lowest possible viscosity in order to enable it to be distributed as evenly as possible in the intermediate space. In the case of thermally conductive masses with a higher viscosity, correspondingly higher injection pressures are required, which could damage the battery module or, on the other hand, would require a more robust design of the battery module, which in turn entails disadvantages in terms of installation space, weight and complexity.

The object of the present invention is therefore to provide a method, a battery and a motor vehicle that enable such a space to be sealed as efficiently as possible and at the same time allow the gap heights of the space between a battery module and a housing part to be as small as possible.

This object is achieved by a method, a battery and a motor vehicle having the features according to the respective independent patent claims. Advantageous configurations of the invention are the subject matter of the dependent patent claims, the description and the figures.

In a method according to the invention for introducing a heat-conducting compound into an intermediate space between a battery module and part of a battery housing, the battery housing is provided, the battery module is arranged in a receiving area of the battery housing, and a seal that at least partially delimits the intermediate space is provided between the battery module and the part of the battery housing . Furthermore, the heat-conducting compound is introduced into the intermediate space. The seal is made to be hardenable by external activation Sealing compound provided, which in a non-activated state is brought into a certain final position between the battery module and the part of the battery housing, in which the sealing compound contacts the battery module and the part of the battery housing, and is activated when it is in the certain final position.

It can thus advantageously be achieved that such a seal, which is provided by sealing compound, is very soft in the non-activated state. This makes it possible that when the battery module is inserted into the compartment, ie the receiving area provided by the battery housing, it does not exert any counterforce or does not exert an excessively large counterforce. In addition, this can advantageously result in the seal completely filling the gap between the battery module and the part of the battery housing, despite height tolerances of the gap height or height of the intermediate space in the range between, for example, 0.5 mm and 2 mm. If, on the other hand, the sealing compound is then activated by the external activation, it reacts and forms, for example, a hard border to limit the gap. As a result, a seal is then provided which can also withstand the typical injection pressures of, for example, up to 4 bar. All of the requirements mentioned at the outset can thus advantageously be met by the sealing compound. Accordingly, by using such a sealing compound as a seal, very small gap heights between the battery module and the part of the battery housing, in particular the housing base, can be achieved, which in turn promotes heat dissipation from the battery module and ultimately significantly improves the cooling of the battery.

The introduction of the thermally conductive compound into the intermediate space takes place after the battery module has been arranged in the receiving area. However, the seal can be provided either after or before the battery module is arranged in the receiving area. In the latter case, no counter-pressure at all is then exerted on the battery module or the housing base by the sealing compound during the arrangement, since this is not yet located between the battery module and the part of the battery housing at this point in time. The thermally conductive compound can be the gap filler mentioned at the outset, also known as gap filler. This can be provided in pasty, viscous or liquid form, for example. The part of the battery housing preferably represents a housing base of the battery housing. Such a housing base can also be designed as a cooling base. For this purpose, the housing base can have integrated cooling ducts through which a cooling medium can flow, or it can simply be designed as a cooling plate on which a cooling device is arranged on a side facing away from the battery module. In addition to a housing base, the battery housing can also have side walls and optionally further partitions if the battery housing is designed to accommodate a number of battery modules. The housing can be subdivided into a number of compartments by the respective side and partition walls, which are also referred to as compartments and which can each provide at least one or precisely one accommodation area for accommodating an associated battery module. Correspondingly, the battery housing can also have several receiving areas for receiving respective battery modules. The respective receiving areas can be spatially separated from one another, for example by the aforementioned partitions of the battery housing, or not spatially separated from one another. In addition, the battery housing can also have a housing cover that is put on when the battery modules are arranged in their respective receiving areas. The housing floor and the side walls can be provided in the form of a battery tray, for example. The battery housing and the at least one battery module accommodated therein can preferably provide a high-voltage battery for a motor vehicle, in particular an electric or hybrid vehicle. The heat-conducting compound is preferably introduced into the space between the battery module and the bottom of the housing. Nevertheless, it is also conceivable that such a heat-conducting compound is introduced at any other point between the battery module and another part of the battery housing, for example a side wall. Correspondingly, the part of the housing base can also basically represent a side wall or partition wall of the battery housing.

The battery housing is preferably an overall battery housing of the high-voltage battery. This preferably comprises a plurality of battery modules which, as described for at least one battery module, can be arranged in the battery housing. A corresponding intermediate space can be provided between a respective battery module and the housing floor, which can be sealed as described and filled with a heat-conducting compound. This is described below using only one battery module as an example, but can also be implemented in a very similar way for several battery modules. The battery module can also have one or more battery cells. These can be in the form of lithium-ion cells, for example. In addition, the battery cells can, for example, be in the form of prismatic battery cells, as is preferred here, or alternatively as round cells or pouch cells. Furthermore, the battery module can also have a module housing in which the battery cells are arranged. The module housing can, for example, only be designed as a frame around a cell stack with a number of battery cells and not have a separate module base. In this case, the underside of the battery module is provided by the respective undersides of the battery cells of the cell stack. However, the module housing preferably comprises a housing base. When it is introduced into the receiving area, the battery module is preferably arranged in the receiving area of the battery housing in such a way that an underside of the battery module, which is preferably provided by the named module base, faces the housing base. The heat-conducting compound is introduced accordingly into the space between this module base and the housing base. The seal can, for example, then be arranged according to its specific end position in such a way that it contacts the underside of the battery module, in particular the module base, in a peripheral peripheral area in the form of a closed sealing line. If the module base has a rectangular geometry, for example, then the seal can be designed with such a rectangular geometry in its end position. The module housing and the battery housing are preferably formed from a metal or an alloy, for example aluminum, but can in principle also be made from a plastic or fiber-reinforced plastic. The thermal conduction compound is preferably introduced in the form of an injection through at least one injection opening which opens into the intermediate space. Such an injection opening is preferably provided through the battery housing, in particular through the part of the battery housing, ie preferably through the bottom of the housing. However, the heat-conducting compound can also be injected from another side, for example starting from the module. For example, the injection channel can also be provided continuously through the battery module, for example integrated in a housing part, for example a side wall, of the module housing. If a plurality of battery modules are accommodated in the battery housing, at least one such injection opening is preferably provided per battery module for the respective associated spaces to be filled with the heat-conducting compound. Several such injection openings can also be provided per module.

External activation of the sealing compound is to be understood as actively inducing the curing process of the sealing compound and/or at least actively inducing an acceleration of this curing compared to the speed of curing without such external activation. Correspondingly, the sealing compound can also be designed in such a way that it hardens without external activation, but then not as quickly as is done by such an external activation. Such an external activation of the curing process or an accelerated curing process can thus advantageously be achieved in that long waiting times can advantageously be avoided. This advantageously enables the thermally conductive compound to be filled in in a particularly time-efficient manner, in particular without having to wait a long time for the sealing compound to harden. Such an external activation can be provided in different ways.

In an advantageous embodiment of the invention, the sealing compound is physically activated. Physical activation can be understood to mean, for example, activation by means of light in a predetermined wavelength range, for example by means of UV (ultraviolet) radiation, activation by tempering to a predetermined temperature range, or activation by applying a voltage. Depending on the design of the sealing compound, all of these variants can advantageously achieve very rapid curing of the sealing compound.

In a further, very advantageous embodiment of the invention, the sealing compound is chemically activated by means of a chemical activator. For example, there are plastics that can also be used as the sealing compound in the context of the present invention, which remain viscous for several days and only start crosslinking through certain activators, in particular chemical activators. Examples of this are polyurethanes, which can be activated, for example, using water as a chemical activator. Another example of such a sealing compound are silicones, which can be activated, for example, using platinum as a chemical activator. Such chemical activators can advantageously achieve particularly rapid curing of the sealing compound as soon as the sealing compound comes into contact with the chemical activator.

Accordingly, it is very advantageous, for example, if the activator is arranged in at least one contact area of the battery module and/or the battery housing, in which the sealing compound makes contact with the battery module or the battery housing, in particular the housing base, in the specific end position. For example, the activator component can already be applied in the battery tray and then begins the chemical reaction when it comes into contact with the sealing compound after the module has been set. The big advantage here is that the sealing compound only shows its properties after the assembly builds up. Advantageously, the sealant remains soft and viscous during module setting. Accordingly, it exerts hardly any forces on the case back and therefore does not deform it. When the module has reached its final position, the sealing compound forms a connection with the module underside and the housing base, triggered by activation by the activator. It is only then that it is activated and unfolds its hardening so that the pressure can later be withstood during the injection.

It is therefore a further very advantageous embodiment of the invention if the sealing compound in the specific end position contacts the battery module in a first contact area and contacts the part of the battery housing in a second contact area, with the activator being in the first contact area before the battery module is arranged in the receiving area is arranged and the sealing compound is arranged in the second contact area or the activator is arranged in the second contact area and the sealing compound is arranged in the first contact area, and wherein the sealing compound is activated by arranging the battery module in the receiving area.

The battery module can thus advantageously be inserted into the receiving area while the sealing compound is still soft, as a result of which it can easily compensate for tolerances and counteracting forces on the housing base can be avoided. This allows particularly small gap widths to be implemented. If the sealing compound is then activated by arranging the battery module, it hardens quickly and the heat-conducting compound can then be injected into the intermediate space.

Accordingly, it represents a further advantageous embodiment of the invention that the thermally conductive compound is introduced into the sealed intermediate space after the activated sealing compound has hardened. Because the activated sealing compound has already hardened at this point in time, it can advantageously withstand high injection pressures.

In a further very advantageous embodiment of the invention, the sealing compound is provided as part of the thermally conductive compound and is injected into the intermediate space after the battery module has been arranged in the receiving area. In this very advantageous embodiment of the invention, the injected gap filler itself can be used as a seal. As a result, a so-called chemical (or physical) booster can be used as an activator, for example, which enables extremely rapid, sudden crosslinking of the sealing compound, which is provided here as part of the thermally conductive compound. Such an abrupt crosslinking is also referred to as snap curing. Such an abrupt curing, ie curing within a few minutes or even seconds, can in turn be achieved by a physical activator, as described above, or by a chemical activator. Here, too, possible materials for the sealing compound are, for example, polyurethanes, which can be activated with a water booster, or silicones as a sealing compound, which can be activated with platinum boosters. Such so-called snap-curing processes are already available in plastics processing and are used in other areas. These can now also be used advantageously to provide the seal described. In addition to these chemical activators, there are also physical possibilities. Examples are UV radiation or another type of concentrated energy input, such as temperature.

Precisely because of such an abrupt hardening, it is now advantageously possible to inject the sealing compound as part of the thermally conductive compound into this intermediate space. As soon as the injected thermal compound comes into contact with the chemical booster, for example, it hardens abruptly and forms a hard border for the subsequent gap filler.

Accordingly, it represents a further, very advantageous embodiment of the invention if the sealing compound in the specific end position contacts the battery module in a first contact area and contacts the part of the battery housing in a second contact area, with the activator being placed in the first area before the battery module is arranged in the receiving area and/or second contact area is arranged, and wherein the sealing compound represents a flow front when injecting the thermally conductive compound, which hardens through contact with the activator as soon as the flow front reaches the specific end position. The heat-conducting compound is therefore filled in through, for example, one or more such injection openings and spreads out in all directions in the intermediate space until the flow front of this filled-in heat-conducting compound finally contacts the circulating chemical booster as an activator. As a result, the thermally conductive compound hardens abruptly in the edge region provided by the flow front, whereby the gap filler flowing in, ie the thermally conductive compound flowing in, is also held within the intermediate space and is restricted to this by the seal. In this case, too, it is possible to arrange the battery module in the receiving area without too great a counterforce. In particular, an arrangement without any counterforce is possible here, since at this point in time of the arrangement there is still no sealant between the battery module and located on the bottom of the case. This advantageously makes it possible to arrange the battery module in the battery housing while forming the smallest possible gap widths. The seal is only formed after the filling of the heat-conducting compound into the intermediate space, as described, and withstands the injection pressure due to the rapid activation and the resulting abrupt hardening.

In a further advantageous embodiment of the invention, the same gap filler material is used as a part of the heat-conducting compound that provides the sealing compound and a part of the heat-conducting compound that does not provide the sealing compound. However, only the flow front contacts the chemical booster, causing the activated part of the thermal compound to cure faster than the rest of the thermal compound that was filled in the gap. In the examples described above, in which the sealing compound is not part of the thermally conductive compound but is introduced separately, a different material than that used for the thermally conductive compound or also the same material can optionally be used as the sealing compound. In these cases, too, it is preferred that the sealing compound then hardens significantly faster after activation than the thermally conductive compound after it has been introduced into the intermediate space.

Furthermore, the invention also relates to a battery for a motor vehicle, the battery having a battery housing with a receiving area, a battery module which is arranged in the receiving area of the battery housing, a heat-conducting compound in an intermediate space between the battery module and at least one part of the battery housing, and a the seal at least partially delimiting the gap between the battery module and the part of the battery housing. The seal is designed as a sealing compound that can be hardened by external activation in the hardened state.

The advantages described for the method according to the invention and its configurations apply in the same way to the battery according to the invention. In particular, the battery according to the invention is a battery that was produced by means of a method according to the invention or one of its configurations. The battery is preferably designed as a high-voltage battery.

The invention also includes developments of the battery according to the invention, which have features as have already been described in connection with the developments of the method according to the invention. For this reason, the corresponding developments of the battery according to the invention are not described again here.

Furthermore, the invention also relates to a motor vehicle with a battery according to the invention or one of its configurations.

The motor vehicle according to the invention is preferably designed as a motor vehicle, in particular as a passenger car or truck, or as a passenger bus or motorcycle.

The invention also includes the combinations of features of the described embodiments. The invention also includes implementations that each have a combination of the features of several of the described embodiments, unless the embodiments were described as mutually exclusive.

• 1 eine schematische und perspektivische Darstellung eines Gehäusebodens und eines Batteriemoduls während des Einsetzens des Batteriemoduls in einen Aufnahmebereich gemäß einem Ausführungsbeispiel der Erfindung;
• 2 eine schematische Querschnittsdarstellung des Batteriegehäuses und der darin aufgebrachten Dichtmasse vor dem Aktivieren während des Einsetzens des Batteriemoduls gemäß einem Ausführungsbeispiel der Erfindung;
• 3 eine schematische Darstellung der Anordnung aus 2 nach dem Einsetzen des Batteriemoduls in den Aufnahmebereich bei aktivierter und ausgehärteter Dichtmasse gemäß einem Ausführungsbeispiel der Erfindung;
• 4 eine schematische Querschnittsdarstellung eines im Batteriegehäuse eingesetzten Batteriemoduls während des Einfüllens der Wärmeleitmasse vor dem Aushärten der Dichtmasse gemäß einem Ausführungsbeispiel der Erfindung; und
• 5 eine schematische Darstellung der Anordnung aus 4 nach ausgehärteter Dichtmasse, die einen Teil der Fließfront der eingeleiteten Wärmeleitmasse darstellt gemäß einem Ausführungsbeispiel der Erfindung.

Exemplary embodiments of the invention are described below. For this shows:

• 1 a schematic and perspective view of a housing base and a battery module during the insertion of the battery module in a receiving area according to an embodiment of the invention;
• 2 a schematic cross-sectional view of the battery housing and the sealing compound applied therein prior to activation during insertion of the battery module according to an embodiment of the invention;
• 3 a schematic representation of the arrangement 2 after inserting the battery module into the receiving area with activated and hardened sealing compound according to an exemplary embodiment of the invention;
• 4 a schematic cross-sectional view of a battery module used in the battery housing during the filling of the heat-conducting compound before the sealing compound hardens according to an exemplary embodiment of the invention; and
• 5 a schematic representation of the arrangement 4 after cured sealant, which represents part of the flow front of the thermally conductive compound introduced according to an embodiment of the invention.

The exemplary embodiments explained below are preferred embodiments of the invention. In the exemplary embodiments, the described components of the embodiments each represent individual, independent gig represent features of the invention to be considered from one another, which also further develop the invention independently of one another. Therefore, the disclosure is also intended to encompass combinations of the features of the embodiments other than those illustrated. Furthermore, the described embodiments can also be supplemented by further features of the invention that have already been described.

In the figures, the same reference symbols designate elements with the same function.

1 shows a schematic and perspective representation of a housing base 10, at least a part thereof, and a battery module 12, which is inserted into a receiving area 14 of the housing base 10. The housing bottom 10 is part of a battery housing 16 (cf 2 until 5 ), where for reasons of clarity in 1 only the bottom 10 is shown. In particular, the part of the housing base 10 that is shown can also relate only to a single receiving compartment of the battery housing 16, which can have a plurality of such receiving compartments, also called compartments, which each provide such a receiving area 14. After the battery module 12 has been inserted into the receiving area 14, an intermediate space should be filled with a heat-conducting compound 20 (cf 3 until 5 ) fill out. In order to preferably only fill the area below the battery module 12 with such a heat-conducting compound 20 , a seal 22 in the form of a sealing compound 22 is provided between the battery module 12 and the housing base 10 . In 1 this is arranged, for example, on the housing floor 10 , in particular in the form of at least one sealing line, the geometry of which is designed to correspond to an edge region 24 of an underside 26 of the battery module 12 .

This sealing compound 22 is now advantageously provided as a sealing compound 22 that can be cured by external activation. This means that the curing process can be activated or greatly accelerated by an external activation, in particular a physical or chemical activator. In the present example, the sealing compound 22 is activated with a chemical activator 28 of the 1 is applied in the edge area 24 of the underside 26 of the battery module 12 . In the non-activated state, the sealant 22 is soft and viscous. Alternatively, the sealing compound 22 could also be arranged on the underside of the module base 26 of the battery module 12 in the edge area 24 and the activator 28 on the corresponding point of the housing base 10, at which 1 the sealant 22 is located. In both cases, this advantageously allows the battery module 12 to be inserted into the receiving area 14 without the sealing compound 22 exerting too strong counteracting forces on the housing base 10 . At the same time, advantageously, tolerances in height can be very easily compensated for by the very soft and viscous sealing compound 22, which ensures an optimal seal. If the battery module 12 is inserted into the receiving area 14, then the chemical activator 28 contacts the sealing compound 22, in the present example on the upper side, as a result of which the sealing compound 22 hardens or hardens more quickly. The seal 22 thus forms a connection with the module underside 26 and the housing base 10, in particular the compartment base, i.e. the part of the housing base 10 that corresponds to a receiving compartment assigned to the battery module 12, is activated and unfolds its hardening, so that later during the Injection of the thermal compound 20 can withstand the injection pressure.

This process is shown again schematically in a cross-sectional view in 2 and 3 illustrated. 2 again shows the battery housing 16 with the housing base 10, as well as the battery module 12 to be inserted into the receiving area 14. The chemical activator 28 is in turn arranged circumferentially on the underside 26 of the battery module 12. The externally activatable sealing compound 22 is arranged on the housing base 10 or the compartment base 10 , with a geometry that corresponds to the edge region 24 of the underside 26 of the battery module 12 . This means that the sealing compound 22 contacts the chemical activator 28 when the battery module 12 is inserted into the receiving area 14 as intended. 3 shows the battery module 12 in the inserted state. In this case, on the one hand, the initially soft sealing compound 22 has been deformed by the insertion of the battery module 12 and has hardened after activation by the chemical activator 28 . The sealing compound 22 thus stably seals the intermediate space 18 between the battery module 12 and the housing base 10 in the hardened state, which, as shown in FIG 3 shown, can now be filled with the thermal compound 20. Gap 18 is generally defined by gasket 22, module base 26, and a portion of housing base 10. In this example, the thermal conduction compound 20 is filled through an injection opening 30 via an injection device 32, for example an injection lance or the like, with the injection opening 30 being arranged in the housing base 10 in this example. After filling in the heat-conducting compound 20, this also hardens over time. This can also optionally be accelerated by activation, but this does not necessarily have to be the case. That the curing of the sealant 22 due to the External activation takes place much faster than the curing of the thermal compound 20 has the great advantage that long waiting times until the thermal compound 20 is filled in can be avoided.

4 and 5 show a further example of filling in the heat-conducting compound 20 using a sealing compound 22 that can be hardened by external activation. In this example, a battery housing 10 and a battery module 12 are again shown. The battery module 12 is first inserted into the receiving area 14 of the battery housing 10 and fastened by means of screws 34, for example. Before being inserted, the battery module 12 and/or the housing base 10 was provided with a chemical activator, in particular a chemical booster 36 . This chemical booster 36 can be analogous to 1 described in an edge region 24 of the module base 26 can be arranged. Additionally or alternatively, this can also be arranged in an area of the housing base 10 that corresponds geometrically to this edge area 24, in particular, for example, at the point at which in 1 the sealant 22 is illustrated. In this case, the sealing compound 22 is now provided as part of the thermally conductive compound 20 . In particular, the sealing compound 22 represents the flow front 20a during the filling of the thermally conductive compound 20 into the gap 18, as is shown in 4 is illustrated. As soon as this flow front 20a comes into contact with the chemical booster 36, it hardens through sudden crosslinking and thus forms the seal 22. This is in 5 illustrated. In particular, the 5 the arrangement 4 in a state in which now the flow front 20a has already come into contact with the chemical booster 36 and has thereby hardened. So when the gap filler, i.e. the heat-conducting compound 20, flows in through the injection hole 30, it spreads over the surface to be wetted, and as soon as the material comes into contact with the applied booster 36, it suddenly begins to harden and forms at these points a hard flow barrier. Here, too, the seal 22 forms a hard border for the gap filler 20 that flows in and can withstand the injection pressure. The advantage here, namely with the boosted seal 22, is that it also develops its property only after assembly. There is no seal during module placement, and consequently no force is exerted on the compartment base 10 either. It is also not deformed as a result. In addition, no additional component in the form of a pre-applied seal is required, and an additional process step is eliminated.

Overall, the examples show how the invention can provide a seal for the gap filler injection under an HV battery module with properties that can be activated, in particular by local boosting, among other things. In this way it can be achieved that the seal either does not have to be present at all during the setting of the module or is very soft and viscous so that it does not develop too great a counterforce. The seal only becomes hard after external activation and can then withstand the injection pressure during injection.

QUOTES INCLUDED IN DESCRIPTION

This list of the documents cited by the applicant was 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.

Patent Literature Cited

• DE 102018208070 A1 [0002]
• DE 112019002449 T5 [0004]

Claims (10)

Method for introducing a heat-conducting compound (20) into an intermediate space (18) between a battery module (12) and a part (10) of a battery housing (16), comprising the steps of: - providing the battery housing (16); - Arranging the battery module (12) in a receiving area (14) of the battery housing (16); - Providing a seal (22) at least partially delimiting the intermediate space (18) between the battery module (12) and the part (10) of the battery housing (16); and - introducing the thermally conductive compound (20) into the intermediate space (18); characterized in that the seal (22) is provided as a sealing compound (22) which can be hardened by external activation and which, in a non-activated state, can be placed in a specific end position between the battery module (12) and the part (10) of the battery housing (16). , in which the sealing compound (22) contacts the battery module (12) and the part (10) of the battery housing (16), is placed and activated when it is in the determined end position. procedure after claim 1 , characterized in that the sealing compound (22) is physically activated. Method according to one of the preceding claims, characterized in that the sealing compound (22) is activated chemically by means of an activator (28, 36) which is arranged in at least one contact area (24) of the battery module (12) and/or the battery housing (16). is in which the sealing compound (22) contacts the battery module (12) or the battery housing (16) in the specific end position. Method according to one of the preceding claims, characterized in that the sealing compound (22) in the specific end position contacts the battery module (12) in a first contact area (24) and contacts the part (10) of the battery housing (16) in a second contact area, wherein before the battery module (12) is arranged in the receiving area (14) - the activator (28, 36) is arranged in the first contact area (24) and the sealing compound (22) is arranged in the second contact area; or - the activator (28, 36) is arranged in the second contact area and the sealing compound (22) is arranged in the first contact area (24); wherein the sealing compound (22) is activated by arranging the battery module (12) in the receiving area (14). Method according to one of the preceding claims, characterized in that after the activated sealing compound (22) has hardened, the thermally conductive compound (20) is introduced into the sealed intermediate space (18). Procedure according to one of Claims 1 until 3 , characterized in that the sealing compound (22) is provided as a part (20a) of the thermally conductive compound (20) and is injected into the intermediate space (18) after the battery module (12) has been arranged in the receiving area (14). procedure after claim 6 , characterized in that the sealing compound (22) in the specific end position contacts the battery module (12) in a first contact area (24) and contacts the part (10) of the battery housing (16) in a second contact area, wherein before the battery module is arranged (12) the activator (28, 36) is arranged in the receiving area (14) in the first and/or second contact area (24), with the sealing compound (22) representing a flow front (20a) when the heat-conducting compound (20) is injected, which flows through the contact with the activator (28, 36) hardens as soon as the flow front (20a) reaches the specific end position. Method according to one of the preceding claims, characterized in that at least part of the thermally conductive compound (20) which does not provide the sealing compound (22) hardens more slowly than the activated sealing compound (22) after it has been introduced into the intermediate space (18). Battery for a motor vehicle, comprising: - a battery housing (16) with a receiving area (14); - A battery module (12) which is arranged in the receiving area (14) of the battery housing (16); - A thermal compound (20) in an intermediate space (18) between the battery module (12) and at least a part (10) of the battery housing (16); and - a seal (22) at least partially delimiting the intermediate space (18) between the battery module (12) and the part (10) of the battery housing (16); characterized in that the seal (22) is designed as a sealing compound (22) that can be hardened by external activation in the hardened state. Motor vehicle with a battery claim 9 .

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