AT528021B1 - Battery storage housing for variable thermal insulation of a battery storage system and method therefor - Google Patents

Abstract

The present invention relates, inter alia, to a battery storage housing (10) for variable thermal insulation of a battery storage device (20), comprising an inner housing (11), a thermal insulation layer (12), and an outer housing (13). According to the invention, at least one free space (14) is formed in the insulation layer (12), each of which is in partial contact with a surface of the inner housing (11) and an opposite surface of the outer housing (13). The at least one free space (14) is connected to a media-conducting inlet (E) and an outlet (A) for media transfer of a heat exchange medium (M) through the at least one free space (14). Systems and a method for implementing hydraulically switchable insulation states are also proposed.

Description

Ss N

Description

BATTERY STORAGE HOUSING FOR VARIABLE THERMAL INSULATION OF A BATTERY STORAGE UNIT AND METHOD THEREFOR

[0001] The present invention relates to a battery storage housing for variable thermal insulation of a battery storage device, a hydraulic insulation system for hydraulically switchable thermal insulation of a battery storage device by means of the battery storage housing, a temperature control system for a battery storage device with hydraulically switchable thermal insulation by means of the battery storage housing, and a method for changing variable thermal insulation of a battery storage device using the battery storage housing.

[0002] Concepts for a combination of external thermal insulation and internal thermal conditioning of battery storage systems with multiple battery cells or battery modules using liquid cooling are known in the prior art, particularly in the field of electromobility. The advantage of liquid cooling (often a water-glycol mixture) compared to cooling by gas flow arises because the product of mass flow and specific heat capacity exhibits advantageously high values for common flow rates, and the size of the battery can be minimized. Furthermore, heat dissipation can be easily adapted to temperature fluctuations caused by fluctuating power dynamics in different operating states by regulating the circulating mass flow.

[0003] Various battery storage systems with fluid-carrying channels are known, which provide indirect contact between the medium and the battery cells via one or more materials with high thermal conductivity for heat transfer. On the other hand, systems with immersion cooling are known, which establish direct contact between the medium and the battery cells surrounded by it in a closed reservoir or an immersion bath connected to a circulation system.

[0004] Furthermore, the use of a thermal insulation layer on the outside of the battery storage system is known, which passively decouples the inside and outside of the battery storage system through low thermal conductivity. Especially in a primary application area of such systems, i.e., in mobile applications of larger battery storage systems such as traction batteries, these systems are subjected to spontaneous use under complete exposure to external weather conditions. Therefore, a constant temperature control of the battery cells, especially at the beginning of operation, can be significantly impaired by significant deviations in the outside temperature.

[0005] In other operating situations, however, thermal insulation of the battery storage system to prevent heat exchange between a battery storage housing and the environment can be disadvantageous. This is disadvantageous, firstly, in terms of a higher cooling demand, which requires a larger power capacity of a temperature control system. Secondly, it is also disadvantageous with regard to the energy efficiency of the temperature control system in various temperature-dependent operating situations, which, in the case of an electric vehicle, means a reduction in range.

[0006] Thus, based on considerations of the target system and the specific application of the battery storage system, especially in mobile applications, it is always necessary to decide whether or not to use an external thermal insulation layer on a battery storage system, or to dimension the thermal insulation layer accordingly. To date, there are hardly any dedicated means or structures known that allow for variable or selective insulation in an external area of a battery storage system.

[0007] It is an object of the invention to at least partially remedy the aforementioned disadvantage of the prior art. Another object of the invention is to create a technology that enables variable thermal insulation properties of a battery storage device or supports the creation of switchable thermal insulation states.

SS SS

Ss N

Sr 'hes AT 528 021 B1 2025-09-15

[0008] The above objects are achieved by a battery storage housing having the features of claim 1, a corresponding hydraulic insulation system having the features of claim 5 or a corresponding temperature control system having the features of claim 10 and, with corresponding use, a method for changing a variable thermal insulation of a battery storage device having the steps of claim 16.

[0009] Further features and details of the invention emerge from the subclaims, the description and the drawings.

[0010] Features and details that are described in connection with the battery storage housing according to the invention naturally also apply in connection with the hydraulic insulation system or the temperature control system, and these in turn also apply in connection with the method and vice versa, so that with regard to the disclosure of the individual aspects of the invention, reference can always be made to each other.

[0011] The battery storage housing according to the invention serves for the variable thermal insulation of a battery storage device and comprises an inner housing enclosing a plurality of battery cells; and a thermal insulation layer that at least partially encloses the inner housing. According to the invention, an outer housing encloses the inner housing and the insulation layer, wherein the inner housing and the outer housing are each made of a thermally conductive material. At least one free space is formed in the insulation layer, and the at least one free space is in partial contact with a surface of the inner housing and an opposite surface of the outer housing. In addition, the at least one free space is connected to an inlet and an outlet to an outside of the battery storage housing in a media-conducting manner, and the at least one free space is designed to be fillable and emptied with a heat exchange medium by means of the inlet and the outlet.

[0012] Building on this, the hydraulic insulation system serves for hydraulically switchable thermal insulation of the battery storage unit. For this purpose, the hydraulic insulation system comprises, in addition to the battery storage housing according to the invention, a hydraulic circuit for transferring a heat exchange medium to and from the battery storage housing, for hydraulically generating insulation states. The hydraulic circuit comprises media-carrying lines that are communicatively connected to the inlet and outlet of the at least one transfer channel and/or the at least one free space in the battery storage housing; an expansion tank for storing a volume of the heat exchange medium; a pump for conveying the heat exchange medium between the expansion tank and the battery storage housing; and at least one valve, which is arranged between the battery storage housing and the expansion tank and/or between the battery storage housing and the pump in the hydraulic circuit, for switching between media transfers of the heat exchange medium for filling, emptying, and/or flowing through the at least one free space in the battery storage housing. Thus, the hydraulic insulation system serves to create different thermal insulation states in the battery storage housing by filling or flowing through and emptying the free spaces with a thermally conductive liquid heat exchange medium.

[0013] Alternatively, a temperature control system for the battery storage unit serves for hydraulically switchable thermal insulation of the battery storage unit. For this purpose, the temperature control system comprises, in addition to the battery storage unit housing according to the invention, a temperature control circuit for temperature control of battery cells by circulation of a heat exchange medium, and a hydraulic circuit for transferring the heat exchange medium to and from the transfer channel and/or the at least one free space in the battery storage unit housing, for hydraulically generating insulation states. The temperature control circuit comprises media-carrying lines that are communicatively connected to an inlet and an outlet of the at least one temperature control channel in the battery storage unit housing; at least one heat exchanger for heat exchange between the heat-

SS SS

Ss N

Sr 'hes AT 528 021 B1 2025-09-15

heat exchange medium and an atmosphere of a system environment; and a temperature control pump for circulating the heat exchange medium in the temperature control circuit. The hydraulic circuit comprises media-carrying lines that are communicatively connected to the inlet and outlet of the at least one transfer channel and/or the at least one free space in the battery storage housing; an equalization tank for storing a volume of the heat exchange medium; and at least one valve, which is arranged between the battery storage housing and the equalization tank and/or between the battery storage housing and the temperature control pump, for switching between media transfers of the heat exchange medium for filling, emptying, and/or flowing through the at least one free space in the battery storage housing. The temperature control circuit and the hydraulic circuit are communicatively connected to one another.

[0014] Similarly, a method for changing a variable thermal insulation of a battery storage device using the battery storage housing according to the invention is provided. The method comprises at least the following steps:

[0015] - filling or flowing through the at least one free space in the battery storage housing with a heat exchange medium via the inlet or via the inlet and the outlet by means of a hydraulic circuit, in order to produce a thermal insulation state with a higher thermal conductivity between an inside and an outside of the battery storage housing, and

[0016] - Emptying the heat exchange medium from the at least one free space in the battery storage housing via the outlet by means of the hydraulic circuit, in order to produce a thermal insulation state with a lower thermal conductivity between an inside and an outside of the battery storage housing.

[0017] According to the definition of the present disclosure, the term "battery storage" particularly encompasses modularly constructed battery storage systems, such as a traction battery for a vehicle, which comprises multiple battery modules with battery cells. However, the term "battery storage" also encompasses battery storage systems that contain battery cells without a modular intermediate structure, or battery storage systems that themselves form a battery module in a modular battery storage system.

[0018] The invention provides for the first time a liquid-fillable structure with a free space or several connected chamber-like free spaces in an insulated housing shell for an influenceable, local insulation property on a battery storage device against external thermal influences.

[0019] A major advantage of the invention, compared to a permanently constant thermal insulation property, such as in a continuous rigid foam layer, is that variable insulation can be produced temporarily. This, in turn, in combination with a technology based on it, enables a selection of insulation states that can preferably be controlled depending on the situation.

[0020] In technical implementation, this property is achieved by locally bridging an insulation layer in a casing section of the battery storage housing by the thermal conductivity of a liquid heat exchange medium. When the heat exchange medium is removed again, a emptied volume, i.e., a substitute gas volume of air, acts as a thermal insulator at the same location.

[0021] Advantageously, the invention thus provides a variable heat transfer between the battery cells and the environment, which can be influenced based on a thermal conductivity of the chamber-like structure according to the invention in the battery storage housing, wherein the thermal conductivity can be adjusted via a filling state of free spaces.

[0022] As a further advantage, a local center of gravity, i.e., a boundary or course, as well as an overall dimensioning, i.e., a maximum heat exchange capacity, of the described variable heat transfer through the battery storage housing can be selected depending on the selected arrangement and surface area of the chamber-like structure according to the invention in a housing shell. Thus, these properties can be determined either via the

A 'hes AT 528 021 B1 2025-09-15

Ss N

Housing design can be specified or, based on this, can be adjusted technically during operation by means of area-related, targeted filling of free spaces using additional hydraulic means such as channels and actuators.

[0023] Viewed more globally, an area-normalized maximum value of thermal conductivity can be defined based on the number and size of the fillable spaces in the insulation layer, i.e., the area-related density of such a chamber structure. Remarkably, this property exists despite the presence of an insulation layer that ensures effective insulation, and whose insulating properties are hardly affected by the aforementioned chamber structure due to the equally insulating effect of air cushions in the unfilled state of the spaces.

[0024] According to one aspect of the invention, a plurality of chamber-like free spaces can be formed in the insulation layer, and the chamber-like free spaces can each be in partial contact with a surface of the inner housing and an opposite surface of the outer housing. The free spaces are connected by at least one media-carrying transfer channel for transferring the heat exchange medium through the free spaces, and the at least one transfer channel comprises the inlet and the outlet to the outside of the battery storage housing. Accordingly, the free spaces are designed to be filled and emptied with the heat exchange medium via the inlet, the transfer channel, and the outlet. Thus, the free spaces can be flowed to and from the free spaces on one side of the battery storage housing via a bundled channel structure in the form of a distributor, and on an opposite side of the battery storage housing, the heat exchange medium can be discharged from the free spaces again through a similar channel structure in the form of a collector. In addition, a design of several chamber-like free spaces has the advantage that during operation of a mobile application, the chamber walls of the chamber-like free spaces counteract a one-sided or acceleration-loaded distribution of the heat exchange medium due to the inertia of the liquid volume.

[0025] According to one aspect of the invention, the plurality of free spaces in the insulation layer can extend over at least two differently oriented surface sections of the inner housing and/or the outer housing. Thus, in a state in which the switchable insulation state is deactivated, an active area for heat transfer between the battery cells and the environment can be enlarged or maximized.

[0026] According to one aspect of the invention, at least one media-carrying temperature control channel can run through the inner housing and preferably be in thermal contact with the battery cells, allowing circulation of the heat exchange medium to control the temperature of the battery cells. In this context, a temperature control medium can also be used as the heat exchange medium in the free spaces. Furthermore, a combination with a separate, conventional temperature control system is also conceivable.

[0027] According to one aspect of the invention, the lines of the hydraulic circuit can connect the transfer channel and/or the at least one free space in the battery storage housing, the expansion tank, and the pump to form a circuit for circulating media transfer in the hydraulic circuit. Thus, a hydraulic variant is created for unidirectional transfer of the heat exchange medium through the free spaces from an inlet port to an outlet port of the transfer channel in conjunction with the hydraulic circuit.

[0028] According to one aspect of the invention, the lines of the hydraulic circuit can connect the transfer channel and/or the at least one free space in the battery storage housing and the expansion tank to one side of the pump in a single path, for a bidirectional media transfer in the hydraulic circuit. This enables an alternative hydraulic variant, not discussed in detail below, in which a bidirectional transfer of the heat exchange medium through the free spaces takes place via a common inlet/outlet connection of the transfer channel in connection with the hydraulic circuit.

A 'hes AT 528 021 B1 2025-09-15

Ss N

Additional means for ventilation and de-aeration of the open spaces are required.

[0029] According to one aspect of the invention, the at least one valve can comprise at least one switchable valve for selecting between hydraulic states of thermal insulation, which valve is communicatively connected to the transfer channel and/or the at least one free space in the battery storage housing, wherein a closed position of the at least one switchable valve blocks a filling volume of the heat exchange medium in the at least one free space, and an open position of the at least one switchable valve allows the heat exchange medium to be drained from the at least one free space. Thus, means for circuitry support in initiating and maintaining hydraulic processes in establishing thermal insulation states in the battery storage housing are provided.

[0030] According to one aspect of the invention, the at least one valve may comprise at least one check valve, wherein an opening direction of the check valve provides a direction for media transfer of the heat exchange medium and/or a blocking direction for maintaining a backflow of the heat exchange medium. Thus, additional means for circuitry support in initiating and maintaining hydraulic processes in establishing thermal insulation conditions in the battery storage housing are provided.

[0031] According to one aspect of the invention, the hydraulic circuit integrated into the temperature control system can additionally comprise its own pump for independently conveying the heat exchange medium between the expansion tank and the battery storage housing. Thus, the insulation conditions can be realized independently of the operation of the temperature control system.

[0032] According to one aspect of the invention, a heating device arranged in the temperature control circuit can be provided for electrically heating the heat exchange medium. This allows active heating, particularly at the start of operation and at low outside temperatures, and a target temperature can be reached more quickly.

[0033] According to one aspect of the invention, a refrigeration machine arranged in the temperature control circuit can be provided for thermodynamically cooling the heat exchange medium. Thus, at high power and high outside temperatures, active cooling can be achieved in order to reach a target temperature more quickly or at all.

[0034] According to one aspect of the invention, a temperature sensor arranged on an exterior of the battery storage unit or in a system environment can be provided to detect an outside temperature. Thus, control of the insulation states is supported by measured values generated in the system.

[0035] According to one aspect of the invention, a temperature sensor arranged in the battery storage unit can be provided for detecting a battery temperature. This sensor also supports control of the insulation states through measured values generated in the system.

[0036] Further advantages, features, and details of the invention will become apparent from the following description, in which exemplary embodiments of the invention are described in detail with reference to the drawings. The features and embodiments mentioned in the claims and in the description may be essential to the invention individually or in any combination. They show schematically:

[0037] Fig. 1 is a sectional view of a portion of a battery storage housing with hydraulically variable insulation through a chamber-like structure in a housing shell according to an embodiment of the invention;

[0038] Fig. 2 is a block diagram of a further embodiment of the invention in the form of a temperature control system with a functionally dependent, integrated hydraulic circuit for the battery storage housing, and

A 'hes AT 528 021 B1 2025-09-15

Ss N

[0039] Fig. 3 is a block diagram of an embodiment of the invention with a combination of a temperature control system and a functionally independent hydraulic isolation system with a hydraulic circuit for the battery storage housing.

[0040] Fig. 1 shows a cross-section through a housing shell of a multi-part battery storage housing 10 of a battery storage device 20, which consists of an inner housing 11, an outer housing 13, and an insulating layer 12 arranged therebetween, which serves for thermal decoupling between an inner side and an outer side of the battery storage housing 10. The outer housing 13 essentially completely encloses the insulating layer 12 and the inner housing 11, wherein the insulating layer 12 at least partially encloses the inner housing 11. The inner housing 11 and the outer housing 13 are made of a material with high thermal conductivity, such as a metallic or ceramic material or a composite material. The insulating layer 12 consists, for example, of a polymer-based rigid foam with a gas-containing pore structure and low thermal conductivity. This creates a sandwich structure for the housing shell, which provides a thermally conductive structure and surface to an inside and an outside of the battery storage housing 10, and has thermal insulation in the core.

[0041] The figure on the right shows an exemplary, media-carrying channel structure of a temperature control channel 16, which runs through a bottom section of the inner housing 16 in order to temperature-control the battery cells 22 of the battery storage unit 20 accommodated therein. Alternatively, a channel structure of the temperature control channel 16 can also extend through a receiving chamber of the inner housing 11 directly to the battery cells 22 or communicate with an immersion volume in the inner housing 11 in order to establish direct thermal contact between the heat exchange medium M and the battery cells 22. It is functionally essential that the temperature control channel 16, expediently with a branching channel structure to the battery cells 22, runs through the inner housing 11 in order to temperature-control the battery cells 22 with the heat exchange medium M.

[0042] A chamber-like structure of free spaces 14 is formed in the insulation layer 12. The free spaces 14 are formed as openings, i.e., as recesses, across the entire material thickness of the insulation layer 12, so that over a surface-related section with respect to at least a portion of the outer side of the inner housing 11 and at least a portion of the inner side of the outer housing 13, no material of the insulation layer 12 remains in the free spaces 14 between the inner housing 11 and the outer housing 13. Similar to the media-carrying channel structure of the temperature control channel 16 in the inner housing 11, the free spaces 14 are also used as a media-carrying channel structure or media-carrying chamber structure, wherein the individual free spaces 14 can additionally be connected to one another in a media-communicating manner via a channel structure of a transfer channel 15. The transfer channel 15 serves functionally for filling or flowing through the free spaces 14 with the heat exchange medium M as well as for emptying the free spaces 14, wherein the transfer channel 15 for this purpose comprises an inlet E and an outlet A to an outside of the battery storage housing 10.

[0043] Alternatively, instead of a plurality of free spaces 14 connected by the transfer channel 15, only one continuous free space 14 may be formed, which includes the inlet E and the outlet A to the outside of the battery storage housing 10 or is directly connected to them in a communicating manner.

[0044] The heat exchange medium M is a liquid, water- or oil-based medium that offers a high, at least a higher thermal conductivity and, in the liquid phase, a better heat transfer than the solid material of the insulation layer 12. When the free spaces 14 are filled with a sufficient filling volume of the heat exchange medium M, the heat exchange medium M closes a thermally conductive path in each free space 14 from a surface of the inner housing 11 to the surface of the outer housing 13. Depending on the temperature ratio or direction, the free spaces 14 in the battery storage housing 10 accordingly form

A 'hes AT 528 021 B1 2025-09-15

Ss N

Thermal bridges or cold bridges between the inner housing 11 and the outer housing 13, each effective with respect to a surface extension of the housing shell, in which the insulation layer 12 is perforated by the free spaces 14. If, however, the heat exchange medium M is emptied from the free spaces 14 via the transfer channel 15, these fill with air or at least a gas phase that has a thermally insulating effect, similar to the gas-containing pore structure of the rigid foam material of the insulation layer 12. Consequently, by creating at least two filling states of the free spaces 14 with the heat exchange medium M, i.e., at least by bringing about a fully filled state and an empty state, two different hydraulically induced insulation states with different thermal conductivities of the battery storage housing 10 can be provided. This applies both to a local value of the thermal conductivity in relation to surface sections of the housing shell in which the hydraulically active or activatable chamber-like structure of the free spaces 14 is arranged, but also globally, to an average value of the thermal conductivity in relation to the entire structure and housing shell of the battery storage housing 10. In addition, in a fine-tuning of a required hydraulic system, intermediate states in the range of almost complete filling can be set optionally, which cause a variation in the thermal conductivity over a distance through the respective free space 14.

[0045] With a horizontal orientation of the sandwich structure of the housing shell, such as in a housing cover, an air gap that occurs in an unfilled upper section of the free space 14 causes an interruption in the heat transfer. With a vertical orientation of the sandwich structure of the housing shell, such as in a side wall, the unfilled upper section of the free space 14 causes a proportional reduction in the active area of the heat transfer. By dimensioning and arranging the chamber-like free spaces 14, as well as by combining differently oriented sections of the housing shell with them, the thermal performance of the heat transfer and its behavior with respect to a hydraulic process for filling or flowing through and emptying with the heat exchange medium M can be designed model-specifically.

[0046] Fig. 2 shows a schematic block diagram of the temperature control system 200 for the battery storage unit 20, in which a hydraulic circuit 30, as a functionally essential fragment, has been retained from the hydraulic isolation system 100 of the embodiment shown in Fig. 3. In contrast to the embodiment shown in Fig. 3, in the embodiment shown in Fig. 3, the hydraulic circuit 30 integrated in the temperature control system 200 is driven by the pump 32, whereby driving the hydraulic circuit 30 is dependent on the operation of the temperature control system 200, but with a simplified system structure with fewer components and, in particular, only one pump, the temperature control pump 42.

[0047] In this case, a relatively small partial flow, compared to the total flow of the temperature control system, is diverted for hydraulic purposes from the circulation of the heat exchange medium M in the temperature control circuit 40. A control-switchable directional control valve 37 with two positions selectively directs the diverted partial flow into the hydraulic circuit 30 and through the free spaces 14 via the transfer channel 15, for the previously described hydraulic isolation processes. Thus, the free spaces 14 are completely filled and flowed through, and the hydraulically switchable isolation feature is deactivated.

[0048] In the other position, the directional control valve 37 selectively directs the branched partial flow via a bypass past the battery storage housing 10 into the expansion tank 31 and back to the temperature control pump 42. Without the supply of the heat exchange medium M from the temperature control pump 42 upstream into the transfer channel 15, any existing filling of the free spaces 14 with heat exchange medium M flows into the expansion tank 31. Thus, the free spaces 14 are emptied and the hydraulically switchable insulation property is activated.

[0049] Fig. 3 shows a schematic block diagram of an embodiment with two interconnected media-carrying systems, a hydraulic isolation system 100 for the

A 'hes AT 528 021 B1 2025-09-15

Ss N

Battery storage housing 10 from Fig. 1 and a temperature control system 200 for the battery storage 20. The battery storage housing 10, which is shown in cross-section in Fig. 1, is shown in longitudinal section in Figs. 2 and 3. The insulation system 100 and the temperature control system 200 are connected to each other via media communication, i.e., they are operated jointly with the same heat exchange medium M. However, both systems can be driven functionally independently of each other via their own pumps, i.e., a pump 32 and a temperature control pump 42.

[0050] The hydraulic isolation system 100 requires significantly smaller volumes and a significantly lower flow rate than the temperature control system 200.

[0051] The temperature control system 200 largely corresponds to a known cooling circuit for a battery. The heat exchange medium M circulates under a delivery pressure of the temperature control pump 42 in a temperature control circuit 40 through the temperature control channel 16 of the battery storage housing 10 and through an ambient heat exchanger 41. Depending on the overall thermal situation with regard to a temperature in the battery storage 20 and an outside temperature, the heat exchanger 41 can also be bypassed via a switchable directional control valve 45. Furthermore, a heating device 43 and a refrigeration machine 44 are arranged in the temperature control circuit 40. These can additionally actively heat or cool the heat exchange medium M if necessary for correct temperature control of the battery cells 22. The temperature control system 200 is controlled exclusively or predominantly as a function of maintaining a target range of the operating temperature of the battery cells 22 in the battery storage unit 20 in order to ensure high performance for power consumption and output as well as low aging and a long service life.

[0052] The hydraulic isolation system 100 is connected to an inlet and an outlet of the transfer channel 15 in the battery storage housing 10. The heat exchange medium M circulates under the discharge pressure of the pump 32 in a hydraulic circuit 30, which in this embodiment is configured as a circuit, through the transfer channel 15 and the free spaces 14 in the battery storage housing 10 and through an expansion tank 31. The check valves 34, 35, and 36 specify a direction of circulation from the pump 32 to the transfer channel 15. The transfer channel 15 comprises a branched channel structure, not further illustrated in the longitudinal section of the battery storage housing 10, which connects all of the free spaces 14 to one another. In particular, the channel structure of the transfer channel 15 communicates with each free space 14 both from an upstream side with respect to the circulation direction of the pump 32 and from a downstream side. On the downstream side, the transfer channel 15 leads to a compensation tank 31 via a switchable valve 33. The valve 33 can be actuated by an actuator from a controller.

[0053] When the valve 33 is in the closed position, the heat exchange medium M supplied by the pump 32 does not flow into the expansion tank 31 via the opposite side. Thus, the free spaces 14 fill with the heat exchange medium M until the maximum fill level in the riser, which is shown as a bypass to the switchable valve 33, is reached. To control a fill level, in particular a complete fill, a pressure sensor can be arranged in a section between the pump 32 and the valve 33. Furthermore, sensors can be provided for the volumetric detection of an average, incomplete fill or a fill level of the heat exchange medium M in the entirety of the free spaces 14 or in selected groups of free spaces 14.

[0054] In an open position of the valve 33, the heat exchange medium M flows from the free spaces 14 into the expansion tank 31. As long as the pump 32 continues to supply circulation, the free spaces 14 are flowed through under the action of the delivery pressure. This ensures complete filling of all free spaces 14 and thus also uninterrupted heat transfer without an air gap, even in a horizontal orientation of the sandwich structure of the housing shell, as in the housing cover. In this state, the battery storage housing 10 has the highest thermal conductivity, i.e., the hydraulically switchable

A 'hes AT 528 021 B1 2025-09-15

Ss N

thermal insulation property is deactivated.

[0055] When the pump 32 stops pumping, the heat exchange medium M flows out of the free spaces via the open valve 33 and collects in the expansion tank 31. After the free spaces 14 are emptied and replaced with air, the heat transfer through the free spaces 14 is eliminated by air cushions. In this state, the battery storage housing 10 has the lowest thermal conductivity, i.e., the hydraulically switchable thermal insulation property is activated.

[0056] Alternatively, in the embodiments of Figures 2 and 3, instead of the plurality of chamber-like free spaces 14 and the transfer channel 15, only a single and possibly correspondingly larger free space 14 can be formed in the battery storage housing 10, which is filled and emptied or flowed through via the inlet E and the outlet A.

[0057] To support the hydraulic processes and to avoid the formation of a mixture of gas phase and liquid phase, i.e., hydraulically unstable conditions, a pressure equalization line with a check valve 36 for ventilating and de-aerating the free spaces 14 with air from the equalization tank 31 is arranged between the equalization tank 31 and the side upstream of the transfer channel 15. Furthermore, for hydraulic reasons, a riser is arranged as a bypass to the switchable valve 33. A liquid column and its pressure in the riser are selected such that, in a rest state in which the pump 32 is not delivering, no gas volume below atmospheric pressure in the equalization tank 31 returns to the free spaces 14, thereby causing undefined conditions with regard to thermal conductivity.

[0058] The above explanations of the embodiments describe the present invention exclusively by way of examples. Of course, individual features of the embodiments can be freely combined with one another, provided they are technically feasible, without departing from the scope of the present invention.

LIST OF REFERENCE SYMBOLS

10 Battery storage housing 11 Inner housing 12 Insulation layer

13 Outer casing

14 open spaces

15 transfer channel

16 Temperature control channel 20 Battery storage 22 Battery cells

30 Hydraulic circuit 31 Expansion tank 32 Pump

33 switchable valve 34 check valve

35 Check valve

36 Check valve

37 Directional control valve with two switching states 40 Temperature control circuit

41 heat exchangers

42 Tempering pump

43 Heating device

44 Refrigeration machine

45 directional control valve with two switching states 100 hydraulic isolation system

200 temperature control system

E Input E Output M Heat exchange medium

10 / 16

Claims (1)

A 'hes AT 528 021 B1 2025-09-15 Ss N Patent claims 1. Battery storage housing (10) for variable thermal insulation of a battery storage unit (20), comprising: an inner housing (11) enclosing a plurality of battery cells (22); and a thermal insulation layer (12) which encloses the inner housing (11) at least in sections; characterized in that an outer housing (13) encloses the inner housing (11) and the insulation layer (12), wherein the inner housing (11) and the outer housing (13) are each made of a thermally conductive material; wherein at least one free space (14) is formed in the insulation layer (12), and the at least one free space (14) is in partial contact with a surface of the inner housing (11) and an opposite surface of the outer housing (13); and wherein the at least one free space (14) is connected to an inlet (E) and an outlet (A) to an outside of the battery storage housing (10) in a media-conducting manner, and the at least one free space (14) is designed to be fillable and emptied with a heat exchange medium (M) by means of the inlet (E) and the outlet (A). 2. Battery storage housing (10) according to claim 1, wherein a plurality of chamber-like free spaces (14) are formed in the insulation layer (12), and the chamber-like free spaces (14) are each in partial contact with a surface of the inner housing (11) and an opposite surface of the outer housing (13); and wherein the free spaces (14) are connected by at least one media-carrying transfer channel (15) for a media transfer of the heat exchange medium (M) through the free spaces (14), and the at least one transfer channel (15) comprises the inlet (E) and the outlet (A) to the outside of the battery storage housing (10), wherein the free spaces (14) are designed to be fillable and emptied with the heat exchange medium (M) by means of the inlet (E), the transfer channel (15) and the outlet (A). 3. Battery storage housing (10) according to claim 2, wherein the plurality of free spaces (14) in the insulation layer (12) extend over at least two differently aligned surface sections of the inner housing (11) and/or the outer housing (13). 4. Battery storage housing (10) according to one of claims 1 to 3, comprising at least one media-carrying temperature control channel (16) which is arranged leading through the inner housing (11) and preferably in thermal contact with the battery cells (22), for circulation of the heat exchange medium (M) for temperature control of the battery cells (22). 5. Hydraulic insulation system (100) for hydraulically switchable thermal insulation of a battery storage unit (20), comprising: the battery storage housing (10) according to one of claims 1 to 4; and a hydraulic circuit (30) for the media transfer of a heat exchange medium (M) to and from the battery storage housing (10), for a hydraulic generation of different insulation states, with: media-carrying lines which are communicatively connected to the inlet (E) and the outlet (A) of the at least one transfer channel (15) and/or the at least one free space (14) in the battery storage housing (10), an expansion tank (31) for storing a volume of the heat exchange medium (M), a pump (32) for conveying the heat exchange medium (M) between the expansion tank (31) and the battery storage housing (10), and at least one valve (33, 34, 35, 36) which is arranged between the battery storage housing 10. AT 528 021 B1 2025-09-15 (10) and the expansion tank (31) and/or between the battery storage housing (10) and the pump 32 in the hydraulic circuit (30), for switching between media transfers of the heat exchange medium (M) for filling, emptying and/or flowing through the at least one free space (14) in the battery storage housing (10). Hydraulic isolation system (100) according to claim 5, wherein the lines of the hydraulic circuit (30) connect the transfer channel (15) and/or the at least one free space (14) in the battery storage housing (10), the expansion tank (31) and the pump (32) to form a circuit for a circulating media transfer in the hydraulic circuit (30). Hydraulic isolation system (100) according to claim 5, wherein the lines of the hydraulic circuit (30) connect the transfer channel (15) and/or the at least one free space (14) in the battery storage housing (10) and the expansion tank (31) each to one side of the pump (32) in a route for a bidirectional media transfer in the hydraulic circuit (30). Hydraulic insulation system (100) according to one of claims 5 to 7, wherein the at least one valve comprises at least one switchable valve for selecting between hydraulic states of the thermal insulation, which is communicatively connected to the transfer channel (15) and/or the at least one free space (14) in the battery storage housing (10), wherein a closed position of the at least one switchable valve blocks off a filling volume of the heat exchange medium (M) in the at least one free space (14), and an open position of the at least one switchable valve enables emptying of the heat exchange medium (M) from the at least one free space (14). Hydraulic insulation system (100) according to one of claims 5 to 8, wherein the at least one valve comprises at least one check valve, wherein an opening direction of the same effects a direction specification in a media transfer of the heat exchange medium (M) and/or a blocking direction of maintaining a back pressure of the heat exchange medium (M). Temperature control system (200) for a battery storage unit (20) with a hydraulically switchable thermal insulation, comprising: the battery storage housing (10) according to one of claims 1 to 4; a temperature control circuit (40) for temperature control of battery cells (22) by circulation of a heat exchange medium (M), with: media-carrying lines which are communicatively connected to an inlet and an outlet of the at least one temperature control channel (16) in the battery storage housing (10), at least one heat exchanger (41) for heat exchange between the heat exchange medium (M) and an atmosphere of a system environment, and a tempering pump (42) for circulating the heat exchange medium (M) in the tempering circuit (40); a hydraulic circuit (30) for media transfer of the heat exchange medium (M) to and from the transfer channel (15) and/or the at least one free space (14) in the battery storage housing (10), for hydraulically generating insulation states, with: media-carrying lines which are communicatively connected to the inlet (E) and the outlet (A) of the at least one transfer channel (15) and/or the at least one free space (14) in the battery storage housing (10), a compensating tank (31) for storing a volume of the heat exchange medium (M), and at least one valve (33) arranged between the battery storage housing (10) and the expansion tank (31) and/or between the battery storage housing (10) and the temperature control pump (42), for switching between media transfers of the Heat exchange medium (M) for filling, emptying and/or flowing through the at least one free space (14) in the battery storage housing (10); wherein the temperature control circuit (40) and the hydraulic circuit (30) are communicatively connected to one another. 11. Temperature control system (200) according to claim 10, wherein the hydraulic circuit (30) additionally comprises a pump (32) for independently conveying the heat exchange medium (M) between the expansion tank (31) and the battery storage housing (10). 12. Temperature control system (200) according to claim 10 or 11, comprising a heating device (43) arranged in the temperature control circuit (40) for electrically heating the heat exchange medium (M). 13. Temperature control system (200) according to one of claims 10 to 12, comprising a refrigeration machine (44) arranged in the temperature control circuit (40) for thermodynamically cooling the heat exchange medium (M). 14. Temperature control system (200) according to one of claims 10 to 13, comprising a temperature sensor arranged on an outside of the battery storage unit (20) or in a system environment for detecting an outside temperature. 15. Temperature control system (200) according to one of claims 10 to 14, comprising a temperature sensor arranged in the battery storage (20) for detecting a battery temperature. 16. A method for changing a variable thermal insulation of a battery storage device (20) using the battery storage housing (10) according to one of claims 1 to 4, comprising the steps: - filling or flowing through the at least one free space (14) in the battery storage housing (10) with a heat exchange medium (M) via the inlet (E) or via the inlet (E) and the outlet (A) by means of a hydraulic circuit (30), in order to produce a thermal insulation state with a higher thermal conductivity between an inside and an outside of the battery storage housing (10), and - Emptying the heat exchange medium (M) from the at least one free space (14) in the battery storage housing (10) via the outlet (A) by means of the hydraulic circuit (30), in order to produce a thermal insulation state with a lower thermal conductivity between an inside and an outside of the battery storage housing (10). 3 sheets of drawings 13 / 16