DE102020116051A1 - Housing system for accommodating a liquid-cooled component, energy storage system with such a housing system and motor vehicle with such an energy storage system - Google Patents

Abstract

The invention relates to a housing system (2) for accommodating a liquid-cooled component (6), with at least one outer pan (3) which has an outer pan base (16) which is continuously closed; at least one inner pan (4) which is arranged in the outer pan (3) and which has an inner pan base (12) which is provided with a one-way valve (5) which allows a flow from the inner pan (4) to the outer pan (3). and blocks a flow from the outer pan (3) to the inner pan (4), the liquid-cooled component (6) being arranged in the inner pan (4). The invention also relates to an energy storage system (1) with such a housing system (2). The invention also relates to a motor vehicle with such an energy storage system (1).

Description

The invention relates to a housing system for accommodating a liquid-cooled component, in particular an electrical energy store. In addition, the invention relates to an energy storage system having an electrical energy storage device, which is received in the housing system, and a motor vehicle with such an energy storage system.

Electrified motor vehicles have electrical energy stores, so-called traction stores or high-voltage stores, which are often arranged in the floor area of the motor vehicle. For the purpose of temperature control, i.e. for heating and / or cooling, these energy stores are in contact with heat exchangers through which a coolant flows. In the event of a leak in the coolant circuit, there is a risk that the escaping coolant will damage the energy store. For example, in the event of a leak, up to 10 liters of electrically conductive coolant (e.g. a water-glycol mixture) could escape from the break and collect in the housing of the energy storage device. It should also be noted that the cell poles, i.e. the connection poles of the storage cells of the energy storage device, have different electrical voltage levels to one another, which can lead to equalizing currents if several cell poles are wetted with conductive liquid at the same time. This can result in electrical corrosion, which can damage the storage cells or the energy storage device. Since the cell contacting system is usually welded on during assembly and this results in a complex geometric system in today's energy stores, it would be very time-consuming and expensive to seal the cell poles. Cell poles that are exposed to the environment are therefore common today.

It is therefore an object of the present invention to at least partially eliminate the above-mentioned disadvantages. This object is achieved by a housing system according to claim 1, an energy storage system according to claim 8 and a motor vehicle according to claim 12. Advantageous further developments of the invention are the subject of the dependent claims.

According to an exemplary embodiment of the invention, a housing system for receiving a liquid-cooled component, with at least one outer trough, which has an outer trough bottom, which is continuously closed; at least one inner tub, which is arranged in the outer tub and which has an inner tub bottom which is provided with a one-way valve, which allows a flow from the inner tub to the outer tub and blocks a flow from the outer tub to the inner tub, in particular permanently blocks, the liquid-cooled component is arranged in the inner tub. The advantage of this housing system is that, in the event of a leak, the coolant or refrigerant can be removed from the inner tub in which the component is located, thus preventing damage to the component itself. The discharged coolant or refrigerant is discharged from the inner tub into the outer tub, preventing it from flowing back into the inner tub. The coolant or refrigerant is collected in the outer tub. In view of an estimated total volume of 10 liters of coolant or refrigerant, it is possible, even in the event of a complete leak, to collect this coolant or refrigerant in the outer pan without it escaping anywhere. The advantage of collecting the coolant or refrigerant in the outer tub without releasing it directly to the environment is that an outer tub that is completely sealed at the bottom and free from both openings and valves can be provided, so that this is reliably prevented it can be that water enters from the outside and thus the component is damaged by water entering from the outside, for example when crossing a river. In short, this exemplary embodiment has the advantage that, on the one hand, the coolant or refrigerant is discharged from the component in the event of a leak and, at the same time, water can be reliably prevented from entering from the outside, thus ensuring that the vehicle can be wading.

According to a further exemplary embodiment of the invention, the component is an energy store or a storage module of an electrical energy store. The advantages described above are particularly important in the case of an energy storage device or a storage module, since these components are usually arranged on the vehicle floor and, in order to ensure that the vehicle is safe for wading, it must be ensured that no water can reach the energy storage device from below and, at the same time, that the energy storage device prevents liquid leaks is protected.

According to a further exemplary embodiment of the invention, the inner tub bottom slopes down towards the one-way valve. In other words, in the installed state in the intended use, with regard to a direction of a weight force, the inner tub bottom falls down towards the one-way valve. Thus, in the event of a leak, the coolant or refrigerant flows due to its weight to the one-way valve. That is to say, in particular, the one-way valve is located at the lowest point with regard to the direction of the weight force.

According to a further exemplary embodiment of the invention, the inner tub base is formed from a plurality of flat surfaces which face the outer edges of the inner tub base One-way valve are arranged sloping down. This also relates to the direction of the weight force, in the installed state in the intended use. Thus, in the event of a leak, the coolant or refrigerant flows due to its weight to the one-way valve. That is to say, in particular, the one-way valve is located at the lowest point with regard to the weight force.

According to a further exemplary embodiment of the invention, the inner tub has a plurality of side walls which are closed in a ring-like manner, in particular in the form of a rectangular ring.

According to a further exemplary embodiment of the invention, the one-way valve has a membrane.

According to a further exemplary embodiment of the invention, the inner tub is made of plastic or rubber. In particular, the inner tub is designed in one piece, for example monolithically. The advantage of an inner tub made of plastic or rubber is that it can be manufactured inexpensively. Another advantage is that plastic or rubber has a certain dampening effect on vibrations and shocks and thus protects the component.

The outer tub is in particular made of metal, for example aluminum or steel. The outer tub can be designed in one piece. For example, the individual side parts and the bottom are non-destructively detachable connected to one another, e.g. welded.

The invention also relates to an energy storage system with such a housing system. This energy storage system also has an electrical energy store, the component being the energy store or a storage module of the electrical energy store.

According to a further exemplary embodiment of the invention, the energy storage system is furthermore provided with a heat exchanger which is connected to the component in a thermally conductive manner or is integrated into it and through which a coolant or refrigerant can flow.

According to a further exemplary embodiment of the invention, the energy storage system is designed in such a way that the outer trough has several areas separated by struts and an inner trough is arranged in several or all of these areas.

According to a further exemplary embodiment of the invention, the energy storage system is designed in such a way that adjacent areas have at least one liquid passage opening.

In particular, the outer tub is designed in such a way that it is open on an upper side with regard to the direction of the weight force and the other sides (including the bottom) are closed in a liquid-tight or fluid-tight manner.

In particular, the inner trough is designed in such a way that it is open on an upper side with respect to the direction of the weight force and the other sides (including the bottom) are closed in a liquid-tight or fluid-tight manner.

The present invention also provides a motor vehicle with such an energy storage system.

• 1 zeigt eine schematische Darstellung eines Energiespeichersystems mit einem Gehäusesystem gemäß einem Ausführungsbeispiel der Erfindung;
• 2 zeigt schematisch eine Schnittdarstellung durch eine Innenwanne des Gehäusesystems aus 1, und
• 3 zeigt schematisch einen Innenwannenboden der Innenwanne aus 2.

A preferred embodiment of the present invention is described below with reference to the accompanying drawings. These drawings show:

• 1 shows a schematic representation of an energy storage system with a housing system according to an embodiment of the invention;
• 2 shows schematically a sectional view through an inner tub of the housing system 1 , and
• 3 shows schematically an inner tub bottom of the inner tub 2 .

In 1 is schematically the energy storage system 1 , including the housing system 2 , shown according to an embodiment of the invention. The housing system 2 has an outer tub 3 , an inner tub 4th as well as a one-way valve 5 on. The energy storage system 1 instructs the housing system 2 , a liquid-cooled component 6th as well as one in the component 6th integrated or thermally connected heat exchangers 7th on. The energy storage system 1 is installed in particular in a motor vehicle. The motor vehicle is, for example, a passenger car. In particular, the motor vehicle is an electrified vehicle with a hybrid drive or a purely battery-electric drive.

The component 6th is in particular an electrical energy store or, as in the illustrated case, a storage module 8th of the energy storage. The electrical energy store stores electrical energy on an electrochemical basis, can provide it to at least one electric motor for driving the motor vehicle, and can be recharged. The energy store has several electrical in series or memory modules connected in parallel 6th on. Each of the memory modules 6th has a multiplicity of storage cells that store electrical energy on an electrochemical basis, can provide this to at least one electric motor for driving the motor vehicle, and can be recharged. The memory cells are electrically connected in series or in parallel. The memory cells are, for example, so-called pouch cells, prismatic cells or round cells. The energy store is adapted for an output voltage of more than 50 volts, in particular more than 100 volts, in particular more than 300 volts. The connection poles 9 of the memory cells are in 1 indicated. These are, for example, on the side, above or below (with regard to a direction of a weight force).

The component 6th can instead of a memory module 8th or an energy store can also be another liquid-cooled component, such as an electric motor for driving a motor vehicle, a computing unit (for example for autonomous driving), a fuel cell, an inverter, other power electronics components, etc.

The component 6th is thermally conductive with the heat exchanger for the purpose of heating or cooling 7th connected, which is designed for example in the form of a heating / cooling plate. The heat exchanger 7th can also be in the component 6th be integrated. Furthermore, the heat exchanger is 7th with an inlet 10 and an outlet 11 Via which a temperature control fluid, in particular a temperature control liquid, into a flow-through interior of the heat exchanger 7th can be fed in and removed again from this. The temperature control liquid is, for example, a coolant, such as a water-glycol mixture, or a refrigerant. The heat exchanger 7th can be at the bottom, side or top of the component 6th be arranged.

The component 6th as well as the heat exchanger 7th are in the inner tub 4th arranged, in particular these elements are completely or predominantly (more than 50% of their common volume) in the inner tub 4th arranged.

The inner tub 4th is trough-like, ie it has an inner trough bottom 12th on, the outer edges of which are side walls 13th be hemmed. In particular, the inner tub 4th designed in such a way that it is open on an upper side with regard to the direction of the weight force and the other sides (including the inner tub bottom 12th ), apart from the one-way valve 5 , liquid-tight or fluid-tight are closed. In particular, the inner tub bottom 12th apart from the one-way valve 5 , continuously liquid-tight or fluid-tight closed. In the inner tub floor 12th is the one-way valve 5 provided, which is designed as a check valve, which allows a flow from the inner pan 4th to the outside tub 3 and a flow from the outer pan 3 to the inner tub 4th locks. This functionality is implemented, for example, purely mechanically via a membrane.

As in the 2 and 3 shown, the inner tub bottom falls towards the one-way valve, so that the one-way valve 5 , based on the weight, at the deepest point of the inner tub 4th is arranged. For example, the inner tub floor 12th from several flat surfaces 14th formed opposite outer edges 15th of the inner tub floor 12th to the one-way valve 5 are arranged downhill.

The inner tub 4th is made of plastic or rubber, for example. In particular, the inner tub 4th in one piece, for example monolithically, formed.

The outside tub 3 is in particular a high-voltage storage housing, as it is already known today. The outside tub 3 is also trough-like, ie it has an outer trough bottom 16 on, the outer edges of which are side walls 17th be hemmed. In particular, the outside tub 3 designed in such a way that it is open on an upper side with regard to the direction of the weight force and the other sides (including the outer tub bottom 16 ) are closed in a liquid-tight or fluid-tight manner. In particular, the outer tub floor 16 evenly and continuously closed in a liquid-tight or fluid-tight manner. The outside tub 3 is made of metal such as steel or aluminum, for example. In particular, the inner tub 4th formed in one piece. For example, the outside tub 3 formed in one piece in that separately formed sides are non-destructively releasably connected to one another, for example welded.

The outside tub 3 has several, by one or more struts 18th separate areas 19th on. In some or all of these areas 19th are each an inner tub 4th is arranged. Preferably there are multiple areas 19th provided, in each of which an inner tub 4th is arranged. But it can also only be one area 19th be provided and there can also be more than one inner tub per area 4th to be ordered. In the in 1 the case shown has the outer tub 3 a single such strut 18th and two such areas 19th . The areas 19th are connected to one another in a fluid-conducting or fluid-conducting manner, for example by spacing the strut (s) 18th from the bottom of the tub 16 so that at least one liquid passage opening is formed or by forming at least one liquid passage opening in the strut (s) 18th .

While the invention has been illustrated and described in detail in the drawings and the foregoing description, these illustration and description are to be regarded as exemplary and not restrictive, and it is not intended to limit the invention to the embodiment disclosed. The mere fact that certain features are mentioned in different dependent claims is not intended to imply that a combination of these features could not also be used to advantage.

Claims (12)

Housing system (2) for receiving a liquid-cooled component (6), with at least one outer tub (3) which has an outer tub bottom (16) which is continuously closed; at least one inner tub (4) which is arranged in the outer tub (3) and which has an inner tub base (12) which is provided with a one-way valve (5) which allows a flow from the inner tub (4) to the outer tub (3) and blocks a flow from the outer pan (3) to the inner pan (4), wherein the liquid-cooled component (6) is arranged in the inner trough (4). Housing system (2) according to Claim 1 , wherein the component (6) is an energy store or a storage module (8) of an electrical energy store. Housing system (2) according to one of the preceding claims, wherein the inner tub floor (12) slopes down towards the one-way valve (5). Housing system (2) according to Claim 3 wherein the inner tub base (12) is formed from a plurality of flat surfaces (14) which are arranged sloping towards the outer edges (15) of the inner tub base (12) towards the one-way valve (5). Housing system (2) according to one of the preceding claims, wherein the inner tub (4) has a plurality of side walls (13) which are closed in a ring-like manner. Housing system (2) according to one of the preceding claims, wherein the one-way valve (5) has a membrane. Housing system (2) according to one of the preceding claims, wherein the inner tub (4) is made of plastic or rubber. Energy storage system (1) with a housing system (2) according to one of the Claims 1 until 7th , further comprising an electrical energy store, the component (6) being the energy store or a storage module (8) of the electrical energy store. Energy storage system (1) according to Claim 8 , furthermore with a heat exchanger (7) which is connected to the component (6) in a thermally conductive manner or is integrated into it and through which a coolant or refrigerant can flow. Energy storage system (1) according to Claim 8 or 9 wherein the outer trough (3) has several areas (19) separated by struts (18) and an inner trough (4) is arranged in several or all of these areas (19). Energy storage system (1) according to Claim 10 , wherein adjacent areas have at least one liquid passage opening. Motor vehicle with an energy storage system (1) according to one of the Claims 8 until 11 .

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