DE102021126129A1 - Cooling arrangement, battery arrangement and method for cooling a battery - Google Patents

Abstract

The invention relates to a cooling arrangement (10) for cooling a battery with at least one battery cell, the cooling arrangement (10) being designed to produce a cold mixture (13a) that carries out an endothermic reaction for cooling the at least one battery cell. The cooling arrangement (10) has a cooling device (12) through which a coolant (13) can flow, for cooling the at least one battery cell in a first state of the at least one battery cell, the cooling arrangement (10) having a detection device (24) which is is designed to detect a second state, which is different from the first state of the battery cell and represents a fault state, and to trigger the production of the cold mixture (13a) as a function of the detection of the second state, and wherein the cooling arrangement (10) is designed to to cool the at least one battery cell via the cooling device (12) by means of the cold mixture (13a) produced.

Description

The invention relates to a cooling arrangement for cooling a battery with at least one battery cell, the cooling arrangement being designed to produce a cold mixture that carries out an endothermic reaction for cooling the at least one battery cell. Furthermore, the invention also relates to a battery arrangement with such a cooling arrangement and a method for cooling a battery.

With the ever-increasing spread of traction batteries in vehicles, which can be designed in particular as high-voltage batteries, new requirements and laws regarding the safety of these are also being published, which deal, among other things, with the behavior of a traction battery in the vehicle during thermal runaway, the is to deal with a thermal runaway of a cell. For example, there are guidelines that state that after a thermal runaway of a cell has been detected, the vehicle occupants must have at least five minutes to evacuate, during which there must be no danger from fire, for example.

In order to make this possible, attempts are being made, for example, to get propagation under control by means of additional cell isolation or less reactive cell chemistry. Both measures have negative effects on the volumetric and gravimetric energy density. Additional insulation also has a negative effect on the cost side.

Furthermore, it is known from the prior art, such as in DE 20 2017 005 985 U1 described that a cooling effect can be achieved by a cooling mixture that causes an endothermic reaction. This effect is, for example, in the DE 10 2010 004 110 A1 used to cool a battery cell. In this case, an electrochemical energy store is provided, which includes an electrochemical cell and a coolant that performs an endothermic reaction. For example, the heat generated by a short circuit in the energy storage device can be used to initiate and allow the endothermic reaction to take place. Furthermore, the endothermic reaction can also be initiated mechanically, in that the substances which react with one another are initially spatially separated from one another and the endothermic reaction can only take place at all by mechanically bringing the substances together, with the substances being separated from one another by a separating device, for example a plastic film are, through their damage, for example induced by an accident, a merging of the substances is achieved. The coolant, which consists of the substances that react endothermally with one another, is also arranged inside the electrochemical cell, for example in the areas around the winding mandrel or in contact areas inside the cell housing.

However, this type of cooling has the disadvantage that the cell must be short-circuited or mechanically damaged in order to trigger the reaction. Pure heating of a cell, for example, which can also be accompanied by thermal runaway of a cell, does not lead to cooling of the cell in this case. Conversely, mechanical damage to the film can also occur for other reasons and the endothermic reaction can be triggered, even if, for example, there is no cell defect at all. Since the cooling mixture is an electrically conductive liquid that is integrated into the cell, this in turn can cause the cell to short-circuit.

It is therefore the object of the present invention to provide a cooling arrangement, a battery arrangement and a method which enable the simplest, most efficient, reliable and safest possible cooling of at least one battery cell in the event of a defect.

This object is achieved by a cooling arrangement, a battery arrangement and a method 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.

A cooling arrangement according to the invention for cooling a battery with at least one battery cell is designed to produce a cold mixture that carries out an endothermic reaction for cooling the at least one battery cell. The cooling arrangement has a cooling device, through which a coolant can flow, for cooling the at least one battery cell in a first state of the at least one battery cell, wherein the cooling arrangement has a detection device that is designed to detect a second state that is different from the first state of the battery cell, the one Represents fault condition to detect, and in response to the detection of the second condition to trigger the generation of the refrigerant mixture. The cooling arrangement is also designed to cool the at least one battery cell via the cooling device by means of the cold mixture that is generated.

Thus, the cooling device, which is also in the normal operating state of the battery, that is, if there is no defect, can advantageously be used wise fault is present, is used to cool the at least one battery cell, also use in the event of a fault to cool the at least one battery cell using the generated cooling mixture. In this case, the cold mixture is generated when the detection device detects such a fault, which is referred to here as the second state of the battery cell. The first state correspondingly corresponds to a normal state, ie a specified operating state in which there is no error or defect. The generation of the cold mixture is thus actively triggered, ie for example by a control signal, when the detection device detects the second state. This increases reliability and safety enormously. In addition, the use of an existing cooling device not only saves installation space and costs, since additional precautions, such as the integration of the cold mixture components in a cell, can be dispensed with, but at the same time a safe separation of coolant or cold mixture is also possible and provide the at least one battery cell. As a result, neither the coolant nor the cold mixture can come into direct contact with the at least one battery cell. Dangers resulting from this can also be avoided. An additional particularly great advantage of using the cooling device to cool the at least one battery cell in the event of a fault via the cooling mixture is that it is so easy to cool not only the defective cell in question, but also other cells included in the battery battery cells. For this purpose, for example, a common cooling device, for example a type of cooling plate with cooling channels, which can represent a cooling floor of a battery housing, for example, can be used. The cooling effect generated by the cold mixture can thus advantageously be used not only to cool the at least one battery cell that has the defect, but also to cool other battery cells comprised by the battery. This in turn is based on the knowledge that a thermal runaway of a battery cell often spreads very quickly to other adjacent battery cells and also leads to overheating of these battery cells and in turn to a thermal runaway of these battery cells. This ultimately ends in a chain reaction across all cells of the battery. This can advantageously be avoided, for example, by the invention and its configurations, which will be explained later, in that, for example, the cooling effect of the cooling mixture can also be used simultaneously for other cells in the event of a defect. Another major advantage of the invention is that the coolant provided during normal operation for cooling the at least one battery cell can be used to generate the cold mixture. A short-term, extremely efficient cooling effect can thus be implemented by generating the cold mixture in a particularly efficient and space-saving manner. The invention thus advantageously makes it possible, by cooling the at least one battery cell, to greatly reduce the intensity of a thermal runaway of this cell and even to prevent propagation to the neighboring cells with sufficient cooling. Although most batteries in electric or hybrid vehicles have cooling to regulate the temperature of the battery cells during driving and charging in order to achieve effective cooling of the battery in the event of thermal runaway, this cooling is not sufficient. By adding chemicals, as can be provided in the course of generating the cooling mixture, a strong endothermic reaction, preferably with the coolant, can be brought about and the battery or at least the at least one battery cell can be greatly cooled in the process, and the reaction is thus slowed down be or even be stopped.

On the one hand, by creating a cooling mixture, the original temperature of the starting components from which the cooling mixture is produced can be reduced. As a result, an additional cooling effect of the coolant can be achieved, as a result of which the cooling effect or fire-fighting effect can be significantly increased. Especially when, for example, only little coolant is available, as is usually the case in a motor vehicle with limited installation space, this additional temperature reduction offers great added value in terms of preventing or slowing down thermal runaway. On the other hand, the cooling mixture can also absorb a certain amount of energy without the temperature of the cooling mixture increasing as a result. The energy supplied to the cryogenic mixture is instead used for a phase transition or solution process of at least one component of the cryogenic mixture. This in turn allows the cooling effect of the refrigeration mixture to be sustained for longer periods than with pure refrigerants such as water.

To produce the cold mixture, at least two substances are preferably mixed with one another, as will be explained in more detail later. In principle, the initial state of aggregation of these at least two substances can be arbitrary, for example gaseous, liquid or solid. However, it is particularly advantageous if at least one of the two substances is liquid. A liquid component maximizes the cooling effect. The other of the two components is preferable at least in the initial state, i.e. before the cold mixture is produced. After the cold mixture has been produced, in particular by mixing the at least two substances, the second substance can, for example, change its state, for example its state of aggregation or its solution state, and can also change from the solid state of aggregation to the liquid state of aggregation or from an undissolved to a dissolved state transition to a state in which energy is extracted from the environment as a result of its dissolving process, which enables the cooling mixture to be cooled down.

The motor vehicle battery to be cooled is preferably a high-voltage battery. This comprises at least one battery cell, but preferably more than just one battery cell, in particular numerous battery cells, which can optionally also be combined into battery modules. For example, the high-voltage battery can therefore include multiple battery modules, each with multiple battery cells. The motor vehicle in which the invention is preferably used can be designed accordingly as an electric or hybrid vehicle. The battery acts accordingly as a traction battery for the motor vehicle. The battery cells are, for example, lithium-ion cells. Compared to other cell chemistries, these have a very high energy density.

As already mentioned, the cooling device can be a cooling plate, for example, which has cooling channels through which the coolant can flow. The detection device can include one or more sensors for detecting the error state. A detection can be based, for example, on a voltage measurement of the cell voltage of the at least one battery cell, with a short circuit or defect in the cell being able to be detected, for example, based on a voltage drop. For example, the detection device can also include a pressure sensor that can detect an overpressure in the battery cell and/or inside a battery housing in which the battery cell is accommodated. The detection device can also have a gas sensor which can, for example, detect a specific gas composition that indicates outgassing of a battery cell. The detection device can also have a temperature sensor which can detect a temperature associated with the at least one battery cell. If this exceeds a predetermined threshold value, then the second state can be considered as detected. The second state can thus be detected by detecting an overpressure in the battery, by detecting an increased cell temperature, by a voltage drop or by detecting outgassing of a cell. Any combinations of these detection options are also conceivable. This enables a defect in the at least one battery cell to be detected very reliably. The detection of a specific temperature increase for the detection of the second state is particularly advantageous since the beginning of a thermal runaway can be detected very early on, in particular even before the cell in question outgasses.

As already mentioned above, it is preferable for the cooling arrangement to be designed to mix at least two substances that were separated from one another before they were produced, in order to produce the cold mixture. It is furthermore very advantageous if, for example, a first substance of the at least two substances represents the coolant, which in particular represents a water-based coolant. A water-glycol mixture is usually used as the coolant, which is also ideal for generating the cooling mixture. In this way, resources that are usually already present in the vehicle can advantageously be used to produce the cold mixture. In this case, the coolant can in particular be that which flows through the cooling device for cooling the at least one battery cell in the first state of the at least one battery cell. Thus, the coolant used in normal operation to cool the cells can also be used at the same time to generate the cold mixture in the event of a fault.

Furthermore, it is very advantageous if at least one second substance of the at least two substances is a salt. This salt can be endothermically dissolved in the first water-based substance to produce the cryogenic mixture. So if the cold mixture is produced by mixing the at least two substances, i.e. if the salt provided is mixed with at least the water, the salt is dissolved in the water, whereby energy is extracted from the environment, which on the one hand leads to the cooling of the cold mixture and on the other hand corresponding to the cooling of the environment. After the mixing of the at least two substances, the temperature of the cooling mixture is lower than the starting temperature of the at least two substances before mixing for at least a certain period of time. This cooling can be implemented in a particularly simple and cost-effective manner by mixing a salt with water. In principle, this effect can be used at any starting temperature. The cooling arrangement can also have a dosing unit with a reservoir for receiving at least the second substance of the at least two substances. In other words, in this dosing unit with the Reservoir, the salt or the salt mixture are kept, which in an emergency, that is, upon detection of the second state of the at least one battery cell, the coolant is supplied to generate the cold mixture.

In order to cool the at least one battery cell in the event of a fault using the cooling mixture via the cooling device, there are basically two options, namely direct cooling using the cooling mixture and indirect cooling using the cooling mixture, which are now explained in more detail below.

It represents an advantageous embodiment of the invention when the cooling arrangement is designed in such a way that the cooling mixture generated can flow through the cooling device for cooling the at least one battery cell. So this corresponds to direct refrigeration mixture cooling. The cold mixture produced flows through the cooling device, for example its cooling channels, through which the refrigerant flows during normal operation. In order to accomplish this, for example, the second substance described above, that is to say for example the salt or the salt mixture, can simply be added to the coolant circulating in the coolant circuit. As a result, the cooling mixture is automatically generated, which is then correspondingly further circulated through this cooling circuit and accordingly also through the cooling device.

Furthermore, it is particularly advantageous if the cooling arrangement has a supply line for supplying the coolant to the cooling device in the first state of the at least one battery cell and for supplying the cold mixture to the cooling device if the second state of the at least one battery cell is detected, the coolant supply line having a first degassing device which is designed to carry out at least part of a gas produced during the generation of the cold mixture from the coolant supply line. This advantageous embodiment of the invention is based on the knowledge that gases are generally produced when a cold mixture is produced. If these gases get into the cooling system, for example into the cooling channels provided by the cooling device, this reduces the cooling effect in many respects. On the one hand, this leads to very inhomogeneous cooling, since the parts of the cooling channels filled with gas have a significantly lower cooling effect than the parts of the cooling channels filled with the cooling mixture. Furthermore, such a gas can cause an overpressure in the cooling system for which the actual cooling system, ie the cooling device, is not designed. In the worst case, this leads to damage to the cooling device, for example a leak in one of the cooling channels. This can now advantageously be avoided by the degassing device, in that at least a large part of the gas produced during the generation of the cold mixture is discharged from the coolant supply line, so that it cannot get into the cooling device at all. Such a degassing device can, for example, simply be designed as a pressure relief valve. For example, the degassing device can be arranged at a spatial local maximum of the feed line. As a result, such a gas, which is usually lighter than a liquid, would accumulate in this locally elevated area and could therefore be easily discharged via the degassing device.

The coolant supply line can also have such a degassing device at several points. Alternatively or additionally, such a degassing device can also be arranged in a region of the cooling device itself and fluidly coupled to one of the cooling channels.

In a further very advantageous embodiment of the invention, the cooling arrangement has a first cooling circuit, the cooling device being part of the first cooling circuit, the cooling arrangement being designed to generate the cooling mixture in a cooling mixture area which is fluidically separated from the first cooling circuit, and the cooling arrangement having a Having heat exchanger device, which thermally couples the first cooling circuit with the cold mixing area.

This corresponds to the indirect cold mixture cooling mentioned above. In this case, the cold mixture generated does not itself run through the cooling channels of the cooling device, but only cools the coolant via a heat exchanger, the coolant continuing to circulate as usual through the first cooling circuit and thus also runs through the cooling device. The cold mixture area can be provided in particular as a cold mixture reservoir and/or as a cold mixture circuit. This can therefore represent a second cooling circuit. This refrigeration mixture circuit is correspondingly fluidly separated from the first cooling circuit, but thermally coupled to it via the heat exchanger. Although this configuration is somewhat more complex in terms of construction, it has the great advantage that it can be ensured that no gas that is produced when the cold mixture is generated can get into the first cooling circuit, since this is completely fluidically separated from the cold mixture area. Any damage to the cooling structures of the cooling device due to excess pressure or inhomogeneous cooling due to such ingress of gas can thus advantageously be ruled out. Nothing the less can nevertheless, a corresponding degassing valve or a degassing device may be provided.

It is therefore a further very advantageous embodiment of the invention if the cold mixture region, which is provided in particular by a cold mixture reservoir and/or a cold mixture circuit, has a second degassing device which is designed to remove at least part of a gas produced when the cold mixture is generated to perform the cold mixing area. This has advantages similar to those already described for the first degassing device. This makes it possible, for example, to design the cold mixture reservoir or the cold mixture circuit in a simpler way, since it accordingly does not have to withstand high pressures. In addition, this can also in turn increase the cooling efficiency, since the heat absorption via the heat exchanger would also be reduced by the gas circulating in the cooling mixture circuit.

In principle, a heat exchanger can be designed in any way. For example, in the simplest case, a heat exchanger device could already be provided by arranging a line section corresponding to the first cooling circuit very close or even in contact with a line section assigned to the cold mixture circuit, or directly at the cold mixture area or cold mixture reservoir. However, a coupling can also take place via a heat sink, which thermally couples the two line sections mentioned to one another even better. Other configurations are also conceivable.

As already described above, the cooling arrangement can have a dosing unit with a reservoir for receiving at least one second substance of the at least two substances, which is in particular a salt. It is preferred that the dosing unit is designed to supply at least a portion of the at least one second substance received in the reservoir to the feed line and/or the cold mixture region upon detection of the second state for generating the cold mixture. If the cooling mechanism is designed as direct cold mixture cooling, according to which the generated cold mixture is circulated directly through the cooling channels of the cooling device, then to generate the cold mixture the salt in the reservoir can simply be fed in a suitable quantity via the dosing device to the feed line for feeding the cold mixture to the cooling device become. In particular, the salt contained in the reservoir can easily be fed to the first cooling circuit, which is provided by the circulating conventional coolant. In the case of indirect cold mixture cooling, the salt contained in the reservoir can be fed to the cold mixture area, in particular the cold mixture circuit, in which the coolant, in particular preferably also a water-glycol mixture, is already circulated. In the second case, in principle, a first substance that is different from the coolant can also be used to generate the cold mixture, which is preferably a liquid substance, in particular under normal conditions, and is preferably a water-based substance.

Furthermore, the invention also relates to a battery arrangement with a cooling arrangement according to the invention or one of its configurations. The advantages mentioned for the cooling arrangement according to the invention and its configurations also apply in the same way to the battery arrangement according to the invention.

In this case, the battery arrangement has the battery with the at least one battery cell. The battery preferably comprises a plurality of battery cells including the at least one battery cell, the cooling device being designed for cooling the plurality of battery cells. In particular, the cooling device can be designed for the simultaneous cooling of the multiple battery cells. This applies both to normal operation and to cooling in the event of a fault using the cooling mixture. In other words, in the event of a fault, not only is the defective or thermally continuous cell cooled in a targeted manner, but also all the other battery cells that are connected to the same cooling device. As a result, the neighboring cells of the thermally continuous cell can already be cooled before they are themselves in thermal runaway and the propagation can be stopped much more efficiently as a result. In addition, this central solution offers cost and installation space advantages.

As already described above, the battery can be in the form of a high-voltage battery and can, for example, comprise a number of battery modules each having a number of battery cells. In principle, it is also conceivable to provide separate cooling devices for each module or group of modules. However, all of the battery cells and battery modules included in the battery can also be cooled by a common cooling device. In other words, selective battery module cooling or cell cooling does not have to be implemented.

A motor vehicle with a battery arrangement according to the invention or one of its designs designs should be considered as belonging to the invention.

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.

Furthermore, the invention also relates to a method for cooling a battery with at least one battery cell by means of a cooling arrangement that produces a cold mixture that carries out an endothermic reaction for cooling the at least one battery cell. The cooling arrangement has a cooling device through which a coolant flows in a first state of the at least one battery cell. Furthermore, the cooling arrangement has a detection device, which detects a second state, which is different from the first state of the battery cell and represents a fault state, and triggers the production of the cold mixture as a function of the detection of the second state. Furthermore, the at least one battery cell is cooled via the cooling device by means of the cold mixture produced.

The advantages described for the cooling arrangement according to the invention and its configuration also apply in the same way to the method according to the invention.

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

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 einer Kühlanordnung mit einer direkten Kältemischungskühlung gemäß einem Ausführungsbeispiel der Erfindung; und
• 2 eine schematische Darstellung einer Kühlanordnung mit einer indirekten Kältemischungskühlung gemäß einem weiteren Ausführungsbeispiel der Erfindung.

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

• 1 a schematic and perspective view of a cooling arrangement with a direct cooling mixture cooling according to an embodiment of the invention; and
• 2 a schematic representation of a cooling arrangement with an indirect cooling mixture cooling according to a further 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 features of the invention that are to be considered independently of one another and that each also 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 representation of a cooling arrangement 10 according to an embodiment of the invention. In this example, the cooling arrangement is designed as a direct cold mixture cooling, as will now be explained in more detail below. The cooling arrangement 10 initially has a cooling device 12 which in turn comprises a plurality of cooling channels 14 through which a coolant 13 can flow. The coolant 13 and its direction of flow are illustrated here as an example by arrows. This cooling device 12 is part of a first cooling circuit 16, only part of which is shown here. The coolant 13 can be supplied to the cooling device 12 , in particular to the cooling channels 14 , via a coolant supply line 18 . This cooling structure shown, that is, the cooling channels 14, can also be integrated into a cooling plate on which battery cells of a battery, not shown in detail here, in particular a high-voltage battery for a motor vehicle, are arranged. The battery cells comprised by such a high-voltage battery can be cooled in particular by a common cooling device 12 of this type. The coolant supply line 18 is connected via a supply connection 20 to the cooling device 12 or its cooling channels or cooling channel system 14 . It is also conceivable here to supply the coolant 13 not only via one such supply connection 20, but also via several, for example. Furthermore, the cooling device 12 has at least one discharge connection 22, several such discharge connections 22 for discharging the coolant 13 from the cooling device 12 being conceivable here as well. The discharge connection 22 can in turn be fluidically connected to the supply connection 20 via a further line system with further cooling circuit components, such as a pump, a coolant reservoir, and so on. Thus, during normal operation of the battery, the coolant 13 circulates in this coolant circuit 16, passing through it for cooling the battery cells, the cooling device 12 is then cooled again and fed back to the cooling device 12 via the feed line 18, and so on. In principle, such a cooling device 12 or the cooling circuit 16 is also suitable for heating battery cells, for example for the purpose of preconditioning or the like. Whether a cooling or heating function is implemented as a result depends on the set temperature of the coolant.

In the case of a thermal runaway of a battery cell, such a thermal runaway can be greatly reduced in intensity and propagation to neighboring cells can even be prevented if the cells are sufficiently cooled. However, conventional cooling for battery cells is not sufficient for this. The invention and its configurations now advantageously make it possible to greatly increase the cooling capacity of the described cooling system, at least for a short time, and thus to slow down or even stop the reaction. This can be achieved by creating a cryogenic mixture 13a. In order to make this possible, the cooling arrangement 10 initially also has a detection device 24 which is designed to detect such a defect in a battery cell. Furthermore, in this example, as part of the cooling arrangement 10, a dosing unit 26 with a reservoir 28 for receiving a substance, in the present example a salt 30, is provided. The detection device 24 is also designed to trigger the production of the cold mixture. For this purpose, the detection device 24 can be designed either directly or indirectly to correspondingly control the dosing unit 26 in order to admix the salt 30 to the coolant 13 in order thereby to produce the cold mixture 13a. Meanwhile, the coolant, which is now mixed with this salt 30, continues to circulate as usual through the cooling device 12 and in particular through the cooling circuit 16, as previously described. By adding the salt 30, a cold mixture 13a is produced, which leads to an enormous cooling of the coolant 13. The coolant is preferably a water-glycol mixture, to which the salt 30 is added. Barium hydroxide and ammonium thiocyanate, for example, could be admixed as salts to the coolant 13 in order to achieve the cooling mixture 13a. This can be described, for example, by the following formula: Ba(OH) ₂ + _8H2O + _2NH4SCN → Ba2 ⁺ + 2SCN- + _2NH3 + _10H2O

However, other salts such as ammonium nitrate or ammonium chloride, which enter into an endothermic reaction with water, are also conceivable.

If a thermal runaway is detected, as can be accomplished by the detection device 24, the coolant 13 of the battery, i.e. usually a water-glycol mixture, is mixed directly with the salt 30 in or by means of a dosing unit 26 in the area of the coolant inlet 20 and thereby bring about an endothermic reaction directly in the refrigerant circuit 16 . As a result, the coolant 13 cools down abruptly, which now in combination with the supplied salt 30 represents the cold mixture 13a, and can thus cool the battery or the battery cells better and prevent propagation. In order to avoid excessive overpressure within the cooling system and to avoid gas accumulations in the area of the cell cooling, which impair the heat transfer, it is also preferred that the cooling arrangement 10 has a degassing device 32, for example a pressure relief valve. This can be integrated into the feed line 18, for example. As a result, the gas can be discharged from the supply line 18 before it reaches the cooling device 12, in particular the cooling channels 14. The discharged gas can be discharged into the surroundings of the cooling arrangement 10, in particular into the surroundings of the entire battery and even into the surroundings of the motor vehicle. Alternatively, it can also be collected in a gas collection container or introduced into one. Mixing the salt 30 with the coolant 13 to form the cold mixture 13a in the area of the dosing unit 26 is also in 1 illustrated by arrows.

2 shows another example of a cooling arrangement 10. This cooling arrangement 10 in turn has a cooling device 12, which as for 1 described can be formed. Here, too, this cooling device 12 is part of a cooling circuit 16 in which the coolant 13 circulates and thus cools or tempers the cells in the normal operating state of the battery. If an error now occurs, which in turn can be detected by the detection device 24, a cold mixture 13a is again produced here as well. However, this is not fed to the first cooling circuit in which the cooling device 12 is integrated, but instead circulates in a second separate cooling circuit 34. These two cooling circuits 16, 34 can be thermally coupled to one another via a heat exchanger 36. This means that a thermal resistance between the two circuits 16, 34 in the area of the heat exchanger 36 is lower than outside of the heat exchanger 36. Nonetheless, the cold mixture 13a can also be produced here as described above. For this purpose, too, the cooling arrangement 10 can comprise a dosing unit 26 with a reservoir 28, in which one for generating the Cold mixture 13a to be used substance 30, preferably in turn a salt 30 is arranged. This can be supplied to a further substance for generating the cold mixture 13a via the dosing unit 26 in response to activation, for example via the detection device 24 . This further substance is preferably in turn a coolant 13 ′, preferably in turn a water-glycol mixture, which is located in the second circuit 34 . Alternatively, a separate reservoir can also be provided for this second substance 13', which is not shown here, however. In principle, however, a liquid that is different from the coolant 13 can also be used as the second substance 13 ′. It is also conceivable that this second circuit 34, which is fluidly decoupled from the first circuit 16, is fed via a common coolant reservoir. In this example, the salt 30 is not mixed directly with the coolant 13, which circulates in the first coolant circuit 16, but in a separate circuit 34. The coolant 13 of the battery, i.e. the first circuit 16, is then mixed via the heat exchanger 36 cooled. This has the advantage that no gas produced when generating the cooling mixture 13a can get into the battery circuit, that is to say into the first cooling circuit 16 . In addition, a degassing device 32 can also be provided here, but this time in the second circuit 34.

Overall, the examples show how the invention can be used to provide battery cooling during thermal propagation through an endothermic reaction in the cooling water using a cold mixture. This significantly increased cooling capacity, at least in the short term, makes it possible to use cells with a higher energy density or to reduce the inter-cell insulation and still ensure sufficient safety even in the event of thermal propagation of a cell.

QUOTES INCLUDED IN DESCRIPTION

This list of 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 202017005985 U1 [0004]
• DE 102010004110 A1 [0004]

Claims (10)

Cooling arrangement (10) for cooling a battery with at least one battery cell, the cooling arrangement (10) being designed to produce a cold mixture (13a) which carries out an endothermic reaction for cooling the at least one battery cell, characterized in that - the cooling arrangement (10 ) has a cooling device (12) through which a coolant (13) can flow for cooling the at least one battery cell in a first state of the at least one battery cell; - wherein the cooling arrangement (10) has a detection device (24) which is designed to detect a second state, which is different from the first state of the battery cell and represents a fault state, and depending on the detection of the second state, the generation of the cold mixture (13a) to trip; and - wherein the cooling arrangement (10) is designed to cool the at least one battery cell via the cooling device (12) by means of the cold mixture (13a) produced. Cooling arrangement (10) after claim 1 , characterized in that the cooling arrangement (10) is designed such that the cooling device (12) of the cold mixture (13a) generated can flow through for cooling the at least one battery cell. Cooling arrangement (10) according to one of the preceding claims, characterized in that the cooling arrangement (10) has a coolant supply line (18) for supplying the coolant (13) to the cooling device (12) in the first state of the at least one battery cell and for supplying the cooling mixture (13a ) to the cooling device (12) in the event of the detection of the second state of at least its battery cell, the coolant supply line (18) having a first degassing device (32) which is designed to remove at least a part of a gas generated during the production of the cooling mixture (13a). Run gas from the coolant supply line (18). Cooling arrangement (10) according to one of the preceding claims, characterized in that the cooling arrangement (10) has a first cooling circuit (16), the cooling device (12) being part of the first cooling circuit (16), the cooling arrangement (10) being designed for this purpose is to generate the cold mixture (13a) in a cold mixture area (34) which is fluidically separated from the first cooling circuit (16), the cooling arrangement (10) having a heat exchanger device (36) which thermally connects the first cooling circuit (16) with the cold mixture area (34 ) couples. Cooling arrangement (10) according to one of the preceding claims, characterized in that the cold mixture region (34), which is provided in particular by a cold mixture reservoir and/or a cold mixture circuit (34), has a second degassing device (32) which is designed to at least to discharge part of a gas produced during the production of the cryogenic mixture (13a) from the cryogenic mixture region (34). Cooling arrangement (10) according to one of the preceding claims, characterized in that the cooling arrangement (10) is designed to mix at least two substances (13, 13'; 30) which are separated from one another prior to the production in order to produce the cold mixture (13a). Cooling arrangement (10) according to one of the preceding claims, characterized in that a first substance (13, 13`) of the at least two substances represents the coolant (13), which in particular represents a water-based coolant (13). Cooling arrangement (10) according to one of the preceding claims, characterized in that the cooling arrangement (10) has a dosing unit (26) with a reservoir (28) for receiving at least one second substance (30) of the at least two substances (13, 13'; 30 ), which is in particular a salt (30), wherein the dosing unit (26) is designed, upon detection of the second state for generating the cold mixture (13a), at least part of the at least one second substance ( 30) to the supply line (18) and/or to the cold mixing area (34). Battery arrangement with a cooling arrangement (10) according to one of the preceding claims, characterized in that the battery arrangement has the battery with the at least one battery cell, in particular wherein the battery has a plurality of battery cells comprising the at least one battery cell, the cooling device (12) for cooling the several battery cells is designed. Method for cooling a battery with at least one battery cell by means of a cooling arrangement (10) which produces a cold mixture (13a) which carries out an endothermic reaction for cooling the at least one battery cell, characterized in that - the cooling arrangement (10) has a cooling device (12) through which a coolant (13) flows in a first state of the at least one battery cell; - wherein the cooling arrangement (10) is a detection device (24) which detects a second state, which is different from the first state of the battery cell and represents a fault state, and triggers the production of the cold mixture (13a) as a function of the detection of the second state; and - wherein the at least one battery cell is cooled by means of the cold mixture (13a) produced via the cooling device (12).

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