WO2019197540A1

WO2019197540A1 - Temperature-control device for controlling the temperature of a battery device of a vehicle

Info

Publication number: WO2019197540A1
Application number: PCT/EP2019/059273
Authority: WO
Inventors: Tobias Mayer; Christian Behlen
Original assignee: Lion Smart Gmbh
Priority date: 2018-04-13
Filing date: 2019-04-11
Publication date: 2019-10-17
Also published as: DE102018205650A1

Abstract

The invention relates to a temperature-control device (10) for controlling the temperature of a battery device (200) of a vehicle, comprising at least one temperature-control medium line (20) for conveying temperature-control medium for exchanging heat with the battery device (200), wherein the temperature-control medium line (20) has at least one temperature-control medium inlet (22) for the introduction of temperature-control medium and at least one temperature-control medium outlet (24) for the discharge of temperature-control medium, wherein the temperature-control medium line (20) also has at least one fire-protection section (26) with a filling (30) of fire-protection particles (32) with a defined melting range for the dissipation of heat in the event of a fire via phase transition.

Description

Temperature control device for a temperature control of a battery device of a vehicle

Description

The present invention relates to a tempering device for the temperature control of a battery device of a vehicle, a fire protection insert for use in such a tempering device and a method for producing such a T emperiervorrichtung.

In the context of the application, the battery device for a vehicle, in particular an at least partially electrically powered vehicle, a water and / or underwater vehicle, in particular a boat, or an aircraft can be used. Furthermore, it is conceivable that the battery device can be used in a trailer. The battery device may be used, for example, as a drive battery or supply battery.

It is known that vehicles with battery devices should be equipped with temperature control devices with regard to the adjustment of the temperature of the battery device. Thus, battery devices for reducing wear and improving usability are to be kept within an ideal temperature window. In cold outdoor conditions, this leads to a heating of the battery device as well as a cooling of the battery device is necessary at high power output or high ambient temperatures. Typically, this tempering is carried out with a liquid and / or gaseous temperature control, which is passed by means of Temperiermittelleitungen in corresponding heat transfer zones of the battery device.

A disadvantage of the known solutions is that the battery devices in addition to the tempering still need to have a fire protection functionality. Thus, battery devices consist of individual battery modules or individual battery cells in which the chemical components are arranged for the electrical power to be provided. Under mechanical influence, for example at a In the event of an accident or in a crash situation, damage to the battery devices may cause the individual chemical components to react with each other and cause high temperatures. These high temperatures can lead to a fire situation in the battery device and / or on the vehicle. For this purpose, extinguishing devices or fire protection concepts are usually provided to avoid such a risk situation. However, these have the disadvantage that they bring additional weight, additional costs and, above all, additional space requirements.

It is an object of the present invention to at least partially overcome the disadvantages described above. In particular, it is an object of the present invention to ensure cost-effective and simple way of fire protection in a battery device.

The above object is achieved by a tempering with the features of claim 1, a fire protection insert with the features of claim 1 1 and a method having the features of claim 12. Further features and details of the invention will become apparent from the dependent claims, the description and the Drawings. In this case, features and details that are described in connection with the tempering device according to the invention, of course, also in connection with the fire protection insert according to the invention and the method according to the invention and in each case vice versa, so that with respect to the disclosure of the individual aspects of the invention always reciprocal reference is or may be ,

According to the invention, a temperature control device is provided for the temperature control of a battery device of a vehicle. For this purpose, the tempering at least one tempering medium for the promotion of temperature control for the exchange of heat with the battery device. The tempering medium line is equipped with at least one Temperiermitteleingang for the entry of temperature control and at least one Temperiermittelausgang for the exit of temperature control. In this case, the Temperiermittelleitung further at least one fire protection section with a bed of fire protection particles with a defined melting range for the reduction of heat in a fire by phase transition.

According to the invention, the temperature control device is based on the known solutions for providing a temperature control functionality in a battery device. It may be a battery device for a vehicle, which is an electrical Drive as a main drive or as a power take-off has. The battery device is heat-transferring connected to the tempering in the range of Temperiermittelleitung via a heat transfer section, so that tempering, which is pumped by a Temperiermittelpumpe in forced circulation on the Temperiermitteleingang by Temperiermittelleitung to Temperiermittelausgang can be introduced or applied via the temperature control. The desired heat exchange can also be understood as the primary tempering functionality of the tempering device.

In addition to the tempering function, the tempering device according to the present invention still has a secondary fire protection function. Thus, the temperature control can provide two functionalities as a unit available, so that a separate fire protection unit with a separate fire protection functionality in terms of size, cost and space requirements can be avoided.

For this fire protection functionality fire protection particles are introduced in the form of a bed in a fire protection section. The fire protection section can be constructed or arranged in the region of the heat transfer, that is to say in the heat transfer section with the battery device. The fire protection section preferably overlaps or is completely inserted into the heat transfer section. However, in principle it is also conceivable that the fire protection section is arranged at other locations or even extends completely or essentially completely over the temperature control line. For this fire protection functionality, a bed of fire protection particles is arranged in the fire protection section. Fire protection particles are characterized in the context of the present invention in that they have a defined melting range and / or a defined melting point. This means that when a defined temperature is reached, which lies above or in the range of the melting range or the melting temperature of the fire protection particles, they begin to melt. In the normal operating state of the temperature control device, the fire protection particles are thus present in a solid phase, while they are present in a phase transition in the liquid or even gaseous phase when the defined melting range is exceeded. For this phase transition, heat is needed to supply the phase transition with the appropriate enthalpy. This heat is removed from the environment, so that in this way a cooling function cools the surrounding components, in particular the battery device and / or the heat transfer section. The introduction of the fire protection particles takes the form of a bed, which brings in particular two major advantages. On the one hand, the introduction can be simple, inexpensive and quick, since pourable, in particular free-flowing fire protection particles can be easily and inexpensively introduced into the temperature control line. A further advantage of the introduction in a bed is that a bed prevents a complete flow closure within the temperature control line, since the individual fire protection particles in the form of the bed have a bedding porosity through which the temperature control medium can continue to flow. Thus, at the same point, in particular in the heat transfer section of the tempering medium line or the battery device by the bed of fire protection particles on the one hand the fire protection functionality and on the other the primary main function of the temperature can be made available because the temperature control flow and can be available for heat transfer.

For the purposes of the present invention, a defined melting range is to be understood as meaning a temperature range and / or a temperature point. This defines the phase transition of the fire protection particles from the solid phase into the liquid or gaseous phase. A melting range or melting point in a defined manner is preferably adjusted so that the phase transition occurs before the risk of burning of the surrounding components occurs. Thus, the defined melting range is preferably provided with a temperature which is smaller than the melting range of the surrounding wall of the tempering medium line and / or the surrounding components, in particular the battery device, the corresponding adjacent battery modules or the housing of the adjacent battery modules. Thus, a local and in particular decentralized operation of the fire protection particles take place directly at the place where the temperature rises. If the entire tempering device and in particular a large part of the tempering medium lines are provided with a corresponding fill with fire protection particles, local, where overheating of the battery device occurs from the inside or from the outside, can result in direct, local and also decentralized cooling functionality due to the phase transition of the melting fire protection particles be guaranteed. This is not only decentralized and local, but also immediately available, so not just in a centralized fire protection system appropriate cooling or fire protection liquid must be brought to the desired location. Another decisive advantage of the solution according to the invention is the essentially automated and control-free functionality. Thus, the fire protection particles are triggered solely by the corresponding temperature situation, so melt when the temperature reaches or exceeds the defined melting range. A detection of a fire by electrical sensors and a corresponding rules of a fire protection system is no longer necessary. Rather, the functionality of the fire protection with the bulk of the fire protection particles can be made available here with maximum security through the phase transition, while the functionality of the temperature control device with respect to the main function of the temperature control of the battery device unimpaired or substantially unimpaired.

It may be advantageous if, in a temperature control device according to the invention, the defined melting range is more than 10% above the maximum operating temperature in the temperature control line and / or less than 10% below the fire temperature in the temperature control line. This is to be understood as the maximum limits in order to ensure safe and early functioning of the fire protection. These two limits can be particularly combined, but also kept separate. Defining a melting range by appropriate choice of material of the fire protection particles in the bed of 10% above the maximum operating temperature of the temperature control avoids it with a corresponding safety distance that the fire protection particles get into the phase transition in normal operation. In particular, the defined melting range is thus greater than the maximum operating temperature in the temperature control line. Also at the other end of the defined melting range is a corresponding safety margin of 10% of the improved functionality. Thus, a fire temperature can be determined in the temperature control, which can be defined for example by the melting or ignition temperature of the adjacent conduit wall of Temperiermittelleitung or the adjacent battery modules, battery cells or battery case. Once this temperature is reached, there is a risk that the adjacent components will melt or ignite. In order to avoid this, the cooling functionality of the fire protection of the fire protection particles should be triggered beforehand, which is why the defined melting range is below this fire or melting temperature or ignition temperature of the surrounding components. Again, a safety buffer of about 10% is preferably provided in order to be able to ensure a false trip with too low temperatures and on the other hand a timely release in case of fire with a simplified triggering and high security. It also brings advantages with it if, in a tempering device according to the invention, the fire protection particles are at least partially porous. The porosity leads to an enlarged surface, so that a corresponding fire protection functionality can be defined and adjusted even easier. In particular, this leads to a faster melting when the defined melting range is reached, so that a larger amount of enthalpy of fusion and accordingly of cooling functionality can be provided in a shorter time. In addition, the porosity can influence the desired melting points or melting ranges so that a preferred choice of material can be adjusted by the porosity with respect to a preferred and defined melting range. In principle, the individual pores of the fire protection particles can be formed both in an open and in a closed manner. The combination of open and closed pores in fire protection particles as well as non-porous and porous fire protection particles is of course conceivable within the meaning of the present invention.

There may be advantages if, in a tempering device according to the invention, the fire protection particles are at least partially hollow, in particular with a closed cavity. Such a cavity can also be provided by many individual small cavities in the form of closed pores. The cavity or hollow pores cause penetration of tempering in this cavity can be avoided by the completed and thus gas-tight training. Thus, when the temperature control device is full, that is to say when the temperature control medium is filled, the respective gas volume is not filled with temperature control agent, so that the total weight of the temperature control device is reduced by the proportion of the temperature control medium saved in this way. In addition, such a cavity, which is formed as a closed and gas-tight cavity, have an additional fire protection functionality, if a corresponding fire protection gas is arranged in this cavity. This may be, for example, inert gas, for example nitrogen. Other fire protection gases, which in particular exert a positive, because cooling or reaction-reducing effect on the adjacent chemicals in the battery device, are of course conceivable in the context of the present invention.

Another advantage is when in a tempering device according to the invention, the fire protection particles a regular geometric shape, in particular spherical or substantially spherical. This is particularly advantageous in that the bulk density of the poured fire protection particles is more easily predictable in this way. The layering or packing of the fire protection particles is easier to predict in this way. Regarding the cost in the production of a regular geometric shape for the fire protection particles also brings benefits. Not least can be provided by a regular geometric shape, in particular in a spherical or substantially spherical manner, also a good prediction of the melting functionality or the melting process in the phase transition.

Another advantage can be achieved if, in a tempering device according to the invention, the fire protection particles have a mixed grain size. This is understood to mean that the individual fire protection particles have different particle sizes, that is to say different particle diameters or particle diameters. This also refers in particular to the fact that the individual fire protection particles can have different geometric outer contours. A mixed grain size is considered to be particularly simple and inexpensive in terms of the production of the fire protection particles. In this case, a screening in a coarse manner and in terms of desired upper limits and desired lower limits set the mixed grain size to give a good predictability of the influence of fire protection in the temperature control in the fire protection section.

It may also be advantageous if, in a tempering device according to the invention, the fire protection particles have a sieved grain size, in particular with a defined grain size and / or with a grain size in the range of ± 10%. This is an alternative or additional embodiment to the preceding paragraph. A sieved grain allows the individual fire protection particles to be placed on each other, so to speak, so that a denser packing with a lower bulk porosity in the fill can be made available. Also, a more precise prediction can be made by a sieved grit, in what way and with what quantitative and also qualitative intensity the influence of the fire protection in the fire protection section of the temperature control can be provided.

Moreover, it is advantageous if, in a temperature control device according to the invention, the fire protection particles have a conductivity and / or a transmission capacity for acoustic and / or have optical signals. In particular, when using data communication within the temperature control this brings advantages, since the resistance functionality of the fire protection particles is reduced to the influence of fire protection in the fire protection section. The resistance to the passage of acoustic and / or optical signals is reduced or even minimized by the passability. Thus, for example, a visual communication based on light waves and / or an acoustic communication based on sound waves within the temperature control is possible. The passability relates in particular to a low scattering and / or a lower resistance to such signaling.

It also has advantages when, in a tempering device according to the invention, the fire protection section has at least one section wall transversely or essentially transversely to the flow direction for stabilizing the position of the fire protection particles. The position of the fire protection particles is to be understood in particular as the amount of the bed of fire protection particles in the fire protection section. Transverse to the direction of flow is thus avoided in this way co-promoting the fire protection particles together with the temperature control or at least reduced. Flat and / or acute angles of attack of such a section wall are also possible within the meaning of the present invention. Decisive here is in particular the non-parallel or unparallel design of the section wall correlating with the flow direction of the temperature control. Also, an increased stability against centrifugal forces or other transverse accelerations can be provided in this way, which can occur during operation of the vehicle in which such a temperature control device is installed.

Moreover, it is advantageous if in a tempering device according to the invention the fire protection section, the Temperiermitteleingang and / or the Temperiermittelausgang comprises a retaining device for a retention of the fire protection particles against co-promotion with the temperature control. Such a restraint device may also be referred to and understood as a filter device or grating device. It prevents at least partially leakage of the bed or individual fire protection particles of the bed. Particularly in the direction of a pumping device for generating a flow of the temperature control, this retaining device can prevent penetration of the fire protection particles in such a pump. At the exit and / or at the entrance the temperature control, especially in the flow direction, this retainer thus brings the advantages described with it.

Likewise provided by the present invention is a fire protection insert for use in a fire protection section of a temperature control line of a temperature control device according to the invention. Such a fire protection insert has an insert chamber with a bed of fire protection particles with a defined melting range for the reduction of heat in a fire by phase transition. Thus brings a fire protection insert according to the invention with the same advantages, as they have been explained in detail with respect to a temperature control device according to the invention. Such a fire protection insert can on the one hand provide a modular mode of production in the production, and at the same time allow a retrofitting of existing tempering device.

Likewise provided by the present invention is a method for the production of the temperature control device according to the present invention, comprising the following steps:

Introducing a bed of fire protection particles into the temperature control line,

- Arranging the introduced fire protection particles in the at least one fire protection section with a defined melting range for the reduction of heat in a fire by phase transition.

By producing a tempering device according to the invention, a method according to the invention brings about the same advantages as have been explained in detail with reference to a tempering device according to the invention. The introduction of the bed is carried out in particular in a trickling or pouring manner, if it is free-flowing material in the fire protection particles. With regard to the respective application, the introduction of the bedding and the corresponding selection of the fire protection particles leads to a preliminary definition and adjustment of the fire protection by the selected influencing particles for the bed

Moreover, it is advantageous if, in a method according to the invention, the introduction of the fire protection particles takes place through the temperature control medium input and / or the temperature control medium output. Thus, an additional input for the introduction of the bed is avoided, so that by dispensing with the complexity of the tempering and also the complexity in the implementation of the method can be reduced. The incorporation and construction are significantly simplified in this way.

It is also advantageous if, in a method according to the invention, the influencing particles are introduced in the form of a fire protection insert according to the present invention. The use of a fire protection insert can take place in a prefabrication, so that during the final production of the tempering and / or the battery device of the fire protection insert as such without a risk of spillage or increased expenditure by the handling of free-flowing fire protection particles is usable.

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

1 shows a first embodiment of a tempering device according to the invention,

Fig. 2 shows another embodiment of an inventive

tempering,

3 shows an embodiment of a fire protection particle according to the invention,

Fig. 4 shows a further embodiment of an inventive

Fire particle,

Fig. 5 shows an embodiment of a temperature control device according to the invention and

Fig. 6 shows a further embodiment of an inventive

Temperature control device with a fire protection insert.

FIGS. 1, 2, 5 and 6 show different forms of a tempering device 10 according to the present invention. These are all based on a solution which combines two basic functionalities for the temperature control device 10 with each other. All these four representations have in common that a battery device 200 here with different battery modules or battery cells adjacent to a Temperiermittelleitung 20 of the temperature control 10 is arranged. This area can also be understood as a heat transfer section, in which heat can be introduced by a temperature control into the battery device 200 or introduced from the battery device 200 in the temperature control. Thus, a heating functionality and / or a cooling functionality for the battery device 200 can be provided by the temperature control device 10 and by the passage of a temperature control in the Temperiermittelleitung 20.

In order to be able to provide a flow through the tempering medium line 20, it is preferably connected via the Temperiermitteleingang 22 with a Temperiermittelpumpe which can pump the corresponding temperature control over the Temperiermitteleingang 22 through the Temperiermittelleitung 20 through the Temperiermittelausgang 24 in the circulation.

For fire protection, a fire protection section 26 is provided within the tempering medium line 20, in which a bed 30 of fire protection particles 32 is arranged. This bed 30 has a bedding porosity, which is to be understood as free flow porosity, through which the temperature control medium can flow through the tempering medium line 20. Thus, although the fire protection particles 32 in the form of the bed 30 in principle constitute a fluidic resistance, but avoid complete blockage of the temperature control 20, so that despite the presence of the bed 30 in the fire protection section 26 further flow of the temperature control by the temperature control 20, and in particular through the fire protection portion 26 is possible. The flow direction is indicated by the corresponding arrow directions. While the free flow cross section SQ before and after the fire protection section 26 is completely available, remains through the bedding porosity in the area of the fire protection section 26 still a residual free cross-section, although smaller, but still present, so that also continues the flow of temperature control free or substantially free is possible.

In order to provide fire protection, the individual fire protection particles 32 are equipped with a defined melting range. This is above the normal operating temperature of the temperature control and below the melting temperature of the adjacent wall of Temperiermittelleitung or the ignition temperature of the adjacent battery modules of the battery device 200. In case of fire, for example due to increased temperature influence from the outside or due to a chemical reaction in the adjacent battery device 200, the temperature will also rise in the temperature control line 20. This happens much faster and higher than in normal operation, so that the temperature will reach and exceed the defined melting range of the fire protection particles 32 in the bed 30. As soon as this happens, the fire protection particles 32 start to melt locally and precisely at the point of the highest temperature and, for this melting process, require the corresponding enthalpy of fusion or phase transition enthalpy as phase transition. In order to provide this energy, it must be removed from the environment, so that a cooling effect and thus a fire protection effect locally, decentralized and automated controlled or can be provided without control.

The embodiments of FIGS. 2, 5 and 6 are based on the same combination of fire protection functionality with the tempering functionality. However, here are different details shown in more detail. While FIG. 1 shows a regular bed 30 with the same and / or substantially identical and spherical influencing particles 32, FIG. 5 shows, for example, a more irregular bed 30. Here, too, regular geometric shapes are for example spherical or cylindrical , provided for the individual fire protection particles 32, but they are equipped with different sizes, so that, as Fig. 5 shows well, a larger bulk porosity arises, which is accompanied by a facilitated flow with faster flow rates and larger volume flows of temperature control through the fire protection section 26 , In FIG. 5, it can also be clearly seen that in order to avoid a misplacement of the fire protection particles 32 of the bed, here section walls 28 are provided, which at the same time also serve as restraint devices 40. These are grid inserts with a corresponding grid size, which avoids and prevents co-conveying of the fire protection particles 32 with the flowing temperature control agent.

FIG. 2 shows that, for a facilitated flow, nevertheless a combination with the fire protection functionality can also be provided a central clearance, for example a central tube, which is surrounded by the fire protection particles 32 as a charge 30.

FIG. 6 shows a solution which brings great advantages, in particular with regard to the production method. So here are the fire protection particles 32 of Batch 30 as a fire protection section 26 in an insert chamber 1 10 of an interference use 100 arranged. Thus, a prefabrication of this fire protection insert can be made available without the bed must be formed only during the final production of the temperature control. This leads to a further simplification and improvement of the production.

FIGS. 3 and 4 show alternative ways in which the individual fire protection particles can be further improved. Thus, FIG. 3 shows a fire protection particle 32 with a central cavity. This is gas-tight and can, for example, have a fire gas or an inert gas. The gas-tight termination functionality of the cavity ensures that no temperature control medium can penetrate into this cavity, so that the total weight of the temperature control device 10 can be reduced by the corresponding displacement. FIG. 4 shows a fire protection particle 32 in a porous design, wherein both open and closed pores can be used here.

The above explanation of the embodiments describes the present invention solely by way of example. Of course, individual features of the embodiments, if technically feasible, can be combined freely with one another without departing from the scope of the present invention.

B ez u c se l i s te s

tempering

temperature control agent

Temperiermitteleingang

Temperiermittelausgang

Fire protection section

Abschnittswandung

fill

Fire particles

Retaining device, fire protection insert

Insert chamber Battery device flow cross-section

Claims

Patent claims

1. Temperature control device (10) for the temperature control of a battery device (200) of a vehicle, comprising at least one Temperiermittelleitung (20) for the promotion of temperature control means for exchanging heat with the battery device (200), wherein the Temperiermittepipe (20) at least one Temperiermitteleingang ( 22) for the admission of tempering agent and at least one Temperiermittelausgang (24) for the outlet of tempering, further the Temperiermittelleitung (20) at least one fire protection portion (26) having a bed (30) of fire protection particles (32) having a defined melting range to reduce heat in a fire by phase transition.

2. tempering device (10) according to claim 1, characterized in that the defined melting range is more than 10% above the maximum operating temperature in the temperature control (20) and / or less than 10% below a fire temperature in the temperature control (20).

3. tempering device (10) according to any one of the preceding claims, characterized in that the fire protection particles (32) are at least partially porous.

4. tempering device (10) according to any one of the preceding claims, characterized in that the fire protection particles (32) are at least partially hollow, in particular with a closed cavity formed.

5. tempering device (10) according to any one of the preceding claims, characterized in that the fire protection particles (32) have a regular geometric shape, in particular spherical or substantially spherical.

6. temperature control device (10) according to one of the preceding claims, characterized in that the fire protection particles (32) have a mixed grain size.

7. tempering device (10) according to one of claims 1 to 3, characterized in that the fire protection particles (32) has a sieved grain, in particular with a defined grain size and / or with a grain size in the range of + - 10%.

8. Temperature control device (10) according to one of the preceding claims, characterized in that the fire protection particles (32) have a conductivity and / or a transmissibility for acoustic and / or optical signals.

9. temperature control device (10) according to any one of the preceding claims, characterized in that the fire protection portion section (26) at least one section wall (28) transversely or substantially transversely to the flow direction for stabilizing the position of the fire protection particles (32).

10. tempering device (10) according to any one of the preceding claims, characterized in that the fire protection portion section (26), the

Temperiermitteleingang (22) and / or the Temperiermittelausgang (24) has a retaining device (40) for retaining the fire protection particles (32) against co-promotion with the temperature control.

1 1. A fire protection insert (100) for use in a fire protection section section (26) of a temperature control line (20) of a tempering device (10) having the features of one of claims 1 to 10, comprising an insert chamber (110) with a bed (30) of fire protection particles ( 32) with a defined melting range for the reduction of heat in a fire by phase transition.

12. A method for the production of a tempering device (10) with the features of one of claims 1 to 10, comprising the following steps:

Introducing a bed (30) of fire protection particles (32) into the temperature control line (20),

- Arranging the introduced fire protection particles (32) in the at least one fire protection section (26) with a defined melting range for the reduction of heat in a fire by phase transition.

13. The method according to claim 12, characterized in that the introduction of the fire protection particles (32) through the Temperiermitteleingang (22) and / or the Temperiermittelausgang (24).

4. The method according to any one of claims 12 or 13, characterized in that the influencing particles (32) in the form of a fire protection insert (100) are introduced with the features of claim 11.