WO2019197536A1 - Temperature-control device for controlling the temperature of a battery device - Google Patents

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 influencing section (26) with a filling (30) of influencing particles (32) for influencing the flow of the temperature-control medium in the influencing section (26).

Description

 TEMPERATING DEVICE FOR TEMPERING ONE

 BATTERY DEVICE

Description

The present invention relates to a tempering device for the temperature control of a battery device, an influencing insert and a method for the production of a tempering device.

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 generally known that battery devices of vehicles must be tempered. This serves on the one hand for cooling during operation but also for heating in cold ambient temperatures. Usually, such tempering are equipped with Temperiermittelleitungen, which tempering or tempering into the battery device in and away from this again. In corresponding heat exchange sections heat can be exchanged between the temperature control on the one hand and the battery device on the other hand. In order to ensure a continuous heat flow into the battery device in a heating functionality and out of the battery device out with a cooling functionality, the temperature control must be promoted in the temperature control. For this purpose, this is usually equipped with a Temperiermittelpumpe which provides a flow of temperature control in a Temperiermitteleingang through the Temperiermittelleitung therethrough to a Temperiermittelausgang available.

A disadvantage of the known solutions is that a great deal of effort has to be made to provide fluidically ideal heat transfer solutions in the region of the heat transfer from the battery device into the temperature control means put. For example, changes in the flow cross-sections, internals or similar complicated components are necessary to provide in the desired manner a fluidic design within the Temperiermittelleitung available that the exchange of heat can be done to the battery device in an optimal manner.

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 be able to provide a temperature control device in a cost-effective and simple manner, with simple adjustability of the thermal or flow-mechanical parameters within the temperature control line.

The above object is achieved by a tempering with the features of claim 1, an interference use 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 influencing 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 used to control the temperature 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. Furthermore, the tempering medium line has at least one influencing section, which has a bed of influencing particles for influencing the flow of the temperature control medium in the influencing section.

Thus, according to the invention, the temperature control device again serves to be able to ensure cooling and / or heating of the battery device. For this purpose, temperature control is conveyed in positively-conveying manner by a Temperiermittelpumpe by a Temperiermitteleingang in the temperature control and from the Temperiermittelausgang brought out again. The tempering agent is preferably guided in the tempering in a circuit so that heat can be actively introduced into this way in the battery device or discharged from it.

In order to be able to provide a simple setting of the flow speed of the temperature control means in the region of the temperature control device, according to the invention an influencing section is now arranged in the temperature control line. This influencing section serves to influence the flow of the temperature control agent through this influencing section, and in particular to adapt or change it with regard to the flow velocity or the volumetric flow of the temperature control medium. This setting is preferably carried out once during assembly of the temperature control device, that is to say when the influencing section in the temperature control line is configured by introducing the bed of influencing particles.

While in known tempering a high cost must be operated in a constructive manner to make it possible to influence the flow of the temperature control within the Temperiermittelleitung available, this invention is much simpler and cheaper possible. So it is now sufficient to introduce a plurality, preferably of two or more influencing particles, in the form of a bed in the Temperiermittelleitung and there to arrange as a bed. In the context of the present invention, a bed means an irregular or regular arrangement of individual influencing particles adjacent to one another. In particular, the influencing particles are free-flowing, so that the amount of influencing particles can be introduced into the tempering medium line in a pouring manner as a pourable bed. A bed of influencing particles, on the one hand, has a solids content, which is formed by the influencing particles themselves. Since the influencing particles, as a function of their geometric shape, do not adjoin one another like a key in the lock but rather span a space between them, there remains a pouring porosity, ie a region between adjacent influencing particles which is occupied by the temperature control agent when the temperature control medium is filled becomes. The bulk porosity of the bed of influencing particles thus forms the remaining flow cross-section through which the temperature control medium can flow through the influencing section. By selecting the bedding, and in particular by selecting the influencing particles, the bedding porosity can now be influenced. If, for example, large, bulky influencing particles are used, a respective large interspace will accordingly be formed as bulk porosity between adjacent influencing particles. In the case of very regular geometric shapes of the influencing particles and / or small cross-section of these influencing particles, the bulk porosity will decrease markedly, so that the closed portion in the influencing section increases. The less free flow cross section in the form of the bulk porosity in the bed of the influencing particles is made available, the lower the volume flow and / or the flow speed of the temperature control medium through the influencing section.

As can be seen from the above explanation, it can now be adjusted in a simple manner by the selection and combination of different or identical influencing particles, how the flow of the temperature control agent through the influencing section is to be made available. Thus, one and the same temperature control can be adjusted by selecting different beds to different desired flow conditions. Even within a battery device in which, for example, two or more temperature control devices are to provide the temperature control functionality at a different location, different temperature control functionalities can be formed in this way by different fillings with different flow conditions in the respective influencing section. Thus, it can be actively selected by the selection of the bed, whether a fast or a slow flow rate of the temperature control at the respective temperature control of the battery device is desired.

Based on the known solutions, the ability to be adjusted by the bed for the tempering functionality in the influencing section is now significantly easier, less expensive and more flexible. In particular, it can be decided only at the time of assembly whether and in what manner an influence on the flow of the temperature control medium in the influencing section is to be made available.

Preferably, it is sufficient in this case if, at least in a subsection of the entire tempering medium line, this influencing section is arranged. This is preferred formed correlating or at least overlapping with a tempering, in which a heat transfer between the temperature control and the battery device is to be provided.

The tempering agent itself is preferably configured as a tempering fluid, in particular as a tempering liquid and / or as a tempering. The individual materials, in particular the choice of material of the influencing particles is formed in an electrically non-conductive manner or preferably in an electrically insulating manner. The individual influencing particles can be identical, substantially identical or else designed in different ways, as will be explained in more detail later.

It is also advantageous if, in a tempering device according to the invention, the influencing particles are at least partially formed as porous influencing particles, in particular with closed or substantially closed pores. A porous design of the influencing particles significantly reduces the total weight of these influencing particles. In particular, in the production of the influencing particles as well as during handling during the manufacturing process steps when introducing the bed of these porous influencing particles, this can bring advantages. If the influencing particles are, in particular, porous embodiments with closed or essentially closed pores, this results in a sealed and enclosed gas inclusion being present within these closed pores. If a liquid temperature control agent is used as the temperature control agent, this further leads to the fact that the closed pores with their gas represent a displacement volume which no longer has to be filled with the temperature control medium in liquid form when filling the temperature control medium with temperature control agent. To the corresponding volume weight of the closed pores, therefore, the total weight of the temperature control can be reduced based on the Temperiermittelvolumen saved in this way.

In addition, it is advantageous if, in a tempering device according to the invention, the influencing particles are at least partially formed as hollow bodies and / or have a closed cavity. For example, completely formed as balls hollow body with a corresponding central cavity as influencing particles are possible. These may be plastic balls or even glass beads. In particular, this optimizes the reduction desire in weight, so that a maximum volume of sealed, air-entrapped, Gas-tight cavity is provided to reduce in this way by the displacement of Temperiermittelvolumen the corresponding total weight by the no longer required Temperiermittelvolumen. Of course, a wide variety of influencing particles can also be combined with one another in a temperature control device.

It is also advantageous if, in a tempering device according to the invention, the influencing particles have a mixed grain size. This is to be understood as meaning that the individual influencing particles have different grain sizes, that is to say different grain diameters or particle diameters. This also applies in particular to the fact that the individual influencing particles can have different geometric outer contours. A mixed grain size is to be regarded as particularly simple and inexpensive with regard to the production of the influencing particles. In this case, a screening in a coarse manner and with respect to desired upper limits and desired lower limits set the mixed grain size to be able to give a good predictability of the influence of the flow conditions in the temperature control in the influencing section.

Additionally or alternatively, it is conceivable that in a tempering device according to the invention the influencing particles have a sieved grain, 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 influencing particles to be aligned, 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 grain size, in which way and with what quantitative and also qualitative intensity the influencing of the flow conditions in the influencing section of the temperature control line can be made available.

Further advantages can be achieved if, in a tempering device according to the invention, the influencing particles are distributed in the influencing section over the entire flow cross section, in particular form a flow resistance over the entire flow cross section. While basically a cross-sectional constriction by introducing a corresponding cross-section narrowing bed of influencing particles, the inventive Advantages would be to provide an introduction over the entire flow cross-section with further advantages provided. Thus, influencing the flow conditions is provided at least over a defined length section of the influencing section on the complete flow width of the temperature control line. In a defined and / or tightest packing, the influencing particles preferably serve to be able to form a defined flow resistance in a qualitative and / or quantitative manner against the flow of the temperature control agent.

In addition, it is advantageous if, in the case of a tempering device according to the invention, the influencing particles have a conductivity and / or a transmissibility for acoustic and / or optical signals. In particular, when using data communication within the temperature control means, this brings advantages, since the resistance functionality of the influencing particles is reduced to influencing the flow ratio in the influencing 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.

In addition, it may be advantageous if, in a tempering device according to the invention, the influencing section has at least one section wall transversely or essentially transversely to the flow direction for stabilizing the position of the influencing particles. The position of the influencing particles is to be understood in particular as the amount of the bed of the influencing particles in the influencing section. Transverse to the flow direction is thus avoided in this way co-promoting the influencing 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 influencing section, the temperature control element inlet and / or the tempering medium outlet have a retaining device for retaining the influencing particles against co-conveying with the temperature control medium. Such a restraint device may also be referred to and understood as a filter device or grating device. It at least partially prevents leakage of the bed or individual influencing particles of the bed. In particular, in the direction of a pumping device for generating a flow of the temperature control, this retaining device can prevent penetration of the influencing particles in such a pump. Seen at the outlet and / or at the entrance of the temperature control, in particular in the flow direction, this retainer thus brings the advantages described with it.

It is also advantageous if, in a tempering device according to the invention, the influencing particles at least partially have a regular geometric shape, in particular are at least partially spherical or essentially spherical. Regular geometrical shapes allow a much more accurate prediction of the type and quantity of influence of the flow in the influencing section. If spherical shapes are chosen as a regular geometric shape for the influencing particles, an even better predictability is possible not only for the flow influencing itself, but also for the formation of the bed and the bulk porosity. The corresponding packing density and the defined free space, which is provided by the bulk porosity, can be predicted in this way exactly or substantially exactly. Completely closed areas can advantageously be avoided in this way.

A further subject matter of the present invention is an influencing insert for use in an influencing section of a temperature control device of a temperature control device of the present invention. Such an influencing insert has an insert chamber with a bed of influencing particles for influencing the flow of the temperature control medium through the influencing insert. Thus, an influencing insert 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. Such an influencing insert can, on the one hand, provide a modular production method during manufacture, and at the same time also allow retrofitting of existing tempering device. A further subject of the present invention is a method for the production of a tempering device according to the present invention, comprising the following steps:

 Introducing a bed of influencing particles into the temperature control line,

- Arranging the introduced influencing particles in the at least one influencing section for influencing the flow of the temperature control in the influencing section

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 trickling or pouring manner, if it is free flowing material in the influencing particles. With regard to the respective application, the introduction of the bed and the corresponding selection of the influencing particles make a preliminary definition and adjustment of the flow influencing by the selected influencing particles for the bed.

There may be advantages if, in a method according to the invention, the introduction of the influencing particles takes place through the tempering medium input and / or the temperature control medium output. Thus, an additional input for the introduction of the bed is avoided, so that waiving the complexity of the Temperiermittelvorrichtung 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 further advantageous if, in a method according to the invention, the influencing particles are introduced in the form of an influencing insert having the features of the present invention. The use of an influencing insert can take place in a prefabrication, so that during the final production of the tempering device and / or the battery device the influencing insert can be used as such without a risk of spillage or an increased outlay due to the handling of free-flowing influencing particles.

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,

2 shows a further embodiment of a battery device according to the invention,

3 shows an embodiment of an influencing particle,

4 shows a further embodiment of an influencing particle,

Fig. 5 shows a further embodiment of an inventive

 Temperature control and

Fig. 6 shows a further embodiment of an inventive

 T emperiervorrichtung.

Fig. 1 shows schematically in cross-section a temperature control device 10 for a battery device 200. In the temperature control 10 here a temperature control 20 is provided, which flow over a Temperiermitteleingang 22 temperature control and via a Temperiermittelausgang 24, the temperature control can flow out again. Not shown is a Temperiermittelpumpe which along the direction of the arrow provides the described Temperiermittelfluss available. Here, the temperature control line 20 has a flow cross section SQ, which is provided by the temperature control line 20 for the free flow of the temperature control medium. Within the tempering medium line 20, an influencing section 26 is now provided in direct proximity to individual battery cells of the battery device 200, in which a bed 30 of influencing particles 32 is arranged. In FIG. 1, these are spherical, regular influencing particles 32 equipped with a screened granulation. As soon as the temperature control medium flows into the free flow cross section SQ and reaches the influencing section 26, these influencing particles 32 arranged in bed 30 provide a flow resistance for the free flow Flow of the temperature control, so that the flow is changed at this point in terms of flow and flow rate. FIG. 2 shows schematically that the influencing with the flow particles 32 in the influencing section 26 can not necessarily be made available over the entire flow cross section SQ. Rather, a central channel or a laterally arranged channel remain free, but a surrounding part of the flow cross-section SQ can ensure the influencing described according to the invention by arranging the bed 30 of influencing particles 32.

FIGS. 3 and 4 show schematically how influencing particles 32 can advantageously be designed. In FIG. 3, a variant is shown, in which the influencing particles 32, made for example of glass or plastic, have a central cavity. FIG. 4 schematically shows a porous influencing particle 32 with a large number of closed pores. In both cases, the influencing particle 32 in a sealed manner to a closed gas volume, which leads to the fact that here by the gas displacement of Temperiermittelvolumen is provided, so that the total weight of the temperature control 10 is reduced by the no longer required Temperiermittelvolumen.

In Fig. 5 is shown schematically, as well as a non-sieved or mixed grain of the bed 30 of different influencing particles 32, here with different sizes, is possible. Also, in this embodiment according to FIG. 5, a retaining device 40 in the form of a filter insert is arranged on the front side and the rear side of the influencing insert 26 in order to prevent the individual influencing particles 32 from being conveyed together with the temperature control medium.

FIG. 6 schematically shows a solution, how the installation capability of the temperature control device 10 can be significantly simplified and improved by means of an interference insert 100 with an insert chamber 110 by a pre-assembly.

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 uqs zeenlis te Temperiervorrichtung

temperature control agent

Temperiermitteleingang

Temperiermittelausgang

control section

Abschnittswandung

fill

influencing particles

Retainer influencing 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 wherein the Temperiermittelleitung (20) at least one influencing section (26) having a bed (30) of influencing particles (32) for influencing the flow of the temperature control in the influencing section (26).

Second tempering device (10) according to claim 1, characterized in that the influencing particles (32) are at least partially formed as porous influencing particles (32), in particular with closed or substantially closed pores.

3. tempering device (10) according to any one of the preceding claims, characterized in that the influencing particles (32) are at least partially formed as a hollow body and / or have a closed cavity.

4. tempering device (10) according to any one of the preceding claims, characterized in that the influencing particles (32) have a mixed grain size.

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

6. tempering device (10) according to any one of the preceding claims, characterized in that the influencing particles (32) in the influencing section (26) over the entire flow cross-section (SQ) are distributed, in particular over the entire flow cross-section (SQ) form a Strömungswiederstand.

7. tempering device (10) according to any one of the preceding claims, characterized in that the influencing particles (32) have a conductivity and / or a transmissibility for acoustic and / or optical signals.

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

9. tempering device (10) according to any one of the preceding claims, characterized in that the influencing portion (26), the Temperiermitteleingang (22) and / or the Temperiermittelausgang (24) comprises a retaining device (40) for retaining the influencing particles (32) against a co-promotion with the temperature control.

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

1 1. influencing insert (100) for use in an influencing section (26) of a temperature control line (20) of a temperature control device (10) having the features of one of claims 1 to 10, comprising an insert chamber (110) having a bed (30) of influencing particles ( 32) for influencing the flow of the temperature control agent through the influencing insert (100).

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 influencing particles (32) into the temperature control line (20),

- Arranging the introduced influencing particles (32) in the at least one influencing section (26) for influencing the flow of the temperature control in the influencing section (26).

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

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