EP3673524A1 - Temperature-control device for battery modules, battery housing and method for controlling the temperature of battery modules - Google Patents

Abstract

The present invention relates to a temperature-control device for battery modules, having a housing top part and a housing bottom part connected to the housing top part, wherein an interior for receiving a temperature-control medium is arranged between the housing top part and the housing bottom part, and at least one flow-influencing element is arranged in the interior, which flow-influencing element extends starting from the housing top part to the housing bottom part and has one or more recesses for conducting the temperature-control medium.

Description

 DESCRIPTION

title

 Temperature control device for battery modules, battery case and

 Method for tempering battery modules

State of the art

The present invention relates to a tempering device for battery modules, having an upper housing part and a lower housing part connected to the housing lower part, wherein an inner space for receiving a tempering medium is arranged between the upper housing part and the lower housing part.

Such a temperature control device for battery modules is described for example in DE 10 2014 202 162 A1. This known temperature control device has a housing lower part, which is inseparably connected to an outer wall surface of a bottom of a battery housing. In this respect, the bottom of the battery housing forms the upper housing part of the temperature control. Between the upper housing part and the lower housing part, the temperature control device has an inner space in which a cooling liquid is accommodated.

In the known temperature control device, the lower housing part is formed as an upwardly open molding with channels forming formations. Thus, only by the connection of the lower housing part with the upper housing part is a closed line system created. However, it has proved to be disadvantageous that the production of such a housing lower part requires a relatively complex manufacturing process. In addition, the course of the flow, the pressure and the temperature of the cooling liquid can be adjusted only insufficiently in the channels thus formed. Disclosure of the invention

The object of the present invention is to allow an improved adjustability of the flow, the pressure and the temperature of the tempering medium without increasing the complexity of the upper housing part or housing lower part.

In order to achieve the object, a temperature control device for battery modules is proposed, having an upper housing part and a housing housing connected to the upper housing part. terteil, wherein between the upper housing part and the lower housing part, an interior space for receiving a tempering is arranged, wherein in the interior at least one Stromungsbeeinflussungselement is arranged, which extends from the upper housing part to the lower housing part and one or more recesses for passing the tempering.

Since the at least one flow-influencing element extends from the upper housing part to the lower housing part and has one or more recesses for passing the tempering medium, the course of the flow of the temperature-control medium in the interior of the temperature-control device can be adjusted by the flow-influencing element. In addition, it becomes possible, for example by the selection of suitable cross-sectional areas of the recess (s), to adjust the pressure of the temperature-control medium in the interior, in particular in a region of the interior adjacent to the flow-influencing element. These measures also have an effect on the temperature of the tempering medium. There are no changes to the upper housing part and the lower housing part required, so that the production of the upper housing part and the lower housing part can be done with the same effort.

The temperature control device preferably has at least one inlet for the temperature control medium which is flow-connected to the interior and at least one outlet for the temperature control medium which is flow-connected to the interior. The interior can be connected to other elements of a temperature control system, for example a conveyor for the temperature control medium, via the inlet and the outlet. Tempering of the battery modules can generally take place via the temperature control medium, which includes both the cooling and the heating of the battery modules. The tempering medium can be gaseous or liquid or can be added to further increase the heat transport properties with particles in the nanometer to micrometer range.

According to a preferred embodiment, the Stromungsbeeinflussungselement is elastically deformable, so that the Stromungsbeeinflussungselement can act as a spring element, can be damped against the movements of the upper housing part and the lower housing part against each other and / or torsional movements of the upper housing part or the lower housing part. In addition, it is possible for the housing upper part and / or the housing lower part to be reset after such a movement into an initial position by the elastic flow-influencing element. It is particularly preferred if the flow-influencing element is designed as a spiral spring, in particular as a curved spiral spring. is formed. Trained as a bending spring flow influencing element can bend elastically due to a force.

According to a structural embodiment, it is provided that the flow-influencing element is designed as a profiled sheet. The profile sheet can be folded or bent. For example, the profile sheet may have a C-shaped or V-shaped profile cross-section. Alternatively, the flow influencing element may be formed as a hollow profile component, i. with a closed profile. The hollow profile component preferably has a round, elliptical or rectangular profile cross section.

According to an advantageous embodiment of the invention, the flow influencing element has a main area, in which the one or more recesses are arranged and a connection area for connection of the Strömungsbeeinflus- sungselements on the upper housing part and / or the lower housing part, wherein the connection area angled relative to the main area or is bent. In this case, the connection region does not necessarily have to be angled over the entire length of the flow-influencing element. The angling can also take place only in sections in one direction or alternately in one direction and the other direction. The connection of the flow influencing element to the housing upper part and / or the housing lower part can be simplified by the angled connection region. For example, a welded connection, soldered connection, an adhesive connection or a combination of these connection types can be provided in the connection region. Furthermore, in the upper housing part and / or in the lower housing part grooves and / or other depressions, as well as raised formations in the interior be embossed, which allow a fixation of the flow influencing element and thereby dispense with welding, soldering, adhesive joints and their combination.

According to an advantageous embodiment of the invention, the flow influencing element to a flow area, in which at least one or an increased number of recesses is arranged and a separation region in which a small number of recesses, preferably no recesses, are arranged. The flow-influencing element may preferably have a plurality of flow areas and / or a plurality of separation areas. In this respect, it is possible to structure the interior of the temperature control device by the flow influencing element. For example, a flow area of the flow-influencing element can provide an inflow or outflow for the tempering medium to a region of the interior space. A separation area of the Flow-influencing element may represent a boundary or a wall of a region of the interior.

It has proved to be advantageous if the lower housing part has one or more, in particular trough-shaped, contact areas for contacting a respective battery module to be tempered, wherein the region of the inner space adjoining the contact area forms a tempering zone for the respective battery module. The temperature control medium contained in the tempering zone can be in thermal contact with the battery module to be tempered via the lower housing part. The temperature and flow rate of the tempering medium in the tempering zone is therefore decisive for setting a desired temperature of the battery module.

In this context, it is preferred if the flow-influencing element is arranged at the edge of a tempering zone in order to form an inlet or an outlet for the temperature-increasing medium to the tempering zone. The flow in the tempering zone, the pressure of the tempering medium in the tempering zone and the temperature can be adjusted via the flow influencing element.

According to an advantageous embodiment of the invention, the temperature control to one or more temperature control zones, which are arranged adjacent in a Temperierzonenreihe, wherein the flow influencing element is arranged to form an inlet or a drain for the Temperierzonenreihe at the edge of Temperierzonenreihe. Preferably no flow influencing elements are provided between the individual tempering zones so that the tempering medium can flow through the tempering zones of a tempering zone row unhindered. Alternatively, flow control elements may be arranged between the tempering zones of a tempering zone row if, for example, the tempering task makes it necessary to set a temperature profile and / or pressure profile and / or flow profile from the tempering zone to the tempering zone.

It is advantageous if the tempering device has several flow influencing elements with one or more recesses for passing the tempering medium, wherein a first of the flow influencing elements is arranged to form an inlet at the edge of a tempering zone or a Temperierzonenreihe and a second of the flow influencing elements to form a sequence on The edge of a tempering zone or a Temperierzonenreihe is arranged, wherein the second flow influencing element transversely, in particular perpendicular to the first Strömungsbeeinflussungsele- is arranged. Thus, with the first flow influencing element on one end face of a tempering zone row, an inlet can be formed through which the tempering medium flows in a controlled manner into the first tempering zone of the tempering zone row. A first part of the tempering medium can flow from the first tempering zone into a further tempering zone of the tempering zone row. A second part of the temperature-control medium can be led out of the first temperature-control zone through the second flow-influencing element, which is arranged in particular perpendicular to the first flow-influencing element. It is particularly advantageous if the tempering device has one or more tempering zone rows, and one or more flow influencing elements, which are arranged on the edge of a respective Temperierzonenreihe to form an inlet or a drain for each Temperierzonenreihe, wherein between two adjacent Temperierzonenreihen a flow channel for the tempering , in particular a drainage channel, is provided. Through the drainage channel, the temperature control medium flowing out of the temperature control zone rows can be discharged to a drain of the temperature control device.

A further subject of the invention is a battery housing with a plurality of module receptacles for battery modules, and with a tempering device for battery modules, in particular designed as a cover element or floor element for the receptacle, as described above.

Another object of the invention is a vehicle battery with such a Batte- riegehäuse, wherein in a module receptacle of the battery case, a battery module is arranged, which is in contact with the lower housing part or housing upper part of the temperature control device, in particular with a trough-shaped contact region of the lower housing part or the upper housing part. To solve the above-mentioned object, a method for tempering battery modules is further proposed with a temperature control, wherein the temperature control comprises an upper housing part and a housing upper part connected to the lower housing part, wherein between the upper housing part and the lower housing part, an interior is arranged in which received a temperature control is, wherein in the interior at least one flow influencing element is arranged, which extends from the upper housing part to the lower housing part and has one or more recesses through which the temperature control medium is passed. The battery housing, the vehicle battery and the method for controlling the temperature of battery modules have the same advantages as have already been described in connection with the temperature control device.

According to an advantageous embodiment of the method, the temperature control medium is passed through an inlet of the temperature control into the interior, in which a plurality of flow influencing elements are arranged, each having one or more recesses, wherein the temperature control by one or more first of the flow influencing elements respectively in a Temperierzonenreihe is passed from adjacent Temperierzonen. With such a configuration, the tempering of a plurality of battery modules can be made possible with the temperature control.

The temperature control medium from the temperature control zone row is preferably conducted through a respective second one of the flow influencing elements into an outlet of the temperature control device, the second flow influencing elements being arranged parallel to the first flow influencing elements.

Alternatively, it is preferred if the temperature control medium from the Temperierzonenreihe is passed through one or more second of the flow influencing elements in a flow channel, wherein the second flow influencing elements are arranged transversely, in particular perpendicular to the first flow influencing elements and the flow channel between two Temperierzonenreihen runs. In addition to the advantageous embodiments described above, the method and the battery housing can also be used alone or in combination with the advantageous features and configurations described in connection with the temperature control device. Further details, features and advantages of the invention will become apparent from the drawings, as well as from the following description of preferred embodiments with reference to the drawings. The drawings illustrate only exemplary embodiments of the invention, which do not limit the inventive concept. Brief description of the figures

1 shows a schematic sectional view through a tempering according to a first embodiment of the invention.

FIG. 2 shows a schematic sectional illustration through the tempering device from FIG. 1 along the section line II-II, wherein the tempering device is provided as a cover element of a battery housing. FIG. 3 shows a schematic sectional view through the tempering device from FIG. 1 along the section line III - III, wherein the tempering device is provided as a cover element of a battery housing.

4 shows a flow influencing element according to an embodiment of the invention in a perspective view.

FIGS. 5a-5d show various cross-sectional profiles of flow-influencing elements. FIG. 6 shows a schematic sectional illustration through a tempering device according to a second exemplary embodiment of the invention.

FIG. 7 shows a schematic sectional illustration through a temperature control device according to a third exemplary embodiment of the invention.

FIG. 8 shows a schematic sectional illustration through a temperature control device according to a fourth exemplary embodiment of the invention.

FIG. 9 shows a schematic sectional illustration through a temperature control device according to a fifth exemplary embodiment of the invention.

Embodiments of the invention

In the various figures, the same parts are always provided with the same reference numerals and are therefore usually named or mentioned only once in each case. FIG. 1 shows a schematic sectional view through a tempering device 2 according to the invention, which is designed as a cover element of a battery housing 1. The tempering device 2 has a substantially plate-shaped, but alternatively also structured housing upper part 3, which is not visible in the sectional view of Figure 1. Another component of the temperature control device 2 is a housing lower part 4, which is designed as an upwardly open, structured molded part. The lower housing part 4 is liquid-tightly connected to the upper housing part 3, for example, welded or glued, so that between the upper housing part 3 and the lower housing part 4, an inner space 5 is formed, which is flowed through by a liquid or gaseous Tempermedium.

As can also be seen from the illustration in FIG. 1, the lower housing part 4 is structured. In the housing lower part 4 according to the first exemplary embodiment, a plurality of trough-shaped contact regions 6 are designed for contacting a respective battery module 7 to be tempered. The region of the interior 5 adjoining the contact region 6 forms a tempering zone 5.1 for the respective battery module 7.

In order to allow an improved adjustability of the flow, the pressure and the temperature of the tempering medium, without increasing the complexity of the upper housing part 3 or lower housing part 4, one or more flow influencing elements 8, 8 'are arranged in the inner space 5 extending from the upper housing part 3 to the lower housing part 4 and have one or more recesses 9 for passing the tempering medium. In the housing lower part 4, one to several, here tannenformige, contact areas for contacting each ten tempering 5.1 are arranged adjacent in a Temperierzonenreihe 5.2. In this respect, the lower housing part 4 has one to several, here ten, trough-shaped contact regions 6, which are arranged in a row. According to the embodiment one to several, here three, Temperierzonenreihen 5.2 are provided. The tempering zone rows 5.2 have an identical number of tempering zones 5.1. Adjacent Temperierzonenreihen 5.2 are each separated by a flow channel 10.

2 shows a sectional view along the section line II-II in Figure 1 by a vehicle battery with a battery case 1, which comprises a plurality of module receptacles 1 1 for each battery module 7. The battery modules 7 are arranged resting on a bottom 12 of the battery housing 1. The battery modules 7 lie laterally on inner walls 13 designed as hollow carriers or on outer walls designed as hollow carriers. fertilize 14 of the battery case 1 at. The temperature control device 2 forms a cover element of the battery case 1. Alternatively, and not shown here, the temperature control device may form a bottom element of the battery case. It can be seen that the lower housing part 4 of the temperature control device 2 has one to several trough-shaped contact regions 6, which rest against the individual battery modules 7, in particular their upper sides. The contact areas 6 form insofar thermally interconnected Einzeltemperiereinheiten for corresponding battery modules 7. The lower housing part 4 may be formed of a plastic film or a metallic sheet or a combination of both as a sandwich or composite material. The lower housing part 4 has a certain flexibility, which makes it possible that the lower housing part 4 is pressed by the pressure of the temperature in the inner space 5 against the battery modules 7, so that the heat transfer between the battery modules 7 and the lower housing part 4 is improved. Between the trough-shaped contact regions 6 adjacent Temperierzonenreihen 5.2 a channel bottom 15 is arranged, which limits the flow channel 10. The channel bottom 15 is preferably formed of the same material as the lower housing part 4 and fixedly connected thereto.

As can further be seen from the illustration in FIG. 1, a first flow-influencing element 8 is arranged on a first end side of a tempering zone row 5.2, which extends from the upper housing part 3 to the lower housing part 4 and has one or more recesses 9. The first flow influencing elements 8 form an inlet for the respective tempering zone row 5.2. At a second end face of the tempering zone row 5.2 opposite the first end face, a second flow influencing element 8 'is arranged in each case. The first and second flow influencing elements 8, 8 'are thus aligned parallel to one another. The second flow influencing elements 8 'form a sequence of the respective tempering zone row 5.2. The tempering medium is passed through an inlet 16 of the temperature control 2 into the interior 5 and then through the first flow influencing elements 8 in one of the Temperierzonenreihen 5.2. From the Temperierzonenreihen 5.2 the Temperiermedium each exits through one of the second flow influencing elements 8 'and is passed into a flow channel 10, which runs between two Temperierzonenreihen 5.2. Inlet 16 and outlet 17 of the temperature control are arranged on the same side of the temperature control. Alternatively, the inlet or outlet can be arranged on another side of the temperature control device 2, for example the opposite or adjacent side or alternatively on the top and / or bottom, ie that the inlet and / or the outlet in the housing upper part 3 and / or housing base 4 are arranged. FIG. 3 shows a sectional view of the tempering device 2 along the section line III-III in FIG. 1, wherein the tempering device 2 is arranged as a cover element above the module receptacles 11 of a battery housing 1. The first flow influencing elements 8 extend over the complete height of the inner space 5 of the temperature control device 2. They are arranged substantially perpendicular to the main extension plane of the upper housing part 3 and the main extension plane of the lower housing part 4.

The flow-influencing elements have one or more recesses 9, which are formed as through-holes. Such recesses 9 can be made for example by complete punching of a metal sheet. Alternatively, the recesses may be produced by drilling or sawing or by laser cutting.

FIG. 4 shows by way of example a flow-influencing element 8, 8 'as can be used in a tempering device 2 according to the invention. The flow-influencing element 8. 8 'is designed in the manner of a bending spring and can, in particular be elastically deformed. It can be seen that the flow-influencing element 8, 8 'has a flow area in which at least one or an increased number of recesses 9 is arranged and a separation area in which a small number of recesses 9, preferably no recesses 9, are arranged. As an alternative to a plurality of recesses 9, the flow area can also be formed only by a recess, for example in the form of a single slot with a rectangular, wedge, trapezoidal or oval cross section.

According to the illustrated embodiment, the Stromungsbeeinflussungselement 8, 8 'is formed as a profiled sheet with a C-shaped profile cross section, see. FIG. 5a. Alternatively, the flow-influencing element 8, 8 'may have a C-shaped cross-section, for example as shown in Figure 5b.

In addition, the flow-influencing element may be formed as a hollow profile component, for example with an elliptical or rectangular profile cross-section, as shown in Figure 5c.

In order to facilitate the connection of the flow influencing element 8, 8 'to the upper housing part 3 and / or lower housing part 4, connecting areas 21 are preferably provided on the flow-influencing element 8, 8', cf. FIG. 5d. In this respect, the flow-influencing element 8, 8 'has a main area 18, in which the one or more recesses 9 are arranged and one adjacent to the main area Connection area 21. The connection region 21 is angled relative to the main region 18 or alternatively bent.

FIG. 6 shows a second exemplary embodiment of a temperature control device 2 according to the invention. On a first side of the temperature control device 2, an inlet 16 is provided. This tempering device 2 has one to several, here three, Temperierzonenreihen 5.2, 5.2 ', and one to several, here three, first flow influencing elements 8, the formation of an inlet for each Temperierzonenreihe 5.2, 5.2' at the edge of each Temperierzonenreihe 5.2, 5.2 'are arranged. Between two adjacent Temperierzonenreihen 5.2, 5.2 'is a flow channel for the temperature control, in particular a flow channel 10, 10', is provided. The drainage channel is closed on its side facing the inlet 16 of the temperature control device 2.

At the edges of the Temperierzonenreihen 5.2, which are facing a drain channel 10, a plurality of second flow influencing elements 8 'are arranged, which form a sequence of the respective tempering 5.1. The second flow-influencing elements 8 'are arranged transversely, in particular perpendicular, to the first flow-influencing elements 8. By the second flow influencing elements 8 ', the temperature control medium in one of the flow channels 10, 10' is passed. First drainage channels 10 run between each two Temperierzonenreihen 5.2, 5.2 '. Furthermore, second drainage channels 10 'are provided on the edge of the temperature control device 2, which are each adjacent only to a tempering zone row 5.2.

In the tempering device 2 according to the second exemplary embodiment, second flow influencing elements 8 'are arranged on both longitudinal sides of the tempering zone rows 5.2, 5.2' so that the tempering medium is directed into two adjacent flow channels 10, 10 'adjacent to the respective tempering zone row 5.2, 5.2' ,

According to a modification of this embodiment, it is provided that the tempering medium from the outer tempering zone rows 5.2 arranged at the edge of the tempering device 2 is conducted exclusively into the second flow channels 10 'arranged at the edge of the tempering device 2 and the tempering medium from the middle tempering zone row 5.2' into the two first drain channels 10 is passed. In such an embodiment, second flow influencing elements 8 'with recesses 9 are provided only on the outer sides of the outer Temperierzonenreihen 5.2 and the inner sides are closed relative to the respective first flow channel 10. A further modification of the embodiment provides that no outer drainage channels 10 'are present and the tempering medium from all Temperierzonenreihen 5.2, 5.2' is passed into the first flow channels 10. In such an embodiment, the outer sides of the outer Temperierzonenreihen 5.2 are closed and only on the inner side of the outer Temperierzonenreihen 5.2, second flow influencing elements 8 'with recesses 9 are arranged.

The drainage channels 10, 10 'open into a drain 17 of the temperature control device 2, which is arranged on a side opposite the inlet 16 of the temperature control device 2.

In deviation from the second exemplary embodiment, the temperature control device 2 may have a plurality of inlets 16 and / or a plurality of outlets 17. Inlets 16 and drains 17 can be arranged on the end faces of the temperature control device 2, as shown in FIG. 6, alternatively on adjacent sides or in the upper housing part 3, i. coming from above, and / or in the housing base 4, i. coming from below. In addition, flow-influencing elements with recesses may be arranged in the inlet 16 and / or in the outlet 17.

FIG. 7 shows a third exemplary embodiment of a temperature control device 2. In contrast to the first and second embodiments, in this tempering device 2, the inlet 16 is arranged in the middle of the housing lower part 4. The tempering zones 5.1 are arranged in a plurality of tempering zone rows 5.2 which, starting from an empty space 22 in the middle of the tempering device 2, extend outwards. The temperature control medium is therefore conducted from the inlet 16 through the temperature control zones 5.1 through the first flow influencing elements 8 arranged at the end faces of the temperature zones 5.2. The temperature control medium is removed by means of drains 17 which, opposite one another, are arranged on the sides of the tempering device 2. In this respect, the tempering zones 5.1 in the tempering device 2 according to the third embodiment flows through from the inside to the outside.

FIG. 8 shows a fourth exemplary embodiment of a temperature control device 2. This temperature control device 2 has an inlet 16 and a drain 17, which are arranged on opposite sides of the temperature control device 2. Furthermore, the tempering device 2 comprises tempering zone rows 5.2, 5.2 'with a different number of tempering zones 5.1. In the present case, the outer tempering zone rows 5.2 'have more tempering zones 5.1 than the inner tempering zone rows 5.2. In the area facing the inlet 16, located in front of the middle Temperierzonenreihe 5.2 a Arrangement a plurality of first flow influencing elements 8, which guide the temperature control both in the direction of the middle Temperierzonenreihe 5.2 and in the direction of the two adjacent Temperierzonenreihen 5.2 '. FIG. 9 shows a fifth exemplary embodiment of a temperature control device 2. The arrangement of the temperature control zones 5.1 and Temperierzonenreihen 5.2 corresponds to the arrangement of the third embodiment, see. In contrast to the third exemplary embodiment, first flow-influencing elements 8 are arranged around the inlet 16 in such a way that they guide the temperature-control medium starting from the inlet 16 into four different spatial directions. The flow influencing elements 8 are arranged on a rectangular, in particular square, circumferential line which surrounds the inlet concentrically.

All of the above-described temperature control devices 2 for battery modules comprise an upper housing part 3 and a lower housing part 4 connected to the upper housing part 3, wherein an inner space 5 for receiving a tempering medium is arranged between the upper housing part 3 and the lower housing part 4. In the interior 5 at least one flow influencing element 8, 8 'is arranged, which extends from the housing upper part 3 to the lower housing part 4 and one or more recesses 9 for passing the tempering medium has. The upper housing part 3 and the lower housing part 4 may be formed as shaped sheet metal parts. Alternatively, it is possible to form the upper housing part 3 and / or the lower housing part 4 as a plastic part or molded part made of a plastic film or a combination of both as a sandwich or composite material. These moldings may additionally have a coating, for example for corrosion and / or abrasion purposes.

LIST OF REFERENCE NUMBERS

1 battery case

 2 tempering device

 3 housing upper part

 4 housing base

 5 interior

 5.1 tempering zone

 5.2, 5.2 'Temperierzonenreihe

 6 contact area

 7 battery module

 8, 8 'flow influencing element

9 recess

 10 drainage channel

 1 1 module holder

 12 floor

 13 inner wall

 14 outer wall

 15 channel bottom

 16 inlet

 17 process

 18 main area

 19 flow range

 20 separation area

 21 connection area

 22 empty space

Claims

tempering

(2) for battery modules (7), with an upper housing part (3) and one with the upper housing part (3) connected to the lower housing part (4), wherein between the upper housing part

(3) and the lower housing part

(4) an interior space (5) for receiving a temperature control medium is arranged,

characterized in that

in the interior

(5) at least one Stromungsbeeinflussungselement (8, 8 ') is arranged, which extends from the upper housing part (3) to the lower housing part (4) and one or more recesses (9) for passing the tempering medium.

Temperature control device (2) according to claim 1, characterized in that the Stromungsbeeinflussungselement (8, 8 ') is elastically deformable, in particular in the manner of a spiral spring.

Temperature control device (2) according to one of the preceding claims, characterized in that the flow-influencing element (8, 8 ') is designed as a profiled sheet or hollow profile component.

Temperature control device (2) according to one of the preceding claims, characterized in that the Stromungsbeeinflussungselement (8, 8 ') has a main region (18) in which the one or more recesses (9) are arranged and a connection region (21) for connecting the Strömungsbeeinflussungsele- element (8, 8 ') on the upper housing part (3) and / or the lower housing part (4), wherein the connection region (21) relative to the main region (18) is angled or bent.

Temperature control device (2) according to one of the preceding claims, characterized in that the flow-influencing element (8, 8 ') has a flow-through region (19) in which at least one or an increased number of recesses (9) is arranged and a separation region (20). , in which a small number of recesses (9), preferably no recesses (9), are arranged.

Temperature control device (2) according to any one of the preceding claims, characterized in that the housing lower part (4) one or more, in particular vane nenförmige, contact areas (6) for contacting each one to be tempered Battery module (7), wherein the contact area

(6) adjacent region of the interior (5) forms a tempering zone (5.1) for the respective battery module (7).

7. tempering device (2) according to claim 6, characterized in that the flow-influencing element (8, 8 ') at the edge of one or more tempering zones (5.1) is arranged to an inlet or a drain for the temperature control to the tempering (5.1 ) to build.

8. tempering device (2) according to any one of claims 6 or 7, characterized in that the temperature control device (2) one or more tempering (5.1), which are adjacent in a Temperierzonenreihe (5.2, 5.2 ') are arranged, wherein the flow influencing element ( 8, 8 ') to form an inlet or a drain for the Temperierzonenreihe (5.2, 5.2') at the edge of Temperierzonenreihe (5.2, 5.2 ') is arranged.

9. tempering device (2) according to one of claims 6 to 8, characterized by a plurality of flow influencing elements (8, 8 ') with one or more recesses (9) for passing the tempering, wherein a first of the flow influencing elements (8) for forming a Inlet at the edge of a tempering zone (5.1) or a Temperierzonenreihe (5.2, 5.2 ') is arranged and a second of the flow influencing elements (8') to form a drain at the edge of a tempering zone (5.1) or a Temperierzonenreihe (5.2, 5.2 ') is arranged , wherein the second flow-influencing element (8 ') is arranged transversely, in particular perpendicular to the first flow-influencing element (8).

10. tempering device (2) according to any one of claims 8 or 9, characterized by one or more Temperierzonenreihen (5.2, 5.2 '), and one or more flow-influencing elements (8, 8'), for forming an inlet or a drain for in each case a Temperierzonenreihe (5.2, 5.2 ') at the edge of a Temperierzonenreihe (5.2, 5.2') are arranged, between two adjacent Temperierzonenreihen (5.2, 5.2 ') a flow channel for the temperature control, in particular a flow channel (10) is provided.

1 1. Battery housing (1) with a plurality of module receptacles (1 1) for battery modules (7), characterized by a temperature control device (2) designed in particular as a cover element or base element for the module receptacles (1 1) according to one of the preceding claims. forthcoming claims.

12. Vehicle battery with a battery housing (1) according to claim 1 1, wherein in a module receptacle (1 1) of the battery case (1) a battery module (7) is arranged, in contact with the housing lower part (4) or upper housing part (3) Temperature control device (2) is.

13. A method for controlling the temperature of battery modules (7) with a temperature control device (2) comprising an upper housing part (3) and a housing upper part (3) connected to the lower housing part (4), wherein between the upper housing part (3) and the

Housing bottom part (4) an interior space (5) is arranged, in which a temperature control medium is accommodated,

 characterized in that

 in the interior (5) at least one flow influencing element (8, 8 ') is arranged, which extends from the upper housing part (3) to the lower housing part (4) and one or more recesses (9), through which Temperature control medium is passed.

14. The method according to claim 13, characterized in that the temperature control medium is passed through an inlet (16) of the temperature control device (2) in the interior (5), in which a plurality of flow influencing elements (8, 8 ') are arranged, each one or have a plurality of recesses (9), wherein the temperature control is guided by one or more first of the flow influencing elements (8) in each case in a Temperierzonenreihe (5.2, 5.2 ') from adjacent temperature control zones (5.1).

15. The method according to claim 14, characterized in that the temperature control from the Temperierzonenreihe (5.2, 5.2 ') by a second of the flow influencing elements (8') in a sequence (17) of the temperature control (2) is passed, wherein the second flow influencing elements (8 ') parallel to the first

Flow influencing elements (8) are arranged.

16. The method according to claim 14, characterized in that the tempering medium from the Temperierzonenreihe (5. 2, 5.2 ') by one or more second of the flow influencing elements (8') in a discharge channel (10) is passed, wherein the second flow influencing elements (8 ') transversely in particular perpendicular to the first flow influencing elements (8) are arranged and the drainage channel (10) between two Temperierzonenreihen (5.2, 5.2 ') extends.