DE102019003534A1 - Temperature control device for an energy store - Google Patents

Abstract

The invention relates to a temperature control device (10) for an energy store (102), with at least one thermoelectric device (14) which has at least a first and a second heat exchange surface (16, 18), with a second heat exchange surface (18) is arranged so that the thermoelectric device (14) is in convective heat exchange via the second heat exchange surface (18) with a heat exchange fluid (22) passed past the thermoelectric device (14).

Description

The invention relates to a temperature control device for an energy store, with at least one thermoelectric device, which has at least a first and a second heat exchange surface, wherein a second heat exchange surface is arranged so that the thermoelectric device via the second heat exchange surface with a the thermoelectric device passed heat exchange fluid is in convective heat exchange.

The invention also relates to an energy storage system with an energy storage device comprising a plurality of electrically conductively connected storage cells, and a temperature control device for temperature control of the energy storage device, the storage cells of the energy storage device being arranged in one or more storage cell areas of the temperature control device.

In addition, the invention relates to a vehicle with an electric drive and an energy storage system which is set up to provide the electric drive with electrical energy.

Modern rechargeable energy storage devices must be operated within a comparatively narrow temperature range in order to avoid a drop in performance and a loss of capacity. In addition, rechargeable energy storage devices can be damaged by operation outside of an intended temperature range. The service life and the charging times of rechargeable energy stores are also dependent to a considerable extent on the operating temperature.

In order to be able to operate rechargeable energy stores within the intended temperature range, temperature control devices are used, via which the energy stores can be cooled and / or heated during operation.

Temperature control devices known from the prior art rely exclusively on convection temperature control, in which the rechargeable energy storage device is subjected to a fluid flow in order to implement cooling or heating of the energy storage device. Since comparatively large amounts of heat have to be transported away during the temperature control of high-performance energy storage devices, corresponding temperature control solutions require the use of powerful fans. Such fans usually have a high energy consumption and cause a high level of noise during operation, which means that exclusive convection temperature control is ruled out for some areas of application. In addition, with a corresponding temperature control of an energy store, a temperature gradient arises along the storage cells of the energy store, since the fluid flow undergoes a temperature change along the storage cells to be tempered.

In an alternative temperature control approach, thermoelectric devices are used whose heat exchange surfaces are to be connected to the energy store in a thermally conductive manner in order to implement contact temperature control. In this context, it is known to guide a discharge air flow along the opposite heat exchange surfaces of the thermoelectric devices in order to carry out heat removal from the thermoelectric devices. Since the coefficient of performance of corresponding thermoelectric devices is usually less than 1, the heat to be dissipated at the thermoelectric devices is usually higher than the heat to be dissipated by the energy store. In order to generate suitable exhaust air flows, extremely powerful fans are therefore also required, which involve high energy consumption and a high noise level. In the case of contact temperature control with thermoelectric devices, there are also often local temperature control differences at the storage cells, since the size of the contact area between the individual storage cells and the thermoelectric devices sometimes deviates from one another.

The object on which the invention is based is thus to improve the temperature control of energy stores without increasing the noise level generated during the storage temperature control.

The object is achieved by a temperature control device of the type mentioned above, a first heat exchange surface being arranged in such a way that the thermoelectric device is in conductive heat exchange with the energy store via the first heat exchange surface, and the second heat exchange surface is also arranged in this way that at least part of the heat exchange fluid passed there was previously additionally in convective heat exchange with the energy store.

The invention makes use of the knowledge that through the combination of convection temperature control and contact temperature control, energy storage devices can be temperature controlled in a particularly energy-efficient and low-noise manner.

The heat exchange fluid can be a gas or a gas mixture, for example air, or a liquid. In the heating mode of the temperature control device, the first heat exchange surface is one Heating surface and the second heat exchange surface a heat supply surface. In the cooling mode of the temperature control device, the first heat exchange surface is a cooling surface and the second heat exchange surface is a heat dissipation surface. The energy store can be a rechargeable and / or electrochemical energy store.

In a preferred embodiment of the temperature control device according to the invention, a conductive heat exchange can be made possible directly by direct contact between the components involved or indirectly with the interposition of thermally conductive elements such as metal layers or thermally conductive pastes. Alternatively or additionally, a convective heat exchange can be made possible directly through direct contact of the heat exchange fluid with the components involved or indirectly with the interposition of heat exchangers, cooling plates, heat distribution plates, surface enlargers or components to reduce thermal contact resistance or corrosion.

In a further development of the temperature control device according to the invention, one or more thermoelectric devices are set up to be connected to at least one storage cell of the energy store in a thermally conductive manner by the first heat exchange surface. The temperature control device preferably comprises one or more heat exchange bodies and the second heat exchange surface of the one or more thermoelectric devices is in each case connected to a heat exchange body in a thermally conductive manner.

In another embodiment, the temperature control device according to the invention comprises one or more storage cell areas which are set up to accommodate storage cells of the energy store. The temperature control device preferably has a fluid guide device which is set up to guide the heat exchange fluid for heat exchange through a storage cell area and along a heat exchange body and / or through a heat exchange body. In contrast to the temperature control devices known in the prior art, the heat exchange fluid is first passed through the storage cell area for convection temperature control of the storage cells, before heat is exchanged with the second heat exchange surface of the one or more thermoelectric devices, with the one or more thermoelectric devices ensure additional contact temperature control on the energy storage device. The combined convection and contact temperature control of the temperature control device according to the invention also avoids or at least significantly reduces a temperature gradient along the storage cells of the energy store to be temperature controlled. Any temperature differences in the storage cells due to different contact area sizes between the storage cells and the one or more thermoelectric devices are compensated or at least significantly reduced by the heat exchange fluid that is passed through the one or more storage cell areas.

The first heat exchange surface of the thermoelectric device can be connected to the storage cells of the energy store in a thermally conductive manner via a heat distribution device. The heat distribution device can comprise one or more heat distribution plates and / or thermal paste.

In particular, the temperature control device is designed as a temperature control unit into which the storage cells of the energy store can be used or integrated. In particular, the temperature control device has an outer housing, the one or more storage cell areas for the storage cells of the energy store being arranged within the outer housing. The one or more thermoelectric devices can be designed as Peltier elements or each comprise one or more Peltier elements. The temperature control device can be set up to cool and / or heat the energy store.

In a preferred embodiment of the temperature control device according to the invention, the fluid supply device has a distribution channel which has a fluid inlet opening and one or more fluid outlet openings. The heat exchange fluid can be introduced into a storage cell area via the one or more fluid outlet openings of the distribution channel. The distribution channel is preferably set up to divide the heat exchange fluid into a plurality of individual fluid flows. The distribution channel of the fluid guide device can be designed, for example, as a plastic part, in particular as a plastic injection-molded part.

In a further preferred embodiment of the temperature control device according to the invention, the fluid inlet opening is formed on an end face of the distribution channel. Alternatively or additionally, one or more fluid outlet openings are formed on at least one side surface of the distributor channel. The one or more fluid outlet openings are preferably formed by recesses in the side wall of the distribution channel. The distributor channel is preferably designed and arranged in such a way that the heat exchange fluid flows into the distributor channel in the longitudinal direction through the fluid inlet opening. Preferably, the distribution channel is designed and arranged such that the heat exchange fluid in Transverse direction through which one or more fluid outlet openings flows out of the distributor channel.

A temperature control device according to the invention is also preferred in which the distributor channel has opposite fluid outlet openings, via which the heat exchange fluid can be introduced into storage cell areas which are arranged on opposite sides of the distributor channel. The fluid outlet openings are preferably formed on opposite side surfaces of the distribution channel and / or are formed by recesses in opposite side surfaces of the distribution channel. The distribution channel is preferably arranged between two storage cell areas of the temperature control device.

In another preferred embodiment of the temperature control device according to the invention, the fluid guide device has at least one deflecting body, which is set up to convey the heat exchange fluid flowing out of a storage cell area to one or more heat exchange bodies. The inflow direction of the at least one deflecting body preferably deviates from the outflow direction of the at least one deflecting body, so that a flow deflection is implemented within the at least one deflecting body. The at least one deflection body can be designed as a plastic part, in particular as a plastic injection-molded part.

In another preferred embodiment of the temperature control device according to the invention, the at least one deflecting body is arranged on a lateral outside of a storage cell area. The distribution channel of the fluid guide device is preferably arranged on an opposite outside of the storage cell area. The heat exchange fluid flowing out of the distributor channel can thus enter the deflecting body after flowing through the storage cell area and be deflected by the deflecting body in the direction of one or more heat exchange bodies.

A temperature control device according to the invention is also advantageous in which the at least one deflecting body has a plurality of fluid outlet channels, the fluid outlet channels each being set up to convey the heat exchange fluid to a heat exchange body. The at least one deflecting body preferably has a fluid inlet opening and a plurality of fluid outlet openings, the fluid outlet openings being provided by the fluid outlet channels.

In another embodiment, the temperature control device according to the invention has a first outer deflecting body and a second outer deflecting body. The first external deflecting body is preferably designed to feed the heat exchange fluid flowing out of a first storage cell area to one or more heat exchange bodies which are connected in a thermally conductive manner to the second heat exchange surface of one or more thermoelectric devices, this being one or more thermoelectric devices for this purpose are designed to be connected with their first heat exchange surface in a thermally conductive manner to memory cells within the first memory cell region. The second external deflecting body is preferably set up to feed the heat exchange fluid flowing out of a second storage cell area to one or more heat exchange bodies which are connected in a thermally conductive manner to the second heat exchange surface of one or more thermoelectric devices, this being one or more thermoelectric devices are designed to be connected with their first heat exchange surface in a thermally conductive manner to memory cells within the second memory cell region. The first storage cell area and the second storage cell area are preferably arranged between the two outer deflecting bodies. The distribution channel is preferably arranged between the two outer deflecting bodies.

In a development of the temperature control device according to the invention, the fluid guide device has a collecting channel which has one or more fluid inlet openings and a fluid outlet opening. The collecting channel is arranged behind the one or more heat exchange bodies in the flow direction and is designed to guide the heat exchange fluid out of the temperature control device. The collecting channel is preferably set up to merge several individual fluid flows back together to form a main fluid flow in order to guide this main fluid flow out of the temperature control device. The collecting channel of the fluid guide device is preferably designed as a plastic part, in particular as a plastic injection-molded part.

In another preferred embodiment of the temperature control device according to the invention, the one or more fluid inlet openings are formed at least on one side surface of the collecting channel. The collecting channel is preferably designed and arranged in such a way that the heat exchange fluid flows into the collecting channel in the transverse direction through the one or more fluid inlet openings. In addition, the collecting channel is preferably designed and arranged such that the heat exchange fluid in Flows longitudinally through the collecting channel in the direction of the fluid outlet opening of the collecting channel.

In a further development of the temperature control device according to the invention, the collecting duct has opposite fluid inlet openings, via which the heat exchange fluid can be introduced from the heat exchange bodies into the collecting duct, which are arranged on opposite sides of the collecting duct. The collecting channel is preferably arranged between two groups of heat exchange bodies. The first group of heat exchange bodies is preferably assigned to a first group of thermoelectric devices. The first group of thermoelectric devices is preferably assigned to a first memory cell area. The second group of heat exchange bodies is preferably assigned to a second group of thermoelectric devices. The second group of thermoelectric devices is preferably assigned to a second memory cell area.

In a preferred embodiment of the temperature control device according to the invention, the one or more heat exchange bodies each have one or more heat exchange fins, one or more heat exchange fins and / or one or more heat exchange pins. Heat exchange fins, heat exchange fins and heat exchange pins increase the surface over which a heat exchange with the heat exchange fluid can take place, so that the heat exchange between the heat exchange fluid and the one or more heat exchange bodies is increased. The one or more heat exchange bodies can be formed from a metal or a metal alloy.

A temperature control device according to the invention is also advantageous which has at least one flow generator which is set up to generate a flow of the heat exchange fluid. The at least one flow generator can be positioned within the outer housing, on the outer housing or away from the outer housing of the temperature control device. The at least one flow generator can be designed as a fan or as a pump.

In another preferred embodiment, the temperature control device according to the invention has a control device which is set up to control the one or more thermoelectric devices and the at least one flow generator. The control device is preferably set up to selectively initiate simultaneous or time-delayed operation of the one or more thermoelectric devices and of the at least one flow generator. Thus, when there is little need for temperature control, only contact temperature control by the one or more thermoelectric devices or only convection temperature control via the heat exchange fluid can be initiated. If there is an increased need for temperature control, contact temperature control and convection temperature control can then be combined with one another.

The object on which the invention is based is further achieved by an energy storage system of the type mentioned at the beginning, the temperature control device of the energy storage system according to the invention being designed according to one of the embodiments described above. With regard to the advantages and modifications of the energy storage system according to the invention, reference is made to the advantages and modifications of the temperature control device according to the invention. The storage cells of the energy store can be electrochemical storage cells, for example lithium-ion cells.

In a preferred embodiment of the energy storage system according to the invention, the energy store comprises a first group of storage cells and a second group of storage cells, the first group of storage cells being arranged in a first storage cell area of the temperature control device and the second group of storage cells being arranged in a second storage cell area of the temperature control device. The first memory cell area and the second memory cell area are preferably arranged at a distance from one another.

In another preferred embodiment of the energy storage system according to the invention, a distribution channel of the fluid supply device of the temperature control device is arranged between the first group of storage cells and the second group of storage cells and / or between the first storage cell area and / or the second storage cell area. In particular, a first deflecting body of the fluid guide device is arranged on a lateral outside of the first group of storage cells. A second deflecting body of the fluid guide device is preferably arranged on a lateral outside of the second group of storage cells.

The object on which the invention is based is also achieved by a vehicle of the type mentioned at the outset, the energy storage system of the vehicle according to the invention being designed according to one of the embodiments described above or comprising a temperature control device according to one of the embodiments described above. With regard to the advantages and modifications of the vehicle according to the invention, reference is made to Advantages and modifications of the energy storage system according to the invention and reference is made to the advantages and modifications of the temperature control device according to the invention.

• 1 ein Ausführungsbeispiel des erfindungsgemäßen Energiespeichersystems in einer schematischen Darstellung;
• 2 Speicherzellen eines Energiespeichers eines erfindungsgemäßen Energiespeichersystems in einer schematischen Darstellung;
• 3 Wärmetauschkörper einer erfindungsgemäßen Temperiereinrichtung in einer schematischen Darstellung;
• 4 ein weiteres Ausführungsbeispiel des erfindungsgemäßen Energiespeichersystems in einer teilweisen Explosionsdarstellung;
• 5 das in der 4 abgebildete Energiespeichersystem in einer weiteren Explosionsdarstellung;
• 6 die Strömungswege eines Wärmeaustausch-Fluids durch ein erfindungsgemäßes Energiespeichersystem; und
• 7 einen Verteilerkanal einer erfindungsgemäßen Temperiereinrichtung in einer perspektivischen Darstellung.

Preferred embodiments of the invention are explained and described in more detail below with reference to the accompanying drawings. Show:

• 1 an embodiment of the energy storage system according to the invention in a schematic representation;
• 2 Storage cells of an energy store of an energy storage system according to the invention in a schematic representation;
• 3 Heat exchange body of a temperature control device according to the invention in a schematic representation;
• 4th a further embodiment of the energy storage system according to the invention in a partial exploded view;
• 5 that in the 4th energy storage system shown in a further exploded view;
• 6th the flow paths of a heat exchange fluid through an energy storage system according to the invention; and
• 7th a distribution channel of a temperature control device according to the invention in a perspective view.

The 1 shows an energy storage system 100 , which can be used, for example, to provide electrical energy to an electrical drive of a vehicle. The energy storage system 100 has an energy store 102 on, which comprises a plurality of electrically conductive interconnected memory cells. The storage cells of the energy store 102 are within a memory cell area 12 a temperature control device 10 positioned. The temperature control device 10 serves to control the temperature of the energy store 102 .

The temperature control device 10 has a thermoelectric device 14th on, which comprises a plurality of Peltier elements. The thermoelectric device 14th has a first heat exchange surface 16 and a second heat exchange surface 18th . The first heat exchange surface 16 and the second heat exchange surface 18th are on opposite sides of the thermoelectric device 14th arranged. The first heat exchange surface 16 the thermoelectric device 14th is thermally conductive with the storage cells of the energy store via a heat distribution device 102 connected. The second heat exchange surface 18th the thermoelectric device 14th is thermally conductive with a heat exchanger body 20th the temperature control device 10 connected. The heat exchanger body 20th has heat exchange fins and is designed to be flowable through.

The temperature control device 10 also has a fluid guide device 24 on, via which a flow of a heat exchange fluid generated by a flow generator 22nd for heat exchange initially through the storage cell area 12 and then through the heat exchanger body 20th is controllable.

With the temperature control device shown 10 consequently, a contact temperature control of the energy store 102 via the thermoelectric device 14th with a convection temperature control of the energy storage 102 through the heat exchange fluid 22nd combined.

The 2 shows two groups of memory cells 104a , 104b an energy storage 102 , which are in two spaced apart memory cell areas 12a , 12b a temperature control device 10 are arranged. The first group of memory cells 104a is in a first memory cell area 12a the temperature control device 10 arranged. The second group of memory cells 104b is in a second memory cell area 12b the temperature control device 10 arranged. Between the first group of memory cells 104a and the second group of memory cells 104b and between the first memory cell area 12a and the second memory cell area 12b is a distribution channel 26th the fluid guide device 24 the temperature control device 10 arranged. That in the distribution channel 26th incoming heat exchange fluid 22nd is through opposite fluid outlet opening in the side walls of the distribution channel 26th into the memory cell areas 12a , 12b initiated. Within the memory cell areas 12a , 12b heat exchange takes place between the storage cells 104a , 104b and that in the memory cell areas 12a , 12b introduced heat exchange fluid 22nd .

After flowing through the memory cell areas 12a , 12b the heat exchange fluid arrives 22nd in external deflectors 28a , 28b the temperature control device 10 . The deflection body 28a , 28b derive this from the memory cell areas 12a , 12b outflowing heat exchange fluid 22nd several heat exchangers 20a , 20b to.

The 3 shows the multiple heat exchanger bodies 20a , 20b , which of the out of the deflectors 28a , 28b outflowing heat exchange fluid 22nd are flowed through. The heat exchanger body 20a , 20b are thermally conductive with the second heat exchange surface 18th of thermoelectric devices 14th connected. So worry the heat exchanger body 20a , 20b for a heat exchange between the second heat exchange surface 18th of thermoelectric devices 14th and the heat exchange fluid 22nd .

In the direction of flow behind the heat exchanger bodies 20a , 20b is a collecting channel 30th arranged, within which the heat exchange fluid 22nd collects to this collected from the temperature control 10 to be able to lead out.

The 4th and the 5 show an energy storage system 100 with an energy store 102 , which contains several electrically conductively connected memory cells 104a , 104b includes. For temperature control of the energy storage 102 includes the energy storage system 100 also a temperature control device 10 . The memory cells 104a , 104b of the energy storage 102 are in memory cell areas 12a , 12b the temperature control device 10 arranged.

The fluid guide device 24 the temperature control device 10 includes a manifold 26th , two deflectors 28a , 28b and a collecting channel 30th .

The distribution channel 26th includes a fluid inlet port 38 and a plurality of fluid outlet ports 40a , 40b . That via the fluid inlet port 38 incoming heat exchange fluid 22nd is through the manifold 26th divided into several individual fluid flows. The heat exchange fluid is via the fluid outlet openings 40a , 40b of the distribution channel 26th into the memory cell areas 12a , 12b initiated. The fluid inlet port 38 is at the front of the distribution channel 26th educated. The fluid outlet openings 40a , 40b are arranged opposite one another so that the heat exchange fluid enters the storage cell areas 12a , 12b can be introduced, which on opposite sides of the distribution channel 26th are arranged. On the outside of the storage cells 104a , 104b are covers 32a , 32b arranged, which prevent the heat exchange fluid in the area of the storage cell areas 12a , 12b from the energy storage system 100 escapes.

The deflection body 28a , 28b are on the lateral outsides of the memory cell areas 12a , 12b arranged. The deflection body 28a , 28b each have several fluid outlet channels 48a , 48b on, the fluid outlet channels 48a , 48b the heat exchange fluid in a heat exchange body 20a , 20b initiate.

The deflector 28a is set up to do this from the memory cell area 12a outflowing heat exchange fluid several heat exchange bodies 20a forward. The heat exchanger body 20a are thermally conductive with the second heat exchange surface 18th of several thermoelectric devices 14th connected. These thermoelectric devices 14th are with their first heat exchange surface 16 Thermally conductive with the storage cells via a heat distribution device 104a within the memory cell area 12a connected. The deflector 28b is set up to do this from the memory cell area 12b outflowing heat exchange fluid several heat exchange bodies 20b forward. The heat exchanger body 20b are thermally conductive with the second heat exchange surface 18th of several thermoelectric devices 14th connected. These thermoelectric devices 14th are with their first heat exchange surface 16 Thermally conductive with the storage cells via a heat distribution device 104b within the memory cell area 12b connected.

The collecting channel 30th has multiple fluid inlet ports 42a , 42b and a fluid outlet port 44 on. The collecting channel 30th is behind the heat exchanger bodies in the direction of flow 20a , 20b arranged and set up for this, the heat exchange fluid from the temperature control device 10 to lead out. The fluid inlet openings 42a , 42b are on opposite sides of the collecting duct 30th educated. Via the opposite fluid inlet openings 42a , 42b is the heat exchange fluid from the heat exchange bodies 20a , 20b into the collecting duct 30th initiable.

The heat exchanger body 20a , 20b each have heat exchange fins, the heat exchange fins of a cover 36 are surrounded. The cover 36 is a U-shaped body. Between the thermoelectric devices 14th , which are designed as Peltier elements, and the memory cells 104a , 104b are heat distribution devices 46 arranged, which in the present case are designed as heat distribution plates.

The 6th shows that the heat exchange fluid 22nd first in the longitudinal direction through the fluid inlet opening 38 in the distribution channel 26th flows in. Through the distribution channel 26th becomes the heat exchange fluid 22nd on several individual fluid flows 22nd divided which in the transverse direction through the plurality of fluid outlet openings 40a , 40b from the distribution channel 26th pour out. About the deflector 28a , 28b becomes the heat exchange fluid 22nd deflected twice, so that the inflow direction and the outflow direction into or out of the baffles 28a , 28b run in the opposite direction. That in the deflector 28a , 28b incoming heat exchange fluid 22nd has an outward flow direction. That from the baffles 28a , 28b outflowing heat exchange fluid 22nd has an inward flow direction. Thus, the heat exchange fluid flows 22nd in the transverse direction into the collecting channel 30th one. After merging the individual fluid flows 22nd within the common channel 30th the heat exchange fluid flows 22nd in the longitudinal direction through the collecting channel 30th and from the collecting duct 30th out. In the collecting duct 30th a further fluid flow can be introduced at the end, which has already flowed, for example, through another upstream temperature control device.

The 7th shows that the fluid outlet openings 40a , 40b of the distribution channel 26th can have different sizes. Opposite fluid outlet openings 40a , 40b are, however, made the same size in this exemplary embodiment. The size of the fluid outlet openings 40a , 40b increases in the flow direction of the heat exchange fluid 22nd from.

List of reference symbols

10

Temperature control

12, 12a, 12b

Memory cell areas

14th

thermoelectric devices

16

first heat exchange surface

18th

second heat exchange surface

20, 20a, 20b

Heat exchanger body

22nd

Heat exchange fluid

24

Fluid supply device

26th

Distribution channel

28a, 28b

Deflection body

30th

Collecting duct

32a, 32b

Covers

36

cover

38

Fluid inlet port

40a, 40b

Fluid outlet openings

42a, 42b

Fluid inlet openings

44

Fluid outlet port

46

Heat distribution device

48a, 48b

Fluid outlet channels

100

Energy storage system

102

Energy storage

104a, 104b

Storage cells

Claims (17)

Temperature control device (10) for an energy store (102), with - at least one thermoelectric device (14) which has at least a first and a second heat exchange surface (16, 18), a second heat exchange surface (18) being arranged in this way that the thermoelectric device (14) is in convective heat exchange via the second heat exchange surface (18) with a heat exchange fluid (22) guided past the thermoelectric device (14), characterized in that - a first heat exchange surface (16 ) is arranged in such a way that the thermoelectric device (14) is in conductive heat exchange with the energy store via the first heat exchange surface (16), and - the second heat exchange surface (18) is also arranged so that at least a part of the there heat exchange fluid (22) carried past has also previously been in convective heat exchange with the energy store (102). Temperature control device (10) Claim 1 , characterized in that - a conductive heat exchange can be made possible directly through direct contact between the components involved or indirectly with the interposition of thermally conductive elements such as metal layers or thermally conductive pastes; and / or - a convective heat exchange can be made possible directly through direct contact of the heat exchange fluid (22) with the components involved or indirectly with the interposition of heat exchangers, cooling plates, heat distribution plates, surface enlargers or components to reduce thermal transfer resistance or corrosion. Temperature control device (10) Claim 1 or 2 , characterized in that one or more thermoelectric devices (14) are set up to be connected to at least one storage cell (104a, 104b) of the energy store (102) by means of the first heat exchange surface (16) in a thermally conductive manner; wherein the temperature control device (10) comprises one or more heat exchange bodies (20, 20a, 20b) and the second heat exchange surface (18) of the one or more thermoelectric devices (14) is each connected to a heat exchange body (20, 20a, 20b) in a thermally conductive manner is. Temperature control device (10) according to one of the preceding claims, with - one or more storage cell areas (12, 12a, 12b) which are set up to accommodate storage cells (104a, 104b) of the energy store (102); marked by a Fluid conveying device (24) which is designed to carry the heat exchange fluid (22) for heat exchange through a storage cell area (12, 12a, 12b) and along a heat exchange body (20, 20a, 20b) and / or through a heat exchange body (20, 20a , 20b). Temperature control device (10) Claim 4 , characterized in that the fluid guide device (24) has a distribution channel (26) which has a fluid inlet opening (38) and one or more fluid outlet openings (40a, 40b), wherein the heat exchange fluid (22) via the one or more fluid outlet openings (40a, 40b) can be introduced into a memory cell area (12, 12a, 12b). Temperature control device (10) Claim 5 , characterized in that the fluid inlet opening (38) is formed on an end face of the distribution channel (26) and / or one or more fluid outlet openings (40a, 40b) are formed on at least one side surface of the distribution channel (26). Temperature control device (10) Claim 5 or 6th , characterized in that the distribution channel (26) has opposite fluid outlet openings (40a, 40b) via which the heat exchange fluid (22) can be introduced into storage cell areas (12, 12a, 12b) which are arranged on opposite sides of the distribution channel (26) are. Temperature control device (10) according to one of the Claims 4 to 7th , characterized in that the fluid guide device (24) has at least one deflecting body (28a, 28b) which is designed to transfer the heat exchange fluid (22) flowing out of a storage cell area (12, 12a, 12b) to one or more heat exchange bodies (20, 20a, 20b). Temperature control device (10) Claim 8 , characterized in that the at least one deflection body (28a, 28b) is arranged on a lateral outside of a memory cell region (12, 12a, 12b). Temperature control device (10) Claim 9 , characterized in that the at least one deflection body (28a, 28b) has a plurality of fluid outlet channels (48a, 48b), the fluid outlet channels (48a, 48b) each being designed to convey the heat exchange fluid (22) to a heat exchange body (20, 20a, 20b). Temperature control device (10) according to one of the Claims 4 to 10 , characterized by - a first external deflecting body (28a) which is set up to feed the heat exchange fluid (22) flowing out of a first storage cell area (12a) to one or more heat exchange bodies (20a) which conductively with the second heat exchange surface ( 18) are connected by one or more thermoelectric devices (14), which are designed to be connected with their first heat exchange surface (16) in a thermally conductive manner to memory cells (104a) within the first memory cell area (12a), and a second outside Deflection body (28b) which is set up to direct the heat exchange fluid (22) flowing out of a second storage cell area (12b) to one or more heat exchange bodies (20b) which conductively with the second heat exchange surface (18) from one or more thermoelectric Means (14) are connected, which are set up with their first heat e-exchange surface (16) to be connected in a thermally conductive manner to memory cells (104b) within the second memory cell area (12b). Temperature control device (10) according to one of the Claims 4 to 11 , characterized in that the fluid guide device (24) has a collecting channel (30) which has one or more fluid inlet openings (42a, 42b) and a fluid outlet opening (44), the collecting channel (30) downstream of the one or more heat exchange bodies in the direction of flow (20, 20a, 20b) is arranged and is set up to lead the heat exchange fluid (22) out of the temperature control device (10). Temperature control device (10) Claim 12 , characterized in that the one or more fluid inlet openings (42a, 42b) are formed on at least one side surface of the collecting channel (30). Temperature control device (10) Claim 12 or 13 , characterized in that the collecting channel (30) has opposite fluid inlet openings (42a, 42b) via which the heat exchange fluid (22) from the heat exchange bodies (20, 20a, 20b) can be introduced into the collecting channel (30) which are located on opposite sides Sides of the collecting channel (30) are arranged. Temperature control device (10) according to one of the Claims 3 to 14th , characterized in that the one or more heat exchange bodies (20, 20a, 20b) each have one or more heat exchange fins, one or more heat exchange fins and / or one or more heat exchange pins. Temperature control device (10) according to one of the preceding claims, characterized by at least one flow generator which is adapted to generate a flow of the heat exchange fluid (22). Temperature control device (10) Claim 16 , characterized by a control device which is set up to control the one or more thermoelectric devices (14) and the at least one flow generator, the control device preferably being set up to selectively operate the one or more thermoelectric devices at the same time or at different times To cause devices (14) and the at least one flow generator.

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