FR3068773A1 - DEVICE FOR THERMALLY REGULATING BATTERY MODULES - Google Patents

Abstract

The present invention relates to a device for thermal regulation (1), in particular for cooling, of at least one electrical energy storage element (3). According to the invention, the thermal regulation device (1) comprises a heating plate (1). base (10) on which are secured at least two stamped plates (11) juxtaposed, said base plate (10) or said stamped plates (11) being intended to come into thermal contact with said at least one energy storage element electric (3), each of said at least two stamped plates (11) delimiting, with said base plate (10), a conduit (12) for circulating the coolant comprising two channels (121, 122) of spiral shape interleaved one in the other, said channels (121, 122) being fluidly connected to each other in the center of the double spiral, said thermal regulating device (1) comprising a single inlet (E) and a single outlet ( S) of coolant rel each of the conduits (12) for circulating the coolant.

Description

Device for thermal regulation of battery modules.

1. Field of the invention

The invention relates to the field of thermal regulation of batteries, and more particularly of batteries fitted to a motor vehicle, the propulsion of which is supplied in whole or in part by an electric motor.

More specifically, the invention relates to the field of thermal regulation devices for battery modules.

2. Prior art

In the field of electric and hybrid vehicles, the electrical energy storage cells are linked together so as to create an electric generator of desired voltage and capacity, and positioned in a battery module (called module in the following) .

When the vehicle is in operation, the battery modules - generally placed at the level of the vehicle floor - may be subjected to temperature variations which can in some cases cause them to be damaged or even destroyed.

Consequently, the thermal regulation of the modules is essential in order, on the one hand, to maintain them in good condition and, on the other hand, to ensure the reliability, the autonomy, and the performance of the vehicle.

Car manufacturers are also seeking today to provide more powerful electric or hybrid vehicles with increased electric range.

To this end, an increasing number of modules are onboard in vehicles.

Thus, the modules cover an increasingly substantial surface area of the vehicle floor and they sometimes even form the bottom of the vehicle body.

The devices intended to regulate the temperature of these modules must therefore extend over equivalent surfaces to optimize the functioning of the modules.

A thermal regulation device is conventionally positioned directly in contact with the modules, or indirectly in contact with the modules.

Such a thermal regulation device is traversed by a heat transfer fluid and performs the heating and / or cooling functions of the modules.

The heat transfer fluid can thus absorb the heat emitted by each module in order to cool it or, if necessary, it can provide it with heat if the temperature of the module is insufficient for its proper functioning.

Two technologies for thermal regulation devices for the battery modules of a vehicle are known, namely tube technology and plate technology.

In the first technology, the thermal regulation device consists of a plurality of tubes comprising fluid circulation channels, the ends of which are connected by manifolds so as to form a circulation circuit for a heat transfer fluid.

This tube regulation device technology is relatively simple to implement but has a major drawback in that it does not make it possible to create complex fluid circulation circuits adapted to the new size constraints of the batteries.

In the second technology, the thermal regulation device consists of a flat plate (conventionally called "base plate" in English) on which is crimped or riveted a plate that has been stamped (conventionally called "channel plate" in English) to form a hollow imprint with a fluid inlet and outlet.

Once the flat and stamped plates are assembled one on the other, the hollow imprint forms a conduit or circuit in which the heat transfer fluid can circulate from a fluid inlet to a fluid outlet.

In a variant, the flat plate is replaced by a stamped plate.

This second technology makes it possible to create, by the use of stamped plates, circulation circuits for the heat transfer fluid of complex shapes, which make it possible to homogenize the temperature of the modules.

However, a drawback of this plate technology lies in the fact that the production of deep-drawn plates is complex and expensive because it requires the use of large presses.

To solve this problem, it has been proposed to associate a thermal plate regulation device with each of the battery modules.

A drawback of this solution lies in the fact that the multiple thermal regulation devices must be connected together to allow the distribution of the heat transfer fluid, which complicates the assembly and increases the risks of leakage of the heat transfer fluid.

3. Summary of the invention

The object of the present invention is to solve these problems of the state of the art and proposes a device for thermal regulation, in particular for cooling, of at least one element for storing electrical energy (called module in the detailed description which follows) which, according to the invention, comprises a base plate on which are joined at least two stamped plates juxtaposed, said base plate or said stamped plates being intended to come into thermal contact with said at least one storage element of electrical energy, each of said at least two stamped plates delimiting, with said base plate, a conduit for circulation of the heat-transfer fluid comprising two spiral-shaped channels nested one inside the other, said channels being fluidly connected to each other other at the center of the double spiral, said thermal regulation device comprising a single inlet and a single outlet for heat transfer fluid linked to each of the heat transfer fluid circulation conduits.

The invention thus provides a device for thermal regulation of large battery modules of a hybrid or electric vehicle, which implements a single base plate on which are secured a plurality of stamped plates juxtaposed.

Each battery module is made up of several electrical cells.

Once the stamped plates are assembled on the base plate, the assembly forms a single circuit in which a heat transfer fluid can flow from a fluid inlet to a fluid outlet.

Each stamped plate forms with the base plate a heat exchange plate in which is formed a duct having a double spiral shape.

The thermal regulation device is thus composed of several double spiral conduits connected together in the same fluid circuit, which does not require connection pipes.

A double spiral shape of the circulation duct in each stamped plate allows:

an improved heat exchange between the incoming fluid and the fluid leaving each heat exchange plate, and

- a homogeneous distribution of the temperature over the entire surface of the heat exchange plate and thus improves the heat exchange with the battery over the entire surface of the latter.

In addition, with a conduit formed of two spiral channels nested one inside the other, with equivalent size of heat exchange plate, the heat exchange surface between the battery and the heat transfer fluid is increased, which increases the efficiency of the heat exchange plate.

The spiral shapes of the channels also allow a good definition of the walls of the duct and thus allows a good distribution of the mass of the battery on the heat exchange plate which is an advantage to have a good coefficient of heat exchange between these two elements.

The base plate, which is a cut metal sheet, can have dimensions equal to those of the battery while each stamped metal plate of the device can have dimensions equal to those of a module or group of modules (it can therefore be provided a stamped plate per module or group of modules to be thermally regulated).

This solution makes it possible to easily manufacture, at a relatively low cost, large and complex shape thermal regulation devices suitable for batteries having large sizes.

The solution of the invention therefore does not require a large press to stamp the plates, which reduces the manufacturing costs of the device of the invention.

Because it is produced by assembling a plurality of stamped plates on a base plate, the thermal regulation device of the invention is modular and can be adapted to the size and dimension of the battery modules to be cooled.

According to a particular aspect of the invention, the surfaces of the base plate are flat.

Thus, the base plate is a simple sheet, for example aluminum, which is only cut to the desired shape and dimensions (it is therefore not stamped).

The manufacturing cost of such a base plate is therefore relatively low.

Preferably, it is the base plate of the thermal regulation device which is in contact (direct or indirect) with the electrical energy storage elements, and which constitutes the heat exchange plate.

Indeed, it is simpler and less expensive to ensure the flatness of the base plate than that of the stamped plates.

According to another aspect of the invention, each conduit has the shape of a double rectangular spiral.

This rectangular spiral type profile optimizes the surface of the heat exchange plate as much as possible and provides the largest possible exchange surface.

According to one aspect of the device according to the invention, the heat transfer fluid inlets of the plurality of heat exchange plates are connected to a common heat transfer fluid inlet and the heat transfer fluid outlets of the plurality of heat exchange plates are connected to a common heat transfer fluid outlet.

This type of connection allows temperature uniformity at each heat exchange plate of the device and on the whole of the exchange surface of said device.

According to another particular aspect of the invention, each conduit has at least three distinct and spaced zones of circulation of the countercurrent heat transfer fluid, intended to be placed opposite the electrical energy storage elements to be thermally regulated.

According to another particular aspect of the invention, each of said at least three zones comprises three portions of the two channels, two portions allowing circulation of the heat transfer fluid in a first direction and a portion allowing circulation of the heat transfer fluid in the opposite direction, with against the current.

According to another particular aspect of the invention, the width of said at least three zones is substantially equal to the width of the electrical energy storage elements to be thermally regulated.

According to another particular aspect of the invention, at least a portion of the conduits comprises at least one restriction of passage of the heat transfer fluid intended to balance the flow rates of heat transfer fluid in the conduits.

According to another particular aspect of the invention, one of said stamped plates is connected on the one hand to an input connector allowing the supply of coolant to said thermal regulation device, and on the other hand to an output connector allowing the evacuation of the heat transfer fluid from the thermal regulation device.

According to another particular aspect of the invention, said base plate, said at least two stamped plates and said input and output connectors are secured by soldering.

According to another particular aspect of the invention, the surfaces of the base plate are flat.

According to another particular aspect of the invention, the base plate and said at least two stamped plates are joined by brazing.

The stamped plates are brazed together and brazed on the base plate.

This inexpensive joining technique makes it possible to provide the device of the invention with high mechanical strength.

According to yet another particular aspect of the invention, said at least two stamped plates partially overlap.

This aspect makes it possible, on the one hand, to facilitate the brazing of all the plates together and, on the other hand, to seal the circulation circuit of the heat transfer fluid in the device.

This also makes it possible to dispense with the use of conduits for connecting the plates stamped together.

Thus, the assembly is simplified and the risks of leakage of the heat transfer fluid are reduced.

The thermal regulation device therefore takes the form of a row of juxtaposed stamped plates.

This modular structure makes it possible to simplify the assembly of the device while adapting its shape to that of the battery and its dimensions to the number of modules constituting the battery.

According to one aspect of the invention, each stamped plate is intended to regulate the temperature of a module or a group of modules.

According to another particular aspect of the invention, different circulation circuits for the heat transfer fluid can be configured in each stamped plate.

According to another particular aspect of the invention, the base plate has a shape corresponding to the shape of the battery containing the elements (or modules) for storing electrical energy.

According to yet another aspect of the invention, the base plate constitutes the bottom of the vehicle body in which the thermal regulation device is implemented.

4. Figures

Other characteristics and advantages will appear more clearly on reading the following detailed description of particular embodiments of the invention, given by way of simple illustrative and nonlimiting examples, and of the appended drawings, among which:

Figure 1 is a top view of modules of a vehicle battery and a thermal regulation device of these modules according to a first embodiment of the invention;

FIG. 2 schematically illustrates the direction of circulation of the heat transfer fluid within the thermal regulation device of FIG. 1;

Figure 3 is a top view of a thermal regulation device of battery modules according to a second embodiment of the invention;

Figure 4 is a detailed view of the connection between two stamped plates of a thermal regulation device according to the invention.

5. Detailed description of embodiments

Identical elements in the different figures have the same references.

Figure 1 is a top view of modules of a large battery of a hybrid or electric vehicle and a thermal regulation device of these modules according to a first embodiment of the invention.

The thermal regulation device 1 comprises a base plate 10 on which a plurality of stamped plates 11, in this case three in this example, are joined.

The base plate 10, partially visible in FIG. 4, is a flat sheet metal cut by laser, for example, whose shape and dimensions correspond to those of the battery to be thermally regulated.

In this example, the base plate 10 is rectangular and is in direct or indirect thermal contact with several electrical energy storage elements, or modules, referenced 3.

On this base plate 10 are therefore joined three stamped plates 11 juxtaposed.

Each pressed plate 11 forms with the base plate 10 a heat exchange plate, the heat exchange plates being intended to thermally regulate the modules 3.

In this case, nine modules 3 are arranged opposite each stamped plate 11 in FIG. 1.

As illustrated in FIG. 2, each of the three stamped plates 11 delimits, with the base plate 10, a duct 12 for circulation of the heat transfer fluid.

The circulation of the heat transfer fluid is only illustrated for the stamped plate 11 located on the left, closest to the inlet E and outlet S of the heat transfer fluid in the thermal regulation device 1.

Each conduit 12 comprises two channels 121, 122 of spiral shape nested one inside the other, the channels 121, 122 being fluidly connected to each other at the center C of the double spiral.

Furthermore, the thermal regulation device 1 comprises a single input connected to an input connector E and a single output connected to an output connector S of heat transfer fluid, the single input and the single output being connected to each of the three conduits 12 for circulation of the heat transfer fluid.

In other words, the heat transfer fluid inlets of the plurality of heat exchange plates are connected to a common heat transfer fluid inlet or inlet, and the heat transfer fluid outlets of the plurality of heat exchange plates are connected to a common heat transfer fluid outlet or outlet.

In the example illustrated, the input E and output S connectors of the heat transfer fluid are arranged on the same lateral edge of the thermal regulation device 1.

Thus, in summary, the thermal regulation device 1 comprises a single circuit for circulation of the heat-transfer fluid consisting of three separate conduits 12, each conduit 12 comprising two channels 121, 122 of spiral shape nested one inside the other, the channels 121, 122 being fluidly connected to each other at the center C of the double spiral.

The base plate 10 is preferably made of aluminum so as to allow the brazing of the stamped plates 11 on the latter.

The stamped plates 11, preferably made of aluminum and clad, are therefore intended to be joined by brazing to the base plate 10.

They are stamped so as to form internal walls, to define conduits 12 for circulation of a heat transfer fluid, or cooling conduits, when they are mounted on the base plate 10.

The heat transfer fluid circulation duct of each heat exchange plate, consisting of a portion of the base plate 10 and a stamped plate 11, comprises two channels 121, 122 of spiral shape nested one in the other, the channels 121, 122 being fluidly connected to each other at the center C of the double spiral.

The channels 121, 122 of spiral shape are nested one inside the other in order to allow a homogeneous distribution of the temperature on all the surface of the heat exchange plate and thus improves the heat exchanges with the battery on the whole. from the surface of the latter.

It is noted that the spiral of the first channel 121 approaches more and more the central point C in the direction of circulation of the fluid, at the same time that it rotates around. From this central point C, the spiral of the second channel 122 moves further and further away from the central point C, at the same time as it rotates around.

Such a design of the heat exchange plate also allows improved heat exchange between the fluid entering and the fluid leaving the heat exchange plate.

The cold incoming fluid is understood as the fluid circulating in the first channel 121 from the inlet opening to the center C of the double spiral of the heat exchange plate (in dashed lines in FIG. 2), while that the hot leaving fluid is understood as the fluid circulating in the second channel 122, in fluid communication with the first channel 121, from the center C of the double spiral towards the outlet of the heat exchange plate (dotted on the figure 2).

In addition, with a spiral shape of the channels, with an equivalent heat exchange plate size, the heat exchange surface between the battery and the heat transfer fluid is increased, which increases the efficiency of the heat exchange.

The spiral shape also allows a good definition of the walls of the channels 121, 122 and thus allows a good distribution of the mass of the battery on the heat exchange plate which is an advantage to have a good coefficient of heat exchange between these two elements.

The conduits 12 each have a shape of a double rectangular spiral here, which optimizes the surface of the heat exchange plate as much as possible and provides the largest possible exchange surface.

The connections between the stamped plates 11 and the base plate 10 are sealed, as is the connection of the stamped plates 11 between them.

The pressed plates 11 juxtaposed form a first half-shell and the base plate 10 a second half-shell, the assembled half-shells forming the thermal regulation device 1.

This makes it possible to obtain a thermal regulation device 1 which can have a complex shape and relatively large dimensions.

Indeed, the use of stamped plates 11, on a single flat base plate 10, allows great modularity of the thermal regulation device 1 so that the latter can be easily adapted to multiple configurations, more or less complex, of a battery.

Thus, for this embodiment, only a die for a stamping press is necessary to manufacture the thermal regulation device 1.

It is of course understood that other types of stamped plates, having different shapes and / or fluid circulation circuits, can be implemented according to the configuration of the battery on board the motor vehicle.

In all cases, the invention makes it possible to be free from the constraints relating to the size of the presses making the large stamped plates since the device of the invention no longer implements a single large stamped plate but a plurality of stamped plates whose dimensions are reduced and substantially identical to those of a module or a group of modules.

The invention therefore makes it possible to reduce the costs of manufacturing thermal regulation devices for modules or elements for storing electrical energy.

It also makes it possible to provide a modular thermal regulation device, easily adaptable to all shapes and dimensions of the battery.

FIG. 3 is a top view of a device for thermal regulation of battery modules according to a second embodiment of the invention.

On the base plate 10 are joined two stamped plates 11 juxtaposed, the stamped plates 11 being intended to come into thermal contact with several electrical energy storage elements, or modules, not illustrated, so as to thermally regulate the latter.

The heat transfer fluid circulation duct of each heat exchange plate, consisting of a portion of the base plate 10 and a stamped plate 11, comprises two channels 121, 122 of spiral shape nested one in the other, the channels 121, 122 being fluidly connected to each other at the center C of the double spiral.

In the embodiments illustrated in Figures 1 to 3, there are for each heat exchange plate three zones Zl, Z2, Z3 distinct and spaced from the circulation of the fluid against the current.

Each of these zones Zl, Z2, Z3 comprises three portions of the channels 121, 122 disposed under each module 3 (FIG. 1), thus making it possible to have two portions of channels with a circulation of the heat-transfer fluid in a first direction and a portion of channel with circulation in the opposite direction or second direction.

Thus, in FIG. 3, the zones ZI and Z3 each have alternately a circulation of the heat transfer fluid in a first direction, a second direction and the first direction, and zone Z2 alternately present a circulation of the heat transfer fluid in the second direction, the first sense and second sense.

The cooling duct 12 consisting of the two channels 121, 122 comprises at least once a circulation of the heat transfer fluid against the current (first direction / second direction) under a module.

However, it is possible to provide three counter-currents (Figures 2 or 3) or even more (four counter-currents, for example).

In the examples presented, the inlet connector E and the outlet connector S of the cooling duct 12 are on opposite edges of the thermal regulation device 1, as are the supply ducts 123 and evacuation ducts 124 (FIG. 3).

The width and height of the cooling duct 12 (and therefore of the channels 121, 122) are determined in order to optimize the pressure drop of the circuit, according to the flow rates and temperatures of the heat transfer fluid imposed.

The length of the cooling duct 12, and therefore the number of countercurrents, are linked to this pressure drop constraint.

Likewise, the width and the height of the supply conduit 123 are determined in order to optimize the pressure drop of the circuit, according to the flow rates and temperatures of the heat transfer fluid imposed.

By way of example, the feed channel 123 can have a width ranging from 5 mm to 60 mm, and a height from 1 mm to 10 mm.

Balancing the heat transfer fluid flows in the cooling conduits 12 in at least part of the stamped plates 11 can be implemented by means of local restrictions, in order to force the heat transfer fluid to go to the last stamped plate 11 relative to the input E of the circuit. These restrictions are positioned:

either only at the inlet of the cooling duct 12, or at the inlet and at the outlet of the cooling duct 12.

In FIG. 2, four restrictions 125 obtained by local stamping of the stamped plates 11 are shown diagrammatically and are located near the inlet and the outlet of the conduits 12 of the two heat exchange plates closest to the inlet connectors E and output S.

Depending on the pressure drop levels to be compensated in the stamped plates 11, it is also possible to envisage balancing by acting on the sections of heat transfer fluid passage in the cooling conduits 12, in order to force the heat transfer fluid to go up to the last stamped plate 11 relative to the input of the circuit of the thermal regulation device 1.

As indicated above, the stamped plates 11 of the thermal regulation device 1, whatever their types, are brazed to the base plate 10.

In order to guarantee the tightness of the circulation circuit of the heat transfer fluid in the thermal regulation device 1 after brazing, the stamped plates 11 adjacent can partially overlap.

Figure 4, which is a detail view of Figure 3, illustrates such an overlap between two stamped plates 11 adjacent.

This overlapping one on the other of the stamped plates 11 makes it possible to ensure a joint plane suitable for brazing and to guarantee, once the plates are bonded by brazing, the tightness of the circulation circuit of the heat transfer fluid within the device thermal regulation 1.

This technique makes it possible to dispense with the implementation of additional connection conduits and seals between the stamped plates, which, in known manner, increase the risks of leakage of the heat transfer fluid.

This technique according to which the stamped plates 11 are brazed together and on the base plate 10 makes it possible to eliminate, or at the very least limit, the risk of leakage of the heat transfer fluid from the thermal regulation device 1.

These embodiments are given by way of simple illustrative and nonlimiting examples.

It is easily understood that the number of stamped plates and their shape can vary without departing from the general principle of the invention.

The base plate 10 is obtained by a single cutting operation.

The base plate 10 has a thickness adapted to withstand the mechanical forces undergone during its brazing with the stamped plates 11 and during the operation of the thermal regulation device 1.

In particular, the base plate 10 must have a thickness allowing the flatness of the surfaces of the base plate 10 to be maintained under the pressure of the heat transfer fluid circulating in the thermal regulation device 1 during its operation.

Preferably, it is the base plate 10 which is in direct or indirect contact with the modules so as to reduce the flatness constraints of the stamped plates.

In fact, it is simpler and less expensive to manufacture a flat base plate with optimal flatness than stamped plates with equivalent flatness.

In order to facilitate the brazing operations, the base plate 10 is not clad while one face of the stamped plates is clad.

Alternatively, it is the base plate 10 which is clad while the stamped plates 11 are not. In this scenario, the stamped plates 11 are joined together and on the base plate 10 by a supply of external material, by means of a clade strip, for example.

In another variant, none of the plates is cladée. The joining is then carried out by a bonding process.

The bonding process is not limited to the type of adhesive (epoxy, silicone, polyurethane, mono / two-component), nor to a hardening process (called curing in English) at room temperature or at a predetermined temperature.

The input E and output S connectors of the heat transfer fluid in the thermal regulation device 1 are preferably not clad in order to guarantee an optimal surface state at the level of the connectors.

In a variant, these connectors are clad and a resumption of machining can be carried out in order to guarantee an optimal surface state.

The location of the input E and output S connectors of the heat transfer fluid in the thermal regulation device 1 is not limited to the examples described above.

The connectors for the inlet and outlet of the heat transfer fluid may, without limitation, be:

in the plane of joint between the flat base plate and the stamped plates;

perpendicular to the stamped plates, the openings being formed in one or two stamped plates;

perpendicular to the base plate, the openings being formed in the latter;

at any angle to the base plate or to the stamped plate or plates, the openings being formed in one or the other of the plates.

The thermal regulation device according to the invention makes it possible to cool and, if necessary, to heat the modules.

In a particular embodiment, the thermal regulation device 1 is composed of stamped plates having different cooling circuits (length, hydraulic section, number of counter-currents under the modules).

By way of example, the zones Zl, Z2, Z3 distinct for circulation of the fluid against the current can comprise respectively three, five and three portions of channels.

In another particular embodiment, the thermal regulation device 1 is composed of stamped plates having different supply circuits, in particular in terms of hydraulic section, thus making it possible to reduce the size of the thermal regulation device 1 in areas where the available space is less.

In another particular embodiment, the inlet connector E and the outlet connector S of heat transfer fluid of the thermal regulation device 1 are on opposite sides (right / left).

This has the advantage of facilitating the balancing of the fluid flow rates in the different stamped plates, provided that the cooling conduits are identical or close in terms of pressure drop.

In another particular embodiment, the input connector E and the output connector S of the cooling circuit are on the same side of one of the stamped plates.

This implies that the inlet supply duct is on one side of the flat plate, and that the outlet exhaust duct is on the opposite side (or vice versa).

In another particular embodiment, the channels of the conduits can be split in two lengthwise through an internal wall (the coolant circulating in the same direction on either side of the wall internal) so as to optimize the mechanical strength of the thermal regulation device 1.

Furthermore, the base plate may have recesses intended for the passage of screws, reinforcements or its lightening (in order to optimize its mass).

Claims (10)

1. A thermal regulation device (1), in particular for cooling, of at least one electrical energy storage element (3), characterized in that it comprises a base plate (10) on which are secured at least two stamped plates (11) juxtaposed, said base plate (10) or said stamped plates (11) being intended to come into thermal contact with said at least one electrical energy storage element (3), and in that each said at least two stamped plates (11) delimits, with said base plate (10), a conduit (12) for circulation of the heat-transfer fluid comprising two channels (121, 122) of spiral shape nested one inside the other, said channels (121, 122) being fluidly connected to each other at the center of the double spiral, said thermal regulation device (1) comprising a single inlet (E) and a single outlet (S) of heat transfer fluid connected to each of the fluid circulation conduits (12) e coolant. 2. A thermal regulation device (1) according to claim 1, characterized in that each conduit (12) has the shape of a double rectangular spiral. 3. A thermal regulation device (1) according to claim 1 or 2, characterized in that each conduit (12) has at least three distinct zones (Zl, Z2, Z3) spaced apart from circulation of the heat-transfer fluid against the current, intended to be placed opposite the electrical energy storage elements to be thermally regulated. 4. A thermal regulation device (1) according to claim 3, characterized in that each of said at least three zones (Zl, Z2, Z3) comprises three portions of the two channels (121, 122), two portions allowing circulation of the fluid heat transfer fluid in a first direction and a portion allowing circulation of the heat transfer fluid in the opposite direction, against the current. 5. A thermal regulation device (1) according to claim 3 or 4, characterized in that the width of said at least three zones (Zl, Z2, Z3) is substantially equal to the width of the electrical energy storage elements to be regulated thermally. 6. A thermal regulation device (1) according to one of claims 1 to 5, characterized in that said at least two stamped plates (11) partially overlap. 7. A thermal regulation device (1) according to one of claims 1 to 6, characterized in that at least a portion of the conduits (12) comprises at least one restriction (125) for the passage of the heat transfer fluid intended to balance the heat transfer fluid flows in the conduits (12). 8. A thermal regulation device (1) according to one of claims 1 to 7, characterized in that one of said stamped plates (11) is connected on the one hand to an input connector (E) allowing the supply in heat transfer fluid from said thermal regulation device (1), and on the other hand to an outlet connector (S) allowing the evacuation of the heat transfer fluid from the thermal regulation device (1) 9. A thermal regulation device (1) according to claim 8, characterized in that said base plate (10), said at least two stamped plates (11) and said input and output connectors are secured by soldering. 10. A thermal regulation device (1) according to one of claims 1 to 9, characterized in that the surfaces of the base plate (10) are planar.