FR3137752A1 - Thermal regulation device, in particular cooling - Google Patents

Abstract

Thermal regulation device, in particular for cooling The invention relates to a thermal regulation device (1), in particular for cooling, for a component (101) capable of releasing heat during its operation, in particular for an energy storage module electrochemical, this device comprising a circulation network (2) for a heat transfer fluid, this network comprising: - at least two channels (3) each provided with at least one first obstacle of the fluid facing an inlet (5) of the channel, obstacle which defines an obstructed portion of cross section of the channel and leaves free a free portion of cross section of the channel, - a fluid inlet collector (10) arranged to distribute the fluid towards the inlets of said at least two channels, the fluid inlet manifold (10) being configured to direct the fluid flow favorably towards the free cross-sectional portion of the channels (3). Figure for abstract: Figure 1

Description

Thermal regulation device, in particular cooling

The present invention relates to a thermal regulation device, in particular a cooling device, in particular for an electrical component capable of releasing heat during its operation, in particular a device for cooling at least one vehicle battery or battery cells, for example a motor vehicle.

The vehicle can be land, sea or air.

The invention relates in particular to plate heat exchangers intended for the circulation of a heat transfer fluid, for example a refrigerant fluid or brine, allowing the cooling of hybrid or electric vehicle batteries. The first plate, or upper plate, which comes into contact with the components to be cooled, is generally flat. The second plate, or lower plate, is a stamped plate in which circulation channels for the heat transfer fluid are formed.

In known manner, to increase the turbulence in the heat transfer fluid, which has the effect of increasing the exchange coefficient and therefore the thermal performance, two types of elements can be used.

First there are elements called “hard dimples” in English, which are bosses making the connection between the lower plate and the upper plate. These bosses provide the mechanical connection of the assembly, while ensuring a minimum level of disturbance to the coolant. These bosses are robust from a mechanical point of view, but the thermal performance is not optimized. Indeed, by crossing the circulation channels over their entire height, the bosses produce significant pressure losses without creating enough turbulence for the increase in thermal performance to compensate for this pressure loss.

There are still elements called “soft dimples” in English, which are bosses inside the circulation channels, but of lower height so as to be set back from the upper plate. These bosses do not contribute to the mechanical strength of the cooling plates but ensure a high level of turbulence in the fluid. Patent application DE102014202161 describes such bosses.

Tubes are also used to define the channels, instead of two plates joined together.

It is also known to heat exchangers provided with channels connected to inlet and outlet collectors having identical orifices for all the tubes. Most exchanger channels are symmetrical along two planes of symmetry. There is therefore no preferential flow distribution which minimizes the pressure loss.

At the entrance to the channel, there is a flow establishment zone which depends on the orientation of the distribution upstream, in the inlet collector. In the example of an inlet collector forming a 90° angle with the channel(s), the distribution is initially heterogeneous, with a distortion in the direction of the flow before the change of direction, due to the inertia of the fluid. This distortion is resolved after a distance depending on the geometry and the Reynolds number to find the profile of a Poiseuille flow, namely a laminar type flow. This distortion generates load loss, which penalizes the performance of the regulation device.

The invention aims in particular to improve the thermal performance of a thermal regulation device with an inlet collector and which uses obstacles in the channels, obstacles which serve to homogenize the temperature over the section of the channel.

• au moins deux canaux pourvus chacun d’au moins un premier obstacle du fluide en regard d’une entrée du canal, obstacle qui définit une portion obstruée de section transversale du canal et laisse libre une portion libre de section transversale du canal,
• un collecteur d’entrée de fluide agencé pour distribuer le fluide vers les entrées desdits au moins deux canaux, le collecteur d’entrée de fluide étant configuré pour diriger l’écoulement de fluide de manière privilégiée vers la portion libre de section transversale des canaux.

The subject of the invention is thus a thermal regulation device, in particular cooling, for a component capable of releasing heat during its operation, in particular for an electrochemical energy storage module, this device comprising a circulation network for a heat transfer fluid, this network comprising:

• at least two channels each provided with at least one first obstacle of the fluid facing an inlet of the channel, obstacle which defines an obstructed portion of cross section of the channel and leaves free a free portion of cross section of the channel,
• a fluid inlet manifold arranged to distribute the fluid towards the inlets of said at least two channels, the fluid inlet manifold being configured to direct the fluid flow in a preferred manner towards the free portion of cross section of the channels.

According to the present invention, the first obstacle in each channel, and where appropriate the following obstacles downstream of this first obstacle, are arranged to generate chaotic mixing in the flow.

The principle of chaotic mixing is particularly used for mixing viscous fluids at low speeds. As is known, chaotic mixing is based on the "baker's transformation" for mixing the different layers of fluid.

For example, according to one way of doing this transformation, the fluid layers undergo passive division, then rotation into bends of different chiralities, and finally recombination to achieve stretching and folding to ensure homogeneous mixing.

There is another way to cause mixing, without dividing the flow. Mixing can thus be caused by bends that the flow undergoes, bends which allow the fluid layers to be mixed in the manner of a vorticity generator.

The invention can thus allow mixing which can be done at relatively low fluid speeds. Obstacles in each channel are configured to impose fluid flows with angles allowing chaotic mixing.

The invention can thus allow mixing at low speed or at low Reynolds number, typically at a Reynolds number Re less than 2000, in particular between 100 and 1,400. This is particularly advantageous when the thermal regulation device operates with speeds of fluid flow insufficient to generate turbulent flows.

In this context of chaotic mixing, the invention proposes arrangements of the inlet collector which make it possible to minimize the pressure loss by taking into account the speed distribution to which the fluid downstream is constrained, namely in the obstacle channel. chaotic type, with or without fluid flow division. In fact, the singular pressure loss generated by the junction between the inlet collector and the channels is all the greater as the speed distribution is different before and after the junction.

The inlet collector according to the invention is thus configured to impose, before entering the channel, a non-homogeneous speed distribution in order to minimize the pressure loss of the assembly, ensuring that speed distributions before and after the junction are as close as possible. This inlet manifold is used to modify the upstream velocity profile, just before the fluid reaches the entrance to the chaotic obstacle channel.

In other words, the invention recommends reducing singular pressure losses, due to the distortions described above, by eliminating sudden changes of direction and recirculation zones, zones in which swirling structures are set up and where the fluid is generally immobile.

The invention achieves this thanks to the fluid inlet manifold which is configured to direct the fluid flow in a preferred manner towards the free portion of cross section of the channels, thus avoiding unwanted recirculation zones which could form at the level of the blocked portion of the canal.

According to the present invention, the first obstacle presents on a face that the fluid encounters first, namely the face upstream in the direction of circulation of the fluid, an angulation making it possible to reduce pressure losses. Advantageously, only the first obstacle has this angulation in order to reduce the load losses without losing the recombination and/or chaotic effect. Indeed, if all the following obstacles included this angled face, we could lose the chaotic mixing effect.

According to one of the aspects of the invention, the channels which are supplied by the input collector are parallel to each other.

According to one of the aspects of the invention, the fluid inlet collector comprises at least one deflector arranged to direct the fluid flow in a preferred manner towards the free portion of cross section of one of the channels.

According to one of the aspects of the invention, the inlet collector comprises at least two junctions with said channels, each junction being arranged to allow a turn of heat transfer fluid flow from the inlet collector towards the free portion of section transversal of the corresponding channel.

According to one aspect of the invention, the deflector is arranged at an angle chosen so that the fluid flow turn is progressive between the inlet collector and the associated channel.

For example, the bend allows the fluid to gradually rotate 90°.

According to one of the aspects of the invention, the deflector is arranged with an angle measured between a main direction of the inlet collector and this deflector, an angle which is between 45° and 90°, in particular between 45° and 80° .

Thus the deflector allows the heat transfer fluid to change direction, for example 90°, progressively. Without the presence of the deflector, and for a 90° turn, the fluid would have suffered significant pressure losses.

In other words, in an example of implementation of the invention, the deflectors are added in the inlet collector in order to direct part of the flow preferentially on the upper or lower part of the channel, depending on whether the channel has an open obstacle. up or down, first.

According to one of the aspects of the invention, the deflector has a surface area which corresponds to only a portion of a passage section of the inlet collector.

Thus each deflector directs only part of the flow from the inlet collector towards each of the channels.

According to one of the aspects of the invention, the fluid inlet collector comprises at least two deflectors arranged to direct the fluid flow in a preferred manner respectively towards the free portion of cross section of each of the channels.

The first of the deflectors is arranged downstream of the second of the deflectors.

Thus the flow of fluid in the inlet collector successively sees the first deflector then the second deflector.

Part of this flow is sent, through the first of the junctions and with a change of direction imposed by the first of the deflectors, towards the first of the channels, in the direction of the free portion of cross section of this channel. Another part of this flow is sent, through the second of the junctions and with a change of direction imposed by the second of the deflectors, towards the second of the channels, in the direction of the free portion of cross section of this channel.

According to one aspect of the invention, the inlet manifold comprises a plurality of deflectors arranged one behind the other in the direction of flow of the fluid in the inlet manifold.

According to one aspect of the invention, each deflector is associated with a junction to a channel.

According to one aspect of the invention, the junctions are placed spaced apart along the inlet collector.

According to one of the aspects of the invention, the number of deflectors is, for example, between 2 and 10, in particular between 3 and 8, being for example equal to 5.

According to one of the aspects of the invention, the deflectors arranged one behind the other in the inlet collector have an increasing surface area as one moves away from the inlet of the collector. This makes it possible in particular to balance the flow rates in the different channels which leave the inlet collector.

According to one of the aspects of the invention, the deflectors have edges which are on a wall on the junction side with the channels to be served.

According to one of the aspects of the invention, the channels each have a first obstacle, these first obstacles being configured so that, when passing from one channel to the neighboring channel, the obstructed portion is replaced by the free portion.

According to one of the aspects of the invention, the deflectors associated with this succession of channels are alternately in one half and in the other half of cross section of the inlet collector.

Thus, when this collector has a face at the bottom and a face at the top, the deflectors are alternately at the bottom and at the top in the inlet collector.

According to one of the aspects of the invention, the inlet collector has a width measured in a direction perpendicular to the main direction of the collector.

According to one of the aspects of the invention, the deflectors have a width which increases as one moves away from the inlet of the collector.

According to one of the aspects of the invention, the deflectors have a substantially rectangular circumference.

According to one of the aspects of the invention, the channels each present a succession of obstacles, downstream of the first obstacle, and this succession of obstacles is configured to generate turns of the fluid flow in this channel, without division of the flow into multiple streams.

In this case, each obstacle is in particular in one half of the channel section, for example a high half or a low half, and leaves the other half of the channel section free.

Alternatively, the channels each present a succession of obstacles, downstream of the first obstacle, and this succession of obstacles is configured to successively generate divisions and recombinations of the fluid flow in this channel.

In this case, one of the obstacles occupies a central portion of the channel section so that the fluid flow in the channel is divided into two flows which pass on each side of this dividing obstacle. The next obstacle, called the mixing obstacle, downstream of this dividing obstacle, includes two sections which are each facing each free portion associated with the dividing obstacle just upstream. The mixing obstacle is thus configured to have a single central free portion between the sections, so as to force the mixing of the previously divided flows.

According to one of the aspects of the invention, the sides of the obstacle are adjacent to opposite walls of the channel.

This succession of dividing obstacles and mixing obstacles ensures effective chaotic mixing in each channel.

In this case, the deflector, which faces a dividing obstacle, can extend in a central region of the inlet collector, over only part of the width of the inlet collector or over the entire width of the inlet collector.

According to one of the aspects of the invention, the deflector, which faces a mixing obstacle, extends on either side of a free central portion of the inlet collector, over only part of the width of the inlet collector or over the entire width of the inlet collector. The deflector thus has two sides on either side of the free central portion.

According to one of the aspects of the invention, the fluid inlet collector comprises a plurality of channels each opening into the inlet of each of the channels, and each channel comprises a narrowed fluid outlet cross section which faces the free portion of cross section of each of the channels.

According to one of the aspects of the invention, the inlet collector supplies flow to the different channels and each channel is smaller, in cross section, than the channel it supplies so as to direct the flow towards the free portion. of the first obstacle encountered. Thus the exit section of the channel corresponds to the free portion left by the first obstacle.

For example, the fluid outlet cross section of the channel is substantially of the same area as the free portion left by the first obstacle.

According to one of the aspects of the invention, the channels form with the channels connected to them respective angles of at most 45°.

According to one of the aspects of the invention, at least one of the channels is connected to the associated channel by forming a zero angle, namely that the channel is parallel to the channel.

In the implementation examples above, the channel has the largest possible inlet section, gradually moving from the largest available section in the inlet collector to the narrowed outlet section.

The invention makes it possible to minimize the pressure loss at the entrance to the channel, while reducing the pressure loss between the exit of the channel and the first obstacle in the channel.

According to one of the aspects of the invention, the fluid inlet collector comprises a plurality of elbow channels each opening into the inlet of each of the channels, the first obstacle of each channel having a free portion of the side corresponding to the side outside of the channel bend.

The fluid circulating in the elbow presents a non-homogeneous speed profile, due to the bend imposed by the elbow.

The outside of the elbow sees fluid which circulates with greater speed than on the inside of the elbow.

The invention thus recommends taking advantage of higher speeds by positioning the free portion of each first obstacle facing the exterior part of the bent channel so as to receive fluid circulating at higher speeds. Thus pressure losses can be reduced.

Thus the first chaotic obstacle is open on the side opposite to the direction of arrival of the flow in the channel.

According to one of the aspects of the invention, the input collector is positioned equidistant from two neighboring channels.

According to one of the aspects of the invention, the first obstacles are symmetrical to each other with respect to a plane of symmetry perpendicular to a plane defined by the two channels and equidistant from the two channels.

According to one of the aspects of the invention, the channels are themselves symmetrical to each other with respect to the aforementioned plane of symmetry.

The invention also makes it possible to combine a narrowed fluid outlet cross section and a first obstacle of each channel which has a free portion on the side corresponding to the exterior side of the bend of the channel. This makes it possible to accentuate the guidance of the flow, particularly in the case of a first vertical obstacle.

Thus, according to one of the aspects of the invention, the fluid inlet collector comprises a plurality of channels each opening into the inlet of each of the channels, and each channel comprises a narrowed fluid outlet cross section which makes facing the free portion of cross section of each of the channels, and the plurality of elbow channels each open into the entrance of each of the channels, the first obstacle of each channel having a free portion on the side corresponding to the exterior side of the elbow of the channel .

According to one of the aspects of the invention, the channels which are supplied by the inlet collector have trapezoidal or rectangular cross sections.

According to one of the aspects of the invention, the channels open at the outlet to an outlet collector which is arranged to evacuate the heat transfer fluid having passed through these channels.

According to one of the aspects of the invention, the outlet collector is connected to a pump or a compressor to set the fluid in motion.

According to one of the aspects of the invention, the channels are formed by tubes distinct from each other.

According to one aspect of the invention, these tubes are assembled in a sealed manner with the inlet collector, and, at the other end, with an outlet collector.

Alternatively, the channels are formed between two plates.

According to one of the aspects of the invention, the inlet collector and the channels are made of a material chosen from: a metal in particular aluminum or steel, a plastic material, a ceramic material, a material composite or a combination of these types of materials.

The invention also relates to an assembly comprising a component capable of releasing heat during its operation, and a thermal regulation device as mentioned above, in contact with which the component is cooled.

Other characteristics and advantages of the invention will appear more clearly on reading the following description, given by way of illustrative and non-limiting examples, and the appended drawings among which:

- there illustrates, schematically and partially, a thermal regulation device according to an example of implementation of the invention;

- there illustrates, schematically and partially, a channel of the thermal regulation device of the ;

- there illustrates, schematically and partially, a cross section along III-III of the thermal regulation device of the ;

- there illustrates, schematically and partially, a view along IV-IV of the thermal regulation device of the ;

- there illustrates, schematically and partially, a channel of a thermal regulation device according to another example of implementation of the invention;

- there illustrates, schematically and partially, a cross-sectional view of the channel of the ;

- there illustrates, schematically and partially, another view of the canal of the ;

- there illustrates, schematically and partially, a channel of a thermal regulation device according to another example of implementation of the invention;

- there illustrates, schematically and partially, in view according to IX-IX, the thermal regulation device of the ;

- there illustrates, schematically and partially, yet another example of implementation of the invention,

- there illustrates, schematically and partially, the channels side by side of the device of the .

We represented on the , which is a top view, an assembly 100 comprising battery cells 101 to be cooled, for example arranged in a plurality of parallel rows, and a thermal regulation device 1 arranged to cool the cells 101.

• une pluralité de canaux 3 parallèles, pourvus chacun d’au moins un premier obstacle 4 de mélange du fluide en regard d’une entrée 5 du canal 3, obstacle 4 qui définit une portion obstruée 6 de section transversale du canal et laisse libre une portion libre 7 de section transversale du canal 3, comme visible sur la ,
• un collecteur d’entrée de fluide 10 agencé pour distribuer le fluide vers les entrées 5 desdits canaux 3, le collecteur d’entrée de fluide 10 étant configuré pour diriger l’écoulement de fluide de manière privilégiée vers la portion libre 7 de section transversale des canaux 5.

The thermal regulation device 1 comprises a circulation network 2 for a heat transfer fluid, this network 2 comprising:

• a plurality of parallel channels 3, each provided with at least a first obstacle 4 for mixing the fluid facing an inlet 5 of the channel 3, obstacle 4 which defines an obstructed portion 6 of cross section of the channel and leaves a portion free free 7 of cross section of channel 3, as visible on the ,
• a fluid inlet manifold 10 arranged to distribute the fluid towards the inlets 5 of said channels 3, the fluid inlet manifold 10 being configured to direct the fluid flow in a preferred manner towards the free portion 7 of cross section of the channels 5.

Arrow F1 shows the direction of fluid flow through a fluid inlet 11 in the inlet collector 10.

The inlet collector 10 and the channels 3 are made of a material chosen from: a metal in particular aluminum or steel, a plastic material, a ceramic material, a composite material or a combination of these types of materials .

On the , the x axis represents the width of channel 3 and the y axis represents the height of channel 3.

Inlet manifold 10 is used to modify the upstream velocity profile, just before the fluid reaches inlet 5 of channel 3 with chaotic type obstacles.

This fluid inlet manifold 10 is configured to direct the fluid flow in a preferred manner towards the free portion 7 of cross section of the channels 3, thus avoiding undesirable recirculation zones which could form at the level of the obstructed portion 6 of each channel 3.

The channels 3 open at the outlet to an outlet collector 12 which is arranged to evacuate the heat transfer fluid having passed through these channels 3. The arrow F2 shows the direction of the fluid outlet.

The outlet collector 12 is connected to a pump or compressor, not shown, for setting the fluid in motion.

The inlet manifold 10 comprises a plurality of deflectors 15 arranged to direct the fluid flow in a preferred manner towards the free portion 7 of cross section of each of the channels 3.

The inlet collector 10 comprises a plurality of junctions 16 with said channels 3, each junction 16 being arranged to allow a turn of heat transfer fluid flow from the inlet collector 10 towards the free portion 7 of cross section of the corresponding channel 3 .

Each deflector 15 is arranged with an angle chosen so that the fluid flow turn is progressive between the inlet manifold 10 and the associated channel 3.

For example, the bend at junction 16 allows the fluid to gradually rotate 90°.

Each deflector 15 is arranged with an angle A measured between a main direction DP of the inlet collector 10 and this deflector 15, angle A which is between 45° and 90°, in particular between 45° and 80°.

Thus the deflector allows the heat transfer fluid to change direction, for example 90°, progressively. Without the presence of deflector 15, and for a 90° turn, the fluid would have suffered significant pressure losses.

In the example described, the deflectors 15 are added in the inlet collector 10 in order to direct part of the flow preferentially on the upper or lower part of each channel 3, depending on whether the channel 3 has an obstacle 4 open at the top or bottom, first.

Each deflector 15 has a surface area which corresponds to only a portion of a passage section of the inlet collector 10.

Thus each deflector 15 directs only part of the flow from the inlet collector towards each of the channels 5.

The plurality of deflectors 15 are arranged one behind the other in the direction of flow of the fluid in the inlet collector 10.

Part of this flow is sent, through the first of the junctions 16 and with a change of direction imposed by the first of the deflectors 15, towards the first of the channels 3, in the direction of the free portion 7 of cross section of this channel 3. Another part of this flow is sent, through the second of the junctions 16 and with a change of direction imposed by the second of the deflectors 15, towards the second of the channels 3, in the direction of the free portion 7 of cross section of this channel 3 This happens like this for the following 3 channels.

Each deflector 15 is associated with a junction 16 to a channel 3.

The junctions 16 are placed, spaced and regularly, along the inlet collector 10.

The number of deflectors 15 is chosen according to the number of channels 3.

The deflectors 15 are arranged one behind the other in the inlet collector 10, and have an increasing surface area as one moves away from the inlet 11 of the collector 10. This makes it possible in particular to balance the flow rates in the different channels which leave from the inlet collector.

These increasing surfaces of the deflectors 15 are illustrated more specifically on the . We have noted each of the deflectors from the smallest deflector 15a, which is closest to the inlet 11 of the collector 10, to the largest deflector 15e which is furthest from the inlet 11. The reference 15 generically designates the deflectors, ignoring their respective dimensions.

The deflectors 15 have edges 18 which are on a wall 19 on the junction side with the channels 3 to be served.

The first obstacles 4 of each of the channels 3 are configured so that, when passing from a channel 3 to the neighboring channel, the obstructed portion 6 is replaced by the free portion 7. Thus, in the example described, the obstacles 4 are alternately at the top and bottom of the associated channel 3, as we move from one channel 3 to the neighboring channel.

Thus, the deflectors 15 associated with this succession of channels 3 are alternately in the upper half and in the lower half of the inlet collector 10, as can be seen in the .

The inlet collector 10 has a width LC measured in a direction perpendicular to the main direction DP of the collector 10. The deflectors 15 have an extension in the direction of the width LC of the collector 10, an extension which is increasing as the we move away from the inlet 11 of the collector 10, as can be seen in Figures 3 and 4.

The deflectors 15 here have a substantially rectangular circumference.

The channels 3 each have a succession of obstacles 21, downstream of the first obstacle 4, and these obstacles 4 and 21 are configured to generate bends in the flow of fluid in this channel, without dividing the flow into several flows. This allows for chaotic mixing.

Each obstacle 4, 21 is in one half of the section of channel 3, for example a high half or a low half, and leaves the other half of the section of channel 3 free.

Alternatively, in the exemplary embodiment of the invention illustrated in Figures 5 to 7, the channels 3 each present a succession of obstacles 23, downstream of the first obstacle 22, and these obstacles 22 and 23 are configured to successively generate divisions and recombinations of the fluid flow in this channel 3, to obtain a chaotic type mixture.

In this case, one of the obstacles, here obstacle 23, occupies a central portion of the section of channel 3 so that the flow of fluid in the channel is divided into two flows which pass on each side of this obstacle divider 23. The next obstacle, called mixing obstacle similar to obstacle 22, downstream of this divider obstacle 23, comprises two sections 25 which are each facing each free portion associated with the divider obstacle 23 just upstream . The mixing obstacle 22 is thus configured to have a single central free portion 26 between the sides 25, so as to force the mixing of the previously divided flows.

The sections 25 of the obstacle 22 are adjacent to opposite walls 37 of the channel 3.

This succession of dividing obstacles 23 and mixing obstacles 22 ensures effective chaotic mixing in each channel 3.

The succession of channels 3 begins alternately with a dividing obstacle 23 and a mixing obstacle 22.

The deflector 27, which faces a dividing obstacle 23, can extend in a central region of the inlet collector 10, over only part of the width LC of the inlet collector or over the entire width LC of inlet collector 10.

The deflector 28, which faces a mixing obstacle 22, extends on either side of a free central portion 29 of the inlet collector 10, over only part of the width of the inlet collector. inlet 10 or over the entire width of the inlet collector. The deflector 28 thus has two sides 30 on either side of the free central portion 29.

Figures 6 and 7 represent these deflectors 27 and 28. As in the previous example, the dimensions of the deflectors 27 and 28 increase as one moves away from the inlet 11 of the collector 10.

The types of deflectors 27 and 28 alternate along the inlet collector 10.

Figures 8 and 9 show a thermal regulation device 40 according to another example of implementation of the invention.

In this device 40, the fluid inlet collector 41 comprises a plurality of channels 42 each opening into the inlet 5 of each of the channels 3. These channels 3 are described in the example of the and are not detailed further here.

Each channel 42 comprises a narrowed fluid outlet cross section 46 which faces the free portion 7 formed by the first obstacle 4.

In other words, the exit section 46 of the channel 42 coincides with the free portion 7 left by the first obstacle 4.

The channels 42 form, with the channels 3 which are connected to them, respective angles B of at most 45°.

The middle channel 42 is connected to the associated channel 3 by forming a zero angle, namely that the middle channel 42 is parallel to the associated channel 3.

As can be seen on the , the channel 42 has the largest possible inlet section 47, gradually passing from the largest section available in the inlet collector 41 to the narrowed outlet section 46.

The invention makes it possible to minimize the pressure loss at the entrance to channel 42, while reducing the pressure loss between the exit 46 of the channel and the first obstacle 4 of channel 3.

Figures 10 and 11 show a thermal regulation device 50 according to another example of implementation of the invention

In this device 50, the fluid inlet collector 51 comprises two elbow channels 52 each opening into the inlet of each of the channels 53, the first obstacle 54 of each channel 53 having a free portion 57 on the side corresponding to the exterior side 58 from the bend of channel 52.

The fluid circulating in channel 52 has a non-homogeneous speed profile, due to the bend imposed by the elbow.

The exterior 58 of the elbow sees fluid which circulates with greater speed than on the interior of the elbow.

The invention thus recommends taking advantage of higher speeds by positioning the free portion 57 of each first obstacle 54 facing the exterior part 58 of the bent channel 52 so as to receive fluid circulating at higher speeds. Thus pressure losses can be reduced.

Thus the first chaotic obstacle 54 is open on the side opposite to the direction of arrival of the flow in channel 53.

The input collector 51 is positioned equidistant from two neighboring channels 53.

The first obstacles 54 are symmetrical to each other with respect to a plane of symmetry PS perpendicular to a plane PC defined by the two channels 53 and equidistant from the two channels 53, as illustrated in the .

Obstacles 54 are vertical.

The channels 53 are themselves symmetrical to each other with respect to the aforementioned plane of symmetry PS.

In an example not illustrated, the input collector 51 is located on one side of the plane of symmetry PS of the channels 53, and these channels have first obstacles which are all open on the same side.

In the examples described above, channels 3 and 53 may have trapezoidal or rectangular cross sections.

Channels 3, 53 are formed by tubes distinct from each other, tubes assembled in a sealed manner with the inlet collector, and, at the other end, with an outlet collector.

Alternatively, the channels 3, 53 are formed by two assembled plates, in particular brazed.

Claims (10)

Thermal regulation device (1; 40; 50), in particular cooling, for a component (101) capable of releasing heat during its operation, in particular for an electrochemical energy storage module, this device comprising a circulation network (2) for a heat transfer fluid, this network comprising:

• at least two channels (3; 53) each provided with at least a first obstacle (4; 54) of the fluid facing an inlet (5) of the channel, obstacle which defines an obstructed portion (6) of cross section of the channel and leaves a free portion (7) of cross section of the channel,
• a fluid inlet manifold (10; 41; 51) arranged to distribute the fluid towards the inlets of said at least two channels, the fluid inlet manifold (10; 41; 51) being configured to direct the flow of fluid in a preferred manner towards the free portion of cross section of the channels (3; 53).

Device according to the preceding claim, in which the channels (3) each present a succession of obstacles (21), downstream of the first obstacle (4), and this succession of obstacles is configured to generate turns of the fluid flow in this channel, without dividing the flow into several flows. Device according to claim 1, in which the channels each present a succession of obstacles (22; 23), downstream of the first obstacle, and this succession of obstacles is configured to successively generate divisions and recombinations of the fluid flow in this channel. Device according to one of the preceding claims, in which the fluid inlet collector (10) comprises at least one deflector (15) arranged to direct the fluid flow in a preferred manner towards the free portion (7) of cross section of one of the channels (3). Device according to the preceding claim, in which the deflector (15) is arranged at an angle chosen so that the fluid flow turn is progressive between the inlet collector (10) and the associated channel (3), in particular the deflector being arranged with an angle (A) measured between a main direction of the inlet collector and this deflector, an angle which is between 45° and 90°, in particular between 45° and 80°. Device according to one of claims 4 and 5, in which the fluid inlet collector (10) comprises at least two deflectors (15) arranged to direct the fluid flow in a preferred manner respectively towards the free portion (7) cross section of each of the channels (3). Device according to one of claims 4 to 6, in which the deflectors (15) arranged one behind the other in the inlet collector (10), have an increasing surface area as one moves away from the collector inlet. Device according to claim 1 or 2, in which the fluid inlet collector (41) comprises a plurality of channels (42) each opening into the inlet of each of the channels, and each channel comprises a fluid outlet cross section narrowed (46) which faces the free portion (7) of cross section of each of the channels (3). Device according to claim 1 or 2 or 8, in which the fluid inlet collector (51) comprises a plurality of elbow channels (52) each opening into the inlet of each of the channels (53), the first obstacle (54 ) of each channel having a free portion (57) on the side corresponding to the exterior side of the elbow of the channel. Assembly (100) comprising a component capable of releasing heat during its operation, and a thermal regulation device (1) according to one of the preceding claims, in contact with which the component is cooled.