FR3145602A1 - Thermal regulation device for components - Google Patents

Abstract

Thermal regulation device for components The invention relates to a thermal regulation device (2) for components (4), comprising: - a dielectric fluid flow channel (6), this channel (6) comprising at least one dielectric fluid inlet and at least one dielectric fluid outlet (8, 10), - a separator (12) arranged to receive the components (4) such that these components (4) extend on either side of the separator (12), this separator (12) being configured to create at least two dielectric fluid flow stages (Eh, Eb), these stages being arranged such that the dielectric fluid entering via the inlet first passes through one of the stages which defines a section (26) of said channel (6), then the other of the stages which defines another section (26) of said channel (6) downstream of the preceding section (26), and the separator (12) comprises a free edge (27) so as to provide a fluid passage, in particular a U-shaped one, between the two stages. Figure for abstract: Figure 2

Description

Thermal regulation device for components

The invention relates to a thermal regulation device for components whose operation is sensitive to temperature, these components being in particular intended for energy storage and possibly being battery cells, in particular for vehicles.

The invention also relates to a module comprising such a thermal regulation device and said components placed in the thermal regulation device.

The invention further relates to a method of assembling such a module.

It is known nowadays to equip electric, thermal or hybrid vehicles with electrochemical and/or electronic and/or electrical components. In particular, an electrochemical component is a battery cell. Battery cells can be positioned in a battery pack, or a battery module.

Furthermore, it is known to install all or at least part of these battery packs at the floor level of the vehicle, substantially over the entire width of the vehicle.

It is understood that, during vehicle operation, the battery packs can release a significant amount of heat and therefore be subject to temperature increases which can, in certain cases, cause them to be damaged or even destroyed.

Therefore, their cooling is essential in order to keep them in good condition and thus ensure the reliability, autonomy and performance of the vehicle. In addition, the operation of battery packs can be less efficient in case of low temperatures, the electrical or electronic components equipping these battery packs then needing a time to warm up before operating at full efficiency.

To do this, we know a thermal regulation device intended to regulate the temperature of the battery packs which is implemented to ensure the heating and/or cooling functions of the battery cells forming these battery packs and thus optimize the operation of these battery cells.

These thermal regulation devices are generally traversed by a heat transfer fluid, in particular a dielectric fluid, namely an electrically inert fluid, which can, depending on the needs, either absorb the heat emitted by each battery pack in order to cool it, or provide heat, if the temperature of the battery pack is insufficient for its proper operation.

There is a need to improve the thermal regulation device to increase heat exchange between said components and the heat transfer fluid and to compensate for pressure losses of the heat transfer fluid.

The invention aims to meet this need.

The present invention thus relates to a thermal regulation device for cooling and/or heating components whose operation is sensitive to temperature, these components being in particular intended for energy storage and possibly being battery cells, said device comprising:

- a housing defining a compartment configured to receive the components,

- a dielectric fluid flow channel in this compartment, this channel comprising at least one dielectric fluid inlet and at least one dielectric fluid outlet,

- a separator arranged to receive the components such that these components extend on either side of the separator, this separator being configured to create at least two stages of dielectric fluid flow, the separator being arranged such that the dielectric fluid entering through the inlet first travels through one of the stages which defines a section of said channel, then the other of the stages which defines another section of said channel downstream of the previous section, and the separator comprises a free edge so as to provide a fluid passage, in particular U-shaped, between the two stages.

For the purposes of the present invention, the different stages are located at different heights when the thermal regulation device is mounted on the vehicle. The stages are thus at different vertical positions.

By virtue of the invention, the dielectric fluid can make two or more passes in contact with each of the components to be cooled, which makes it possible to increase the heat exchanges between the components and the dielectric fluid. The invention thus makes it possible to better cool or heat the components.

According to one aspect of the invention, the stage which communicates with the dielectric fluid inlet is a high stage, namely the highest stage among all the stages.

According to one aspect of the invention, the stage which communicates with the dielectric fluid outlet is a low stage, namely the lowest stage among all the stages.

The fact that the fluid passes are at different levels, with dielectric fluid flowing from top to bottom while making one or more vertical turns, makes it possible to take advantage of gravity to compensate for pressure losses.

According to one aspect of the invention, the device comprises a pump configured to force the flow of dielectric fluid.

According to another aspect of the invention, the stage which communicates with the dielectric fluid inlet is a low stage, namely the lowest stage among all the stages.

According to one aspect of the invention, the stage which communicates with the dielectric fluid outlet is a high stage, namely the highest stage among all the stages.

In this example of a bottom-up flow embodiment, a pump is provided to force the flow of dielectric fluid from bottom to top.

According to one aspect of the invention, the thermal regulation device comprises at least two separators, for example two or three separators, configured to provide at least three stages of dielectric fluid flow, and each separator comprises a free edge so as to provide a U-shaped fluid passage between two consecutive stages.

According to one aspect of the invention, the two consecutive separators are arranged alternately on the dielectric fluid flow channel.

According to one aspect of the invention, the separator comprises openings each configured to receive a component.

Once placed in the opening, the component protrudes from each side of the separator.

According to one aspect of the invention, each opening has a circular outline.

According to one aspect of the invention, the openings are arranged in rows, in particular parallel rows.

According to one aspect of the invention, the separator has a generally flat shape.

According to one aspect of the invention, the separator has a plate shape.

According to one aspect of the invention, the separator is configured so as to be able to be placed substantially at mid-height of the component.

According to one aspect of the invention, the separator comprises, for each opening, a seal for each component, this seal being configured to be applied to the component to seal the opening.

Thus, the seals on the separator help prevent leakage of dielectric fluid through the separator, through the openings.

According to one aspect of the invention, the separator has a multi-layer structure with two external layers and an internal layer forming a seal.

According to one aspect of the invention, at least one of the outer layers may comprise at least one polymer material. The polymer material is a polyamide such as PA6 or PA66.

According to one aspect of the invention, the inner layer may comprise at least one polymer material. The polymer material is in particular an elastomer such as FKM. According to an alternative embodiment, the separator comprises a single rigid layer and the at least one sealing gasket.

According to an alternative embodiment, the separator comprises a single rigid layer.

According to one aspect of the invention, the internal layer is configured to be applied against the component placed in the opening to ensure sealing.

According to one aspect of the invention, the separator has a multi-layer structure with two external layers and an internal layer forming a seal, the internal layer being configured to come into contact with the component placed in the opening to ensure sealing.

According to one aspect of the invention, the separator comprises one or more dielectric fluid circulation ports configured to allow dielectric fluid to flow through the separator.

According to one aspect of the invention, the dielectric fluid circulation orifice(s) are placed close to, in particular between, openings receiving the components.

This helps reduce pressure losses while maintaining the desired cooling power. In the case where an electric pump is used to move the heat transfer fluid, this makes it possible to reduce the electrical consumption of the pump.

According to one aspect of the invention, the separator comprises a number of openings for the components, a number which is at least equal to half the total number of components to be placed in the thermal regulation device.

According to one aspect of the invention, the housing defines with a bottom support the compartment configured to receive the components, the housing comprising a side wall and a cover connecting to the side wall.

According to one aspect of the invention, the side wall has an annular shape, namely that it follows a closed perimeter, for example this perimeter being geometrically inscribed in a rectangle.

According to one aspect of the invention, the compartment is delimited between two opposite faces of the side wall of the housing, in particular two opposite vertical faces belonging to the side wall of the housing, and one of the separators being contiguous with one of these faces and the other of the separators being contiguous with the other of these faces.

In other words, at least half of the components are inserted into the separator. The number of openings may be greater than 60% or 70% of the total number of components to be placed in the compartment. This number is preferably less than 80% or 90% of the total number of components.

According to one aspect of the invention, the side wall and the cover are made of a single piece, for example of plastic.

According to one aspect of the invention, the side wall fits within a rectangular perimeter.

According to one aspect of the invention, the side wall comprises a separator attachment region on the side wall.

This fixing region is in the form of a strip in which a border of the separator is embedded.

The separator is, for example, secured to the side wall of the housing during overmolding of material onto the separator in order to form the side wall.

Alternatively, the separator may be in contact with the side wall without being secured to it.

According to one aspect of the invention, the separator may include flow disruptors. These disruptors are, for example, of the “dimples” type in English.

According to one aspect of the invention, the housing comprises a dielectric fluid supply conduit communicating with the inlet of the dielectric fluid flow channel and a dielectric fluid discharge conduit communicating with the outlet of the dielectric fluid flow channel.

According to one aspect of the invention, the conduits are made in one piece with the rest of the housing.

According to one aspect of the invention, the dielectric fluid supply and discharge conduits are arranged in parallel, in particular one above the other.

According to one aspect of the invention, the dielectric fluid supply and discharge conduits are arranged on one face of the side wall.

According to one aspect of the invention, the dielectric fluid supply and discharge conduits are open on the same side.

Thus, the pipes which connect to the conduits are placed on the same side, which allows for optimized space requirements.

According to one aspect of the invention, the cover comprises, on its main external face, reinforcement reliefs, in particular in the form of boxes.

According to one aspect of the invention, the cover comprises, on its internal main face facing the compartment, retaining reliefs configured to retain the components placed in the compartment.

According to one aspect of the invention, these retaining reliefs include studs, in particular made in one piece with the cover.

These pins are arranged in circular lines so that they can surround the top of components, particularly battery cells.

According to one aspect of the invention, the components are battery cells of cylindrical or prismatic shape.

According to one aspect of the invention, the side wall has a shape that fits the perimeter of components to be placed in the compartment.

According to one aspect of the invention, the side wall comprises rounded corrugations.

According to one aspect of the invention, the bottom support is configured to hold the components to be placed in the compartment.

According to one aspect of the invention, the bottom support comprises housings for each housing a component.

According to one aspect of the invention, each housing has a circular shape.

According to one aspect of the invention, the housings are formed by openings on a main wall of the bottom support.

According to one aspect of the invention, each housing comprises a shoulder, in particular of annular shape, configured to serve as a stop for the component to be placed in this housing.

This stop is preferably impermeable to the dielectric fluid.

According to one aspect of the invention, each housing receives a seal configured to be applied to the component which is to be placed in this housing.

According to one aspect of the invention, each component is inserted through the housing and then, at the end of the insertion stroke, the component abuts against this shoulder so that this component cannot pass through the housing beyond a required position.

The components are thus held, at the bottom, by the base support, and, at the top, by these holding reliefs, for example in the form of pins.

According to one aspect of the invention, each housing is provided with one or more slots around its periphery to allow dielectric fluid to pass through.

In this way, the pressure losses due to the passage of the dielectric fluid through the housing are reduced .

According to one aspect of the invention, the bottom support comprises a side wall connecting to the main wall which defines the housings.

According to one aspect of the invention, the bottom support is sealed by a bottom plate which is applied against the side wall of the bottom support.

According to one aspect of the invention, one or more conductive bars are placed in the space between the bottom plate and the bottom support.

This space between the bottom plate and the bottom support is preferably made tight to the dielectric fluid which is prevented from passing through the main wall of the bottom support.

According to one aspect of the invention, these conductive bars, also called “Busbars” in English, are used for the electrical connection of the battery cells.

According to one aspect of the invention, the base plate comprises reliefs, for example in the form of studs, configured to apply the conductive bar(s) against the components.

According to one aspect of the invention, the components come to bear on these conductive bars, once these components are mounted on the thermal regulation device.

According to one aspect of the invention, the device comprises an electrical connector configured to connect the set of conductive bars in contact with the components.

The invention also relates to a module comprising at least one thermal regulation device according to the invention, and components, in particular battery cells, placed in the thermal regulation device.

According to one aspect of the invention, the component comprises an enlarged base configured to abut against the shoulder of the housing which receives this component.

The invention also relates to a method of assembling a module according to the invention, comprising the step of inserting the components into the housings, in particular the openings, of a bottom support of the thermal regulation device.

This insertion is done by passing the component through the opening until the widened base of the component comes up against the shoulder of the housing that receives this component. Once these insertions are completed, the base plate is assembled with the base support, for example by gluing or welding.

The insertion of components, in particular battery cells, is thus carried out, in a way, from below the base support.

In the invention, the components, in particular the battery cells, are immersed in the dielectric fluid, at least to a certain height.

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

- there illustrates a schematic and perspective view of the thermal regulation device according to the invention;

- there illustrates a schematic and perspective view of the thermal regulation device according to the invention without the device housing;

- there shows a sectional view of the thermal regulation device along axis AA of the ;

- there shows a sectional view along the BB axis of the , in perspective, of the thermal regulation device;

- there shows a top view of the bottom support with components;

- there shows a schematic sectional view of the device of the invention with conductive bars;

- there shows a cross-sectional view of the device according to an alternative embodiment of the invention comprising two separators;

- there shows a cross-sectional view of the device according to an alternative embodiment of the invention comprising three separators;

- there shows a variant of the thermal regulation device of the with a separator comprising one or more orifices for circulation of dielectric fluid.

The features, variants and different embodiments of the invention may be combined with each other, in various combinations, to the extent that they are not incompatible or mutually exclusive. In particular, variants of the invention may be imagined comprising only a selection of features described below in isolation from the other features described, if this selection of features is sufficient to confer a technical advantage and/or to differentiate the invention from the prior art.

In the following description, the terms “longitudinal”, “transverse” and “vertical” refer to the orientation of a thermal regulation device according to the invention.

A longitudinal direction corresponds to a main direction of extension of a thermal regulation device, namely the direction of the greatest length of the regulation device. The transverse and vertical directions correspond to directions perpendicular to the longitudinal direction. These three longitudinal, transverse and vertical directions form a trihedron.

Figures 1 to 5 show a thermal regulation device 2 for cooling and/or heating components 4 whose operation is sensitive to temperature, these components 4 being cylindrical battery cells 4.

Device 2 includes:

- a dielectric fluid flow channel 6, this channel comprising a dielectric fluid inlet and outlet 8, 10,

- a separator 12 having a generally flat shape and having a plate shape, said separator 12 being arranged to receive the battery cells 4 so that these battery cells 4 extend on either side of the separator 12, this separator 12 being configured to create at least two stages of dielectric fluid flow.

The stage that communicates with the dielectric fluid inlet is a high stage Eh, namely the highest stage among all the stages.

The stage communicating with the dielectric fluid outlet is a low stage Eb, namely the lowest stage among all the stages.

The separator 12 is arranged so that the dielectric fluid entering through the inlet 8 first passes through one of the stages Eh, Eb which defines a section of said channel 26, then the other of the stages which defines another section 26 of said channel downstream of the preceding section 26, and the separator 12 has a free edge 27 so as to provide a fluid passage, in particular a U-shaped one, between the two stages Eh, Eb.

The separator 12 is configured so that it can be placed substantially halfway up the battery cells 4.

For the purposes of the present invention, the different stages Eh, Eb are located at different heights when the thermal regulation device 2 is mounted on the vehicle (not shown). The stages Eh, Eb are thus at different vertical positions.

By means of the invention, the dielectric fluid can make two or more passes in contact with each of the battery cells to be cooled, which makes it possible to increase the heat exchanges between the battery cells and the dielectric fluid. The fact that the fluid passes are at different stages Eh, Eb, with a flow of dielectric fluid from top to bottom Fh, Fb while making one or more vertical turns Fv, makes it possible to take advantage of gravity to compensate for pressure losses. The invention thus makes it possible to better cool or heat the battery cells 4.

Still referring to the , the thermal regulation device 2 comprises a housing 30 defining with a bottom support 32 a compartment 34 configured to receive the battery cells 4.

The housing 30 further comprises a side wall 36 and a cover 38 connecting to the side wall 36.

The housing 30 comprises a dielectric fluid supply conduit 40 communicating with the inlet of the dielectric fluid flow channel 8 and a dielectric fluid discharge conduit 42 communicating with the outlet of the dielectric fluid flow channel 10.

The conduits 40, 42 are made in one piece with the rest of the housing 30.

The dielectric fluid supply and discharge conduits 40, 42 are arranged in parallel one above the other. These conduits 40, 42 are arranged on one face of the side wall 36 and are open on the same side.

Thus, the pipes (not shown) which connect to the conduits 40, 42 are placed on the same side, which allows for optimized space requirements.

The side wall 36 has an annular shape, namely that it follows a closed circumference. This closed circumference is geometrically inscribed in a rectangle defined, for example by the cover 38 having a substantially rectangular circumference.

As illustrated in the , the side wall 36 has a shape matching the perimeter of battery cells 4 to be placed in the compartment 34. The side wall 36 comprises rounded corrugations.

The side wall 36 comprises a fixing region 46 of the separator 12 on the side wall 36. This fixing region 46 is in the form of a strip in which an edge of the separator 12 is embedded.

In reference to the , the separator 12 is secured to the side wall 36 of the housing 30 during overmolding of material onto the separator 12 in order to form the side wall 36 .

Alternatively, the separator 12 may be in contact with the side wall 36 without being secured to it.

Other means of fixing the separator 12 to the side wall 36 are conceivable, such as for example a notch in the side wall into which the separator 12 is inserted. The notch may comprise sealing means such as an elastic seal to form a sealed connection with the separator 12.

As can be seen on the , the side wall 36 and the cover 38 may be made of a single piece, for example of plastic.

The cover 38 comprises, on its external main face 50, reinforcement reliefs 52 in the form of boxes.

The cover 38 comprises, on its internal main face 54 facing the compartment 60, holding reliefs 70 configured to hold the battery cells 4 placed in the compartment 60.

These retaining reliefs 70 comprise studs made in one piece with the cover 38.

These pins 70 are arranged along circular lines so as to be able to surround the top 72 of the battery cells 4.

As illustrated in the , the bottom support 80 is configured to hold the battery cells 4 to be placed in the compartment 60.

The bottom support 80 comprises housings 82 for each housing a battery cell 4. Each housing 82 has for example a circular shape. In other alternative embodiments, the housings 82 have polygonal shapes, for example hexagonal.

The housings 82 are formed by openings 84 on a main wall 86 of the bottom support 80. Each housing 82 comprises a shoulder 88 of annular shape, configured to serve as a stop for the component 4 to be placed in this housing 82.

This stop 88 is sealed against dielectric fluid.

Each housing 82 may comprise a seal 90 configured to be applied to the battery cell 4 which is to be placed in this housing 82.

The housing seal 90 includes notches 92.

The battery cells 4 each comprise an enlarged base 94 configured to abut against the shoulder 88 of the housing 82 which receives this cell 4.

Each cell 4 is inserted through the housing 90 then, at the end of the insertion stroke, the cell 4 comes to abut against this shoulder 88 so that this cell 4 cannot pass through the housing 90 beyond a required position.

The battery cells 4 are thus held, at the bottom, by the bottom support 80, and, at the top, by these holding reliefs in the form of pins 70.

Referring to the variants of Figures 3 and 9, but including for other variants of the invention, all the battery cells 4 can be held at the bottom, by the bottom support 80, and, at the top, by these holding reliefs in the form of pins 70.

There makes particularly visible the fact that the separator 12 comprises openings 100 having a circular outline, the openings 100 each being configured to receive a battery cell 4.

Once placed in the opening 100, the battery cell 4 protrudes on each side of the separator 12.

The openings 100 are arranged in parallel rows.

The separator 12 may comprise, for each opening 100, a seal 102 for each battery cell 4, this seal 102 being configured to be applied to the battery cell 4 to seal the opening 100.

Advantageously, the seals 102 on the separator 12 make it possible to prevent leaks of dielectric fluid through the separator 12, via the openings 100.

The separator 12 may have a multi-layer structure with two outer layers 104 ( and an inner layer 102 forming a seal 102. In alternative embodiments not shown, the separator 12 comprises a single rigid layer, with or without additional seals.

The outer layers 104 may comprise a polymer material. The polymer material is a polyamide such as PA6 or PA66.

The inner layer 102 may comprise a polymer material. The polymer material is in particular an elastomer such as FKM. In the case of a multilayer structure, the inner layer 102 is configured to come into contact with the battery cell 4 placed in the opening 100 to ensure sealing.

As can be seen on the , the bottom support 80 comprises a side wall 110 connecting to the main wall 86 which defines the housings.

Still in the example of the , the bottom support 80 is sealed by a bottom plate 112 which is applied against the side wall 110 of the bottom support 80.

As an illustration, with reference to the , a conductive bar 116 is placed in the space between the bottom plate 112 and the bottom support 80.

This space between the bottom plate 112 and the bottom support 80 is preferably made tight to the dielectric fluid which is prevented from passing through the main wall of the bottom support 80.

This conductive bar 116, also called “Busbar” in English, is used for the electrical connection of the battery cells 4. The battery cells 4 each further comprise an orifice 117 arranged to be connected to the conductive bar 116.

The bottom plate 112 comprises reliefs, for example in the form of studs, configured to apply the conductive bar(s) against the components.

The battery cells 4 come to bear on this conductive bar 116, once these battery cells 4 are mounted on the thermal regulation device 2.

As illustrated in the , the device 2 comprises an electrical connector 120 configured to connect the set of conductive bars in contact with the components.

In other alternative embodiments not shown, the conductive bar(s) 116 are located between the cover 38 and the cells 4.

Referring to Figures 7 and 8 illustrating variants of the invention, it can be seen that the compartment 60 is delimited between the two opposite vertical faces 130, 132 belonging to the side wall 36 of the housing 30, and one of the separators 12 being contiguous with one of these faces 130, 132 and the other of the separators 12 being contiguous with the other of these faces 130, 132.

In the example of the , the thermal regulation device comprises two separators 12, configured to provide three stages of dielectric fluid flow E1, E2, E3, and each separator 12 has a free edge 27 so as to provide a U-shaped fluid passage between two consecutive stages, namely between E1 and E2 or E2 and E3.

These two U-shaped bends form an S-shaped path between the supply and exhaust ducts 40, 42.

The two consecutive separators 12 are arranged alternately on the dielectric fluid flow channel.

The variant of the invention of the differs from that of the in that the thermal regulation device 2 comprises three separators 12, configured to provide four stages of dielectric fluid flow and in that the supply and discharge conduits 40, 42 are not arranged on the same face of the side wall.

In this embodiment variant illustrated on the , we see that the separators 12 include flow disruptors 140. These disruptors 140 are for example of the “dimples” type in English.

Of course, whatever the variant of the invention, the separator(s) 12 may include flow disruptors 140.

There illustrates an alternative embodiment of the invention as previously described with reference to the .

The separator 12 has a plurality of dielectric fluid circulation ports 150 configured to allow dielectric fluid to flow through the separator 12.

These dielectric fluid circulation orifices 150 are placed in proximity between openings 100 receiving the battery cells 4.

If an electric pump (not shown) is used to move the heat transfer fluid, this reduces the pump's electrical consumption.

In a variant not shown, the stage which communicates with the dielectric fluid inlet is a low stage, namely the lowest stage among all the stages and the stage which communicates with the dielectric fluid outlet is a high stage, namely the highest stage among all the stages.

In this example of a bottom-up flow embodiment, a pump is provided to force the flow of dielectric fluid from bottom to top.

Claims (15)

Thermal regulation device (2) for cooling and/or heating components (4) whose operation is sensitive to temperature, these components (4) being in particular intended for energy storage and possibly being battery cells (4), said device (2) comprising:
- a housing (30) defining a compartment (60) configured to receive the components,
- a dielectric fluid flow channel (6) in this compartment, this channel (6) comprising at least one dielectric fluid inlet and at least one dielectric fluid outlet (8, 10),
- a separator (12) arranged to receive the components (4) such that these components (4) extend on either side of the separator (12), this separator (12) being configured to create at least two stages of dielectric fluid flow (Eh, Eb), the separator being arranged such that the dielectric fluid entering via the inlet first passes through one of the stages (Eh, Eb) which defines a section (26) of said channel (6), then the other of the stages (Eh, Eb) which defines another section (26) of said channel (6) downstream of the preceding section (26), and the separator (12) comprises a free edge (27) so as to provide a fluid passage, in particular a U-shaped one, between the two stages (Eh, Eb). Device according to claim 1, comprising at least two separators (12), for example two or three separators (12), configured to provide at least three stages of dielectric fluid flow (E1, E2, E3), and each separator (12) has a free edge (27) so as to provide a U-shaped fluid passage between two consecutive stages. Device according to claim 1 or 2, the separator further comprises (12) openings (100) each configured to receive a component (4). Device according to claim 3, in which the separator (12) comprises, for each opening (100), a seal (102) for each component (4), this seal (102) being configured to be applied to the component (4) to seal the opening (100). Device according to claim 4, in which the separator (12) has a multilayer structure with two external layers (104) and an internal layer forming a seal (102), the internal layer (102) being configured to come into contact with the component (4) placed in the opening (100) to ensure sealing. Device according to claim 3, in which the separator (12) comprises a single rigid layer and the at least one sealing gasket (102). Device according to claim 3, in which the separator (12) comprises a single rigid layer. A device according to any preceding claim, wherein the separator (12) comprises one or more dielectric fluid circulation ports (150) configured to allow dielectric fluid to flow through the separator (12). Device according to claim 6, in which the dielectric fluid circulation orifice(s) (150) are placed close to, in particular between, openings (100) receiving the components (4). Device according to any one of the preceding claims, in which the housing (30) defines with a bottom support (80) the compartment (60) configured to receive the components, the housing (30) comprising a side wall (36) and a cover (38) connecting to the side wall (36). Device according to the preceding claim, in which the compartment (60) is delimited between two opposite faces (130, 132) of the side wall (36) of the housing (30), in particular two opposite vertical faces (130, 132) belonging to the side wall (36) of the housing (30), and one of the separators (12) being contiguous with one of these faces (130, 132) and the other of the separators (12) being contiguous with the other of these faces (130, 132). A device according to claim 10 or 11, wherein the side wall (36) comprises a fixing region (46) of the separator (12) on the side wall (36). Device according to one of claims 10 to 12, in which the cover (38) comprises, on its internal main face (54) facing the compartment (60), holding reliefs (70) configured to hold the components (4) placed in the compartment (60). Device according to one of claims 10 to 13, in which the bottom support (80) comprises housings (82) for each housing a component (4). Module comprising at least one thermal regulation device according to any one of the preceding claims, and components (4), in particular battery cells (4), placed in the thermal regulation device (2).