WO2022214573A1 - Electrical and/or electronic component for an electronic system comprising a plurality of heat management means - Google Patents

Abstract

The present invention relates to an electrical and/or electronic component (1) for an electronic system, comprising at least one structure (3) defined by an inner wall (4) and an outer wall (5) separated from each other by a space (6), characterised in that the electrical and/or electronic component (1) comprises at least one first heat management means (7) and at least one second heat management means (8) arranged within the space (6) of the structure (3) and capable of regulating the temperature of the electrical and/or electronic component.

Description

DESCRIPTION

TITLE OF THE INVENTION: ELECTRICAL AND/OR ELECTRONIC COMPONENT FOR AN ELECTRONIC SYSTEM COMPRISING A PLURALITY OF THERMAL TREATMENT MEANS

The present invention relates to the field of electronic systems and relates more particularly to heat treatment means associated with one or more electrical and/or electronic components forming part of these electronic systems.

An electronic system likely to be affected by the present invention may just as well consist of a computer server as of an electric battery, in particular a motor vehicle battery.

In order to ensure the operation of an electronic system, for example an electric battery whose function is in particular to provide the electric power necessary to implement propulsion of an electric or hybrid vehicle, an electric storage device forming a component electricity and/or electronics of the electronic system is configured to be able to store electrical energy, for example when recharging the electronic system when the latter is switched off and plugged in, and to supply electrical energy during operation of the electronic system.

Such electrical storage devices are liable to give off heat during their operation. Thus, it is known to use thermal regulation means capable of cooling the electrical storage device when the latter reaches too high a temperature. It is more particularly known to provide thermal regulation means which surround the electrical storage device, or which are pressed against this electrical storage device. In other words, the thermal regulation means are arranged in the vicinity of the electric storage device, as close as possible to the latter, in order to ensure that the calories given off by the electric storage device can be captured by the means thermal regulation. Plays in the manufacture and assembly of the thermal regulation means may involve the presence of air between the latter and the electrical storage device so that the heat exchange performance is reduced.

The invention thus aims to propose a solution making it possible to respond to this technical problem. Furthermore, the invention also aims to take into account an identified need according to which, in order to ensure optimal operation of the electronic system, the latter must have a temperature greater than a minimum temperature threshold, in particular when the electronic system is started. . The present invention falls within this dual context by proposing an electrical and/or electronic component for an electronic system, comprising at least one structure defined by an internal wall and an external wall separated from each other by a space, characterized in that the electrical and/or electronic component comprises at least one first heat treatment means and at least one second heat treatment means arranged within the space of the structure and able to regulate the temperature of the electrical and/or electronic component.

The first heat treatment means and the second heat treatment means can thus regulate the temperature of the electrical and/or electronic component

The inner wall and the outer wall of the structure, which makes it possible to protect and, if necessary, to electrically isolate the electrical and/or electronic component, are sufficiently spaced from each other so that the first processing means heat and the second heat treatment means can be at least partially placed there. Both of the heat treatment means make it possible to participate in increasing or decreasing the temperature of the electrical and/or electronic component as a function of the heat treatment means activated. The electrical and/or electronic component is therefore maintained at a temperature suitable for its correct operation.

More particularly, in the case where the electronic system is an electric battery, for example of a motor vehicle, the present invention proposes an electrical and/or electronic component in the form of an electrical storage device for an electronic system in the form of a battery, the electrical storage device comprising at least one electrical storage core configured to supply electrical energy to the battery, and a structure housing the electrical storage core, the structure being defined by an internal wall and an external wall separated from each other by a space, characterized in that the electrical storage system comprises at least a first heat treatment means and at least a second heat treatment means arranged within the space of the structure and able to regulate the temperature of the electrical storage core.

The first heat treatment means and the second heat treatment means can thus regulate the temperature of the electrical storage core so that the latter is within a temperature range making it possible to ensure optimal operation of the electrical storage device, which results , in particular in a case of application to an electric or hybrid vehicle battery, an improvement in the operating power, the recharging capacity and the battery autonomy.

The electrical storage core makes it possible to accumulate the energy received, for example during electrical charging of the electrical or electronic device. The electric storage core can thus for example correspond to a rechargeable electric battery cell. Subsequently, when the electrical or electronic device is in operation, the electrical storage core transmits the accumulated electrical energy to the electric motor in order to participate in the operation of the electrical or electronic device.

The structure of the electrical storage device makes it possible in particular to protect the electrical storage core and to electrically isolate it. The structure can be of various shapes, provided that the shape of the structure at least partially matches the electrical storage core. The internal wall is oriented towards the electrical storage core while the external wall is oriented towards an environment external to the electrical storage device.

According to one characteristic of the invention, the electrical and/or electronic component comprises a control module capable of activating the first means heat treatment or the second heat treatment means selectively. Depending on a detected temperature of the electrical and/or electronic component, and for example of the electrical storage core forming part of the electrical storage device as mentioned previously, the control module is capable of activating or deactivating the first heat treatment means or the second heat treatment means in order to heat or cool the electric and/or electronic component. The control module performs these operations selectively, that is to say by activating only one of the two heat treatment means at a time, depending on the detected temperature and the type of heat treatment required. The detected temperature of the electrical and/or electronic component can in particular result from a measurement by a temperature sensor configured to communicate the result of the measurement to the control module.

According to one characteristic of the invention, the control module is configured to activate the first heat treatment means so as to maintain the temperature of the electrical and/or electronic component below a maximum temperature threshold. In other words, the first heat treatment means makes it possible to cool the electrical and/or electronic component, where applicable of the electrical storage core when the electrical and/or electronic component is formed by an electrical storage device as mentioned above. The maximum temperature threshold is a maximum limit temperature before the operation of the electrical and/or electronic component decreases in efficiency. The maximum temperature threshold can for example be 40°C. Thus, when the temperature of the electrical and/or electronic component, for example of the electrical storage core, becomes greater than the maximum temperature threshold, the first heat treatment means is activated in order to cool the electrical and/or electronic component, by example the electrical storage core, so that the temperature of the latter again becomes lower than the maximum temperature threshold.

According to one characteristic of the invention, the control module is configured to activate the second heat treatment means so as to maintain the temperature of the electrical and/or electronic component above a minimum temperature threshold. The second way to heat treatment makes it possible to heat the electrical and/or electronic component, where appropriate the electrical storage core when the electrical and/or electronic component is formed by an electrical storage device as mentioned above. Raising the temperature of the electrical and/or electronic component is useful for example when starting up the electronic system, where the electrical and/or electronic component must be at a relatively high temperature to operate correctly. Furthermore, if the ambient temperature is very low, it is possible that it is necessary to increase the temperature of the electrical and/or electronic component. It has been calculated that the operation of the electrical and/or electronic component decreases in efficiency when the temperature of the electrical and/or electronic component becomes lower than the minimum temperature threshold. The minimum temperature threshold can for example be 20°C. Thus, when the temperature of the electrical and/or electronic component becomes lower than the minimum temperature threshold, the second heat treatment means is activated in order to heat the electrical and/or electronic component so that the temperature of the latter again becomes higher than the minimum temperature threshold.

According to one characteristic of the invention, the structure comprises a first compartment and a second compartment participating respectively in forming the first heat treatment means and the second heat treatment means, the two compartments being distinct from each other in such a way to be traversed by respectively a first fluid and a second fluid. Such a configuration constitutes a first embodiment of the electrical and/or electronic component, or electrical storage device according to an example of the invention, which consists in regulating the temperature of the electrical and/or electronic component via the circulation of the first fluid allowing to decrease the temperature of the electrical and/or electronic component or of the second fluid making it possible to increase the temperature of the electrical and/or electronic component.

The first fluid and/or the second fluid circulate within the structure, each of the fluids being able to circulate within its respective compartment. The first fluid and the second fluid can for example be placed in circulated by a pump and respectively cooled and heated by heat exchange. By circulating in the compartments, the first fluid or the second fluid therefore acts thermally on the electrical storage core in order to regulate its temperature.

The fluids may in particular be coolant, for example glycol water, or refrigerant fluid, for example 1234YF or 134A. Advantageously, the fluid is intended to have a liquid phase during its operation.

The two compartments can be arranged so as to have the same volume, with equivalent capacities for cooling or heating the electrical and/or electronic component, or else so as to have a different volume. In the latter case, the first compartment may have a larger volume in the situation where the intended use of the electrical and/or electronic component requires greater cooling properties than the heating properties, and it may have a smaller volume. than that of the second compartment, in the situation where the envisaged use of the electrical and/or electronic component requires heating properties that are greater than the cooling properties.

According to one characteristic of the invention, the first heat treatment means comprises a plurality of microfibers arranged in the space of the structure, said microfibers being configured to be traversed by a cooling fluid. This is a second embodiment of the electrical storage device in which the structure, instead of being divided into compartments, is traversed by microfibers extending into the space between the internal wall and the external wall . The microfibers can be connected to a cooling fluid circuit and divide in order to be distributed within the space of the structure. The coolant may for example have the same properties as those of the first fluid of the first embodiment, the main thing being that it can lower the temperature of the electrical and/or electronic component by circulating within the microfibers. According to one characteristic of the invention, the second heat treatment means comprises a plurality of microfibers arranged in the space of the structure, said microfibers being configured to be traversed by a heating fluid. The structure of the microfibers of the second heat treatment means is similar to that of the microfibers of the first heat treatment means and the heating fluid can for example have the same properties as those of the second fluid of the first embodiment, the main thing being that it can ensure the temperature rise of the electrical and/or electronic component by circulating within the microfibers. According to one characteristic of the invention, the second heat treatment means comprises a plurality of heating filaments arranged in the space of the structure and connected to an electrical power source. As an alternative to the presence of microfibers, the second heat treatment means may comprise resistive elements which heat up and thus make it possible to raise the temperature of the electrical and/or electronic component by activating the electrical power source

According to one characteristic of the invention, the first heat treatment means and the second heat treatment means are arranged in the space of the structure so as to form an alternation between the first heat treatment means and the second heat treatment means . More particularly, an alternation is established within the structure between means capable of heating the electrical and/or electronic component and means capable of cooling the electrical and/or electronic component, for example between a microfiber of the first heat treatment means and a microfiber or heating filament of the second heat treatment means. A distribution in an alternating manner, it being understood that it should be understood that the alternation takes place over the entire periphery of the structure around the electrical and/or electronic component, makes it possible to homogenize the heating or cooling of the electrical component and/or electronics and thus improve the regulation of its temperature.

According to one characteristic of the invention, the space of the structure is filled with a thermally conductive material, the first treatment means heat and the second heat treatment means being embedded in the thermally conductive material. The thermally conductive material can for example be silicone or any other material making it possible to facilitate the heat transfer from one or other of the heat treatment means to the electrical and/or electronic component.

The heat treatment means can initially be integrated within the space of the structure, then said space can be filled with the thermally conductive material. It is also possible to first embed the two heat treatment means in the thermally conductive material, then to place the assembly within the space of the structure.

According to a characteristic of the invention, the internal wall and the external wall have different thermal properties, the internal wall having a greater thermal conductivity than that of the external wall. This difference in thermal property allows the heat and cold generated by the heat treatment means to be transmitted to the electrical and/or electronic component rather than escaping to the outside of the heat treatment structure.

Other characteristics and advantages of the invention will become apparent through the description which follows on the one hand, and several embodiments given by way of indication and not limiting with reference to the appended diagrammatic drawings on the other hand, on which :

[fig 1] is a schematic representation of an electronic system, here an electric motor vehicle battery, comprising a plurality of electrical and/or electronic components according to the invention;

[fig 2] is a perspective view of a first embodiment of an electrical and/or electronic component according to the invention,

[fig 3] is a top view of the first embodiment of the electrical and/or electronic component,

[fig 4] is a schematic representation of a second embodiment of the electrical and/or electronic component. In what follows, an electronic system will be more particularly described in the form of a motor vehicle battery, with electrical and/or electronic components in the form of energy storage devices, or electrical energy accumulators. But it should be noted that the following description can be understood with electronic systems of another kind, such as computer servers for example.

The invention relates in particular to an electrical storage device 1 particular in that it comprises a plurality of heat treatment means 7, 8 arranged within a structure 3 protecting an electrical storage core.

As illustrated in FIG. 1, such electric storage devices 1 can form part of an electric battery 100, and more particularly of storage modules 110 grouping together within a box a plurality of storage devices. The electric battery 100 can be used in any vehicle, for example a motor vehicle, a motorized road electric vehicle with two or three wheels, an electric velocipede, or an electric scooter.

The electrical storage device 1 is configured to supply electrical energy to the battery 100 within which it is housed. The electrical storage device 1 is therefore capable of accumulating and storing electrical energy, for example thanks to an electrical connection of the battery when the latter is inactive. When the battery is in operation, the electrical storage device 1 is capable of transmitting the accumulated electrical energy to the battery, and this during a given period of autonomy. Furthermore, the battery comprises at least one power supply, here an input power supply 100 and an output power supply 101, capable of allowing power to be supplied to the heat treatment means associated with the storage devices housed in the battery.

Figure 2 shows a first embodiment of an electrical storage device 1.

The electrical storage device 1 comprises an electrical storage core 2 disposed inside a protective structure 3 . It's within the heart of electrical storage 2, formed of at least a plurality of layers of electrodes, that the electrical energy is accumulated or is transmitted to the battery. In all of the figures, the electrical storage core 2 is represented by oblique hatching.

The structure 3 can at least partially match the shapes of the electrical storage core 2. In FIG. 2, the electrical storage core 2 and the structure 3 both have a cylindrical shape with a circular section, but the shape of the electrical storage core 2 and structure 3 may have another shape, as will be described later.

The structure 3 is in particular defined by an internal wall 4 and by an external wall 5, separated from each other by a space 6. The internal wall 4 corresponds to the wall in contact or substantially in contact with the electrical storage core 2, while the outer wall 5 corresponds to the wall opposite and therefore farthest from the electrical storage core 2. As will be detailed below, the walls can be made of materials with different thermal properties, the inner wall 4 then being made of a material having a higher thermal conductivity than a thermal conductivity of a material with which the outer wall 5 is made.

According to the invention, the structure is equipped with a plurality of heat treatment means, in order to make it possible to regulate the temperature of the electrical storage core. These heat treatment means are in particular provided for allowing the cooling of the electrical storage core, which is likely during its operation to release heat and thus to rise in temperature. The presence of such heat treatment means makes it possible to prevent the temperature of the electrical storage core 2 from becoming too high and that an electrical power transmitted to the electrical or electronic device may be impacted and that the autonomy of the electrical or electronic device may be damaged. These heat treatment means can also be provided to allow the heating of the electrical storage core when the latter has too low a temperature, in particular when starting up the electrical or electronic device or when the ambient temperature is low. Means of treatment are thus configured to allow optimal operation of the electrical storage device 1 by ensuring that the electrical storage core 2 has a temperature between a minimum temperature threshold and a maximum temperature threshold.

In order to regulate the temperature of the electrical storage core 2, the electrical storage device i comprises a first heat treatment means 7 and a second heat treatment means 8 which respectively make it possible to cool and heat the electrical storage core 2.

In the first embodiment illustrated in FIG. 2, the first heat treatment means 7 and the second heat treatment means 8 respectively ensure the circulation of a first fluid and a second fluid within the space 6 of the structure 3. The first fluid is intended to present, when it circulates in the first heat treatment means 8, a temperature ensuring the cooling of the electrical storage core 2, while the second fluid is intended to present, when it circulates in the second heat treatment means 9, a temperature ensuring the heating of the electric storage core 2, the circulation of the fluids acting by heat exchange with the electric storage heart 2. In FIG. 2, the first heat treatment means 7 is represented by horizontal hatching, while the second heat treatment means 8 is represented by vertical hatching.

The first heat treatment means 7 and the second heat treatment means 8 are at least partially arranged in the space 6 of the structure 3, formed between the internal wall 4 and the external wall 5. The space 6 is configured so to comprise a first compartment 10, within which the first fluid circulates, and a second compartment 11 within which the second fluid circulates. The first compartment 10 and the second compartment 11 form two subsets of the space 6, distinct and sealed with respect to each other, so that the first fluid cannot circulate within the second compartment and the second fluid cannot circulate within the first compartment. These two compartments 10, 11 are delimited by the internal wall 4 and the external wall 5, as well as by partitions 14 which extend perpendicularly to these two walls. In FIG. 2, the compartments 10, 11 are of identical size, with separations 14 which are diametrically opposed, but it is totally possible to define one compartment larger than the other depending on the importance to be given to each of the heat treatment means 7, 8. As mentioned, the separations 14 make it possible to avoid mixing between the first fluid and the second fluid and the junctions between each separation and the internal and external walls of the structure are sealed. In particular, the separations 14 can be formed in one piece with the internal and external walls delimiting the space within the structure 3.

The first compartment 10 participates in forming the first heat treatment means 7, in particular when it is traversed by a fluid, while the second compartment 11 participates in forming the second heat treatment means 8, in particular when it is traversed by a other fluid. Each of these fluids can for example circulate within specific circuits 15, 16 connected to the structure 3 of the electrical storage device and which will be described later.

The first heat treatment means 7 and the second heat treatment means 8 are respectively activated by a control module 9, it being understood that the activation of the first heat treatment means, respectively of the second heat treatment means consists, here in authorizing the corresponding fluid circulation within the first compartment, respectively the second compartment. The control module 9 is capable of activating the first heat treatment means 7 or the second heat treatment means 8 selectively, that is to say without the two heat treatment means 7, 8 being activated simultaneously.

In the example illustrated, the control module 9 is connected to a temperature sensor 13 measuring the temperature of the electrical storage core 2. Thus, depending on the measured temperature, the control module control 9 makes it possible to activate or deactivate the first heat treatment means 7 or the second heat treatment means 8.

More specifically, the control module 9 activates the first heat treatment means 7 when the temperature value of the electrical storage core 2 detected by the temperature sensor 13 is greater than the value of the maximum temperature threshold, in order to cool the core. electrical storage by the fluid circulating in the first heat treatment means. And the control module 9 activates the second heat treatment means 8 when the temperature value of the electrical storage core 2 detected by the temperature sensor 13 is lower than the value of the minimum temperature threshold, in order to reheat the storage core electric by the fluid circulating in the second heat treatment means. In this way, the temperature of the electrical storage core 2 oscillates between the minimum temperature threshold and the maximum temperature threshold, and the electrical storage device 1 can thus operate optimally. The temperature of the electrical storage core 2 can for example be regulated so as to be maintained between a minimum temperature threshold value which is equal to 20° C. and a maximum temperature threshold value which is equal to 40° C., or more generally in a temperature range where the electrical storage device 1 operates optimally.

FIG. 3 represents the first embodiment of the electrical storage device 1, with a top view of the structure 3 and of the electrical storage core that it surrounds, and details of the fluid circuits associated with the first processing means heat 7 and the second heat treatment means 8.

Thus, the first heat treatment means 7 and the second heat treatment means 8 may for example respectively comprise a first fluid circuit 15 within which the first fluid circulates, and a second fluid circuit 16 within which the second fluid circulates. as illustrated in FIG. 3. Each fluid circuit 15, 16 comprises a pump intended to circulate the fluid able to circulate therein, as well as at least one heat exchanger allowing a variation in the temperature of the fluid in the purpose of subsequently interacting with the temperature of the electrical storage core 2.

More precisely, the first fluid circuit 15 makes it possible to circulate the first fluid, which has the function of cooling the electrical storage core 2 when the latter exceeds the minimum temperature threshold. In this context, the first fluid is circulated by a first pump 17 then transfers calories within a first heat exchanger 19 so that its temperature is lowered. The first fluid then circulates until it enters the first compartment 10. The first compartment 10 filled with first fluid at low temperature therefore makes it possible to influence the temperature of the electrical storage core 2. The first fluid thus captures calories generated by the electrical storage core 2. In the previously mentioned case where the internal wall 4 has a higher thermal conductivity than the thermal conductivity of the external wall 5, the heat exchanges between the first fluid and the electrical storage core 2 are favoured, by preventing the cold temperatures of the first fluid from being released into the environment outside the electrical storage device 1.

At the outlet of the first compartment 10, the first fluid is at a higher temperature than at the inlet of the first compartment 10, following the capture of calories generated by the electrical storage core 2. The first fluid circulates in the first circuit of fluid 15 until it crosses again the first heat exchanger 19 in order to yield the calories accumulated within the first compartment 10, and this circulation loop is kept active, in particular by activating the first pump 17, until that the temperature of the electrical storage core 2 is sufficiently lowered.

The principle of the second fluid circuit 16 is identical to that of the first fluid circuit 15, except that the second fluid circuit 16 contributes to the increase in the temperature of the electrical storage core 2. The second fluid is therefore driven by a second pump 18 and passes through a second heat exchanger 20 which allows the accumulation of calories from the second fluid and therefore the rise in temperature of the latter. The second fluid subsequently enters the second compartment 11 at high temperature and thus makes it possible to increase the temperature of the electrical storage core 2. This rise in temperature ensures better transmission of the energy from the electrical storage core 2 to electrical or electronic device when it starts up. Raising the temperature of the electrical storage core 2 can also prove useful when the ambient temperature is low.

During the operation of the second heat treatment means 8, the second fluid therefore accumulates calories by crossing the second heat exchanger 20, then transfers them to the electrical storage core 2 by circulating within the second compartment 11. Such an operation continues until the electrical storage core 2 reaches a temperature high enough for the electrical storage device 1 to operate optimally.

It is thus understood that the control module represented in FIG. 2 can activate the first heat treatment means 7 or the second heat treatment means 8, by activating the pump and the heat exchanger relating to said heat treatment means 7, 8 to be activated according to the measured temperature of the electrical storage core 2. These same heat treatment means 7, 8 are deactivated by the control module when the temperature of the electrical storage core 2 is between the minimum temperature threshold and the maximum temperature threshold.

FIG. 4 represents a second embodiment of the electrical storage device 1. This second embodiment differs from the first embodiment by the shape of the electrical storage core 2 and of the structure 3, as well as by the nature of the first heat treatment means 7 and the second heat treatment means 8.

Unlike the first embodiment, the electrical storage core 2 has a rectangular section shape and the structure 3 therefore also has a cylindrical shape with a rectangular section in order to at least partially cover the electrical storage core 2. In general , the electrical storage core 2 and the structure 3 can be presented as any shape, provided that the structure 3 can at least partially match the electrical storage core 2 so that the heat treatment means 7, 8 can act on the temperature of said electrical storage core 2. The first processing means thermal 7 of the second embodiment of the electrical storage device 1 comprises a bundle of microfibers 21.

The microfibers 21 of the first heat treatment means are represented in FIG. 3 in the form of white circles. The microfibers 21 extend into the space 6 of the structure 3 and allow the circulation of a fluid within them. Thus, the first heat treatment means 7 allows the circulation of a refrigerant fluid within the microfibers 21 in the event that the electrical storage core 2 needs to be cooled. The refrigerant fluid may be identical to the first fluid of the first embodiment. The refrigerant fluid can thus circulate within a circuit allowing the circulation and cooling of the refrigerant fluid, like what has been illustrated in FIG. 3 concerning the first fluid circuit 15, then the circuit can be divided into the plurality of microfibers 21 as shown in Figure 3, since each microfiber has ends adapted to be gathered in a connector here not shown and fluidly connected to the first fluid circuit. The microfibers 21 being arranged all along the space 6 of the structure 3, they thus allow a homogeneous distribution of the circulation of the refrigerant fluid all around the electrical storage core 2 in order to cool the latter.

The second heat treatment means 8 may also comprise a bundle of microfibers within which circulates a heating fluid, which may be similar to the second fluid of the first embodiment of the heat treatment system. In the embodiment illustrated in FIG. 4, the second processing means 8 is however presented in an alternative form, with a plurality of heating filaments 22, represented in the form of solid circles, which participate in forming this second processing means. thermal. Unlike the microfibers 21 which allow the circulation of a fluid, the heating filaments 22 are resistive elements which produce heat by the activation of an electric current capable of to cross them. The electrical storage device 1 thus comprises an electrical power source 23, making it possible to activate the heating filaments 22 of the second heat treatment means 8. For reasons of clarity, the electrical power source 23 is only electrically connected than four heating filaments 22 in Figure 3, but it should be understood that the electrical power source 23 is connected to all of the heating filaments 22 of the second heat treatment means 8.

Thus when the temperature of the electrical storage core 2 is too low, and in accordance with what has been previously mentioned below the minimum temperature threshold value, the control module is able to act on the electrical power source 23 in order to that the latter activates the heating filaments 22, so that the latter can heat the electrical storage core 2.

The first heat treatment means 7 and the second heat treatment means 8 are arranged in the space 6 so as to create an alternation between a microfiber 21 of the first heat treatment means 7 and a microfiber or a heating filament 22 of the second means. heat treatment 8, and this all along the space 6. An alternation of the heat treatment means 7, 8 makes it possible to reinforce the homogeneity of the heat treatment of the electrical storage core 2, and this whatever the means of heat treatment 7, 8 which is activated by the control module 9.

Once arranged within the space 6, the first heat treatment means 7 and the second heat treatment means 8 are embedded in a thermally conductive material 12, shown schematically in FIG. 3 by dotted lines. Alternatively, the heat treatment means 7, 8 can initially be embedded in the thermally conductive material 12, then the assembly can be placed in the space 6 of the structure 3. The thermally conductive material 12 makes it possible to fill the space 6 of the structure 3 and to freeze the microfibers 21 of the first heat treatment means 7 and the microfibers or the heating filaments 22 of the second heat treatment means 8. The thermally conductive material 12 can for example be silicone, and can thus ensure the cold transfer of the first heat treatment means 7 to the electrical storage core 2 or the transfer of heat from the second heat treatment means 8 to the electrical storage core 2.

Of course, the invention is not limited to the examples which have just been described and many adjustments can be made to these examples without departing from the scope of the invention. In particular, and without this example being exhaustive of the possible variants, the presence of resistive elements could be provided in the first embodiment, by filling the second compartment with heating filaments instead of the second fluid.

The invention, as it has just been described, successfully achieves the aim it had set itself, and makes it possible to propose a heat treatment system comprising two heat treatment means making it possible to regulate the temperature of a component electric and/or electronic for an electronic system, whether the latter is in the form of a computer server or an electric battery, without these examples being limiting. Variants not described here could be implemented without departing from the context of the invention, provided that, in accordance with the invention, they comprise an electrical and/or electronic component in accordance with the invention, with heat treatment means arranged in the volume of a protective structure, so as to be as close as possible to this electrical and/or electronic component, and distributed so as to be able to selectively cool or heat this electrical and/or electronic component.

Claims

1- electrical and / or electronic component (I) for an electronic system, comprising at least one structure (3) defined by an internal wall (4) and an external wall (5) separated from each other by a space (6), characterized in that the electrical and/or electronic component (1) comprises at least one first heat treatment means (7) and at least one second heat treatment means (8) arranged within the space (6) of the structure (3) and capable of regulating the temperature of the electrical and/or electronic component. 2- electrical and / or electronic component (1) according to claim 1, comprising a control module (9) capable of activating the first heat treatment means (7) or the second heat treatment means (8) selectively. 3- Electrical and/or electronic component (1) according to any one of the preceding claims, in which the structure (3) comprises a first compartment (10) and a second compartment (11) participating respectively in forming the first processing means (7) and the second heat treatment means (8), the two compartments (10, 11) being distinct from each other so as to be traversed by a first fluid and a second fluid respectively. 4- electrical and / or electronic component (1) according to any one of claims 1 or 2, wherein the first heat treatment means (7) comprises a plurality of microfibers (21) arranged in the space (6) of the structure (3), said microfibers (21) being configured to be traversed by a refrigerant fluid. 5- electrical and / or electronic component (1) according to the preceding claim, wherein the second heat treatment means (8) comprises a plurality of microfibers (21) arranged in the space (6) of the structure (3), said microfibers (21) being configured to be traversed by a heating fluid. 6- electrical and / or electronic component (1) according to claim 4, wherein the second heat treatment means (8) comprises a plurality of heating filaments (22) arranged in the space (6) of the structure (3) and connected to an electrical power source (23). 7- electrical and / or electronic component (1) according to any one of claims 4 to 6, wherein the first heat treatment means (7) and the second heat treatment means (8) are arranged in the space ( 6) of the structure (3) so as to form an alternation between the first heat treatment means (7) and the second heat treatment means (8). 8- electrical and / or electronic component according to any one of claims 4 to 7, wherein the space (6) of the structure (3) is filled with a thermally conductive material (12), the first heat treatment means (7) and the second heat treatment means (8) being embedded in the thermally conductive material (12). 9- electrical and / or electronic component according to any one of the preceding claims, wherein the inner wall (4) and the outer wall (5) have different thermal properties, the inner wall (4) having a higher thermal conductivity than that of the outer wall (5). 10- Electronic system comprising at least one electrical and / or electronic component according to one of the dependent claims.