WO2022268583A1 - Electronic system comprising at least one electrical and/or electronic component and a thermal control device - Google Patents

Abstract

The invention relates to an electronic system comprising electrical and/or electronic components likely to give off heat during their operation, and a device (4) for thermal control of the electrical and/or electronic components (6), the thermal control device (4) comprising a casing (8) configured to house the electrical and/or electronic components (6) which are arranged in the casing (8) so as to form at least two rows of electrical and/or electronic components (6) extending in a first longitudinal direction (L), the two rows of electrical and/or electronic components (6) helping to delimit therebetween a central duct (28) extending in this first longitudinal direction (L), the thermal control device (4) being configured to thermally control these electrical and/or electronic components (6) via a dielectric fluid capable of at least partially immersing the electrical and/or electronic components (6), characterised in that the thermal control device (4) comprises at least one heat exchanger (24) configured for the dielectric fluid and a heat-transfer fluid to pass through same, the heat exchanger (24) being configured to project the dielectric fluid at least through the central duct (28).

Description

DESCRIPTION

Title ^ Electronic system comprising at least one electrical and/or electronic component and a thermal regulation device.

The present invention lies in the field of electronic systems comprising at least one electrical and/or electronic component, and it relates more particularly to a device for thermal regulation of electrical and/or electronic components liable to heat up during their operation.

The electronic systems likely to be concerned by the present invention may consist of computer servers as well as electrical energy storage systems, in particular batteries, for motor vehicles.

In the field of motor vehicles, thermal regulation devices make it possible to modify the temperature of an electric battery, whether when starting the vehicle in cold weather, by increasing its temperature for example, or whether driving or during a battery recharging operation, by reducing the temperature of this electric battery, which tends to heat up during use.

In general, such devices for thermal regulation of electric batteries make use of heat exchangers. The various battery cells of an electrical storage system can in particular be cooled by means of a cold plate inside which a cooling fluid circulates, the plate being in contact with the battery cells to be cooled.

It has been observed that such heat exchangers can lead to inhomogeneous cooling of the electric batteries of the same electric storage system, then leading to a reduction in the overall performance of the electric storage system. These thermal regulation devices also have a high thermal resistance due to the thicknesses of material present between the cooling fluid and the battery cells.

In order to provide an answer to these various problems, there are known devices for cooling electric car battery elements electric or hybrid comprising a hermetically sealed casing in which the battery cells of the electrical energy storage system are partially immersed in a dielectric fluid. In this way, heat exchange is ensured between the battery cells and the dielectric fluid, a tank of dielectric fluid being located outside the casing and connected to said casing via a pump in order to allow the circulation of the fluid dielectric and the renewal of this dielectric fluid inside the case. In this way, the dielectric fluid, set in motion and cooled prior to its return to the casing, is also capable of circulating inside the casing around the electrical storage cells. However, it should be noted that when the cooled dielectric fluid is set in motion by the pump, the storage cells arranged furthest from the inlet of dielectric fluid in the casing are less well cooled by heat exchange with the dielectric fluid. than the storage cells which are located closest to the dielectric fluid inlet, so that the cooling of the electrical or electronic components is not carried out uniformly.

The present invention falls within this context and has as its main object an electronic system comprising electrical and/or electronic components capable of releasing heat during their operation and a device for thermal regulation of the electrical and/or electronic components, the thermal regulation device comprising a casing configured to house the electrical and/or electronic components which are arranged in the casing so as to form at least two rows of electrical and/or electronic components extending along a first longitudinal direction, the two rows of electrical and/or electronic components participating in delimiting between them a central conduit extending in this first longitudinal direction, the regulating device being configured to thermally regulate these electrical and/or electronic components via a dielectric fluid capable of immersing at least in part the electrical components cs and/or electronics, characterized in that the thermal regulation device comprises at least one heat exchanger configured to be traversed by the dielectric fluid and a heat transfer fluid, the heat exchanger being configured to project the dielectric fluid at least through the center duct. The thermal regulation device aims to reduce the temperature of several electrical and/or electronic components thanks to the circulation of the cooled dielectric fluid between the electrical and/or electronic components. The dielectric fluid is also cooled by heat exchange with the heat transfer fluid at the heat exchanger. It is understood from this that the dielectric fluid is cooled in the heat exchanger by heat exchange with the heat transfer fluid, then is directed towards the electrical and/or electronic components to cool them in turn.

The dielectric fluid is directed into the housing, after having been thermally regulated through the heat exchanger, under the effect of the actuation of a pumping member, the outlet of the heat exchanger being configured so that the dielectric fluid is first pushed through the central duct between the rows of electrical and/or electronic components. By circulating through the central duct, the dielectric fluid has as possible escape only the spaces between two electrical and/or electronic components of the same row, in the direction of lateral ducts formed along the side walls of the case arranged symmetrically in either side of the central duct, so that this fluid can be distributed evenly between these two rows of electrical and/or electronic components.

According to an optional characteristic of the invention, the heat exchanger is secured to a wall of the casing at the level of the central duct formed between the two rows of electrical and/or electronic components. The wall of the box on which the heat exchanger is fixed is chosen so that the heat exchanger is arranged at a longitudinal end of the central duct or else that it is arranged in the middle of the central duct. In this context, the heat exchanger is installed in the central duct, between the two rows of electrical and/or electronic components.

According to another optional feature of the invention, the electrical and/or electronic components are arranged in each row parallel to each other, and more particularly perpendicular to the longitudinal direction L of the central duct, two neighboring electrical and/or electronic components d 'a same row participating in defining a channel of circulation extending substantially perpendicular to the central conduit, that is to say substantially along the transverse direction T and connecting the central conduit to a side conduit arranged along a wall of the housing. The circulation channels extending perpendicular to the central duct may all have the same width, measured between two neighboring electrical and/or electronic components which delimit them.

In other words, the thermal regulation device is such that circulation channels are arranged regularly from one longitudinal end to the other of the housing, the dielectric fluid being able to join in a regular manner lateral ducts formed between a row of components electrical and / or electronic and the wall of the facing case, to circulate in the opposite direction relative to the central conduit formed between the two rows of electrical and / or electronic components and form a circulation loop passing through the heat exchanger.

According to another optional characteristic of the invention, the electrical and/or electronic components are arranged in the casing so as to form at least two rows of electrical and/or electronic components extending along a second transverse direction perpendicular to the first longitudinal direction, the heat exchanger being aligned with two electrical and/or electronic components of the same alignment. In other words, the heat exchanger is arranged, in a direction perpendicular to a main direction of elongation of the central duct, between a first electrical and/or electronic component of one of the two rows and a second electrical component and/or or electronics on the other of the two rows. In this way, the heat exchanger, and if necessary the pumping member, is arranged across the housing of the electrical and/or electronic components, as close as possible to them, without however being across them, or the least. possible of a fluid circulation channel formed between two neighboring electrical and/or electronic components.

According to another optional characteristic of the invention, the box comprises a bottom wall, side walls extending perpendicularly to the bottom wall and a cover extending parallel to the bottom wall, the bottom wall, the side walls and the cover participating in delimiting a housing in which the electrical and/or electronic components are arranged, and the heat exchanger, the heat exchanger being arranged at a distance from the side walls arranged perpendicular to the direction of longitudinal elongation of the center duct.

Thus, the heat exchanger, and if necessary the associated pumping member, is then arranged across the central duct. The distance between the side wall opposite the outlet of the heat exchanger is thus reduced with respect to a position in which the heat exchanger is at a longitudinal end of the central duct. The distance to be traveled by the dielectric fluid to reach this side wall opposite the outlet of the heat exchanger is thus reduced, and in particular halved if the heat exchanger is in a central position. The number of first electrical and/or electronic components along which the fluid must circulate in the central duct in the direction of discharge circulation, namely the direction of circulation of the dielectric fluid at the outlet of the heat exchanger, and the number of circulation channels into which the fluid flowing in the discharge circulation direction enters, is thus limited and the corresponding heat exchange surface decreases. Consequently, the flow rate of dielectric fluid circulating facing these first electrical and/or electronic components is increased. At the end of the fluid circulation loop, the distance to be covered by the dielectric fluid to reach the inlet of the heat exchanger from the side wall facing this inlet is again reduced compared to the total longitudinal distance of the conduit central. The number of second electrical and/or electronic components along which the fluid must circulate in the central duct in the direction of suction circulation, namely the same direction of circulation as that of discharge, but upstream of the heat exchanger , and the number of circulation channels from which the fluid exits to take the direction of suction circulation in the central duct, is thus reduced and the corresponding heat exchange surface is reduced. Consequently, a high flow rate of dielectric fluid circulating opposite these second electrical and/or electronic components is ensured. A position of the heat exchanger across the central duct thus makes it possible to optimize the flow rate of fluid circulating along the electrical and/or electronic components, that is to say to limit the difference between the flow rate of dielectric fluid circulating along the electrical and/or electronic components furthest from the heat exchanger and the flow rate of dielectric fluid circulating along the electrical and/or electronic components closest to the heat exchanger, so as to limit the regulation differential heat possible between two electrical and/or electronic components of the same row.

According to another optional characteristic of the invention, the heat exchanger is installed substantially in the center of the bottom wall of the box, or of the cover of the box. The housing can advantageously take the shape of a rectangular parallelepiped, each of the walls of the housing extending by taking a rectangular shape, so that the heat exchanger is arranged in the center of one of the walls of the housing among the bottom wall or lid.

According to another optional characteristic of the invention, the same number of electrical and/or electronic components and/or the same number of circulation channels is installed on either side of the heat exchanger in the first longitudinal direction. In other words, an equivalent number of electrical and/or electronic components is arranged in the housing on either side of a plane perpendicular to the main direction of elongation of the central duct and passing through the heat exchanger.

According to another optional characteristic of the invention, the box comprises a bottom wall, side walls extending perpendicularly to the bottom wall and a cover extending parallel to the bottom wall, the bottom wall, the walls sides and the cover participating in delimiting a housing in which the electrical and/or electronic components and the heat exchanger are arranged, the heat exchanger being arranged on a side wall perpendicular to the direction of longitudinal elongation of the central duct. In other words, the heat exchanger is arranged at a longitudinal end of the central duct. According to another optional feature of the invention, the heat exchanger is placed inside a recess formed in said side wall.

According to another optional characteristic of the invention, the heat exchanger comprises a dielectric fluid inlet and a dielectric fluid outlet fluidly communicating with the housing of the housing, the heat exchanger comprising a heat transfer fluid inlet and a heat transfer fluid outlet fluidly communicating with a heat transfer fluid circulation system, a pumping member being arranged at the level of the dielectric fluid inlet or at the level of the dielectric fluid outlet.

According to one characteristic of the invention, the electronic system as it has just been described above can take the form of an electrical energy storage system of a motor vehicle, in which the electrical and/or electronic components take the form of electrochemical cells forming a battery.

Other characteristics, details and advantages of the invention will emerge more clearly on reading the description which follows on the one hand, and several examples of embodiment given by way of indication and not limitation with reference to the appended schematic drawings on the other. part, on which:

[Fig. î] is a general view of an electrical storage system according to the invention housed within a motor vehicle, comprising a thermal regulation device and electrical and/or electronic components;

[Fig. 2] is a general perspective view of a housing of the thermal regulation device of FIG. i comprising the electrical and/or electronic components;

[Fig. 3] is a view according to a longitudinal section of the thermal regulation device of FIG. 2 in which is housed a heat exchanger between the dielectric fluid and a heat transfer fluid, according to a first embodiment of the invention;

[Fig. 4] is a view according to a longitudinal section of the thermal regulation device of FIG. 2 in which is housed a heat exchanger between the dielectric fluid and a heat transfer fluid, according to a second embodiment of the invention.

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

In the figures, the elements common to several figures retain the same reference.

In the detailed description which follows, the denominations "longitudinal",

"transverse" and "vertical" refer to the orientation of an electronic system according to the invention. A longitudinal direction corresponds to a main direction of elongation of a central duct of the electronic system, this longitudinal direction being parallel to a longitudinal axis L of an L, V, T illustrated in the figures. A transverse direction corresponds to a direction along which a circulation channel mainly extends, this transverse direction being parallel to a transverse axis T of the reference L, V, T and this transverse axis T being perpendicular to the longitudinal axis L Finally, a vertical direction corresponds to a direction parallel to a vertical axis V of the reference L, V, T, this vertical axis V being perpendicular to the longitudinal axis L and the transverse axis T.

Furthermore, in the detailed description which follows, the thermal regulation device according to one aspect of the invention will be described in relation to an electronic system in the form of a motor vehicle electrical energy storage system, but it must be understood that such an application is not limiting and that it could in particular be applied in the context of the invention to electrical and/or electronic components equipping other electronic systems and for example computer servers.

In FIGS. i and 2, an electrical storage system i, suitable in particular for equipping a motor vehicle 2 with electric or hybrid motorization, is illustrated. Such an electrical storage system i is intended in particular to supply electrical energy to the motor vehicle 2 with a view to its movement.

The electrical storage system i comprises a thermal regulation device 4 configured to cool or raise the temperature of each electrical or electronic component 6 forming part of the electrical storage system 1, these components being in particular liable to heat up during their operation or to their load.

More particularly, this thermal regulation device 4 comprises at least one casing 8 which is configured to receive a plurality of said electrical and/or electronic components 6, here taking the form of battery cells 10, and it further comprises means of thermal regulation 12 capable of regulating the temperature of the electrical or electronic components 6 inside the casing 8. It should be noted that other configurations of the electrical storage system 1 could be implemented according to the invention as soon as this system comprises a thermal regulation device 4 in accordance with the invention.

The casing 8 comprises a plurality of walls which define inside this casing 8 a housing 14, more particularly visible in FIG. 2, which is configured to receive at least the electrical and/or electronic components 6 and the regulation means thermal 12. The walls defining the housing 8 form in particular a base 16 and a cover 18.

Base 16 includes a bottom wall 20 and a plurality of side walls 22. More specifically, bottom wall 20 extends in a plane parallel to the longitudinal L and transverse T directions generally in the form of a quadrilateral, advantageously rectangular, the side walls 22 for their part each extending from one side of the bottom wall 20 while being inscribed in a plane parallel to the longitudinal L and vertical V directions. In other words, the side walls 22 s extend from the bottom wall 20 perpendicular to the latter.

The cover 18 has a shape substantially identical to that of the bottom wall 20, therefore here in the form of an advantageously rectangular quadrilateral, and is arranged to cover the base 16 of the housing 8 and close the opening between the side walls 22 whereby the electrical and/or electronic components 6 are placed in the housing 14. It is understood in particular that the cover 18 is arranged overhanging the base 16, in contact with the free edges of the side walls 22, in particular when the electrical storage system 1 is mounted on the motor vehicle 2.

Furthermore, the base 16 and the cover 18 are also fixed to each other so as to seal the housing 14 of the casing 8 from the external environment of the casing 8. 16 and the cover 18 are made integral with each other so that no exchange of fluid can be achieved between the interior of the housing 14 of the housing 8 and the external environment of the housing 8 at the level of the interaction between base and lid.

As illustrated in Figures 3 and 4, which shows the electrical storage system 1 seen along a section plane P and according to two alternative embodiments, the electrical and / or electronic components 6 are arranged in the housing 14 of the housing 8 in the form of at least two rows, that is to say that the electrical and/or electronic components 6 form two sets aligned along a direction parallel to the longitudinal direction L. A first part of the electrical and/or electronic components electronic components 6 form a first set arranged in the form of a first row of electrical and/or electronic components 6 aligned along a first direction parallel to the longitudinal direction L, and a second part of the electrical and/or electronic components electronics 6 form a second assembly arranged in the form of a second row of electrical and/or electronic components 6 aligned along a second direction parallel to the direction longitudinal tion L and the first direction. In this configuration, the two rows of electrical and/or electronic components 6 contribute to delimiting in the housing 14 a central duct 28 which extends along a main direction of elongation A which is advantageously substantially parallel to the longitudinal direction L, this duct also being visible in Figure 2.

The electrical and/or electronic components 6 are arranged in each row parallel to each other, and more particularly perpendicular to the longitudinal direction L. Two electrical and/or electronic components 6 adjacent to the same row participate in defining a channel of circulation 30 extending substantially perpendicular to the central duct 28, that is to say substantially along the transverse direction T. These circulation channels 30 extend from the central duct to a lateral duct 31 formed along of the longitudinal direction L between a side wall 22 and each of the electrical and/or electronic components 6 of a row.

In the example illustrated, the electrical and/or electronic components have the shape of a cell of rectangular section, with long sides which extend opposite the electrical and/or electronic component of the row which is directly adjacent and short sides which extend respectively along the central duct 28 and the corresponding side duct 31. It should however be noted that without departing from the context of the invention, provision could be made for the electrical and/or electronic components to have a different shape and in particular the shape of a cylinder of circular section, several electrical and/or electronic components therefore being able to be grouped together in a set presenting a layout parallel to other similar sets of the same row.

In addition, at least one electrical and/or electronic component 6 of each row is aligned with an electrical and/or electronic component 6 of another row substantially along the transverse direction T. Advantageously and according to the example illustrated in FIG. 3, each electrical and/or electronic component 6 of one of the two rows is aligned with an electrical and/or electronic component 6 of the other row substantially along a direction parallel to the transverse direction T. understands from this that each circulation channel 30 defined by the electrical and/or electronic components 6 of one of the two rows is also aligned transversely with one of the circulation channels 30 defined by the electrical and/or electronic components 6 of the other row, these two channels being arranged symmetrically on either side of the central duct 28.

As can be seen more particularly in FIGS. 3 and 4, the thermal regulation means 12 comprise in particular a heat exchanger 24, capable of cooling a dielectric fluid intended to be sprayed onto the electrical and/or electronic components, and a pumping member 26 of the dielectric fluid forcing the circulation of the dielectric fluid at least in the heat exchanger 24.

The dielectric fluid participates in the thermal regulation of the electrical and/or electronic components 6 by exchanging calories with said electrical and/or electronic components 6. For this, the dielectric fluid is contained in the housing 14 of the casing 8, the electrical components and / or electronic 6 being at least partly immersed in the dielectric fluid, thus allowing the exchange of heat on all of the external surfaces of the electrical and / or electronic components 6 which is immersed. Advantageously, all the electrical and/or electronic components 6 are totally immersed in the dielectric fluid, thus optimizing their thermal regulation by the dielectric fluid.

According to the invention, the heat exchanger 24 allows the exchange of calories between the dielectric fluid and a heat transfer fluid circulating through a heat transfer fluid circuit not shown in the figures. For this and as illustrated in Figures 3 and 4, the heat exchanger 24 comprises a first pass 32 through which the dielectric fluid can circulate and a second pass 34 through which the heat transfer fluid can circulate.

The first pass 32 has a dielectric fluid inlet 36 fluidly connected to the housing 14 in which the dielectric fluid is contained and a dielectric fluid outlet 38 also fluidically connected to the housing 14. The second pass 34 is itself constitutive of the fluid circuit heat carrier, also external to the electrical storage system. The exchange of calories between the dielectric fluid and the heat transfer fluid takes place when said dielectric and heat transfer fluids respectively circulate through their pass 32, 34. For example, the dielectric fluid circulating in the first pass 32 can yield calories to the benefit of the heat transfer fluid circulating in the second pass 34, the temperature of the dielectric fluid thus being reduced by this loss of calories, or the dielectric fluid circulating in the first pass 32 can capture calories transferred by the heat transfer fluid circulating in the second pass 34, the temperature of the dielectric fluid thus being increased by this calorie intake. It is understood from the above that the temperature of the dielectric fluid is thermally regulated at the level of the heat exchanger 24 by the heat transfer fluid, thanks to an exchange of calories between the dielectric fluid circulating in the first pass 32 and the heat transfer fluid circulating in the second pass 34

The pumping member 26 forces the circulation of the dielectric fluid at least through the heat exchanger 24. More precisely, the pumping member 26 forces the circulation of the dielectric fluid at least through the first pass 32 of the heat exchanger 24.

Advantageously, the pumping member 26 is configured to force the circulation of the dielectric fluid on the one hand through the heat exchanger 24, and on the other hand through the housing 14. Thanks to the pumping member 26, which draws in part of the dielectric fluid present in the housing and which generates a movement of the dielectric fluid in which the electrical and/or electronic components 6 are immersed, the dielectric fluid is thermally regulated by circulating through the heat exchanger 24, then is directed in the housing 14 to the electrical and/or electronic components 6, which are therefore supplied with cooled dielectric fluid and more capable of ensuring their thermal regulation.

According to the example illustrated in Figures 3 and 4, the pumping member 26 is preferably arranged at the dielectric fluid inlet 36 of the heat exchanger 24, but it should be noted that without departing from the context of the invention, the pumping member could be placed at the level of the dielectric fluid outlet 38 and more generally could be either placed in the housing 14, since it fulfills its function of forcing the circulation of the dielectric fluid at through heat exchanger 24 and housing 14.

According to the invention, the heat exchanger 24 is installed in the housing 14 of the casing 8 at the level of the central duct 28 between the two rows of electrical and/or electronic components 6. In other words, the dielectric fluid outlet 38 of the heat exchanger 24 is arranged opposite at least a portion of the central duct 28. The thermally regulated dielectric fluid at the level of the first pass 32 of the heat exchanger 24 and expelled from the heat exchanger 24 at the level of the dielectric fluid outlet 38 then circulates in at least a portion of the central conduit 28.

As will be described in more detail below with reference to the embodiments illustrated in Figures 3 and 4, the heat exchanger 24 can be installed according to the invention on a side wall or substantially in the center of the central duct, it being understood that in each of these cases it is installed substantially equidistant from the two rows of electrical and/or electronic components 6.

In each of these configurations, the pumping member 26 and the heat exchanger 24 are configured to propel the dielectric fluid through the central conduit 28 formed between two rows of electrical and/or electronic components 6. As illustrated schematically in Figures 3 and 4, the dielectric fluid is propelled by the pumping member 26 from the dielectric fluid outlet 38 in the central conduit 28 along the main direction of elongation A, the flow of the dielectric fluid in the conduit central 28 being represented by solid arrows. The dielectric fluid circulates in a first direction in the central duct 28 at the outlet of the heat exchanger 24 then in each of the circulation channels 30 between the electrical and/or electronic components 6 before returning in the direction of the heat exchanger 24 in flowing in a second direction opposite to the first direction via the side ducts 31

A first embodiment of the invention will now be described more particularly, with reference to FIG. 3, which is particular in that the heat exchanger 24 takes a central position, at a distance from each of the side walls, being like previously mentioned arranged in the axis of the central duct 28.

The heat exchanger 24 is thus installed on a separate wall from the side walls, at a distance from the latter. The heat exchanger can in particular be installed on the bottom wall 20 of the casing 8, and more particularly, be installed in the center of the bottom wall 20 of the casing 8. In this configuration, the heat transfer fluid circuit can pass through the wall of bottom 20 of housing 8 so as to be able to be fluidically connected to second pass 34 of heat exchanger 24. alternatively, the heat exchanger 24 can be installed on the cover 18 of the box 8, and more particularly in the center of the cover 18 of the box 8, and the heat transfer fluid circuit can pass through the cover to be fluidically connected to the second pass 34 of the heat exchanger 24. It results from this central position that the heat exchanger 24 is installed in the central duct 28 delimited by the electrical and/or electronic components 6. Consequently, the heat exchanger 24 divides into a first portion 28a and in a second portion 28b the central conduit 28, the dielectric fluid inlet 36 being arranged opposite the first portion 28a of the central conduit 28, the dielectric fluid outlet 38 being arranged opposite the second portion 28b of the conduit central 28.

Advantageously, the heat exchanger 24 is arranged between a first electrical and/or electronic component 6 of one of the two rows and a second electrical and/or electronic component 6 of the other of the two rows. In other words, the heat exchanger 24 is aligned with two electrical and/or electronic components 6 of a respective row. This alignment of the heat exchanger 24 with two electrical and/or electronic components 6 along a direction perpendicular to the main direction of elongation A of the central duct 28 makes it possible to ensure that all of the circulation channels 30 is released to facilitate the circulation of dielectric fluid.

In this configuration, the dielectric fluid outlet 38 faces two circulation channels 30 arranged symmetrically on either side of the central duct 28 and respectively delimited by two electrical and/or electronic components 6 of the same row. The thermally regulated dielectric fluid in the heat exchanger 24 and directed into the housing at the level of the dielectric fluid outlet 38 is split into a first portion which circulates mainly in the central conduit 28, and into a second and a third portion which circulate respectively in the circulation channels facing the dielectric fluid outlet 38, the first portion of the dielectric fluid being larger than the second and third portions due to the larger fluid passage section of the central conduit than that of the channels of circulation 30. As the dielectric fluid circulates through the central duct, in a direction of circulation opposite the heat exchanger 24, a portion of dielectric fluid is deflected laterally through a circulation channel to circulate between two electrical and/or electronic components.

As illustrated in the figures, the fluid circulating in the circulation channels 30 coming from the second portion 28b of the central conduit then emerges into the side conduits 31 along the side walls 22 of the housing 8 before returning to the first portion 28a from the central duct via other circulation channels.

When the dielectric fluid circulates through the central duct 28, the circulation channels 30 and along the transverse walls 22 of the housing 8, said dielectric fluid runs along the external surfaces of the electrical and/or electronic components 6 resulting in a heat exchange between the fluid dielectric and electrical and/or electronic components 6.

In the example illustrated in Figure 3, the heat exchanger is arranged in the center of the housing 14, being equidistant from the opposite side walls in the longitudinal direction. In this configuration, the same number of electrical and/or electronic components 6 is arranged in the casing 8 longitudinally on either side of the heat exchanger 24, or more particularly on either side of a plane perpendicular to the main direction of elongation A of the central duct 28 and passing through the heat exchanger 24. Similarly, the same number of circulation channels 30 are arranged in the housing 8 longitudinally on either side of the heat exchanger 24, or more particularly on either side of a plane perpendicular to the main direction of elongation A of the central duct 28 and passing through the heat exchanger 24.

According to the example illustrated here, six electrical and/or electronic components 6 and eight circulation channels 30 are located on either side of the heat exchanger 24. In other words, six electrical and/or electronic components 6 and eight circulation channels 30 participate in defining the first portion 28a of the central conduit 28 while six other electrical and/or electronic components 6 and eight circulation channels 30 participate in defining the second portion 28b of the central conduit 28. As mentioned, the invention allows homogeneous thermal regulation between the rows of electrical and/or electronic components 6 due to the position of the heat exchanger in alignment with the central duct 28, and more particularly due to the arrangement of the dielectric fluid outlet of the heat exchanger in alignment with the central duct. The particular configuration with a heat exchanger arranged in the center, or more generally with a heat exchanger arranged at a distance from the side walls arranged perpendicular to the central duct, makes it possible to reduce the distance between the heat exchanger and the electrical and/or electronic components furthest from this heat exchanger, and therefore to cause a dielectric fluid to circulate at a higher rate along these furthest electrical and/or electronic components.

In other words, the flow rate of dielectric fluid within the circulation channels 30 tends to decrease as the distance between the circulation channels 30 and the heat exchanger 24 increases, and the first exemplary embodiment aims to reduce the maximum distance between a circulation channel 30 and the heat exchanger 24.

By way of example, to illustrate the advantage of such a central position of the heat exchanger, it should be noted that, on the side of the second portion 28b of the central duct 28, the flow rate of dielectric fluid circulating in the channel circulation channel 30 farthest from the heat exchanger is of a lower value of the order of 10% compared to the flow rate of dielectric fluid circulating in the circulation channel 30 closest to the heat exchanger, whereas in the case where the heat exchanger is arranged at one end of the central duct, the flow rate of dielectric fluid circulating in the circulation channel 30 farthest from the heat exchanger is of a lower value of the order of 30% by relative to the flow rate of dielectric fluid circulating in the circulation channel 30 closest to the heat exchanger.

A second embodiment of the invention will now be described more particularly, with reference to FIG. 4, which is particular in that the heat exchanger 24, still arranged in the axis of the central conduit 28 in accordance with , is here arranged in the vicinity of one of the side walls. The heat exchanger 24 is housed inside the casing opposite a side wall perpendicular to the longitudinal direction of the duct, and in particular inside a recess 25 formed in this side wall. A compartmentalization wall can be provided to close this recess and allow the heat exchanger to be dry, that is to say not in contact with the dielectric fluid present in the housing, or the recess can be filled with dielectric fluid with the heat exchanger which is submerged, it being understood that this heat exchanger is sealed against any inlet of dielectric fluid other than at the inlet of dielectric fluid 36.

This second embodiment makes it possible not to reduce the space available for the electrical and/or electronic components 6 within the housing inside the casing 8, while ensuring that the dielectric fluid at the outlet of the heat exchanger is directed at the center of two rows of electrical and/or electronic components, to participate in cooling of these components which is homogeneous from one row to the other.

It follows from the foregoing, and in particular from the detailed description of two exemplary embodiments, that the invention succeeds in achieving the goal it has set itself, namely achieving homogeneous thermal regulation of the electrical and/or electronic components. 6, whether from one row to another or even within each row of these components.

The present invention cannot however be limited to the means and configurations described and illustrated here and it also extends to any equivalent means and configuration as well as to any technically effective combination of such means.

Claims

1. Electronic system (1) comprising electrical and/or electronic components (6) capable of releasing heat during their operation and a device for thermal regulation (4) of the electrical and/or electronic components (6), the device thermal regulation (4) comprising a casing (8) configured to house the electrical and/or electronic components (6) which are arranged in the casing (8) so as to form at least two rows of electrical and/or electronic components ( 6) extending along a first longitudinal direction (L), the two rows of electrical and/or electronic components (6) helping to delimit between them a central duct (28) extending along this first longitudinal direction ( L), the thermal regulation device (4) being configured to thermally regulate these electrical and/or electronic components (6) via a dielectric fluid capable of at least partially immersing the electrical components and/or electronics (6), characterized in that the thermal regulation device (4) comprises at least one heat exchanger (24) configured to be traversed by the dielectric fluid and a heat transfer fluid, the heat exchanger (24) being configured to project the dielectric fluid at least through the central conduit (28).

2. Electronic system (1) according to the preceding claim, wherein the heat exchanger (24) is secured to a wall of the housing (8) at the level of the central duct (28) formed between the two rows of electrical components and /or electronic (6).

3. Electronic system (1) according to any one of the preceding claims, in which the electrical and/or electronic components (6) are arranged in each row parallel to each other, and more particularly perpendicular to the longitudinal direction L of the conduit (28), two neighboring electrical and/or electronic components (6) of the same row participating in defining a circulation channel (30) extending substantially perpendicular to the central conduit (28) and connecting the central conduit (28) to a side duct (31) arranged along a wall of the casing.

4. Electronic system (1) according to any one of the preceding claims, in which the electrical and/or electronic components (6) are arranged in the casing so as to form at least two rows of electrical and/or electronic components (6) extending along a second transverse direction (T) perpendicular to the first longitudinal direction (L), the heat exchanger (24) being aligned with two electrical and/or electronic components (6) of the same alignment.

5. Electronic system (1) according to any one of the preceding claims, in which the housing (8) comprises a bottom wall (20), side walls (22) extending perpendicular to the bottom wall (20) and a cover (18) extending parallel to the bottom wall (20), the bottom wall (20), the side walls (22) and the cover (18) participating in delimiting a housing (14) in which are arranged the electrical and/or electronic components (6) and the heat exchanger (24), the heat exchanger (24) being arranged at a distance from the side walls arranged perpendicular to the central duct (28).

6. Electronic system (1) according to the preceding claim, wherein the heat exchanger (24) is installed substantially in the center of the bottom wall (20) or the cover (18) of the housing (8).

7. Electronic system (1) according to any one of the preceding claims, where appropriate in combination with claim 3, in which the same number of electrical and/or electronic components (6) and/or the same number of circulation (30) is installed on either side of the heat exchanger (24) in the first longitudinal direction (L).

8. Electronic system (1) according to any one of claims 1 or 2, wherein the housing (8) comprises a bottom wall (20), side walls (22) extending perpendicular to the bottom wall ( 20) and a lid (18) extending parallel to the bottom wall (20), the bottom wall (20), the side walls (22) and the lid (18) participating in delimiting a housing (14) in which are arranged the electrical and/or electronic components (6) and the heat exchanger (24), the heat exchanger (24) being arranged on a side wall (22) perpendicular to the direction of longitudinal elongation of the central duct ( 28).

9. Electronic system (1) according to the preceding claim, in which the heat exchanger (24) is disposed within a recess (25) formed in said side wall (22).

10. Electronic system (1) according to one of the preceding claims and taking the form of an electrical energy storage system of a motor vehicle, in which the electrical and/or electronic components (6) take the form of electrochemical cells constituting a battery.