WO2023089029A1

WO2023089029A1 - Device for cooling an electrical and/or electronic component liable to release heat during operation

Info

Publication number: WO2023089029A1
Application number: PCT/EP2022/082275
Authority: WO
Inventors: Bastien Jovet; Sergio Da Costa Pito; Quentin NAVARRE
Original assignee: Valeo Systemes Thermiques
Priority date: 2021-11-21
Filing date: 2022-11-17
Publication date: 2023-05-25
Also published as: FR3129529A1; FR3129529B1

Abstract

The invention relates to a device (1) for thermal management of an electrical and/or electronic component (2) liable to release heat during its operation, comprising at least one face, the device comprising a housing (3), the housing comprising a main compartment (4) defining at least one receptacle (5) able to receive the electrical and/or electronic component (2), the receptacle (5) being designed to receive a dielectric fluid and being delimited by a first (6) and second longitudinal wall, a first side wall (7), a second side wall (8) and a bottom wall (9), characterized in that at least one of the walls (6, 7, 8, 9) has at least one semi-open channel (10) defining a dielectric fluid circulation path.

Description

Title: “DEVICE FOR COOLING AN ELECTRICAL AND/OR ELECTRONIC COMPONENT LIKELY TO RELEASE

HEAT IN OPERATION »

[0001]. The present invention lies in the field of devices for thermal regulation of electrical and/or electronic components capable of releasing heat in operation.

[0002]. Electrical and/or electronic components, whether electrical energy storage cells, integrated circuits, servers, data centers, etc. require thermal regulation to keep them within their operating temperature range.

[0003]. Data centers around the world currently account for 10% of global electricity consumption. The advent of “blockchain” and 5G technologies means that this percentage could increase drastically in the coming years. At least half of this consumption comes from the cooling systems of these data centers. Currently the majority of data centers are air-cooled by cooling the ambient air of the storage rooms by air conditioning devices. The optimal operating temperature for data centers is between 5°C and 40°C, more particularly around 27°C. Considering that air has a very low conductivity, in order to sufficiently cool the electrical and/or electronic components, which can reach temperatures exceeding 60°C, the temperature difference between the air and the electrical components and/or electronics to be cooled must be significant and therefore this type of device is very energy-intensive.

[0004]. In the automotive field, for example, it is known to implement electric batteries in the form of electronic modules capable of generate heat during operation. Each module may comprise a plurality of electronic cells capable of releasing heat in operation received in a casing. High density energy storage cells such as Li-ion or Li-polymer batteries ideally need to operate in a temperature range between 20°C and 40°C, and too low a temperature impacts their autonomy while too high a temperature affects their lifespan.

[0005]. 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 performance of these electric batteries. These thermal treatment devices also have a high thermal resistance due to the thicknesses of material present between the cooling fluid and the battery cells, another parameter contributing to the high thermal resistance being the contact between the cooling plates, the interfaces (PAD) and cell surfaces.

[0006]. In order to provide an answer to these different problems, several devices are known.

[0007]. The document FR3037727 is known in particular, in which a device for cooling the electric batteries of electric or hybrid cars is disclosed. More particularly, this document relates to a device for cooling the cells of the electric batteries of a battery pack of the Ion-Lithium type. It comprises a hermetically sealed case in which a dielectric fluid circulates. The electrical storage cells are partially immersed in the dielectric fluid, so that the heat exchange between the cells and the dielectric fluid is ensured. Thus, the cooling of the electric batteries is carried out by immersing the cells of the electric batteries in said fluid. An additional deformable reserve of dielectric fluid consists of a tank located outside of the housing and makes it possible to limit pressure variations due to fluid temperature variations.

[0008]. However, the total immersion of the electrical storage cells in a fluid requires a large volume of fluid sensitive to the variations in inclination occurring for example during the transport of said devices or, if it is mounted in a vehicle, during the movement of said vehicle. . Thus, the fluid is not optimally distributed over the surface of the electrical storage cells to be cooled.

[0009]. The object of the invention is to offer an alternative for the thermal management of an electrical and/or electronic component capable of releasing heat in operation by at least partially overcoming the aforementioned problems of the state of the art, by optimizing the cooling of the electrical and/or electronic component to be cooled and thus increasing the service life as well as the performance of such an electrical and/or electronic component. The invention can advantageously be used in the automotive field for, for example, thermally regulating a power electronics element or an electrical energy storage element, or even in the field of data centers for cooling servers and other electronic elements.

[0010]. More particularly, the invention relates to a thermal management device for an electrical and/or electronic component capable of releasing heat during its operation, comprising at least one face, said device comprising a casing, said casing comprising a main compartment defining at at least one housing capable of receiving said electrical and/or electronic component, said housing being arranged to receive a dielectric fluid and being delimited by first and second longitudinal walls, a first side wall, a second side wall and a bottom wall, characterized in that at least one of said walls comprises a semi-open channel defining a dielectric fluid circulation path.

[0011]. Thus, thanks to the invention, the dielectric fluid is distributed more evenly over the face of the electrical and/or electronic component capable of releasing heat. The amount of dielectric fluid in contact with the component electrical and/or electronic is therefore optimized to ensure better thermal regulation of this component and therefore less rapid wear of the latter. In the absence of such a semi-open channel, in the event of tilting of the housing, the dielectric fluid could end up accumulated in a restricted area of the housing on only one side, causing poor cooling of the electrical and/or electronic component. . In other words, the presence of the semi-open channel on at least one wall of the housing makes it possible to preserve a wide contact of the electrical and/or electronic component with the dielectric fluid and a uniform distribution of the fluid on said component.

[0012]. Throughout the description, the terms “lateral”, “longitudinal” and “vertical” refer to an arbitrary orientation of a thermal management device according to the invention in an orthonormal frame Oxyz. Thus, a “longitudinal” direction corresponds to a direction parallel to an Oz axis, a “lateral” direction corresponds to a direction parallel to an Ox axis, and a “vertical” direction corresponds to a direction parallel to an Oy axis.

[0013]. The terms “horizontal plane” refer here to a plane perpendicular to the direction of gravity, in particular represented in the present description by the levels of dielectric fluid. The terms "transverse section" meanwhile refer to sections made according to a plane, called the transverse plane, parallel to the plane Oxz in which the lateral axis Ox and the longitudinal axis Oz are inscribed. The terms “lateral section” refer to sections made along a plane, called the vertical plane, parallel to the plane Oxy in which the lateral axis Ox and the vertical axis Oy are inscribed. The terms “longitudinal section” refer for their part to sections made according to a plane, called the longitudinal plane, parallel to the most Ozy in which the longitudinal axis Oz and the vertical axis Oy are inscribed.

[0014]. The cooling device advantageously comprises any one at least of the following characteristics, taken alone or in combination, at the very least if the combination is technically feasible:

[0015]. - at least two walls defining the housing comprise a semi-open channel,

[0016]. - each wall defining the housing comprises a semi-open channel, [0017]. - the semi-open channel is included on a longitudinal wall,

[0018]. - each wall comprises two lateral flanks substantially parallel to the Oy axis and two transverse flanks substantially parallel to the Oz axis.

[0019]. - the semi-open channel protrudes from at least one wall of the main compartment,

[0020]. - the semi-open channel comprises a first and a second end between which the dielectric fluid is intended to circulate,

[0021]. - the first end of the semi-open channel is in fluid communication with an inlet of said dielectric fluid, and the second end of the semi-open channel is in fluid communication with an outlet of said dielectric fluid,

[0022]. - the first end of the semi-open channel is positioned facing a dielectric fluid inlet orifice, and the second end of the semi-open channel is positioned facing a dielectric fluid outlet orifice,

[0023]. - the semi-open channel comprises at least one rib protruding from the wall of the main compartment, said rib being configured to direct the flow of fluid along the channel between the first and the second end of the semi-open channel,

[0024]. - the semi-open channel comprises at least two ribs protruding from the wall,

[0025]. - said included ribs are substantially parallel to each other,

[0026]. - said ribs are substantially parallel to a horizontal plane as defined above,

[0027]. - said ribs are continuous all along the semi-open channel between the first end and the second end of said semi-open channel,

[0028]. - said ribs are made of material with the wall of the main compartment comprising the semi-open channel,

[0029]. - said ribs are molded onto the wall of the main compartment, [0030]. - said ribs originate alternately on one and the other of the two lateral sides of the wall of the main compartment comprising the semi-open channel and extend at least partially on said wall,

[0031]. - the semi-open channel comprises at least one bend which the dielectric fluid path formed by the channel follows,

[0032]. - the semi-open channel comprises at least one section between two elbows, or between an elbow and the first end, or between an elbow and the second end,

[0033]. - the ribs are substantially parallel to the sections of the semi-open channel,

[0034]. - the semi-open channel includes several bends so that the dielectric fluid meanders all along the channel between the first end and the second end,

[0035]. - the ribs are continuous and have a serpentine shape so that the dielectric fluid winds along the half-open channel between the first end and the second end of said channel,

[0036]. - each rib comprises a first and a second slice, the first slice comprising a sealing element, in particular a sealing lip, the sealing element being intended to come into contact with the external face of the electrical component and/or electronics, the second slice being connected to the wall of the main compartment, and a partition body extending between the first and the second slice,

[0037]. - the channel is intended to be closed at least over a portion by an external face of the electrical and/or electronic component, thus defining a closed channel once the electrical and/or electronic component is assembled in the housing,

[0038]. - the channel is arranged so that, once the electrical and/or electronic component has been assembled in the housing, only the first and second ends of the channel are not closed by said component so that the dielectric fluid which enters through the inlet follows the entire path bounded by the channel to the dielectric fluid outlet, [0039]. - the housing is intended to be filled with dielectric fluid so that the electrical and/or electronic component, once assembled in the housing, is at least partially immersed in said dielectric fluid when the device is in a horizontal position substantially parallel to a horizontal plane,

[0040]. - the dielectric fluid inlet is located in the upper position of the housing,

[0041]. - the dielectric fluid inlet is located on a lateral side of the wall of the main compartment comprising the channel,

[0042]. - the device comprises two dielectric fluid inlets located in the upper part of the housing, each of said fluid inlets being located on a lateral side of the wall of the main compartment comprising the channel,

[0043]. - the dielectric fluid outlet is located in the low position of the housing,

[0044]. - the dielectric fluid outlet is located on a lateral side of the wall of the main compartment comprising the channel,

[0045]. - the dielectric fluid outlet is located in a central position between the two lateral sides of the wall of the main compartment comprising the channel,

[0046]. - the device comprises two semi-open channels each comprising a first end and a second end, and each comprising a dielectric fluid inlet, the semi-open channels each defining a dielectric fluid circulation path,

[0047]. - the second end of each of the channels is in fluid communication with a fluid outlet common to the two channels,

[0048]. - the second end of each of each channel is in fluidic connection with each of its own fluid outlet,

[0049]. - the two semi-open channels are symmetrical with respect to each other with respect to a vertical axis, [0050]. The invention also relates to an assembly comprising a device as described previously and an electrical and/or electronic component.

[0051]. 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 of each other. It is possible in particular to imagine variants of the invention comprising only a selection of characteristics described in the present description in isolation from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage.

[0052]. 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 :

[0053]. [Fig. 1] schematically illustrates in sectional view along a longitudinal section a thermal management device known from the prior art.

[0054]. [Fig. 2] schematically illustrates a sectional view along a longitudinal section of the thermal management device according to the invention according to a first embodiment

[0055]. [Fig. 3] schematically illustrates a sectional view along a longitudinal section of the thermal management device according to the invention according to a second embodiment

[0056]. [Fig. 4] schematically illustrates a sectional view along a longitudinal section of the thermal management device according to the invention according to a third embodiment

[0057]. [Fig. 5] schematically illustrates a sectional view along a side section of the thermal management device according to the invention [0058]. In the figures, the elements common to several figures retain the same reference.

[0059]. FIG. 1 represents a thermal management device 100 known from the prior art. This device 100 comprises a housing 103 comprising a main compartment 104 delimited by a first 106 and a second longitudinal wall, a first 107 and a second 108 side wall as well as a bottom wall 109. The main compartment 104 defines a housing 105 configured to receive an electrical and/or electronic component 102. Said housing 105 is arranged to receive a dielectric fluid.

[0060]. In the embodiment illustrated here, the device comprises a dielectric fluid inlet 112 and a dielectric fluid outlet 114. The inlet port 112 and the outlet port 114 are positioned on the first side wall 108.

[0061]. The box 103 includes a cover 1 1 1 intended to close the main compartment 104.

[0062]. The housing 105 comprises a plurality of supports 110, in particular in the form of pilings, resting on or extending from the bottom wall 109. Thus the electrical and/or electronic component 102 is sufficiently remote from the bottom wall 109 allowing the dielectric fluid to be in contact with a face of the electrical and/or electronic component 102 facing the bottom wall 109.

[0063]. FIG. 2 represents a thermal management device 1 according to the invention according to a first embodiment. The thermal management device 1 comprises a housing 3, said housing 3 comprising a main compartment 4 defining at least one housing 5 capable of receiving an electrical and/or electronic component 2 capable of releasing heat during its operation, said housing 5 being arranged to receive a dielectric fluid and being delimited by a first 6 and a second longitudinal wall, a first side wall 7, a second side wall 8 and a bottom wall 9, at least one of said walls comprising a semi-open channel 10 defining a dielectric fluid circulation path represented by arrows in FIGS. 2 to 5. In this example, it is the first longitudinal wall 6 defining the housing 5 which comprises a channel 10 semi-open.

[0064]. The box 3 includes a cover 18 intended to close the main compartment 4.

[0065]. In this embodiment, the semi-open channel 10 comprises a first 11 and a second 12 ends between which the dielectric fluid is intended to circulate. The first end 11 of the half-open channel 10 is in fluid communication with an inlet 13 of said dielectric fluid, and the second end 12 of the half-open channel 10 is in fluid communication with an outlet 14 of said dielectric fluid. More specifically, the first end 11 of the semi-open channel 10 is positioned facing an inlet 13 of dielectric fluid, and the second end 12 of the semi-open channel 10 is positioned facing a outlet 14 of dielectric fluid.

[0066]. In this embodiment, the semi-open channel 10 projects from the longitudinal wall 6. The semi-open channel 10 here comprises several ribs 15 projecting from the wall 6. The ribs 15 originate alternately on the first and on the the second lateral flank of the first longitudinal wall 6 extending partially over said wall 6 substantially parallel to a horizontal axis as defined above. Said ribs 15 are substantially parallel to each other. Said ribs 15 direct the flow of fluid throughout the channel 10 semi-open. The ribs 15 are here integral with the first longitudinal wall 6.

[0067]. The semi-open channel 15 comprises an opening on one of its faces over the entire length of said channel 15 from the fluid inlet 13 to the fluid outlet 14, this face being partially closed when the electrical and/or electronic component 2 is assembled in the device 1 . Only the first 11 and second end 12 of the channel remain open. In an embodiment not represented here, the channel is completely closed when the electrical and/or electronic component is assembled in the device, in particular thanks to the presence of sealing elements coming into contact with the open face of the channel at the level of these areas. [0068]. The semi-open channel 15 comprises several bends 16 so that the dielectric fluid meanders all along the channel 10 between the first end 11 and the second end 12. These bends 16 take position at the free ends of the ribs 15 In this embodiment, the semi-open channel 10 comprises sections 17 between the first end 11 and the first bend 16 located on the path of the dielectric fluid, between each bend 16 and/or between the last bend 16 and the second end 12. The sections 17 of the channel are substantially parallel to the ribs 15.

[0069]. Figure 3 is a schematic representation of the device according to the invention according to a second embodiment. The thermal management device 1 comprises a housing 3, said housing 3 comprising a main compartment 4 defining at least one housing 5 capable of receiving an electrical and/or electronic component 2 capable of releasing heat during its operation, said housing 5 being arranged to receive a dielectric fluid and being delimited by a first 6 and a second longitudinal wall, a first side wall 7, a second side wall 8 and a bottom wall 9, at least one of said walls comprising a semi-open channel 10 defining a dielectric fluid circulation path. In this example, it is the first longitudinal wall 6 defining the housing 5 which comprises a channel 10 that is semi-open.

[0070]. The box 3 includes a cover 18 intended to close the main compartment 4.

[0071]. In this embodiment, the semi-open channel 10 comprises a first 11 and a second 12 ends between which the dielectric fluid is intended to circulate. The first end 11 of the half-open channel 10 is in fluid communication with an inlet 13 of said dielectric fluid, and the second end 12 of the half-open channel 10 is in fluid communication with an outlet 14 of said dielectric fluid. More specifically, the first end 11 of the semi-open channel 10 is positioned facing an inlet 13 of dielectric fluid, and the second end 12 of the semi-open channel 10 is positioned facing a outlet 14 of dielectric fluid. [0072]. In this embodiment, the semi-open channel 10 projects from the longitudinal wall 6. The semi-open channel 10 here comprises two continuous ribs 15 projecting from the wall 6 . The ribs 15 are substantially parallel to each other and have the shape of a serpentine which extends between the first 11 and the second 12 end of the channel 10. Said ribs 15 direct the circulation of the fluid throughout the channel. The ribs 15 are here integral with the first longitudinal wall 6.

[0073]. The semi-open channel 10 comprises an opening on one of its faces over the entire length of said channel 10 from the fluid inlet 13 to the fluid outlet 14, this face being partially closed when the electrical and/or electronic component 2 is assembled in the device 1 . Only the first 11 and second end 12 of the channel remain open. In an embodiment not represented here, the channel is completely closed when the electrical and/or electronic component is assembled in the device, in particular thanks to the presence of sealing elements coming into contact with the open face of the channel at the level of these areas.

[0074]. The semi-open channel 10 includes several bends 16 so that the dielectric fluid meanders all along the channel between the first end 11 and the second end 12 of the channel 10.

[0075]. FIG. 4 represents a device according to the invention according to a third embodiment, is a schematic representation of the device according to the invention according to a second embodiment. The thermal management device 1 comprises a housing 3, said housing 3 comprising a main compartment 4 defining at least one housing 5 capable of receiving an electrical and/or electronic component 2 capable of releasing heat during its operation, said housing 5 being arranged to receive a dielectric fluid and being delimited by a first 6 and a second longitudinal wall, a first side wall 7, a second side wall 8 and a bottom wall 9, at least one of said walls comprising a semi-open channel 10 defining a dielectric fluid circulation path. In this example, it is the first longitudinal wall 6 defining the housing 5 which comprises a channel 10 that is semi-open. [0076]. The box 3 includes a cover 18 intended to close the main compartment 4.

[0077]. The thermal management device 1 comprises a housing 3, said housing 3 comprising a main compartment 4 defining at least one housing 5 capable of receiving an electrical and/or electronic component 2 capable of releasing heat during its operation, said housing 5 being arranged to receive a dielectric fluid and being delimited by a first 6 and a second longitudinal wall, a first side wall 7, a second side wall 8 and a bottom wall 9, at least one of said walls comprising two semi-open channels 10 each defining a dielectric fluid circulation path. In this example, it is the first longitudinal wall 6 defining the housing 5 which comprises two channels 10 semi-open. In an embodiment not shown here, it is possible for at least one of the walls to comprise more than two semi-open channels, for example three channels.

[0078]. In this embodiment, the semi-open channels 10 each comprising a first 11 end and a second 12 end, and each comprising an inlet 13 of dielectric fluid, the semi-open channels 10 each defining a dielectric fluid circulation path . In this embodiment, the device 1 comprises a fluid outlet 14 common to the two channels 10. The first end 11 of the semi-open channels 10 is in fluid communication with the inlet 13 of said dielectric fluid, and the second end 12 of the each half-open channel 10 is in fluid communication with the outlet 14 of said dielectric fluid. More specifically, the first end 11 of each half-open channel 10 is positioned facing an inlet 13 of dielectric fluid, and the second end 12 of each half-open channel 10 is positioned facing a output common 14 of dielectric fluid. The inlet 13 of each channel 10 is here located on a different lateral flank of the wall 6 at the upper level of the housing 5. The common fluid outlet 14 is here located at the lower level of the housing 5, in the center of the two lateral flanks of the wall 6. In an embodiment not shown here, each channel could have its own fluid outlet 804 . [0079]. In this embodiment, the semi-open channels 10 project from the longitudinal wall 6. The semi-open channels 10 here each comprise two continuous ribs 15 projecting from the wall 6 . For each channel, the ribs 15 are substantially parallel to each other and have the shape of a serpentine which extends between the first 11 and the second 12 end of each channel 10. Said ribs 15 direct the circulation of the fluid throughout the channel . The ribs 15 are here integral with the first longitudinal wall 6. The channels here are symmetrical with respect to a vertical axis Oy.

[0080]. The semi-open channels 10 comprise an opening on one of their faces over the entire length of said channels 10 from the fluid inlet 13 to the fluid outlet 14, these faces being partially closed when the electrical and/or electronic component 2 is assembled in the device 1 . Only the first 11 and second end 12 of the channels remain open. In an embodiment not shown here, the channels are completely closed when the electrical and/or electronic component 2 is assembled in the device 1, in particular thanks to the presence of sealing elements coming into contact with the open face of the channel at these areas.

[0081]. The semi-open channels 10 include several bends 16 so that the dielectric fluid winds along the channels 10 between the first end 11 and the second end 12 of each channel 10.

[0082]. FIG. 5 schematically illustrates a sectional view along a side section of the thermal management device according to the invention. Each rib 15 comprises a first 19 and a second 20 edge, the first edge 19 comprising a sealing element, in particular a sealing lip, the sealing element being intended to come into contact with the external face of the electrical component and/or electronics 2, the second slice 20 being connected to the wall 6 of the main compartment 4, and a partition body 21 extending between the first 19 and the second slice 20. Thus, the electrical and/or electronic component is sealed in the dielectric fluid. [0083]. The channel 10 is intended to be closed at least over a portion by an external face of the electrical and/or electronic component 2, thus defining a closed channel once the electrical and/or electronic component 2 is assembled in the housing 5. Thus , the channel 10 is arranged so that, once the electrical and/or electronic component 2 has been assembled in the housing 5, only the first 11 and second 12 ends of the channel 10 are not closed by said component so as to that the dielectric fluid which enters through the fluid inlet 13 follows the entire path delimited by the channel 10 to the outlet 14 of the dielectric fluid. The channel formed is thus sealed and makes it possible to manage the passage of the fluid over the component 2 to optimize its thermal management.

[0084]. The housing 5 is intended to be filled with dielectric fluid so that the electrical and/or electronic component 2 once assembled in the housing 5 is at least partially immersed in said dielectric fluid when the device 1 is in particular in a horizontal position. substantially parallel to a horizontal plane.

[0085]. The invention also relates to an assembly comprising a device as described above and an electrical and/or electronic component.

[0086]. The representations of FIGS. 1 to 5 are schematic. The present invention also covers different embodiments, in particular due to the shape of the housing and/or of the reservoir.

[0087]. The invention cannot however be limited to the means and configurations described and illustrated here, and it also extends to any equivalent means or configuration and to any technical combination operating such means. In particular, the number of walls and the presence of a heat transfer fluid circuit may be modified without harming the invention, insofar as the thermal management device, ultimately, fulfills the same functions as those described herein. document.

Claims

[Claim 1] Device (1) for thermal management of an electrical and/or electronic component (2) capable of releasing heat during its operation comprising at least one face, said device comprising a housing (3), said housing comprising a main compartment (4) defining at least one housing (5) capable of receiving said electrical and/or electronic component (2), said housing (5) being arranged to receive a dielectric fluid and being delimited by a first (6) and a second longitudinal wall, a first side wall (7), a second side wall (8) and a bottom wall (9), characterized in that at least one of said walls (6, 7, 8, 9) comprises at least one semi-open channel (10) defining a dielectric fluid circulation path.

[Claim 2] Device (1) according to the preceding claim, characterized in that the semi-open channel (10) projects from the wall (6, 7, 8, 9) of the main compartment (4).

[Claim s] Device (1) according to one of the preceding claims, characterized in that the semi-open channel (10) comprises a first (1 1) and a second (12) ends between which the fluid is intended to circulate dielectric, the first end (1 1) of the half-open channel (10) is in fluid communication with an inlet (13) of said dielectric fluid, and the second end (12) of the half-open channel (10) is in fluid communication with an outlet (14) of said dielectric fluid.

[Claim 4] Device (1) according to the preceding claim, characterized in that the channel (10) semi-open comprises at least one bend between the first (1 1) and the second (12) end of the channel (10).

[Claim 5] Device (1) according to one of Claims 3 or 4, characterized in that the semi-open channel (10) comprises at least one rib (15) projecting from the wall (6, 7, 8, 9) of the main compartment (4), said rib (15) being configured to direct the flow of fluid along the semi-open channel (10) between the first (11) and the second (12) end of the channel (10 ) semi-open.

[Claim 6] Device (1) according to the preceding claim, characterized in that the semi-open channel (10) comprises at least two ribs (15) projecting from the wall.

[Claim 7] Device (1) according to one of Claims 5 or 6, characterized in that the ribs (15) are integral with the wall (6, 7, 8, 9) of the main compartment (4).

[Claim 8] Device (1) according to one of Claims 5 to 7, characterized in that each rib comprises a first (19) and a second (20) edge, the first edge (19) comprising a sealing element , in particular a sealing lip, the sealing element being intended to come into contact with the external face of the electrical and/or electronic component (2), the second edge (20) being connected to the wall (6, 7 , 8, 9) of the main compartment (4), and a partition body (21) extending between the first (19) and the second section (20).

[Claim 9] Device (1) according to one of the preceding claims, characterized in that the semi-open channel (10) is intended to be closed at least over a portion by an external face of the electrical and/or electronic component ( 2), thus defining a closed channel once the electrical and/or electronic component (2) is assembled in the main compartment (4).

[Claim 10] Assembly comprising a device (1) as described above and an electrical and / or electronic component (2).