Heat dissipation device and electrical connection box, electrical energy storage device, and vehicle comprising such a dissipation device

The heat dissipation device addresses high temperature issues in electric vehicles by using a thermally conductive and insulating material for efficient heat exchange, improving reliability and reducing component size and cost.

WO2026130789A1PCT designated stage Publication Date: 2026-06-25AMPERE SAS

Patent Information

Authority / Receiving Office
WO · WO
Patent Type
Applications
Current Assignee / Owner
AMPERE SAS
Filing Date
2025-10-14
Publication Date
2026-06-25

AI Technical Summary

Technical Problem

Existing electric or hybrid vehicles with battery packs face issues of high temperature increases in critical components due to high-intensity current flow, leading to potential degradation and the need for oversized safety components, which increase weight and cost.

Method used

A heat dissipation device with a thermally conductive and electrically insulating material, featuring a thermal interface component with a head and spacer, facilitates heat exchange between hot and cold sources while maintaining electrical insulation, reducing the temperature on safety devices and avoiding oversizing.

Benefits of technology

The solution effectively dissipates heat, enhances component reliability, reduces the risk of electrical arcing, and minimizes the need for oversized safety components, thereby lowering weight and cost.

✦ Generated by Eureka AI based on patent content.

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Abstract

The invention relates to a heat dissipation device, in particular for a motor vehicle, the device being configured for heat exchange between a hot source, comprising an electrical member, and a cold source, the device further comprising a first thermal interface member (20), the first thermal interface member comprising a head (20b) intended for heat exchange with one of the hot or cold sources, the head (20b) comprising a thermally conductive and electrically insulating material (40) intended to be in contact with the hot or cold source in question, the head (20b) further comprising a spacer (44) for protecting the thermally conductive and electrically insulating material (40).
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Description

[0001] DESCRIPTION

[0002] TITLE: Heat dissipation device as well as electrical connection box, electrical energy storage device and vehicle including such a dissipation device.

[0003] The invention relates to a heat dissipation device, particularly for a motor vehicle. It also relates to an electrical connection box for an electrical energy storage device, particularly a battery, comprising such a dissipation device. It further relates to such an electrical energy storage device, particularly a battery, comprising such a box and / or such a dissipation device. It also relates to a vehicle comprising such a storage device, such a box, and / or such a dissipation device.

[0004] In this field, it is known that electric or hybrid vehicles equipped with a battery pack include a casing that houses several electrochemical cells connected together and providing a high voltage at the battery terminals, typically a voltage of several hundred volts.

[0005] It is then necessary to equip the battery with an electrical connection box containing safety electrical components (relays, fuses) in order to cut off the current when needed. These components are connected using busbars through which the battery's input or output current flows.

[0006] In certain situations, the battery supplies or receives a high electrical power. This is the case, for example, during so-called fast charging of the vehicle's battery, or when the vehicle must exert significant traction. In these situations, the flow of a high-intensity current generates a sharp increase in temperature, particularly in areas commonly referred to as "hot spots," such as safety-critical electrical components, which then present an increased risk of degradation. To mitigate this risk, it is common practice to oversize these components. However, this results in significant bulk, an excessive increase in weight, and a higher cost.

[0007] The invention aims to overcome at least in part the previous drawbacks and proposes for this purpose a heat dissipation device, in particular for motor vehicles, said device being configured for heat exchange between, on the one hand, a hot source comprising an electrical component, and, on the other hand, a cold source, said device further comprising a first thermal interface component, said first thermal interface component comprising a head intended to be in heat exchange relationship with one of said hot or cold sources, said head comprising a thermally conductive and electrically insulating material intended to be in contact with said hot or cold source in question, said head further comprising a protective spacer for said thermally conductive and electrically insulating material.

[0008] This heat dissipation device allows for better removal of the heat generated by the electrical component by establishing a thermal bridge to the cold source. Furthermore, the thermally conductive and electrically insulating material facilitates good contact between the components involved, thus improving thermal conduction between the hot and cold sources while allowing the cold source to remain electrically insulated. Moreover, the head and its spacer provide at least partial encapsulation of this thermally conductive and electrically insulating material. This protection enhances the long-term reliability of the heat dissipation device and reduces the risk of electrical arcing.

[0009] In the context of an application to an electrical energy storage device, it is thus possible to reduce the temperature to which the safety devices will be subjected and to avoid their oversizing.

[0010] According to various additional features of the invention, which may be taken together or separately and which constitute so many embodiments of the invention: said head comprises a housing receiving said spacer, said spacer is movable in said housing, in particular in translation, said spacer slides in said housing, - said head comprises a diffuser intended to be in thermal exchange relationship with said cold or hot source in question,

[0011] - said thermally conductive and electrically insulating material is in contact with said diffuser,

[0012] - said spacer is connected to said diffuser so as to define a housing for said thermally conductive material,

[0013] - said housing is intended to be located between said diffuser and said hot or cold source in question,

[0014] - said casing also houses said diffuser,

[0015] - said thermally conductive and electrically insulating material is compressible,

[0016] - said thermally conductive and electrically insulating material is in the form of a pad,

[0017] - said bearing forms a cover for said casing,

[0018] - said first thermal interface element is configured to compress said thermally conductive and electrically insulating material against said hot or cold source in question, in particular by screwing,

[0019] - said head comprises an elastomeric membrane configured to force said spacer against said cold or hot source in question,

[0020] - said head includes, before assembly, a protective cover for said thermally conductive and electrically insulating material,

[0021] - said device includes a heat pipe configured for said heat exchange,

[0022] - said first thermal interface element is in contact with the heat pipe,

[0023] - said device further comprises a second thermal interface element in contact with the heat pipe and intended to be in a heat exchange relationship with the other of said hot or cold sources,

[0024] - said first thermal interface element further has a base in contact with the heat pipe and a flexible zone located between said base and said head,

[0025] - said flexible zone is configured to deform elastically, - said flexible zone is configured to deform according to a force applied to said first thermal interface element, during assembly, against said hot or cold source in question,

[0026] - said flexible zone comprises one or more blades connecting said base and said head of the first thermal interface element,

[0027] - the said blade(s) extend along a surface generated by an axis displaced parallel to a longitudinal extension axis of said heat pipe,

[0028] - the said blade(s) include at least one bend,

[0029] - said base of the first thermal interface element comprises a first sleeve inside which said heat pipe is inserted,

[0030] - said base of the first thermal interface element includes a first flange for attaching said blade(s),

[0031] - said first bridle extends from said first sleeve,

[0032] - said head of the first thermal interface element includes a second flange for attaching said blade(s),

[0033] - said diffuser extends from said second flange,

[0034] - said casing also accommodates said second flange,

[0035] - said casing includes a passageway for a fastening device to said hot or cold source in question,

[0036] - said housing includes a positioning bracket for said blades,

[0037] - said second thermal interface element has a second sleeve inside which said heat pipe is inserted,

[0038] - the heat pipe is fixed in the said first and / or second sleeve by welding, brazing, crimping and / or by fitting,

[0039] - said second thermal interface element has a third flange for fixing to said hot or cold source in question.

[0040] - said third flange extends from said second sleeve,

[0041] - said device is configured so that the heat exchange between the heat pipe and the cold source occurs via said first thermal interface element, referred to as the cold element,

[0042] - said device is configured so that the heat exchange between the heat pipe and the hot source occurs via said second thermal interface element, said hot, - said heat pipe is inclined so that, in use, a portion of the heat pipe in heat exchange with said hot thermal interface element is vertically at a level lower than that of a portion of the heat pipe in heat exchange with said cold thermal interface element,

[0043] - said heat pipe is straight,

[0044] - said heat pipe has a rounded cross-section, in particular substantially circular,

[0045] - said heat pipe is sintered,

[0046] - said heat pipe is twisted and / or grooved.

[0047] The invention also relates to an electrical connection box for an electrical energy storage device, in particular a battery of accumulators, comprising one or more hot sources, a cold source and a dissipation device as described above to establish a heat exchange between the said hot source(s), on the one hand, and the said cold source, on the other hand.

[0048] According to various additional features of the invention, which may be taken together or separately and which constitute so many embodiments of the invention:

[0049] - The electrical component of the hot source(s) includes an electrical protection device,

[0050] - said electrical protection device includes an electrical relay,

[0051] - the said hot source(s) include a protective casing housing said electrical component,

[0052] - said protective housing includes electrical connection terminals, electrically connected to said electrical component and in heat exchange relationship with said dissipation device,

[0053] - said electrical connection terminals are flush with said protective box,

[0054] - said dissipation device is in a heat exchange relationship with one of said connection terminals,

[0055] - said connection box includes one or more electrical conduction busbars intended to be electrically connected to said hot source, in particular to another of said connection terminals, - said dissipation device is configured to be in thermal exchange relationship with a first of the connection terminals of a first of said hot sources and with a first of the connection terminals of a second of said hot sources, said first connection terminals being provided at the same electrical potential,

[0056] - said dissipation device comprises two said second thermal interface elements respectively in heat exchange relationship with each of said hot sources,

[0057] - said heat pipe is in contact with each of said second thermal interface elements by opposite longitudinal ends of said heat pipe,

[0058] - said heat pipe is in contact with said first thermal interface element by a zone, in particular a median zone, located between said longitudinal ends of the heat pipe,

[0059] - said cold source comprises a plate exhibiting a thermal inertia much greater than that of said hot source

[0060] - said plate includes all or part of a lower face of a casing of an electrical energy storage device.

[0061] The invention further relates to an electrical energy storage device, in particular a battery of accumulators, comprising a dissipation device as described above, in particular at the level of the connection box of said storage device.

[0062] The invention also relates to a vehicle comprising a dissipation device as described above, in particular at the level of the vehicle's electrical energy storage device and / or the connection box of said storage device.

[0063] The invention will be better understood, and other objects, details, features and advantages thereof will become more apparent in the course of the detailed explanatory description which follows, of at least one embodiment of the invention given by way of purely illustrative and non-limiting example, with reference to the accompanying schematic drawings, among which:

[0064] [Fig 1] schematically illustrates, in side view, a motor vehicle according to the invention; [Fig 2] schematically illustrates, in perspective, an example of an embodiment of a heat dissipation device according to the invention;

[0065] [Fig 3] illustrates schematically, in perspective, in partially exploded mode, the dissipation device of figure 2;

[0066] [Fig 4] illustrates schematically, in perspective, partially, an example of the realization of a connection box incorporating the dissipation device of figures 2 and 3, from a first angle of view;

[0067] [Fig 5] reproduces figure 4 from a second viewpoint;

[0068] [Fig 6] illustrates schematically, in perspective, in partially exploded mode, a first thermal interface element of the dissipation device of figures 2 and 3;

[0069] [Fig 7] illustrates schematically, in perspective, in partially exploded mode, sub-parts of the first thermal interface organ of the dissipation device of figures 2 and 3;

[0070] [Fig 8] illustrates schematically, in perspective, in exploded view, parts of one of the sub-parts shown in the previous figure, namely the distal sub-part;

[0071] [Fig 9] schematically illustrates, in perspective, the said distal sub-part, in a configuration before assembly;

[0072] [Fig 10] schematically illustrates, in longitudinal section view, the said distal sub-part, still in the said configuration before assembly;

[0073] [Fig 11] schematically illustrates, in cross-section view, a part of the connection box of figures 4 and 5 in order to visualize said distal sub-part illustrated in figures 9 and 10, after assembly.

[0074] It should be noted that, in this description, the terms "first", "second", "third", ... are used only to distinguish the components concerned from each other and do not imply any order or possible importance of said components.

[0075] The invention relates to a heat dissipation device, particularly for motor vehicles.

[0076] As illustrated in Figure 1, the invention also relates to an electrical connection box 1, an electrical energy storage device 2, in particular a battery, and a vehicle V comprising such a dissipation device. The latter is placed, for example, in the electrical connection box 1, said box 1 being used to connect the electrical energy storage device 2 to an electrical network 3 of the motor vehicle V. Said vehicle V is advantageously an electric or hybrid vehicle connected to said electrical network 3.

[0077] As illustrated in Figures 2 to 5, said heat dissipation device advantageously comprises a heat pipe 10, configured for heat exchange between, on the one hand, one or more hot sources 12 and, on the other hand, a cold source 16. By "heat pipe" is meant a heat-conducting element allowing a fluid to circulate inside the element, in particular by capillarity and / or by gravity, this in a closed cycle according to a principle of successive evaporation and condensation of the fluid.

[0078] Preferably, the heat pipe(s) 10 are straight. They may, for example, have a rounded cross-section, particularly a circular one. The heat pipe(s) 10 are, in particular, sintered and / or grooved.

[0079] In the illustrated embodiment, the heat pipe 10 is unique and the dissipation device is configured to establish a heat exchange between two said hot sources 12 and said cold source 16 through said heat pipe 10.

[0080] As more specifically visible in figures 4 and 5, the said hot source(s) 12 include an electrical component 14. This electrical component 14 is formed here of an electrical protection component, for example an electrical relay and / or a fuse intended to open in the event of an anomaly in the circuit 3. This electrical component 14 includes, for example, a coil, not visible.

[0081] The said hot source 12 further includes here a protective housing 200 housing the said electrical component 14. The said coil is housed in the said housing 200. The said housing 200 is, in particular, substantially parallelepiped in shape.

[0082] The said hot source 12 includes electrical connection terminals 210a, 210b, electrically connected to said electrical component 14, in particular said coil, and in heat exchange relationship with said dissipation device, at least for one of them.

[0083] The said connection terminals 210a, 210b include, for example, sockets, not visible, passing through said protective housing 200. The said electrical connection terminals 210a, 210b, in particular said sockets, are flush with said protective bolter 200. The said sockets are located, for example, at the level of a face 204 of said protective housing 200, here a lower face.

[0084] The cold source 16 comprises, for example, a plate 18 having a thermal inertia much greater than that of the hot source(s) 12. The plate 18 may include all or part of a lower face of a housing for the electrical energy storage device. The plate 18 is here provided with channels for circulating a heat transfer fluid.

[0085] The said dissipation device includes a first thermal interface element 20 intended to be in thermal exchange relationship with one of the said hot or cold sources 12, 16. It is here in contact with the heat pipe 10.

[0086] In the illustrated embodiment, said dissipation device further includes a second thermal interface element 80 in contact with the heat pipe 10 and intended to be in thermal exchange relationship with the other of said hot or cold sources 12,16.

[0087] Referring again to Figures 2 and 3, it can also be seen that, according to the invention, the first thermal interface element 20 has a head 20b intended to be in heat exchange contact with the hot or cold source in question. The first thermal interface element 20 further comprises a base 20a in contact with the heat pipe 10 and a flexible zone 20c located between the base 20a and the head 20b.

[0088] The flexibility thus offered to the dissipation device by means of the said first thermal interface organ 20 allows, in particular during assembly, good contact between the parts in question, despite their possible manufacturing dispersions, and consequently promotes heat conduction between the hot source(s) 12 and the cold source 16.

[0089] According to the illustrated embodiment, said device is configured so that said heat exchange involving said first thermal interface element 20 is in relation with said cold source 16. Said device is thus configured so that said heat exchange between the heat pipe 10 and the cold source 16 occurs via said first thermal interface element 20. Said first thermal interface element 20 is thus said to be cold.

[0090] The said second thermal interface element 80 is then in a heat exchange relationship with the said hot source 12. The said device is thus configured so that the said heat exchange between the heat pipe 10 and the hot source 12 takes place via the said second thermal interface element 80. The said second thermal interface element 80 is thus said to be hot.

[0091] Preferably, said flexible zone 20c is configured to deform elastically. Said flexible zone 20c is here configured to deform according to a force applied to said first thermal interface element 20, during assembly, against said cold source 16.

[0092] As more clearly seen in Figures 6 and 7, said flexible zone 20c comprises one or more blades 22 connecting said base 20a and said head 20b of said first thermal interface element 20. Said blades 22 are flexible. They consist of several substantially identical blades 22 and / or are stacked one on top of the other, for example, in two groups 22a, 22b arranged side-by-side.

[0093] Preferably, the said blades 22 are elastically deformable, which further promotes good contact between the parts.

[0094] The blade(s) 22 extend, for example, along a surface formed by a generatrix moved parallel to a longitudinal extension axis of the heat pipe 10. The generatrix follows a curve substantially in the shape of an S, particularly in a plane perpendicular to the heat pipe 10. More precisely, for example, the curve successively presents a first, a second, and a third straight segment. These are connected by rounded edges.

[0095] Here, the first segment is located at the base 20a and / or the third segment is located at the head 20b of the first thermal interface element 20. They are parallel to each other. The second segment is perpendicular to the first and third segments.

[0096] The said blade(s) 22 thus have an angled shape with successively a first flat portion at the level of said base 20a of said first thermal interface element, a first bend, a second flat portion, perpendicular to the first portion, a second bend and / or a third flat portion, perpendicular to the second portion and parallel to the first, said third portion being located at the level of said head 20b of the first thermal interface element 20.

[0097] The said groups 22a, 22b are here symmetrical to each other along a median plane P perpendicular to said heat pipe 10. They each correspond, for example, to a region of said base 20a of the first thermal interface element 20 respectively in heat exchange relationship with one of said hot sources 12, via the heat pipe 10.

[0098] The said base 20a of the first thermal interface element 20 has, for example, a first sleeve 24 inside which said heat pipe 10 is inserted.

[0099] Alternatively or cumulatively, the base 20a of the first thermal interface element 20 has a first mounting flange 26 for the blade(s) 22. This first flange 26 extends from the first sleeve 24, for example, radially with respect to the heat pipe 10. The blade(s) 22 are held on the first flange 26, in particular, by a first retaining plate 28. The first flange 26 and / or the first retaining plate 28 are substantially flat and parallel to each other. They are connected by one or more first clamping screws 30. The first clamping screws 30 pass through holes provided in the first retaining plate 28 and in the blade(s) 22, in particular in their first flat portion, and are engaged in the first flange 26.The said blades 22, in particular their said first flat portion, are thus sandwiched between said first flange 26 and said first retaining plate 28. Said first flat portion of the plates 22 is substantially parallel to said first flange 26 and / or to said first retaining plate 28.

[0100] As illustrated in figure 8, said head 20b of the first thermal interface element 20 includes, for example, a diffuser 32 intended to be in thermal exchange relationship with said cold source 16.

[0101] The diffuser 32 here has an annular configuration. It is provided, for example, with two large parallel and opposing flat faces, connected by an outer edge 34, in particular circular, and an inner edge 36, in particular circular. Said inner edge 36 is configured for a passage from a fixing member of said first thermal interface member 20 to said cold source 16.

[0102] Alternatively or cumulatively, said head 20b of the first thermal interface element 20 comprises a second mounting flange 38 for said blade(s) 16. Said diffuser 32 extends from said second flange 38, notably with a continuous material surface. Said second flange 38 has a sector-like shape extending angularly over a portion of the ring formed by the diffuser 32.

[0103] According to the invention, said first thermal interface element 20, is electrically insulating.

[0104] For this purpose, as illustrated in figures 9 to 11, said head 20b of the first thermal interface element comprises a thermally conductive and electrically insulating material intended to be in contact with said cold source 16. It is in particular in the form of a layer of paste or a pad 40, advantageously compressible.

[0105] The thermally conductive and electrically insulating material, in particular the pad 40, is, for example, in contact with the diffuser 32. The pad 40 here has an annular shape which overlaps with that of the diffuser 32, for example by extending slightly radially inwards and / or outwards from the ring formed by the diffuser 32.

[0106] Before assembly, as illustrated in figures 9 and 10, said bearing 40 is advantageously protected by a cover 42. Furthermore, said thermally conductive and electrically insulating material, in particular said bearing 40, is uncompressed.

[0107] According to the invention, said head 20b of the first thermal interface member 20 includes a spacer 44 for the protection of said thermally conductive and electrically insulating material, in particular said pad 40.

[0108] Advantageously, said spacer 44 is fixed on said diffuser 32 so as to define a housing for said thermally conductive material, said housing being here intended to be located between said diffuser 32 and said cold source 16.

[0109] The spacer 44 is formed, for example, of an outer ring 46a and / or an inner ring 46b coaxial with each other and / or with the ring formed by the diffuser 32. The outer ring 46a is opposite, or even in contact with, the outer edge 34 of the diffuser 32 and / or a corresponding outer edge of the bearing 40. The inner ring 46b is opposite, or even in contact with, the inner edge 36 of the diffuser 32 and / or a corresponding inner edge of the bearing 40.

[0110] Preferably, said head 20b of the first thermal interface element 20 comprises a housing 48 accommodating said spacer 44. Said housing 48 further accommodates, for example, said diffuser 32 and / or said second flange 38. Said second flange 38 opens here through a window 56 formed in said housing 48.

[0111] Advantageously, said bearing 40 forms a cover of said housing 48, in particular by bearing on said diffuser 32 and / or said spacer 44.

[0112] The said casing 48 has, for example, a flat wall 52, parallel to the large faces of the said diffuser 32. The said window 56 is formed in the said flat wall 52.

[0113] The said flat wall 52 has a disc configuration with a diameter slightly larger than the said diffuser 32. It is extended by a skirt 54. The said diffuser 32 is supported, for example, against the said flat wall 52.

[0114] The housing 48 accommodates the spacer 44, for example at one or more grooves, particularly annular ones. There are two such grooves, namely an external groove 50a and an internal groove 50b. They are concentric and configured to accommodate the external and internal rings 46a and 46b, respectively.

[0115] In the illustrated embodiment, said external groove 50a is formed in said skirt 54.

[0116] The spacer 44 is advantageously provided to be movable within the housing 48. In other words, here, the outer ring 46a is movable within the outer groove 50a and / or the inner ring 46b is movable within the inner groove 50b. In particular, they slide within the grooves 50a and 50b. They are movable in translation along a direction perpendicular to the spacer 32.

[0117] In Figures 9 and 10, the external and / or internal rings 46a, 46b project beyond the internal and / or external grooves 50a, 50b to protect the bearing 40 before assembly. For this purpose, the first thermal interface element 20 comprises an elastomeric membrane 45 housed at the bottom of the groove(s) 50a, 50b and forcing the spacer 44 partially out of the groove(s) 50a, 50b. The elastomeric membrane is formed of two rings 49a, 49b corresponding to the external and internal rings 46a, 46b. More broadly, the elastomeric membrane is configured to force the spacer 44 against the cold source 16.

[0118] A peripheral edge of said operculum 42 is in contact with said external and / or internal rings 46a, 46b, particularly at a distal end edge of the latter. Said housing 48 includes, for example, a stirrup 58 for positioning said blades 22. Said stirrup 58 is located here at the edge of said window 56. It is formed of partitions extending perpendicularly to said flat wall 52.

[0119] The fastening element for the first thermal interface element 20 on the cold source 16, designated 60 in Figure 11, operates, namely, by screwing. The fastening element 60 is advantageously configured to prevent the first thermal interface element 20 from rotating during assembly. It is, for example, a shouldered screw. Alternatively, positioning pins are used.

[0120] Said casing 48 is configured to electrically isolate said fastening member 60 from live parts, in particular said diffuser 32 and said second flange 38.

[0121] In the illustrated embodiment, said housing 48 includes a well 62 for the passage of said fixing member 60. Said well 62 is centered on and / or passes through said disc-shaped wall 52 of the head 20b of the first thermal interface member 20. Said well 62 extends on both sides of said wall 52, in particular perpendicularly, to allow passage of said fixing member 60 of the first thermal interface member 20 over the cold source 16.

[0122] In the illustrated embodiment example, said internal groove 50b is formed in a part of said well 62 intended to be turned around said cold source 16.

[0123] Some of the partitions of the stirrup 58 connect to a part of said well 62 opposite to that turned towards the diffuser 32.

[0124] The diffuser 32 is located radially between the skirt 54 and the portion of the well 62 intended to face the cold source 16. The pad 40 bears against the skirt 54, specifically at a first shoulder 57 formed at a free edge of the skirt 54. The external groove 50a opens onto the first shoulder 57. The pad 40 bears against the well 62, specifically at a second shoulder 64 formed at a distal edge of the well 62, corresponding to the first shoulder 57. The internal groove 50b opens onto the second shoulder 64.

[0125] In Figure 11, the said heat dissipation device has been mounted on said cold source 16. The cover 42 has been previously removed.

[0126] In this configuration, as already mentioned, the first thermal interface element 20 is fixed to the cold source 16, for example, by screwing. For this purpose, the screw forming the fixing element passes 60 through the well 62 and the diffuser 32 to engage with the cold source 16, specifically at a bore 66 formed in the latter. A head 68 of the screw bears against a third shoulder 70 formed in the well 62. Alternatively, not shown, the bore 66 is replaced by a threaded barrel, particularly in the case where the plate 18 is formed by extrusion.

[0127] After assembly, the first thermal interface element 20 rests against the cold source 16. The bearing 40 is thus compressed between the diffuser 32 and the cold source 16, particularly depending on the degree to which the fastener 60 is tightened. The spacer 44 is retracted into the groove(s) 50a, 50b. The housing 48 also rests against the cold source 16, particularly via the free edge of the skirt 54. The bearing 40 is thus encapsulated within the spacer 44 and / or the housing 48. It is thereby protected from external elements, which ensures reliable electrical insulation of the cold source 16 over time. This also limits the risks of creating an electric arc between the diffuser 32 and the cold source 16. The said membrane 45 is then compressed, in particular depending on the degree of screwing of the fixing member 60.

[0128] Referring again to Figures 6 and 7, it can be seen that the blade(s) 22 are held on the second flange 38, in particular, by a second retaining plate 72. The second flange 38 and / or the second retaining plate 72 have facing surfaces that are substantially flat and parallel to each other. They are connected by second clamping screws 74. The second clamping screws 74 pass through holes provided in the second retaining plate 72 and in the blade(s) 22, in particular in their second flat portion, and are engaged in the second flange 38. The blade(s) 22, in particular their first flat portion, are thus sandwiched between the second flange 38 and the second retaining plate 72. The second flat portion of the plates 22 is substantially parallel to the facing surfaces of the second flange 38 and / or the second retaining plate 72.

[0129] The diffuser 32 is fixed to the housing 48, for example by gluing and / or screwing. Here, as illustrated, the housing 48, in particular the flat wall 52, has one or more screw holes 53, not shown, for fixing the diffuser 32. As better illustrated in Figures 2 and 3, the second thermal interface element 80 has a second sleeve 82 inside which the heat pipe 10 is inserted.

[0130] The second thermal interface element 80 has a third flange 84 for attachment to the hot source 12. This third flange 84 is, for example, substantially flat. It extends from the second sleeve 82, notably in a substantially tangential manner. The third flange 84 extends orthogonally to the first flange 26.

[0131] The first and / or second sleeves 24, 82 here have a jaw-like configuration. In other words, they have a longitudinal slot 83 that interrupts the sleeve(s) 24, 82 at an angle. On either side of said slot 83, the sleeve(s) 24, 82 have passage holes for clamping elements such as screws 85. The screw(s) 85 pass through one of said passage holes and engage with the corresponding passage hole located opposite it on the other side of the slot 83. Tightening the screw 85 thus tends to close the jaw formed by the sleeve 24, 82 on the heat pipe 10 for the purpose of fixing the latter in the first and / or second thermal interface elements 20, 80.

[0132] More generally, the heat pipe(s) 10 are fixed in the first or second sleeve(s) 24, 82, for example, by welding, brazing, crimping and / or by fitting, in particular according to a fit known under the reference H7p6.

[0133] Preferably, although not visible, said heat pipe 10 is inclined so that, in use, a part of said heat pipe 10 in contact with said cold thermal interface member 20 is located higher than one or more parts of the heat pipe 10 in contact with said hot thermal interface member(s) 80.

[0134] The diffuser 32, the second flange 38, the blades 22, the first flange 26, and / or the second thermal interface element 80 are, for example, made of copper. The spacer 44 and / or the housing 48 are, for example, made of polymer material, in particular ABS. The spacer 44 is, for example, made of elastomer material.

[0135] In a variant not illustrated, a thin sheet, in particular of copper, is disposed between the operculum 42 and the pad 40. If we refer again to figures 4 and 5, we see that, in addition to the hot source(s) 12, the cold source 16 and the dissipation device intended to establish a heat exchange between the said hot source(s) 12 and the said cold source 16, as described above, the said electrical connection box according to the invention comprises one or more bus bars 100 of electrical conduction intended to be electrically connected to the said hot source 12, in particular to the said electrical element 14.

[0136] The said omnibus 100 busbar(s) are also intended to be electrically connected to another electrical component, not shown, of said connection box and / or said electrical network 3.

[0137] In the illustrated embodiment, only one of said bus bars 100 has been shown for each of said electrical components 14. The said bus bar(s) 100 are provided with electrical connection ports 102, for example located at opposite ends of said bus bars 100. In the figures, one of the ports 102 is visible while the other is not.

[0138] In the illustrated embodiment, the dissipation device is configured to be in heat exchange relationship with one of the connection terminals 210a of the hot source(s) 12, in particular with the corresponding socket. It is further configured here to be electrically connected to the corresponding electrical component(s) 14 via the connection terminal 210a, in particular via the corresponding socket.

[0139] The said dissipation device is fixed to the protective housing 200, in particular by means of a fastening element such as a first connecting screw 202, which engages in the connection terminal 210a, specifically in the corresponding socket. The said first connecting screw 202 is oriented substantially perpendicularly to the face 204 of the protective housing 200.

[0140] Heat is transferred to the hot thermal interface element 80, specifically to the third flange 84, by contact with the bushing and / or the first connecting screw 202. This contact also allows current to flow between the corresponding electrical component 14 and the heat dissipation device. The heat dissipation device is therefore electrically energized, hence the importance of the electrical insulation provided by the thermally conductive and electrically insulating material, particularly the bearing 40 in contact with the cold source 16.

[0141] The other 210b of the connection terminals of the hot source(s) 12 is electrically connected to the busbar(s) 100. For this purpose, the connection box includes second connecting screws 206 passing through certain of the through holes 102 and serving to secure the busbar 100 to the corresponding electrical component 14. Current flows between the electrical component 14 and the busbar 100 through contact with the socket and / or the second connecting screw 206.

[0142] In the illustrated embodiment, the dissipation device is configured to be in heat exchange relationship with both the first 210a of the connection terminals of a first of the hot sources 12 and with the first 210a of the connection terminals of a second of the hot sources 12, the first connection terminals 210a being provided at the same electrical potential. The dissipation device thus plays, in addition to its thermal role, a role as an electrical conductor between the electrical components 14 of the hot sources 12.

[0143] In other words, in the illustrated embodiment, said dissipation device comprises two said second thermal interface organs 80 respectively in thermal exchange relationship with each of said hot sources 12.

[0144] The said heat pipe 10 is in contact, for example, with each of the said second thermal interface elements 80 by opposite longitudinal ends of the said heat pipe 10. The said heat pipe 10 is in contact with the said first thermal interface element 20 by a zone, in particular a median zone, located between its said longitudinal ends.

[0145] It is observed that, in this embodiment, the median plane of symmetry P mentioned above serves as a plane of symmetry for the whole of said dissipation device, or even for said hot sources 12 and / or said omnibus bars 100.

[0146] Such an embodiment is not limiting to the invention, which, alternatively, applies to a configuration with two heat pipes 10, each of said heat pipes connecting the cold thermal interface element 20 and the hot thermal interface element 80 corresponding to each of said hot sources 12, said median plane of symmetry being preserved or not. Also alternatively, the invention applies, in particular, to configurations with such a dissipation device connecting a single hot source 12 and the cold source 16, said device then comprising a single heat pipe 10 connecting the cold thermal interface element 20 and the hot thermal interface element 80 corresponding to said hot source 12.

Claims

DEMANDS 1. Heat dissipation device, in particular for motor vehicle, said device being configured for heat exchange between, on the one hand, a hot source (12) comprising an electrical component (14), and, on the other hand, a cold source (16), said device further comprising a first thermal interface component (20), said first thermal interface component (20) comprising a head (20b) intended to be in heat exchange relationship with one of said hot or cold sources (12, 16), said head (20b) comprising a thermally conductive and electrically insulating material (40) intended to be in contact with said hot or cold source (12, 6), said head (20b) further comprising a spacer (44) for protecting said thermally conductive and electrically insulating material (40).

2. Heat dissipation device according to the preceding claim in which said head (20b) comprises a housing (48) accommodating said spacer (44).

3. Heat dissipation device according to the preceding claim in which said spacer (44) is movable in said housing (48).

4. Heat dissipation device according to any one of claims 2 or 3, wherein said spacer (44) slides within said housing (48).

5. Heat dissipation device according to any one of the preceding claims, wherein said head (20b) comprises a diffuser (32) intended to be in heat exchange relationship with said cold or hot source (12, 16) in question, 6. Heat dissipation device according to claim in which said thermally conductive and electrically insulating material (40) is in contact with said diffuser (32) 7. A heat dissipation device according to any one of claims 5 or 6, wherein said spacer (44) is related to said diffuser (32) so as to define a housing for said thermally dissipated material conductor (40), said housing being intended to be located between said diffuser (32) and said hot or cold source (12, 16) in question.

8. Heat dissipation device according to any one of claims 5 to 7, taken in combination with any one of claims 2 to 4, said housing (48) further housing said diffuser (32).

9. Heat dissipation device according to any one of the preceding claims wherein said thermally conductive and electrically insulating material (40) is compressible.

10. Heat dissipation device according to the preceding claim in which said first thermal interface member (20) is configured to compress said thermally conductive and electrically insulating material (40) against said hot or cold source (12, 16) involved, in particular by screwing.

11. Heat dissipation device according to any one of the preceding claims in which said head (20b) comprises an elastomeric membrane (45) configured to force said spacer (44) against said cold or hot source (12, 16) involved.

12. Heat dissipation device according to any one of the preceding claims in which said head (20b) includes, before assembly, a protective cover (42) for said thermally conductive and electrically insulating material (40).

13. Electrical connection box for electrical energy storage device, in particular accumulator battery, comprising one or more hot sources (12), a cold source (16) and a heat dissipation device according to any one of the preceding claims for establishing a heat exchange between said hot source(s) (12), on the one hand, and said cold source (16), on the other hand.

14. Electrical energy storage device, in particular accumulator battery, comprising a heat dissipation device according to any one of claims 1 to 12.

15. Vehicle comprising one or more of the heat dissipation devices according to any one of claims 1 to 12.