FR3037127A1 - THERMAL DISSIPATOR OF AUTOMOTIVE PROJECTOR LED OPTICAL MODULE - Google Patents

Abstract

The invention relates to a finned heat sink (16) (18) for an optical module for a light device. The heatsink includes a base (22) exchanging calories with a control board and a light source such as an LED or LED of the device. The base (22) comprises one or more openings (20) therethrough according to its thickness so as to allow aeration of the light module through the base (22). Thus, it is possible to ventilate, ventilate a housing housing the optical module to evacuate the moisture it contains. The openings (20) are provided with spans, such as tubes, which receive a cover and a filter, or a pipe conveying air from a ventilation. The heat sink (16) also includes another aperture (16) with a cap with a cap and a filter.

Description

TECHNICAL FIELD [0001] The invention relates to the field of light devices of a motor vehicle. More specifically, the invention relates to a heat sink for a light device of a motor vehicle. The type of heat sink considered is more precisely the asperity type, to dissipate the heat produced by the light source, from a convection obtained by natural upward movement of hot air with respect to gravity along the fins . The invention also relates to a motor vehicle headlight. PRIOR ART Automotive headlamps are generally composed of a housing which is closed by a transparent wall through which emerge one or more light beams. This housing houses at least one optical module, mainly comprising a light source and an optical system capable of modifying at least one parameter of the light generated by the light source for the emission of the light beam by the optical module. The optical system comprises optical components which consist, for example, of a reflector, a lens, a scattering element or a collimator, or even any other device able to modify at least one of the parameters of the light generated by the light source, such as its average reflection and / or direction. The evolution of techniques tends to favor the use of light sources consisting of at least one LED (Electroluminescent Diode), because of their low power consumption and the quality of the lighting obtained. LEDs do not radiate omnidirectionally but in a more directive way than other light sources. The small size of the LEDs and their directional light radiation can reduce the size and simplify the structure of the optical module, with the advantage of facilitating their integration within the housing. The optical system associated with the LEDs makes it possible to send back the light directly emitted by the LED in a general direction of emergence of the light outside the optical module, which corresponds in particular to that of emission of the light beam by the projector. However, during operation, the LEDs produce heat which is detrimental to their operation, because the more a LED rises in temperature, the lower its luminous flux decreases. It is known to provide the LEDs with a finned heat sink, arranged as a finned radiator 10 or the like. Such a heat sink is in particular organized in support of the LED installed on an electronic control board, and comprises a plurality of generally flat fins. This dissipator makes it possible to conduct the heat dissipated by the light source to the fins of the dissipator. These fins make it possible to optimize the heat exchange which takes place between their surface and the ambient air, which thus heats in contact with the fins. A first difficulty to overcome is to find a compromise between the optimization of the heat exchange surface offered by the fins and the overall size of the optical module equipped with the means necessary for its cooling. It is also to be taken into account that the arrangement of the LED cooling means is dependent on the heat they generate according to their operating power, but also on the bulk. [0005] When the optical module is designed to generate a beam requiring a high luminous intensity, such as for crossing lights, high beams or fog lamps. The number of LEDs and / or the power required for their operation are high. As an indication, such a high operating power is likely to be between 5 W and 60 W. The cooling means implemented are arranged to allow the significant heat generated by the LEDs to be removed. When the optical module is designed to generate a constituent beam of a traffic light or the like, the number and power required for the operation of the LEDs are low. As an indication, in 3037127 3/25 the case of a daylight running light (or DRL for "Daytime Running Light"), the optical module is able to exploit about 1 to 14 LEDs, for an operating power of 0.5 W to 6 W. For these less power dissipating LEDs, the heat dissipating means does not require the use of a forced airflow. The heat generated by the LEDs is transmitted by conduction to the fins, which are surrounded by the ambient air. The latter while warming is animated by an upward movement with respect to gravity and evacuates the heat. Such arrangements have the advantage of exonerating the cooling means of specific generating members of a forced air flow. SUMMARY OF THE INVENTION Technical problem [0007] The object of the invention is to solve or improve at least one of the problems posed by the prior art. More specifically, the object of the invention is to increase the cooling of a heat sink. The invention also aims to improve the operation of a light device by exploiting at least one thermodynamic phenomenon. TECHNICAL SOLUTION [0008] The subject of the invention is a heat sink, for example with fins, of a vehicle light device, the dissipator comprising: a base intended to receive a light source of the optical module, in particular a light-emitting diode; and cooling asperities extending from the base, characterized in that the base comprises an aperture with a fixing surface and / or a retention surface located in the thickness of the base. The invention also relates to a heat sink of a vehicle light device, the dissipator comprising: a base with two opposite faces according to its thickness, including an upstream face and a downstream face; cooling asperities extending from the upstream face, the downstream face being intended to receive a light source; It should be noted that the base comprises at least one opening arranged so as to allow the flow of air from one face to the other. According to an advantageous embodiment of the invention, the cooling asperities comprise cooling fins. According to an advantageous embodiment of the invention, the cooling asperities comprise cooling rods. According to an advantageous embodiment of the invention, the cooling asperities comprise cooling grooves. According to an advantageous embodiment of the invention, at least one or each opening comprises at least one orifice formed in the base and at least one attachment surface extending the orifice, and in that it comprises at least one cover cooperating with the attachment surface. The term cover is here considered equivalent to the word cap. According to an advantageous embodiment of the invention, the height of the fins is greater than the height of each span. According to an advantageous embodiment of the invention, the cover, the orifice and the attachment surface defining a passage for air circulation according to the thickness of the base. According to an advantageous embodiment of the invention, the scope surrounds the orifice. In an advantageous embodiment of the invention, at least one bearing is tubular. According to an advantageous embodiment of the invention, at least one bearing is of generally cylindrical shape. According to an advantageous embodiment of the invention, at least one bearing is of generally quadrangular shape. According to an advantageous embodiment of the invention, at least one bearing is profiled. According to an advantageous embodiment of the invention, the scope comprises partitions (56) forming a plurality of compartments. According to an advantageous embodiment of the invention, the base, the asperities, and the span are made of the same material. According to an advantageous embodiment of the invention, the base, the asperities, and the scope are monobloc. According to an advantageous embodiment of the invention, the range is fixed to the base. According to an advantageous embodiment of the invention, the scope comprises a material different from the material of the base. According to an advantageous embodiment of the invention, the base, the asperities, and the span are made of material. According to an advantageous embodiment of the invention, the dissipator comprises a pipe shod on the scope. According to an advantageous embodiment of the invention, the pipe is made of rubber. According to an advantageous embodiment of the invention, the pipe has a portion 10 pavement on the scope, and a portion adjacent to the pavement portion, the adjoining portion has an outside diameter less than the outside diameter of the pavement portion. According to an advantageous embodiment of the invention, the scope comprises partitions forming several compartments. According to an advantageous embodiment of the invention, at least one notch is formed in the partitions so as to allow communication between the compartments. According to an advantageous embodiment of the invention, the partitions have different heights relative to the base. According to an advantageous embodiment of the invention, the cover and the opening are configured to form baffles in the passage. According to an advantageous embodiment of the invention, the opening comprises fixing means disposed inside said opening. According to an advantageous embodiment of the invention, the fastening means are arranged in the orifice. According to an advantageous embodiment of the invention, the fastening means are arranged in the attachment range. According to an advantageous embodiment of the invention, the fastening means are arranged around the orifice. According to an advantageous embodiment of the invention, the fixing means are at a distance from the base. According to an advantageous embodiment of the invention, the cover comprises at least one attachment means configured to cooperate with the means for fixing the opening. According to an advantageous embodiment of the invention, the fastening means of the lid comprise a fastening hook or a fastening bead. According to an advantageous embodiment of the invention, the base comprises at least two openings therethrough according to its thickness. According to an advantageous embodiment of the invention, said at least two openings are separated by a cross member and / or by at least one of the asperities. According to an advantageous embodiment of the invention, the base, the asperities are made of the same material. According to an advantageous embodiment of the invention, the opening comprises a watertight filter and permeable to air. According to an advantageous embodiment of the invention, the filter is disposed at one end of the opening. According to an advantageous embodiment of the invention, the filter is a membrane, such as a woven membrane. According to an advantageous embodiment of the invention, the or at least one or each opening is delimited by the general thickness of the base. The overall thickness may be between the two opposite major faces of the base. According to an advantageous embodiment of the invention, the base comprises at least one opening connecting the opposite faces. The opening thus allows ventilation of the downstream face in order to be able to renew the air towards the light source via the opening. According to an advantageous embodiment of the invention, the attachment surface is a fixing end, and / or a mounting form against. According to an advantageous embodiment of the invention, the cooling fins are oriented in their general plane parallel to the direction of natural upward movement of the hot air generated by the heat produced by the operating light source. According to an advantageous embodiment of the invention, the cooling fins have a constant spacing, possibly at the opening. According to an advantageous embodiment of the invention, the cooling fins are in heat conduction bond with the base. According to an advantageous embodiment of the invention, the thickness of the fins is between 0.8 and 1 millimeter, and / or the distance between the fins is between 4 and 6 millimeters. According to an advantageous embodiment of the invention, at least one or each opening passes through the base according to its thickness. According to an advantageous embodiment of the invention, at least one or each opening comprises a fixing surface, and / or a sealing surface and / or positioning means. According to an advantageous embodiment of the invention, at least one or each opening is circular, triangular, square, rectangular, and / or octagonal. According to an advantageous embodiment of the invention, at least one or each opening is of circular shape. According to an advantageous embodiment of the invention, the base comprises a cross member separating the at least two openings. According to an advantageous embodiment of the invention, the heat sink comprises aluminum and / or copper and / or a thermally conductive polymer material. According to an advantageous embodiment of the invention, at least one or each opening is placed between two fins disposed on the same face of the device. According to an advantageous embodiment of the invention, each opening is placed between two consecutive fins. According to an advantageous embodiment of the invention, at least one or each opening cuts a fin. According to an advantageous embodiment of the invention, at least one or each opening cuts a same fin. According to an advantageous embodiment of the invention, the opposite faces of the base each comprise a main surface, at least one or each opening flush with the main surfaces of the base. According to an advantageous embodiment of the invention, the span is arranged between two consecutive fins which define a space between it, the range being encompassed in said space, preferably the range is spaced apart from each of said two fins. consecutive. According to an advantageous embodiment of the invention, the bearing comprises a generally smooth outer tubular surface, and / or fastening means. According to an advantageous embodiment of the invention, the filter is disposed at a free end of the scope. The term "profile" means that a shape extending in a given direction 10 and having a constant cross section along this direction. The shape can be extruded. The height of the fins and / or asperities can be measured according to the thickness of the base. The invention also relates to a light module and / or signaling for a motor vehicle, the device comprising a heat sink, remarkable in that the heat sink is in accordance with the invention, preferably the device comprises a source light supported by the base which is offset with respect to each opening of the base; optionally the device comprises an electronic control card, each opening of the base being shifted relative to said card. The invention also relates to a light device comprising at least one light source and at least one heat sink, remarkable in that the heat sink is in accordance with the invention. According to an advantageous embodiment of the invention, the light source is supported by the base and is offset with respect to the or each opening of the base. According to an advantageous embodiment of the invention, the light source comprises at least one semiconductor emissive element. According to an advantageous embodiment of the invention, the light source is a light emitting diode. According to an advantageous embodiment of the invention, the light source is arranged directly on the heat sink. According to an advantageous embodiment of the invention, the device comprises an electrical connection substrate adapted to electrically power the light source. According to an advantageous embodiment of the invention, the connection substrate is a printed circuit board, or a flexible printed circuit board or a variable geometry interconnection device. According to an advantageous embodiment of the invention, the connection substrate is arranged on the heat sink. According to an advantageous embodiment of the invention, the light source is arranged on the electrical connection substrate. According to an advantageous embodiment of the invention, the or each opening of the base being offset relative to the electrical connection substrate. According to an advantageous embodiment of the invention, in the normal mounting position, at least one or each opening is placed in the upper half of the base of the heat sink. According to an advantageous embodiment of the invention, the device comprises an enclosure delimited at least partially by the base of the heat sink, the opening being configured to allow an air exchange between the inside and the outside of the enclosure. In an advantageous embodiment of the invention, the device comprises ventilation means. According to an advantageous embodiment of the invention, the ventilation means are a fan or a compressor causing ventilation of the air in the enclosure through the opening. According to an advantageous embodiment of the invention, the fan or the compressor causes ventilation of the air in the enclosure through the opening via a pipe. According to an advantageous embodiment of the invention, the device comprises a housing and a transparent wall which delimit the enclosure. According to an advantageous embodiment of the invention, the luminous device is a lighting device and / or a signaling device. According to an advantageous embodiment of the invention, the luminous device is a front searchlight, or a rear light, or a vehicle interior light device. According to an advantageous embodiment of the invention, the enclosure has an aperture 5 covered by the base of the heat sink. In general, the advantageous modes of each object of the invention are also applicable to the other objects of the invention. In the present application: [0090] *) the direction of natural upward movement of the warming air is to be taken into account with regard to the gravity, and the known natural phenomenon according to which an air mass more hot that the ambient air is animated by a natural ascending movement. [0091] *) the orientation of the fins is to be taken into account in view of their general plan of extension. The fins are oriented so that they are swept by the warming air, heated air then animated by said ascending natural movement. The fins are oriented in their general plane parallel to a plane corresponding to the general direction of emergence of the light out of the luminous device and to the general direction of the upward natural movement of the hot air. The vanes are preferably solid by being formed into a blade or the like, but are also capable of being hollowed out by being formed from at least two blades juxtaposed and spaced apart from each other. *) The orientation of the general direction of emergence of the light out of the luminous device is to be taken into account with regard to the emergence of the light generated directly by the light source after modification of at least one of its parameters by at least one optical component, such as its average reflection and / or direction. Advantages The opening in the base allows air to be supplied to the light source, which helps to cool the face; the side occupied by the latter. Since the air is taken from the side of the fins, the latter is animated with a movement favorable to aeration, a renewal of air. It shows that for a given overall mass and size of the heat sink, which combines the base and the connecting fins, its cooling performance is optimized. The invention makes it possible to dry out the zone receiving the light source. This result is achieved by exploiting the natural air circulation generated by the heat exchange, and the fact that this air is deemed drier since it has previously been reheated. The opening and the fins thus offer a synergy in terms of dewatering. When the dissipator delimits a chamber or cavity of a light device, the invention makes it possible to dry out this space, and possibly to dissipate the mist which would have formed on a diopter. Since this result can be achieved passively, the invention thus contributes to reducing the consumption of primary energy. [0094] Moreover, the invention exploits a thermodynamic effect which favors the operation of a light device since the change in density of the gas as a result of its operation preserves the lighting of a light source by cooling it. In addition, the opening may be used to perform a leak test of the housing by injecting or inspiring air therein. Such tests then become simpler, faster, more accurate and more reliable. Indeed, it is sufficient to connect a sealed device to the opening to measure the tightness of the housing, which allows a saving. Furthermore, the presence of the scope further increases the heat exchange surface of the dissipator; whether for air around the staff, or for air entering the opening in contact with the staff. Brief description of the drawings [0097] FIG. 1 represents a light device with an optical module according to the invention. [0098] FIG. 2 illustrates a finned heat sink according to the invention, the dissipator being observed on the side of the fins. FIG. 3 illustrates a portion of heat sink with asperities according to the invention. Figure 4 illustrates another portion of the heat sink with other asperities according to the invention. [00101] Figure 5 illustrates a finned heat sink according to the invention, the dissipator being observed on the side of the light source. [00102] Figure 6 outlines a base opening of heat sink provided with a filter and a cover surrounding the opening according to the invention. [00103] Figure 7 outlines a basic heat sink opening provided with a filter and a lid inserted into the opening according to the invention. [00104] Figure 8 outlines a base opening heat sink provided with a lid and a filter according to the invention. [00105] Figure 9 illustrates one of the openings receiving a pipe fitted on one of the openings according to the invention. [00106] Figure 10 illustrates one of the openings with partitions according to the invention. DESCRIPTION OF EMBODIMENTS [00107] FIG. 1 is a simplified representation of a light device 2, in particular a headlight 2 providing illumination, for a motor vehicle comprising a housing 4 closed by a transparent wall 6, in particular an ice-cream or a wall made in transparent polycarbonate. The light device may also be a vehicle signaling device. It can still be a luminous device in the passenger compartment of a vehicle, for example for reading. The housing 4 may contain several light modules 8 provided with at least one, preferably several light sources 10; and optical systems 12 capable of concentrating and / or deflecting the light rays emitted by each light source 10. Sets of lenses, and / or light guides, and / or mirrors may be employed for this purpose. The combination of the transparent wall 6 and the housing 4 thus defines at least one enclosure 14, or space, housing at least one light module 8. Optionally, an enclosure 14 is associated with each light module 8. An optical system 12 is placed downstream of the light source 10 to send the light beam R directly emitted by the light source 10 in a general direction of emergence D of the light out of the light device 2. The upstream and downstream locations are to be considered at With this direction of emergence D of the light outside the luminous device 2. [00109] During operation, the light sources 10 produce heat which increases the temperature in the enclosure 14 of the housing 4. It is necessary to to dissipate the calories in order to preserve the equipment, and also to maintain the level of luminous intensity emitted by the light source 10. This aspect must be particularly carefully e case of light-emitting diodes. [00110] The cooling of the light sources 10 is advantageously provided by at least one heat sink 16 or heat exchanger 16, for example a heat sink 16, or several dissipators 16. At least one or each heat sink 16 comprises asperities of cooling 18, including cooling fins 18. The at least one or each heat sink 16 may be a finned heat sink. Advantageously, the heat sink 16 comprises at least one opening 20 formed in its base 22 between fins 18. Thus, the heat sink 16 has a breathable appearance, it allows ventilation and / or ventilation through its base 22 The base 22 of the heat sink 16 may form a wall, which extends the clean shell of the housing 4. Other openings may be formed on the housing, in particular to ventilate it. In particular, the housing 4 may show an aperture 24 on or in which the heat sink 16 is fixed; optionally in a sealed manner. The base 22 can provide a seal between the opening 20 and the opening 24 of the housing 4; the wall that forms the base 22 may be generally sealed. The fins 18 are advantageously placed outside the enclosure 14, in contact with the air surrounding the housing 4. The base 22 may have two opposite faces according to its thickness, and / or opposite so as to form the main faces of the base 22. The upstream face may be on the side of the fins, the other of the two faces; the downstream face; being on the side of the light source. This face receives, supports, and maintains the light source 10. An electrical connection substrate 26 can be placed against the heat sink 16, and optionally support the light source 10. With its conductive tracks it can supply light source 10 The electrical connection substrate 26 may comprise an electronic control board 26 which may be interposed between the base 22 and the light source 10, and have the function of controlling, such as an electronic switch or a control unit, the light source 10. The substrate 26 may comprise a printed circuit board PCB; and / or a flexible printed circuit board, for example a circuit known by the acronym FPCB for "Flexible Printed Circuit Board". The substrate 26 may also comprise a variable geometry interconnection device, for example a device known by the acronym MID for "Molded In Device". The substrate 26 may comprise a combination of a PCB, a FPCB, and a MID. In operation, card 26 can generate heat because of the electrical energy it uses. This card 26 can be housed in the opening of the housing, depending on its position it can conduct the heat of the light source 10 to the base 22, and itself benefit from the cooling of the dissipator 16. [00114] Following a alternative of the invention, the heat sink can be housed inside the housing. In this configuration; the base just as the fins are inside an enclosure, preferably within a single enclosure of the housing. Advantageously, the housing 4 has several openings 20 formed 30 on the same heat sink 16, or distributed on different heat sinks 16. The air can then enter through an opening 20, and out through another opening 20, which promotes ventilation. Optionally, one of the openings 20 is connected to a compressor 27 or a ventilation 27, which allows to cause a flow of air through an opening. Thus, the air of the enclosure 14 can be renewed. [00116] Figure 2 shows a heat sink 16 observed on the side of its fins. [00117] The base 22 may have a general shape of a material plate. It materializes a plate, a junction which connects the different fins 18 between them. It forms at the same time a mechanical link, but also a thermal link between each fin 18. It also forms a thermal bridge between the light source and the fins 18. The heat sink 16 comprises a set of fins 18 of cooling. The fins 18 may be generally parallel. They extend perpendicularly with respect to the base 22. The fins 18 of the heat sink 16 are spaced from each other to provide air passages 28 between them, the channels 28 15 for guiding the exchange flows thermal 30, for example cooling streams. The channels may overlap the openings 20. The cooling fins may have a random spacing. Two fins may be further apart when lining an opening. [00119] Each cooling stream 30 is naturally generated by the upward movement of the air heating in contact with the fins 18 forming the heat exchange surface of cooling since the temperature of this heat exchange surface is greater than that from the surrounding air. Each fin 18 has a side joined to the base 22, 25 and a free opposite side. These sides are opposite perpendicular to the thickness of the base. The fins 18 are oriented in their general plane vertically with respect to gravity, so that the heated air can circulate along their surface from a natural upward movement of this hot air.

The direction S of natural upward movement of the hot air is oriented substantially orthogonal to the direction D of emergence of the light out of the luminous device. The fins have a main elongation oriented in their general plane along the direction S of upward movement of the hot air. The heat sink 16 may comprise at least two fins 18; in the case shown, it shows four. However, it can include 5 more. The fins 18 can form sealed separations, which border the various channels 30. The dissipator 16, its base 22 and its fins 18, have a general shape comb section. [00122] FIG. 3 represents an enlargement of a portion of heat sink 16 observed on the side of the fins, that is to say on the side of the upstream face 34. [00149] The cooling asperities 17 may comprise cooling grooves 19 formed in the thickness of the base 22. The grooves 19 may be between the fins, and follow them in parallel. The grooves may extend on either side of an opening, possibly opening into it. They can extend from one opening to another. Thanks to the heat exchange in the grooves 19, flows 30 can be trained. [00124] Figure 4 shows an enlargement of another portion of the heat sink 16. The upstream face 34 is visible. The cooling asperities 17 may comprise cooling rods 21, such as pins protruding from the base 22. The cooling rods 21 are joined to the base 22 so as to allow thermal conduction. They can be distributed on the base 22, for example between the fins. The cooling rods 21 can be arranged in columns, so as to provide between them channels 28 for guiding and driving the flows 30. The columns of rods can advantageously be arranged vertically in the normal direction of mounting of the dissipator 16 [00126] Cumulating several types of cooling asperities 17 makes it possible to multiply the heat exchange surface of the same exchanger 16. The presence of cooling fins is not essential according to the invention. They can be replaced by cooling rods and / or cooling grooves. Figure 5 shows a heat sink 16 observed on the side of the light source that it supports. The base 22 is shown in solid lines, the fins 18 on the non-visible face are shown in dashed lines. The position of the dissipator 16 shown here may correspond to its mounting position. At least one opening 20 can be placed in the upper half so that the rising air passing through said opening 20 has benefited from the heating of the fins 18. The base 22 has a rectangular plate shape, its downstream face 32 10 receives a light source 10. The light source 10 may comprise a semiconductor emissive element, for example one or more light-emitting diodes (LED or LED). Optionally the light source 10 is a single LED. The light source 10 is at a distance from each opening 20 of the associated dissipator 16; since the latter 15 may have several openings 20. The remote aspect being measured according to the general plane of the base 22, or main plane in terms of area. Each diode is at a distance from each opening 20. The electronic control board 26 is also attached to the base 22, on the side of the light source 10, possibly by gluing 20 or any other means allowing thermal conduction with the base 22. Such an electronic component 26 is part of a control device which manages the ignition, extinction and / or protection of the light-emitting diodes. The extent of the card 26 can receive the light source 10. Alternatively, the light source is remote from the card. Advantageously, the card is remote from each opening 20 to optimize ventilation. Optionally, the card 26 extends on the base so that it covers at least two fins 18, to improve the cooling of the card 26 by means of the fins 18. [00130] The positions of the openings 20 are here between consecutive fins 18. The width or diameter of the openings is greater than the thickness of the fins 18, and less than the average spacing between the fins 18. However, other configurations are possible. For example, at least one opening may be placed in line with a fin 1837 which passes through the opening, said opening may then communicate with different passages. Or, the opening can cut a fin by forming a clearance. [00131] Although several openings 20 are here illustrated, four in this case, it is conceivable that the dissipator comprises one, two, or more than represented. These openings 20 can be placed at different heights, and / or be in communication with different channels. Thus, passive ventilation can be ensured. [00132] Figure 6 shows a section of the heat sink 16 at 10 of one of the openings 16. A portion of the base 22 and a cooling fin 18 are shown. The opening 20 passes through the base 22 according to, it joins the upstream face 34 and the downstream face 32 of the base 22; these two faces being opposed according to the thickness of the base 22. The opening 20 allows aeraulic communication between the two opposite faces (32; 34), allows aeration of the space where it is located, and possibly a ventilation of the housing enclosure 14 with which it is associated. The air on the downstream side, the side occupied by the light source can be renewed. The opening 20 may have an orifice and a fixing surface 36 20 forming a projection 36, a protuberance 36 relative to the base. The span 36 extends the orifice from the base 22, the remaining orifice inscribed in the base 22. The span may be a fixing endpiece 36, possibly extending the opening 20. The bearing surface (36) provides a counterform facilitating the attachment of equipment. The span 36 may surround the opening 20, or be a set of rods, fingers, in the extension of the opening and perpendicular to the base, which serve for example for the attachment of equipment. The span 36 may be profiled in the direction of the thickness of the base 22. The span 36 may be a tube portion, that is to say a hollow bar portion. The tube may be of cylindrical or quadrangular section. The span 36 may form an elevation that moves the mouth of the opening relative to the associated face of the base. According to a variant, the opening is delimited by the general thickness of the base. She can be free of reach. The presence of the scope is optional. Indeed, the opening may simply be an orifice, a cutout which passes through the base 22. The opening may comprise retention means 38. The inner surface of the opening 20, which defines the opening, may have a hole 5. holding surface, and / or a retention surface such as an annular retention groove 38. It may also be localized redents. The heat sink 16 may comprise a filter 40, possibly each opening 20 is equipped with a filter 40. Each filter 40 may be placed at the top of the span 36, possibly being glued therein. The filter 10 may also be placed on one surface of the base, or held in the annular groove 38 formed in the thickness of the base. It can be maintained using an attached filter holder, possibly removable to facilitate its replacement. Each filter 40 may be configured to block dust. It may also have air permeability and water tightness. Owing to its properties, the filter 40 allows a ventilation through the opening 20 while blocking the water, the steam. The filter 40 may be permeable to water in one direction; and waterproof in the other direction. The filter 40 may be a membrane, for example woven. Thus it promotes a drying of the housing enclosure 14, but prevents moisture from entering. Also, the heat sink 16 may be equipped with a lid 42 or cap. The latter is advantageously associated with the opening 20. Optionally, the dissipator 16 comprises several lids each associated with an opening 20. Each lid 42 covers a bearing surface 36 and / or is inserted into an opening 20. The lid 42 allows partially closing the opening 20, it allows to provide a baffle passage to the opening. The edges of the lid 42 are configured to provide a passage 44 with the opening for aeration. At least one or each cover 42 may comprise fixing means 46, such as a hook, cooperating with the opening 20, for example at the level of the bearing surface and / or with an annular groove 38. The span 36 may have beads 48 of engaging material with hooks or cover clipping systems. Advantageously, the cover remains in the space delimited by the fins 18. Thus, its presence does not modify the overall size of the dissipator 16, because the cover 42 remains in the general envelope of the fins 18. 5 [00140] The heat sink 16 is suitable for use not only for low power LEDs of the type used for traffic lights, but also for higher power LEDs of the type used for high beam, fog lamps, dipped beam or even still daytime running lights. The assembly comprising the base 22 and the fins 18 forms a finned heat sink which can advantageously form a monobloc member that can be easily produced by molding, by co-molding, by extrusion, by folding of strips and sealing of these strips. between them or by any other irreversible assembly technique of the different elements of the heat sink 16 to be assembled together. This makes it possible to realize the heatsink at a lower cost, to simplify the installation on the basis of the light source and the electronic and / or optical components associated with it. The dissipator 16 may be made of a material whose thermal resistivity is as low as possible, such as a metal, for example aluminum and / or copper. [00142] Figure 7 shows a section of the heat sink 16 at one of the openings 16. A portion of the base 22 and a cooling fin 18 are shown. [00143] The opening 20 receives a cover or a plug inserted in the range 36. The stopper is configured so as to provide a passage 44 between its outer surface and the inner surface of the span 36 so that a circulation of air is allowed. The span 36, such as the plug, has fastening means (46; 48) for holding in the opening 20. The cap may be capped by the filter 40. [00144] FIG. 8 shows a section of the heat sink 16 at one of the openings 16. A portion of the base 22 and a cooling fin 18 are shown. The opening 20 is protected by means of a cover 42 having an outer portion 47 surrounding the bearing surface 36, and an inner portion 49 inserted into the bearing surface. The span 36 and the cover 42 comprise fastening means (46; 48) cooperating together. These fixing means 5 may be formed inside and / or outside the bearing surface 36. A passage 44 is formed outside the bearing surface 36, then penetrates inside the bearing surface 36. passage runs along the outer portion 47 and the inner portion 49 of the cover. The filter 40 may define the opening 20 opposite the cover 20. FIG. 9 shows one of the openings 20 of the dissipator 16. A pipe 50, a portion of the base 22 and the bearing surface 36 are visible here. Optionally, the dissipator comprises only an opening 20 or openings 20 equipped (s) as follows. The span 36 may be a fastener 36, possibly extending the opening 20. [00147] A pipe 50, such pipe 50 may be associated with the opening 20. This pipe 50 is placed between two fins 18, and extends parallel to them, according to their principal direction. It remains at a distance from the upstream face 34 of the base 22 so as not to limit the heat exchange provided by the base 22. The pipe 50 is fixed to the span by means of a head 52 having a cavity 54 the mouth of the opening 20. The profiled portion of the pipe 50 may be flat, having a passage 44 in the form of air knife, flat. The profile of the profiled portion, elongate, is rectangular to limit the thickness, and therefore reduce compactness remaining under the tops of the fins. [00148] The pipe 50 can be force-fitted on the bearing surface 36. Its portion which is fitted around the bearing surface 36 can deform so that its diameter increases locally. This type of attachment may be based on the friction between the pipe, possibly rubber; and the scope, possibly of aluminum. The pipe 50 is self-supporting, however the securing security can be increased by adding ribs, annular grooves on the outer surface of the span. According to an alternative of the invention, the pipe is mounted inside the bearing, it can hold against the inner surface of the opening, for example by means of the annular groove 38. [00149] Optionally, the pipe may be substantially cylindrical and have a generally constant section. The pipe may be a pipe connected to the blower or compressor and channel the ventillation flow. A filter can be placed at the mouth of the opening, or housed in the profiled part of the pipe, for example at the end opposite the opening 20. [00150] FIG. 10 shows one of the openings 20 of the dissipator The span 36 and a portion of the base 20 are drawn in the form of a perspective. Optionally, the heatsink comprises only one opening or openings having the following configuration. The span 36 may be a fastener 36, possibly extending the opening 20. The span 36 has partitions 56 which surround the associated opening 20. The partitions 56 may have different heights, and / or different thicknesses. The heights are measured perpendicular to the surface of the base 22. The partitions 56 define a series of compartments, baffles, in the passage of the opening 20 between the opposite base faces 22. One or more notches 58 may be formed in partitions 56 to allow communication from one compartment to another, and / or form baffles. These compartments may comprise tabs for fixing a cover (not shown), or tabs forming baffles in a same compartment. The presence of the compartments, as the addition of baffles makes it possible to block the entrance of dust, without requiring a filter. Thus, the operation of the dissipator 16 is preserved without increasing costs, complexity.

Claims (18)

REVENDICATIONS1. Heat sink (16) of a vehicle light device (2), the dissipator (16) comprising: - a base (22) with two opposite faces (32; 34) according to its thickness, including an upstream face (34) and a downstream face (32); - cooling asperities (17) extending from the upstream face (34), the downstream face (32) being intended to receive a light source (10),; characterized in that the base (22) comprises at least one aperture (20) arranged to allow air flow from one face (32; 34) to the other. 2. heat sink (16) according to claim 1, characterized in that the asperities (17) of cooling comprise cooling fins (18). 3. Heat sink (16) according to one of claims 1 to 2, characterized in that at least one or each opening (20) comprises at least one orifice in the base (22) and at least one attachment surface (36) extending the orifice, and in that it comprises at least one cover (42) cooperating with the attachment surface (36). 4. Heat sink (16) according to claim 3, characterized in that the cover (42), the orifice (20) and the attachment surface (36) define a passage (44) allowing air circulation according to the invention. thickness of the base (22). 5. Heat sink (16) according to one of claims 3 to 4, characterized in that the span (36) surrounds the orifice. 6. Heat sink (16) according to one of claims 3 to 5, characterized in that at least one bearing surface (36) is profiled. 7. heat sink (16) according to one of claims 3 to 6, characterized in that the scope (36) comprises partitions (56) forming a plurality of compartments. 8. Heat sink (16) according to one of claims 3 to 7, characterized in that the bearing surface (36) is fixed to the base (22). 3037127 24/25 9. Heat sink (16) according to one of claims 3 to 7, characterized in that the base (22), the asperities (17), and the bearing surface (36) are integral. Heat sink (16) according to claim 7, characterized in that at least one notch (58) is formed in each partition (56) so as to allow communication between the compartments. 11. Heat sink (16) according to one of claims 3 to 10, characterized in that the cover (42) and the opening (20) are configured to form baffles in the passage (44). 10 12. Heat sink (16) according to one of claims 1 to 11, characterized in that the opening (20) comprises fastening means (38) disposed within said opening (20). 13. Heat sink (16) according to one of claims 3 to 11 and one of claims 26 to 30, characterized in that the cover (42) comprises at least one fastening means configured to cooperate with the means of fastening (38; 48) the opening (20). 14. Heat sink (16) according to one of claims 1 to 13, characterized in that the base (22) comprises at least two openings (20) therethrough according to its thickness. 20 15. Heat sink (16) according to claim 14, characterized in that said at least two openings (20) are separated by a cross member and / or by at least one of the asperities (17). 16. Heat sink (16) according to one of claims 1 to 15, characterized in that the aperture (20) comprises a filter (40) impervious to water and dust and permeable to air. 17. Light device (2) comprising at least one light source and at least one heat sink (16), characterized in that the heat sink (16) is in accordance with one of claims 1 to 16. 3037127 25/25 18. Light device (2) according to claim 17, characterized in that the light source (10) is supported by the base (22) and is offset relative to the or each opening (20) of the base (22).