FR2998095A1 - COOLING MODULE OF THERMAL PANEL - Google Patents

Abstract

The invention relates to a device for cooling (1) an area to be cooled (2), the device comprising: - a cooling surface (3) in continuous contact with the zone to be cooled (2); a plurality of blades (4) connected to the surface (3). According to the invention, the device further comprises at least one cooling tube (5) passing through the plurality of blades (4).

Description

The present invention relates to a cooling device that can ensure the cooling including hot surfaces such as a photovoltaic panel but also any hot surface or ambient air. The invention also relates to such a device which makes it possible to recover the heat from the surfaces. 2.Solutions of the Prior Art It is known, for example for the cooling of photovoltaic panels, to implement a heat dissipating device comprising a plurality of parallel pipes in contact with the panel and being embedded in blades. , or fins, formed near the ends of these pipes, on these pipes. Thus, the pipes recover the heat accumulated by the photovoltaic panel and transmit it to the fins by conduction, that is to say by contact between two entities so as to achieve a heat exchange between these two entities. The fins then evacuate the heat into the surrounding air by convection. A disadvantage of such a technique is that the cooling of the photovoltaic panel is not performed on the entire surface of the panel which is not optimal because certain areas of this panel, in this case those which are not in contact direct with the pipes, will be less cooled than the areas in direct contact with the pipes that are cooled by convection. Another disadvantage of such a technique is that the cooling rate of the panel is not optimal. Indeed, the cooling being mainly carried out by conduction, it is conditioned by the thermal conductivity of the pipes as well as the contact area between these pipes and the surface to be cooled. Another disadvantage of such a technique is that the heat transmitted from the surface to be cooled, that is to say of the panel, is evacuated into the ambient air (convection), and is therefore not recovered afterwards, which generates a warming of the ambient air and a relatively large waste. Indeed, this energy being released in the air, it is not used for useful purposes which is not satisfactory. Also known from document US2012 / 0009455 15 battery cooling modules using blades, in the form of spacers separating two cells, composed of two parts and having an "L" profile, the heat exchange takes place. making contact with the blades. A disadvantage of this technique is that the passage of heat from each of the cells to the neighboring blade will be conditioned by the contact between the blade and the cell which is not optimal because the quality of this contact is difficult. controllable (depending on the conditions of manufacture, manipulation, ...). As a result, an imperfect contact and therefore a limited contact surface reduces the heat exchange, and therefore the cooling of the cell which is not satisfactory. Another disadvantage of this technique is that there is no possibility of heat recovery thereafter, the recovered energy being exhausted into the ambient air. OBJECTIVES OF THE INVENTION The invention particularly aims to solve the disadvantages of the prior art.

More particularly, an objective of at least one embodiment of the invention is to provide a surface cooling device for optimizing the cooling of a given surface by acting on the entire surface to be cooled.

Another objective of at least one embodiment is to provide a technique that optimizes convective and conductive energy transport. Yet another object of at least one embodiment is to provide a technique for optimizing the energy recovered by cooling. Another objective of at least one embodiment of the invention is to provide a device that is inexpensive and simple to implement. 4. Summary of the Invention These objectives, as well as others which will appear subsequently, are achieved by means of a cooling device of a surface to be cooled, the device comprising: a cooling surface; in continuous contact with the zone to be cooled; a plurality of blades connected to the surface. According to the invention, the device further comprises at least one cooling tube passing through the plurality of blades. Thus, the invention proposes a new and inventive approach making it possible to optimize the cooling of an area by implementing a cooling surface in continuous contact with this zone and by providing a cooling tube passing through blades or fins. in contact with the cooling surface. As a result, the cooling and therefore the energy transfer is optimally effected by convection and conduction. In a particular embodiment, the blades comprise a first portion and a second portion joined by an edge. Moreover, for two given successive blades, the second portion of the first blade is in contact with the second portion of the second blade, the second portions forming a portion of the cooling surface. Thus, this optimizes the cooling by limiting the number of thicknesses to be crossed for the heat. Indeed, the fact that the cooling surface is "confused" with the blades allows these blades to directly capture the heat and diffuse through their first part and through the cooling tube. In this case, and for two given successive blades, the second portion of the first blade can at least partially cover the second portion of the second blade.

Thus, this prevents two blades are spaced from each other by the constraints and / or manufacturing tolerances. As a result, the contact is continuous between two successive blades, which consequently makes it possible to optimize the cooling of the zone in contact with the cooling surface. In one embodiment of the invention, the cooling tube passes through the blades at the first portions. Thus, this makes it possible to evacuate the heat accumulated by the first part, said heat corresponding to the heat diffused by the second part of each blade at the level of the first part. According to variants of the invention, the second part of each of the blades forms an angle of between 85 ° and 95 ° with the first part, and may even be substantially equal to 90 °. Thus, this makes it possible to provide different implementations of the invention making it possible to adapt to the conditions of use as well as the applications. In a particular embodiment, the edge has a rounded profile. Thus, this facilitates the stamping of such a part, especially during a folding step of a flat part to obtain a blade as implemented in the invention. In a variant of the invention, the blades 20 have a substantially constant thickness and between 0.1 and 0.3 mm. Thus, it allows to adapt the blades to different possible implementations. This allows in particular to adapt the dimensions of the device to its use. In embodiments, the blades are spaced a substantially constant distance and between 1 mm and 6 mm. Likewise, this makes it possible to adapt the blades to the different possible implementations. This allows in particular to adapt the dimensions of the device to its use.

According to a particular embodiment, the cooling device cooperates with heat recovery means placed in contact with the tube. The invention also relates to a thermal panel comprising a thermal plate and further comprising a cooling device according to one embodiment of the invention. 5. List of Figures Other features and advantages of the invention will appear more clearly on reading the following description of an embodiment, given by way of a simple illustrative and nonlimiting example, and the accompanying drawings, among which: - Figure 1 is a perspective view of a cooling device according to one embodiment of the invention; FIGS. 2 to 4 are close-up views of part of a cooling device according to the embodiment of FIG. 1; Figure 5 is an exploded perspective view of a cooling device according to the embodiment. 6. DETAILED DESCRIPTION We now present, in 1 to 4, a first mode another relationship with the embodiments of a cooling device according to the invention. As illustrated in these figures, the cooling device 1, or cooling module, comprises a plurality of blades 4 (otherwise called lamellae or fins) formed of a first portion 41 and a second portion 42, these portions being joined. by a ridge 43. The blades 4 have a substantially "L" profile, the first 41 and second 42 parts respectively forming the long side and the short side of the L and the second portion 42 forming an angle substantially equal to 900 with the first part 41. Of course we can provide other embodiments in which the angle α between the first portion 41 and the second portion 42 is more generally between 85 ° and 95 °. It is even possible to provide angles greater than 95 ° or less than 85 ° so as to adapt to the uses of the cooling device 1. It is also possible to provide variants in which the first part corresponds to the short side of the L while the second part Part would correspond to the long side of L. In this example, the edge 43 has a rounded profile so as to facilitate the stamping. Indeed, in order to give the blades their L profile, they are folded. Thus, a rounded shape of the edge is obtained simply during folding. Such a profile on the finished blade thus limits the manufacturing steps and therefore the costs. However, it is also possible to provide variants of the invention in which the edge has a different profile. Embodiments may also be provided in which the two parts are welded together.

In the embodiment of Figures 1 to 4, the blades have a substantially constant thickness E and between 0.1 and 0.3 millimeters. Of course, it is possible to provide fins having a different thickness in other embodiments.

These blades 4 can be made of aluminum such as hydrophilic aluminum or pre-painted aluminum. They may also be made of copper or a copper alloy such as tinned copper. As illustrated, the blades 4 are connected to a cooling surface 3 in continuous contact with an area to be cooled 2. In the embodiment of FIGS. 1 to 4, the cooling surface 3 is formed by all the second parts 42 4. This thus makes it possible to optimize the cooling by implementing a continuous surface, and this can also improve the speed of "evacuation" of the heat towards the fins by limiting the number of thicknesses to be traversed by the heat. . Indeed, the fact that the cooling surface 3 is "merged" with the blades 4 allows these blades 4 to directly capture the heat of the zone to be cooled 2 and to diffuse through their first portions 41. These blades 4 are placed such as for two successive blades 4 ', 4 "data, the second portion 42' of the first blade 4 'partially covers the second portion 42" of the second blade 4 ". This way, it avoids two blades, and in particular, two successive second portions are spaced apart from each other, thus ensuring contact between the blades, which allows an optimum cooling of the zone to be cooled 2. The thickness of the blades, which is relatively low, makes it possible to obtain a cooling surface (composed of the second parts 42 of the blades 4) that is substantially flat, while having a relatively small thickness of the blade makes the superposition of two blades not generate a "rim" " too important, this rim being formed by a first blade located below a second adjacent blade which is superimposed on this first.

In this example, the different blades are spaced two by two by a distance D substantially constant and between 1 mm and 6 mm, this distance may of course be different from this range of values and may be non-constant in variants of the invention. . Of course, one could also provide embodiments in which the second parts of two successive blades are more or less superimposed.

Embodiments may also be provided in which the second parts of two successive fins are simply in contact with one another without being superposed. One could also imagine embodiments in which the cooling surface 3 would be distinct from the blades 4 and would not be formed by the second parts 42 of the blades 4, but would be in contact with the blades 4. It can furthermore be conceived of embodiments in which the blades would not be formed of two parts but a single portion 41, for example welded to the cooling surface 3 at one of its ends, and forming an angle between 00 and 180 ° with the surface of cooling 3. As illustrated in these Figures 1 to 4, the cooling device 1 further comprises a cooling tube 5 which passes through the plurality of blades 4, at the first portions 41 of these blades 4. This tube may consist of a material such as copper (which may be for example smooth or grooved) or aluminum.

In this embodiment, the tube 5, otherwise called tube circuit or cooling pipe, has a diameter of between 6 and 18 mm for example. It may be, depending on the variant, formed of several sections of pipes or be a single pipe having a "serpentine" profile, conventionally used in systems such as radiators.

This tube 5 passes through each blade, at the first portions 41, so as to create a cooling circuit near the cooling surface 3, which will capture the heat accumulated by the fins. Inside this tube 5 circulates a coolant, that is to say a fluid capable of transporting the heat accumulated during cooling of the zone to be cooled 2. Thus, the thermal energy recovered by the blades 4 is transmitted by conduction to the fluid flowing in the tube 5. This heat transfer fluid is for example water in liquid form or in the vapor state, a liquid such as freon, or a gas such as air. This tube 5 can be placed in contact with heat recovery means (not shown) which cooperate with the cooling device 1 so that the heat accumulated (from the heat recovered at the zone to be cooled 2) in the device cooling 1 is recovered in these means and can be used for example as a means for producing heating or production of domestic hot water via an exchanger device for accumulation for example. Of course, it is possible to provide embodiments in which the device would have several tube circuits, otherwise called layers, arranged so that they pass through the first blade at different levels, that is to say without crossing. In this case, it is also possible to provide variants in which the different plies have a different operating mode, namely a ply inside which air circulates and another ply within which circulates. some water. Of course, the combinations of layers are not limited to this last example. Another embodiment will now be presented in connection with FIG. 5, in which the cooling device is implemented within a solar thermal panel.

As illustrated in this figure, the solar thermal panel 7 comprises a thermal plate 71. In order to cool this plate 71, in other words so as to store the energy accumulated by the plate 71, the thermal panel 7 comprises a cooling device 1 placed in contact with the plate 71. The cooling device, similar in this example to the cooling device of FIGS. 1 to 4, comprises a single ply 5 as well as a plurality of blades 4 whose second parts form a cooling surface in continuous contact with the plate 71 and the first parts allow a flow of ambient air near the blades and the cooling surface, so as to recover the heat accumulated by the plate 71 by conduction and by convection. As before, this thermal panel can cooperate with heat recovery means arranged in contact with the tube 5 so that the recovered energy can be used, for example, means for heating ambient air or water. In other variants of the invention, it could also be provided that the cooling device is included in systems such as a photovoltaic solar panel comprising a plate provided with photovoltaic cells.

Claims (11)

REVENDICATIONS1. Cooling device (1) for a cooling zone (2), the device comprising: - a cooling surface (3) in continuous contact with the zone to be cooled (2); a plurality of blades (4) connected to the surface (3); characterized in that the device further comprises at least one cooling tube (5) passing through the plurality of blades (4). 2. Cooling device (1) according to claim 1, characterized in that the blades (4) comprise a first portion (41) and a second portion (42) joined by an edge (43), and in that, for two successive blades (4 ', 4 ") given, the second portion (42') of the first blade (4 ') is in contact with the second portion (42") of the second blade (4 "), said second portions (42 ', 42 ") forming a portion of the cooling surface (3). 3. Cooling device according to the preceding claim, characterized in that, for two successive blades 25 (4 ', 4 ") data, the second portion (42') of the first blade (4 ') covers at least partially the second part (42 ") of the second blade (4"). 4. Device according to one of claims 2 or 3, characterized in that the cooling tube (5) passes through the blades (4) at the first portions (41). 5. Device according to claim 2, characterized in that, for each of the blades (4), the second portion (42) forms an angle (a) between 85 ° and 95 ° with the first portion (41). 6. Device according to the preceding claim, characterized in that the angle (a) between the first portion (41) and the second portion (42) is substantially equal to 90 °. 7. Device according to one of claims 2 to 6, characterized in that the edge (43) has a rounded profile. 15 8. Device according to one of the preceding claims, characterized in that the blades (4) have a thickness (E) substantially constant and between 0.1 and 0.3 mm. 20 9. Device according to one of the preceding claims, characterized in that the blades (4) are spaced a distance (D) substantially constant and between 1 mm and 6 mm. 25 10. Device according to one of the preceding claims, characterized in that it cooperates with heat recovery means placed in contact with the tube (5). 11. Thermal panel (7) comprising a thermal plate (71), characterized in that it comprises a cooling device (1) of the plate (71) according to any one of claims 1 to 10. 10