FR2960945A1 - TILE INTEGRATING A HELIOTHERMIC SENSOR - Google Patents

Abstract

The tile (2) comprises two plates (4, 5) superimposed and kept at a distance from one another by studs and / or ribs delimiting a heat transfer fluid circulation channel (12), the upper plate (4) ) having at least one opening (8) of the channel (12), this opening (8) facing upwards, the lower plate (5) having at least one opening (13) of the channel (12), this opening (13) ) being turned downwards, a transparent or translucent cover panel (16) disposed substantially on the top of the two plates (4, 5), a support piece (20) having a bowl (21) forming a housing for mounting with sealing of the stack constituted by the 2 plates (4, 5) and the cover panel (16). This support piece (20) comprises at the periphery of the bowl (21) assembly means with neighboring tiles.

Description

The present invention relates to a tile incorporating a solar thermal sensor. The installation of solar thermal collector, whether it is carried out on a house during its construction or adapted to a pre-existing dwelling, poses a problem of integration to the architecture of the house, of additional cost compared to a roof installation simple and incompatibility vis-à-vis certain urbanization plan. For a better architectural and urban integration and a reduction in installation costs, it is known to use, to achieve the roof, tiles incorporating solar thermal collectors.

Such tiles are tiles which, integrating a heat transfer fluid circulation channel, comprises connecting means of said channel so as to form, when they are installed on a roof and connected between elves, a coolant circulation circuit on all or part of the roof. They allow, by exposure to solar radiation of said circuit, to transmit a portion of the heating associated with solar radiation to a heat transfer fluid. This heat can be, depending on the type of installation, transmitted to an individual heating system or a domestic hot water production system. Such tiles are generally, as illustrated in GB 2402999, mounted side by side so as to have a maximum exposure surface of the coolant circulation circuit. If they allow a powerful solar thermal installation, they have a number of disadvantages. This type of installation does not allow an aesthetic integration with a conventional architecture and presents, because of its provision less tightness compared to a conventional roof, it therefore requires the use of additional facilities to complete the seal. The present invention aims to remedy these disadvantages. The technical problem underlying the invention therefore consists in providing a tile comprising a heliothermic sensor module which can be aesthetically integrated with a conventional architecture and which, while providing a high-performance solar thermal capture, allows the installation of a roof identical sealing to a conventional tile installation. To this end, the invention relates to a tile comprising: an upper plate and a lower plate of substantially equal surface, made of synthetic material, superimposed and kept at a distance from each other by studs and / or ribs delimiting a heat transfer fluid circulation channel, the upper plate comprising at least one opening of the channel, this opening being turned upwards, the lower plate comprising at least one opening of the channel, this opening being turned downwards; transparent or translucent surface covering substantially equal to that of the plates, this panel being disposed substantially on the top of the two plates, - a support piece of synthetic material comprising a bowl forming a housing for sealingly mounting the stack constituted by the two plates and the cover panel, this support piece having at the periphery of the bowl, and at the less on some edges thereof, assembly means with neighboring tiles. The use of a heat transfer fluid channel, consisting of two plates, in cooperation with a transparent or translucent cover panel disposed on the top of the plates, allows transmission of solar energy through the panel of Durable since the coolant circulation channel is protected from the weather by the cover panel. This durability is also ensured by the use of synthetic materials also allowing to obtain a light tile. The use of an opening disposed on the top plate and one on the bottom plate also allows a more architecturally integrated installation since it allows, like a conventional tile installation, an overlap of one tile on another. This installation also allows, by this overlap, a seal equivalent to a roof equipped with conventional tiles. Advantageously, the cover panel comprises on its underside ribs and / or pads, these ribs and / or pads being arranged to maintain the cover panel at a distance from the top plate. Such spacing between the panel and the upper and lower plates constituting the heat transfer fluid circulation channel makes it possible to provide a cavity which can be filled with a gas or evacuated, this cavity serving for an optimized heating of the fluid. coolant using the principle of the greenhouse effect.

Preferably, the upper plate comprises first connection means in fluid communication with the opening of the upper plate, and the lower plate comprises second connection means in fluid communication with the opening of the lower plate, the second connection means being intended to cooperate with the first connection means of a neighboring tile during installation on a roof. The presence of connection means disposed on the upper and lower plates allows a tile tile connection of heat transfer fluid circulation channels.

Advantageously, the first connection means comprise a tip surrounding the opening of the upper plate, and the second connection means disposed on the lower plate comprise a tip surrounding the opening of the lower plate, said nozzle being intended to be housed. the tip disposed on the top plate of a neighboring tile.

Preferably, the tip surrounding the opening of the upper plate has an oblong section and is larger than those of the tip of the lower plate. The fact that the tip of the upper plate is of oblong section and of dimensions greater than those of the tip of the lower plate allows freedom of movement of the tip of the upper plate of a tile relative to the tip of the bottom plate of the tile connected to it without breaking the connection between the two tiles. This freedom of movement makes it possible to make the connection between tiles compatible with the thermal expansions related to the temperature variations to which the tiles are exposed. Advantageously, the tile comprises a seal, said seal being placed around the tip disposed under the lower plate of the tile, resting on the support plate, so as to seal the connection between said tip and a tip disposed on the top plate of a neighboring tile.

The use of a seal placed around the tip disposed under the lower plate of the tile, resting on the support plate ensures a sealed coolant circulation circuit, thus limiting the maintenance operations related to a such an installation. Preferably, the lower plate is made of a material 35 more thermally insulating than the upper plate. The use of an insulating lower plate limits the heat losses of the coolant circulation channel. Advantageously, the upper plate is preferably tinted with an opaque color or substantially identical to that of a roof on which the tile is intended to be installed. The use of tinted top plate allows a better architectural integration of a roof made with tiles according to the invention. The choice of an opaque color shade optimizes the absorption of solar radiation. Advantageously, the support piece comprises at least one fastening element intended to allow the tile to hang on a roof. The present invention also relates to a roof installation, such an installation comprising a plurality of tiles compliant with the invention, these tiles being installed so as to form a coolant circulation circuit, the roof further comprising a device temperature measuring device disposed on the roof so as to be able to measure the temperature of said roof to control the emptying of said coolant circulation circuit during the risk of freezing or overheating. Such roofing equipment makes it possible to ensure effective protection of the roof and the coolant circulation circuit with respect to the risks of freezing or overheating. The present invention also relates to a method of manufacturing a tile according to the invention comprising the following steps: - to mold the bottom plate, - to mold the top plate, - to mold the cover panel, - to place the top plate on the bottom plate, - place the cover panel on the top plate so as to form a stack consisting of the two plates and the cover panel, - place the stack in the mold of the support part, - overmold the plate support around the stack so as to ensure the seal between the upper and lower plates.

In any case the invention will be better understood from the description which follows with reference to the attached schematic drawing showing, by way of non-limiting example, an embodiment of this tile and a roof installation.

Figure 1 is a partial perspective view of a roof installation using tiles according to the invention; Figure 2 is a top perspective view of a tile according to the invention; Figure 3 is a side view in section along the axis A - A of Figure 2; Figure 4 is a view in front along the axis B - B of Figure 2; Figure 5 is a side view in section along the axis A - A of Figure 2 of a tile in connection with a neighboring tile. Figure 1 illustrates a roof installation 1 using tiles 2 according to the invention. Such an installation is performed on battens 3 placed on the frame transversely to the slope of the roof 1. The tiles 2 during their installation are placed in overlapping on these battens 3 so as to constitute the heat transfer fluid circuit on all or part of the roof 1. 20 The tiles 2, extending along a longitudinal axis, are installed on the roof 1 so as to have said axis substantially according to the slope of the roof 1. Each tile 2 comprises, as the FIGS. 1 and 2 show an upper plate 4 and a lower plate 5 of substantially equal surface 25 of synthetic material superimposed on one another. The upper plate 4 is in the form of a flat plate extending substantially along the longitudinal axis of the tile 2. The upper plate 4 has, on its lower face, an outline 6, delimiting a circulation zone of the coolant, and ribs 7 substantially parallel to the longitudinal axis of the tile 2. This upper plate 4 also has a substantially circular aperture 8 opening on the one hand on the upper face of the upper plate 4 on the left side near the rear lateral edge and secondly on the fluid circulation zone. The opening 8 thus makes it possible to put in communication the upper face of the upper plate 4 and the coolant circulation zone. An oblong bowl shaped nozzle 9 is provided on the upper face of the upper plate 4 so as to surround the opening 8 of the latter. The lower plate 5 is of substantially identical dimension to the upper plate 4 and also extends substantially along the longitudinal axis of the tile 2. The lower plate 5 has, on its upper face, a contour 10, defining a circulation zone heat transfer fluid, and ribs 11 substantially parallel to the longitudinal axis of the tile. These ribs 11 allow, in cooperation with the ribs 7 of the upper plate, to keep the two plates apart when they are arranged one on the other. These ribs 7, 11 also delimit with the contours 6, 10 of the two plates 4, 5, the walls of a heat transfer fluid circulation channel 12. The lower plate 5 also has a circular opening 13 opening on the lower face of the plate at a location opposite to that of the opening 8 present on the upper plate 4. The opening 13 opens on one end of the channel 12 while the opening 8 of the upper plate opens into the other end of the channel 12. This opening 13 allows communication between the lower face of the lower plate 5 and the channel 12 of coolant circulation.

The bottom plate 5 comprises a tip 14 of substantially cylindrical shape arranged to surround the opening 10 of the latter, the dimensions of the tip 14 being smaller than those of the tip 9 present on the upper plate 6. Thus, the tip 14 of the lower plate 5 can penetrate into the end piece 9 of an upper plate 4 of a neighboring tile 2 during the installation of a roof 1, thus allowing communication between the channels 12 of circulation of heat-transfer fluid of the two tiles 2. To seal this connection, a seal 15, whose surface is greater than that of the nozzle 9 present on the upper face 4 so as to cover the nozzle 9 when connecting two tile, is positioned around the tip 14 of the lower plate resting on the support piece. Each tile 2 also comprises a cover panel 16 of surface substantially equal to that of the plates 4, 5, this panel 16 being disposed substantially on the top of the two plates 4, 5, The cover panel 16 is a panel of transparent synthetic material or translucent. This panel 16 has a flat upper face and a ribbed underside. The ribs 17 formed on the underside of the panel extend substantially along the width of the tile 2 and allow to provide a space 18 between the panel 16 and the top plate 4. This space 18 allows to provide a cavity, which can be filled with gas or evacuated. The panel 16 is further provided on its upper face with a through-hole 19 for the connection end-piece 9 formed on the top plate 4. During the production of the tile 2, the covering panel 16 is placed on the upper plate 4 so as to form a stack consisting of the two plates 4, 5 and the cover panel 11.

Each tile 2 further comprises a support piece 20 made of synthetic material molded around the stack formed by the plates 4, 5 delimiting the heat transfer fluid circulation channel 12 and the cover panel 16. The support piece 20 comprises a bowl 21 forming a housing for sealingly mounting the stack constituted by the lower and upper plates 4, 5 and the cover panel 16, so as to seal both the channel 12 for circulating the coolant and the space 18 between the cover panel 16 and the top plate 4. The support piece 20 is provided on its underside with an orifice 22 formed for the passage of the tip 14 of the lower plate 5.

The support piece 20 is also provided, on its upper face and at the periphery of the bowl 21, assembly means and support means of a neighboring tile. The assembly means comprise a coupling edge 23 projecting from the left lateral face of the tile and on which is formed two ribs 24 substantially parallel to the longitudinal axis of the tile. The assembly means further comprise, on the underside of the support piece, two ribs substantially parallel to the longitudinal axis. These two ribs 25 cooperate with the ribs 24 of the coupling edge 23 of a neighboring tile placed on the location of the roof 1 disposed directly to the right of the tile 2 during the installation of the roof 1, the piece of support further comprises a fastener 26 formed on the coupling edge. This fixing element is a fixing orifice 26, for the passage of a fixing device, such as a nail, intended to cooperate with a lintel 3 during the installation of the tile 2 on the roof 1. The means support members comprise two ribs 27 projecting formed on the rear side edge, these two ribs 27, during the installation of the roof 1, to support the two neighboring tiles placed on top. The method of producing such a tile comprises in particular the steps of: - molding the lower plate 5, - molding the upper plate 4, - molding the cover panel 16, - placing the upper plate 4 on the lower plate 5, - Place the cover panel 16 on the top plate 4 so as to form a stack consisting of the two plates 4, 5 and the cover panel 16, - place the stack in the mold of the support part 20, - overmold the support plate 20 around the stack so as to seal the fluid circulation channel 12 and the space 18 between the cover panel 16 and the top plate 4. A roof installation 1 comprising such tiles 2 may be done on a roof 1 pre-existing, in relation or not with conventional tiles, or on a new roof 1 when making a new home. During installation, the tiles 2 are arranged on lintels 3, as shown in Figure 1, staggered, the lower part of a tile 2 overlapping the upper part of the two tiles placed on the lower directly location of the roof 1. This overlap is made so as to connect the tip 14 of the lower plate 5 of the tile 2 in contact with the tip 9 of the upper plate 4 of the tile placed on the neighboring lower right location. This connection is, as shown in Figure 3, made through the seal 15 to seal the connection. In this way, the connection of the tiles makes it possible to form circulation columns in a diagonal direction to the roof 1. These columns are interconnected with the means of the end pieces 9, 14 present on the tiles of the ends of the roof 1 to allow the realization of a coolant circulation circuit on the entire roof portion 1 equipped with tiles. This circuit is connected to a heating system and / or domestic hot water and filled with a heat transfer fluid to allow the transport and recovery of solar thermal energy.

Such a roof installation 1 can also be equipped with a temperature measuring device, such as a thermocouple, arranged on the roof 1 so as to be able to measure the temperature of said roof 1 to control the emptying of said circulation circuit of the roof. heat transfer fluid when there is a risk of frost or overheating. As goes without saying, the invention is not limited to the sole embodiment of this tile comprising a heliothermic sensor module, described above as an example, it encompasses all the variants. This and especially that the tile could, for example, also take the form, depending on the architecture of the house where it will be installed, a tile-type channel or type failure.

Claims (11)

REVENDICATIONS1. Tile (2) characterized in that it comprises: - an upper plate (4) and a lower plate (5) of substantially equal surface, of synthetic material, superimposed and kept at a distance from each other by studs and / or ribs (7, 11) delimiting a heat transfer fluid circulation channel (12), the upper plate (4) comprising at least one opening (8) of the channel, this opening (8) facing upwards, the lower plate (5) having at least one opening (13) of the channel, this opening (13) being turned downwards, - a cover panel (16) transparent or translucent surface substantially equal to that of the plates (4, 5), this panel (16) being disposed substantially on the top of the two plates (4, 5), - a support piece (20) of synthetic material comprising a bowl (21) forming a housing for sealingly mounting the stack consisting of the two plates (4, 5) and the cover panel (16), this support piece (20) having on the periphery of the bowl 20 (21), and at least on certain edges thereof, means of assembly with neighboring tiles. 2. Tile (2) according to claim 1, characterized in that the cover panel (16) comprises on its underside of the ribs (17) and / or pads, these ribs (17) and / or pads being arranged in order to keep the cover panel (16) away from the top plate (4). 3. Tile (2) according to claim 1 or 2, characterized in that the upper plate (4) has first connection means (9) in fluid communication with the opening (8) of the upper plate (4) , and in that the lower plate (5) comprises second connection means (14) in fluid communication with the opening (13) of the lower plate (5), the second connection means (14) being intended to cooperate with the first 35 connecting means of a neighboring tile during installation on a roof (1). 4. Roof tile (2) according to claim 3, characterized in that the first connecting means (9) comprise a nozzle (9) surrounding the opening (8) of the upper plate (4), and in that the second connecting means (14) comprise an end piece (14) surrounding the opening (13) of the lower plate (5), said end piece (9) being intended to house the end piece (14) arranged on the top plate of a neighboring tile. 5. Tile (2) according to claim 4, characterized in that the tip (9) surrounding the opening (8) of the upper plate (4) has an oblong section and is of greater dimensions than those of the tip (14) of the lower plate (5). 6. Tile (2) according to claim 4 or 5, characterized in that the tile comprises a seal (15), said seal (15) being arranged around the end piece (14) disposed under the lower plate (5) of the tile (2), bearing on the support piece (20), so as to seal the connection between said tip (14) and a tip (9) disposed on the upper plate (4) of a neighboring tile. 7. Roof tile (2) according to one of claims 1 to 6, characterized in that the lower plate (5) is made of a thermally more insulating material than the upper plate (4). 8. Roof tile (2) according to one of claims 1 to 7, characterized in that the upper plate (4) is tinted preferably an opaque color or substantially identical to that of a roof (1) on which the tile (2) is intended to be installed. 9. Roof tile (2) according to one of claims 1 to 8, characterized in that the support piece (20) comprises at least one fastening element (26) for allowing the tile (2) to hang on a roof (1). 10. A roof installation (1) characterized in that it comprises a plurality of tiles (2) according to one of claims 1 to 9, these tiles being installed so as to form a circulation circuit for a coolant, the roof (1) further comprising a temperature measuring device disposed on the roof (1) so as to measure the temperature of said roof (1) to control the emptying of said coolant circulation circuit at risk of freezing or overheating . 11. A method of manufacturing a tile (2) according to one of claims 1 to 9, characterized in that it comprises the steps of: - molding the lower plate (5), - molding the upper plate ( 4), - mold the cover panel (16), - place the top plate (4) on the bottom plate (5), - place the cover panel (16) on the top plate (4) so as to form a stack consisting of the two plates (4, 5) and the cover panel (16), - placing the stack in the mold of the support piece (20), - overmolding the support plate (20) around the stacking so as to ensure the seal between the upper and lower plates.