FR2961539A1 - COVER ELEMENT WITH INTEGRATED PHOTOVOLTAIC MODULE - Google Patents

Abstract

The present invention relates to a cover element (1) comprising a cover tray (3), at least one photovoltaic module (2) disposed on a portion of the cover tray (3), and securing means (7) photovoltaic module (2) on the cover tank (3), characterized in that the securing means (7) comprise hinge means (8) allowing the photovoltaic module (2) to be mobile from a first position (P1) said closure in which the portion of the cover tray (3) is covered by the photovoltaic module (2) to a second position (P2) said opening in which the portion of the cover tray (3) is apparent.

Description

The present invention relates to the field of photovoltaic solutions and more particularly to a cover element comprising a cover tank, a photovoltaic module disposed on a portion of the cover tank, means for securing the photovoltaic module to the cover tank. The energy crisis and environmental considerations are driving manufacturers to find energy-efficient and environmentally friendly solutions. Photovoltaic solutions can contribute to this effort by providing innovative solutions in many areas. In the building sector, roof boxes are used for roofing or cladding. These cover bins can be made of various metallic or non-metallic materials. The most frequently used material is steel. The tightness, the low weight, the ease of implementation and the price of these boxes of covers make it an ideal solution for large areas to cover quickly, typically factories, shops and farm buildings. For reasons of sealing, the cover tanks are fixed on their tops with a fixing system.

Typically, a cover tank is placed on at least three supports called failures. The distances between these failures are specific to each building, and sometimes the assembly of the failures is such that these distances are not all equal on the same roof, and this with variations of up to several centimeters.

Most of the solutions used to attach photovoltaic modules to cover bins use aluminum rails. These rails make it possible to interface between the cover tanks, whose wave pitch has a different value from one building to another, as well as the dimensions of the photovoltaic modules that are specific from one model to another. These photovoltaic modules are therefore mounted after mounting the bins on the roof. This type of solution has the advantage of providing real flexibility for the mounting of all photovoltaic modules on any existing building or construction, against it has at least three disadvantages: - the rails installed on the roof add weight to be supported by the building, - the manpower for assembly of the assembly is significant, and - the number of fasteners to be installed on the roof boxes as well as the mounting method which is specific for each building in function the climatic conditions of the place of installation, such as snow loads and exposure to the winds, lead to risks of errors and drifting which goes against the respect of the assembly instructions given by the manufacturers increasing the risks of loss and in particular of watertightness. In the case where it is desired to premount photovoltaic modules on cover tanks, photovoltaic modules often have standard dimensions that require to find a compromise between the choice of distances between failures and access between modules to allow fixing the cover tray on the purlins. This goes against optimizing the occupancy rate of roofs with photovoltaic modules. In the end, the photovoltaic generator built and delivered to the final customer is not as powerful as it could be given the size of the cover. The present invention aims to solve all or part of the disadvantages mentioned above. To this end, the present invention relates to a cover element comprising a cover tank, at least one photovoltaic module disposed on a portion of the cover tank, means for securing the photovoltaic module to the cover tank, characterized in that that the securing means comprise hinge means allowing the photovoltaic module to be mobile from a first so-called closing position in which the portion of the cover tank is covered by the photovoltaic module to a second position called opening in which the portion of the cover pan is apparent. This arrangement makes it possible to eliminate the constraints related to the distance between the failures and makes it possible to fix the ribbed cover pan 35 on the waves located under the photovoltaic module when it is in its closed position. Thus, the mobility of the photovoltaic module always makes it possible to access the part of the cover tray disposed under the photovoltaic module. According to one embodiment, the hinge means and the securing means are located on the same wave of the cover tray.

This arrangement makes it possible to open the photovoltaic module in a direction transverse to that of the rampant. According to one embodiment, the securing means comprise a locking device in the first position. This arrangement prevents the photovoltaic module from involuntarily switching from its first to its second position and securing access to the wiring at the rear of the photovoltaic module. According to the same embodiment, the locking device in the first position is located on a wave other than that where the hinge means are located.

According to another embodiment, the articulation means of the securing means are located on different waves of the cover tray. This arrangement makes it possible to open the photovoltaic module in a longitudinal direction to that of the rampant.

According to one embodiment, the securing means comprise a locking device in the second position. This arrangement prevents the photovoltaic module from involuntarily passing from its second to its first position, for example under the action of the wind and thus prevents the risk of injury to the operator as well as the risk of damage to the module due to an impact. According to one embodiment, the securing means are glued to the cover tray. This arrangement makes it possible to keep intact the watertightness of the cover tank.

According to the same embodiment, the securing means are glued to the top of the waves of the cover tray. This arrangement makes it possible to protect the glue from the flow of rainwater thus perpetuating the bonding. According to one embodiment, the photovoltaic module is removable.

This provision allows to replace only the module in case of failure thereof. Moreover, when replacing the module the covered surface still ensures its sealing function. According to one embodiment, the securing means 5 comprise a lifting device. This arrangement allows easy handling of the covering element by lifting machines and also allows for heavier cover elements equipped with a cover pan comprising a larger surface covered by photovoltaic modules. According to one embodiment, the cover pan is in the form of a sandwich pan comprising a thermal insulation, for example expanded polyurethane, rock wool or polystyrene. This arrangement avoids thermal isolation in a situation which is more tedious. According to one embodiment, the securing means are pre-drilled with one or more holes. This arrangement allows the passage and the screwing of a screw or other equivalent fastener through the hole having the best position on the securing means and thus ensures the fixing of the cover element on a breakdown of the building which would be located below the means of solidarization considered. According to one embodiment, the cover pan comprises specific dimensions, for example a pitch between smaller waves and / or a larger wave height. This arrangement makes it possible to improve the ventilation under the photovoltaic module as well as to stiffen the cover tank and to increase the ranges between the failures of the building, of the photovoltaic module thus constituted. The present invention also relates to a standard or possibly special cover tank having specific dimensions for extending a roof element according to the invention also including these same standard or specific dimensions. In any case, the invention will be better understood with the aid of the description which follows, with reference to the appended schematic drawing showing, by way of nonlimiting example, covering elements according to the invention.

FIG. 1 illustrates the configuration of a preassembled covering element with photovoltaic modules according to the state of the art. FIG. 2 illustrates the configuration of a covering element according to the invention, all of the photovoltaic modules being illustrated in their closed position. FIG. 3 illustrates the configuration of a covering element according to the invention, one of the photovoltaic modules being illustrated in its open position. Figure 4 shows a perspective view of the cover member of Figures 2 and 3; Figure 5 shows a first embodiment of a cover member in the open position. Figure 6 shows a second embodiment of a cover member in the closed position. Figure 7 shows the arrangement of three cover elements according to a variant of the first embodiment. Figure 8 shows a blanket type cover element in the form of a sandwich tray comprising a thermal insulation. Figure 9 shows a cover pan in a lifting situation. All the figures and examples of applications relate to a roof covering element 1, however without departing from the scope of the invention these may be applied to a roofing element of the wall of a building. As schematically illustrated in FIGS. 1 to 3, a preassembled roofing element 1 comprises mainly a cover tank 3 and one or more photovoltaic modules 2 arranged on one or more parts of this cover tank 3. This or these photovoltaic modules 2 can , according to two variants, present a peripheral frame or be devoid of frame. The cover pan 3 is made of steel. Nevertheless, this can be achieved in other materials adapted to the various embodiments described. These photovoltaic modules 2 are generally mounted irreversibly on the cover tank 3 by means of securing means 7 which can be constituted by fixing lugs held by screws passing through the cover tank 3 and clamping the photovoltaic module 2. against the cover tray 3. The assembly is arranged on purlins 4 serving as a support for the entire cover element 1.

Typically, given its dimensions, a cover tank 3 rests on at least three failures 4. A pre-assembled cover element 1 according to the state of the art, illustrated in FIG. 1, must therefore provide a specific arrangement of the photovoltaic modules. 2 on the cover tray 3 so that the gaps 5 between the photovoltaic modules 2 are sufficient for the passage of fixing means (not shown) of the cover tray 3 on a fault 4 and also provide an adequate positioning thereof for that these differences coincide with the location of failures 4. These fasteners are generally constituted by bolts, screws, rivets or the like associated with parts called "jumpers" arranged for sealing on the top of a wave 6 of the cover tray 3. On a cover element 1 according to the invention, as illustrated in FIGS. 2 and 3, the arrangement of the photovoltaic modules 2 on the neck tray 3 is no longer essential for securing the cover element 1 on the purlins 4.

Indeed, the securing means 7 comprise hinge means 8 enabling the photovoltaic modules 2 to be mobile from a first so-called closing position P1 in which the parts of the cover tank 3 on which the photovoltaic modules 2 are arranged are covered by the photovoltaic modules 2 to a second position P2 said opening illustrated by the position of the photovoltaic module 2 located in the central position in Figure 3, wherein the parts of the cover tray 3 previously covered by the photovoltaic modules 2 are apparent. The accessibility of these parts of the cover tray 3 allows attachment thereof to the failures 4 normally located below the photovoltaic modules 2. A cover element 1 according to the invention, like that illustrated in Figure 4 , thus makes it possible to optimize the occupation of the surface of the cover tank 3 by photovoltaic modules 2 by increasing the useful area 35 of these photovoltaic modules 2 by reducing the gap between the photovoltaic modules 2.

The securing means 7 of the photovoltaic module 2 on the cover tank 3 comprise hinge means 8 but may also comprise a locking device 14 in the closed position P1 and a locking device (not shown) in the position d P2 opening. According to one embodiment, the securing means 7 are also pre-drilled with one or more holes (not shown) allowing the passage and the screwing of a fixing screw to ensure the fixing of the cover element 1 on a failure 4 of the building which would be below a securing means 7. These holes can have the shape of circular holes or oblong. According to one embodiment, the securing means 7 preferably comprise several fastening elements 10.

According to one embodiment, these securing elements 10 each comprise a base 9 of isosceles trapezoidal shape adapted to the shape of a wave 6 of the cover tray 3. According to one embodiment, these securing elements 10 are held by bonding against the cover tank 3, thus denying the cover tank 3 of any piercing that may affect its sealing. The areas and number of bonding points may vary according to the different possible configurations taking into account, for example, the size of the photovoltaic module 2, the size of the cover tray 3, and the size and number of the bases 9, but also geographic areas and altitude, the distance between the bases 9 taking into account the loads of wind and snow and exposure to the wind. Depending on the materials used for the bins 3 and the bases 9, the size of the bases 9 can vary to limit the shear due to differential expansion with the cover tray 3 and to ensure a reliable fixation over time, especially for fasteners by bonding. Depending on its function, a securing element 10 comprises one or more other parts. The hinge means 8, performing the articulation function of the photovoltaic module 2, comprise first hinges arranged on the base 9.

Second hinges complementary to the first hinges are arranged on the photovoltaic module 2 to form a hinge 12 which ensures mobility in rotation about an axis A of the photovoltaic module 2 relative to the cover tank 3.

These second hinges are extended by a plate (not shown) fixed on the photovoltaic module 2. It is also possible to consider fixing this plate directly on the laminate of a photovoltaic panel 2 without frame. In a first embodiment illustrated in FIG. 5, the first and second hinges are arranged so as to arrange the axis A of the hinge 12 longitudinally to the main direction of the waves 6 of the cover pan 3, thus allowing articulation of the photovoltaic panel 2 about a longitudinal axis in the direction of the crawling roof. In this configuration, the position of the hinges or articulation means 8 allow the photovoltaic module 2 to tilt without there being any disturbances between the module 2 and the cover tank 3 on the one hand and the adjacent module 2 'somewhere else. In a second embodiment illustrated in FIG. 6, the first and second hinges are arranged so as to arrange the axis A of the hinge 12 transversely to the main direction of the waves 6 of the cover tray 3, thus allowing articulation of the photovoltaic panel 2 about an axis transverse to the direction of the crawling roof. In this second embodiment, the plate of the second hinges is fixed on the lower edge of the photovoltaic module 2 in the direction of the rampant and places the second hinges and therefore the hinge 12 on a portion of the cover tray 3 which is not covered by the photovoltaic module 2 in its closed position P1. In these two embodiments, the photovoltaic modules 2 can be fixed or removable.

In the case where they would be removable, it is possible to separate a module 2 of the assembly 1, thus replacing a photovoltaic module 2 without having to replace a complete cover element 1. As shown in FIG. 5, to produce the locking device 14 realizing the blocking function of the photovoltaic module 2 in its closed position P1, the bases 9 are fixed on a wave portion 6.

In the second embodiment, the attachment and articulation functions are contained on the same base 9. Obviously, other types of locking devices in the closed position P1 can be envisaged depending on the various possible configurations. As illustrated in Figures 7 and 9, the bases 9 constituting the hinge means 8 and the locking device 14 in the closed position P1 comprise a lifting device 16 of the fastener type for slinging with straps 18 the element of cover 1 to handle it easily with the aid of a hoist. Depending on the range of the cover element 1, it may be necessary to use a spreader distributing the load at different points in order to avoid having too much force on a base 9 as well as to reduce the load. arrow of the cover element 1 during handling. As illustrated in FIG. 8, the cover element 1 is pre-insulated with an insulator 17 conforming to the lower surface of the cover pan 3. This same FIG. 8 shows a use with a cover pan 3 of standard size. However, to optimize the ventilation under the photovoltaic module 2 and the ranges, the cover element 1 can integrate a cover tank 3 having specific dimensions and shapes with an increased wave height 6 and a decrease in the pitch between waves. 6. These two actions also have the effect of stiffening the cover tray 3. In order to be able to finish the cover of the roof or facade, the invention also provides a cover 3 without photovoltaic modules 2, of the same dimensions as the cover tank 3 of specific or standard dimensions supporting photovoltaic modules 2. The cover element 1 allows complete freedom of wiring, and in particular the possibility of wiring the photovoltaic modules 2 according to the rules of the art, namely in horizontal rows with the photovoltaic modules 2 adjacent cover elements 1 in order to benefit from the best operation of the pho installation tovoltaic according to the course of the 35 sun in the sky.

Thus, to install a roofing element 1 on the frame of a roof, the installer starts by slinging the roofing element 1 by its lifting devices 16, then places the roofing element 1 on the frame to the roof. using a hoist.

He then fixes the cover tray 3 on the frame at the places of the purlins 4 by screwing self-drilling screws conventionally used for fixing the cover trays 3. The installer unlocks the locking device 14 in the closed position P1 of all the photovoltaic modules 2 and then locks all the photovoltaic modules 2 in their open position P2 with the aid of the locking device in the open position P2. It thus accesses the portions of the waves 6 initially hidden by the photovoltaic modules 2 when they were in the closed position P1 and can thus continue to fix the cover tank 3 by screwing self-drilling screws on the top of these parts. waves 6. Once the set of cover elements 1 disposed on the frame, the installer proceeds to the different wiring and connections of the photovoltaic modules 2 then he brings all the photovoltaic modules 2 to their closed position P1 and locks them in this closed position P1 with the aid of the locking device 14. Thus, because of its reliability and the time savings it affords on site assembly, this cover element 1 has an added value at the output of factory significantly better than a conventional kit. Although the invention has been described in connection with particular embodiments, it is obvious that it is in no way limited thereto and that it comprises all the technical equivalents of the means described and their combinations, in particular the all the means described can be declined for cladding sheets for the purpose of producing photovoltaic walls.

Claims (14)

REVENDICATIONS1. Covering element (1) comprising: - a cover tank (3), - at least one photovoltaic module (2) disposed on a portion of the cover tank (3), - means for securing (7) the photovoltaic module ( 2) on the cover tray (3), characterized in that the securing means (7) comprise hinge means (8) allowing the photovoltaic module (2) to be movable from a first position (P1) said closure in which the portion of the cover tray (3) is covered by the photovoltaic module (2) to a second position (P2) said opening in which the portion of the cover tray (3) is apparent. 2. Covering element (1) according to claim 1, wherein the hinge means (8) and the securing means (7) are located on the same wave (6) of the cover tray (3). 3. Cover element (1) according to one of claims 1 or 2, wherein the securing means (7) comprise a locking device (14) in the first position (P1). 4. covering element (1) according to claim 3 provided it depends on claim 2, wherein the locking device (14) in the first position (P1) is located on another wave (6) that where are located the hinge means (8). 25 5. Cover element (1) according to claim 1, wherein the hinge means (8) of the securing means (7) are located on waves (6) different from the cover tray (3). 6. Cover element (1) according to one of claims 1 to 5 wherein the securing means (7) comprise a locking device in the second position (P2). 7. Cover element (1) according to one of claims 1 to 6 wherein the securing means (7) are glued to the cover tray (3). 8. Cover element (1) according to claim 7 wherein the securing means (7) are glued to the top of the waves (6) of the cover tray (3). 9. Cover element (1) according to one of claims 1 to 8 wherein the photovoltaic module (2) is removable. 10. Cover element (1) according to one of claims 1 to 9 wherein the securing means (2) comprise a lifting device (16). 11. Cover element (1) according to one of claims 1 to 10 wherein the cover tray (3) is in the form of a sandwich tray comprising a thermal insulation, for example expanded polyurethane, wool of rock or polystyrene. 10 12. Cover element (1) according to one of claims 1 to 11 wherein the securing means (7) are pre-drilled with one or more holes. 13. Cover element (1) according to one of claims 1 to 12 wherein the cover tray (3) comprises specific dimensions, for example a pitch between waves (6) smaller and / or a height of wave (6) larger. 14. Covering box comprising a standard or possibly special cover tray with specific dimensions for extending a cover element (1) according to claim 13, also having these same standard or specific dimensions.