FR2928160A1 - PHOTOVOLTAIC PANEL COVER DEVICE - Google Patents

Abstract

Solar panel covering device disposed on the roof or terrace of a building, for optimizing an inclination of the solar panel relative to the horizontal or an orientation of the photovoltaic panel with respect to the cardinal points, while having a panel integrated in the building, in particular by virtue of a frame comprising a central opening closed by the solar panel, said frame (21, 22, 23, 24) being dimensioned, relative to the inclination or the orientation of the roof, so that the solar panel disposed against the edge (S21, S22, S23, S24) of the upper frame: - an inclination optimized with respect to the horizontal approximating the perpendicular to the sun's rays or - an optimized orientation with respect to the cardinal points closer to the south, or respectively north, if the building is located in the northern hemisphere, or respectively in the southern hemisphere.

Description

The invention relates to the field of the building. The present invention relates more particularly to the installation of photovoltaic panels on the roof of a building. Photovoltaic panels, also called solar panels, placed, for example, on the roof of a building, allow to produce electricity through solar energy. EP 1 310 747 teaches, for example, a set of solar panel inserted in the roof of a building, the solar panel being fixed on a plate with gutters that create ventilation ducts and drain channels d 'water. A disadvantage, however, is that the solar panel of the assembly according to patent EP 1 310 747, is arranged in the alignment of the roof and that its orientation with respect to the cardinal points, as its inclination with respect to the horizontal, are the same as the orientation or inclination of the roof. For optimum efficiency, the solar panels must indeed have a determined orientation with respect to the cardinal points and a slope determined with respect to the horizontal according to the latitude of the building.

For a building located in the northern hemisphere, at the latitude of the center of France for example, the more the orientation deviates from the ideal orientation full south, the inclination then becomes important to improve the yields . Preferably, but not limited to, the solar panel cover is used for buildings located in the northern or southern hemisphere, outside the tropics. In addition, the height of the sun varies during the day and during the months of the year, the inclination of a solar panel placed on the roof, should also be able to adapt to these variations to be able to answer the expectations as well as possible. an electricity producer of photovoltaic origin. For example, a producer using his production for his own needs and needs especially during the winter months, will need to maximize its production in winter and therefore a strong inclination (around 60 °) will be preferred. A producer wishing to resell its production, will have a tendency to favor the summer months favorable to strong sunshine and therefore a small inclination at 20 ° relative to the horizontal, will for example be preferred. The patent application US 2004 / 007,260 teaches a multi-position photovoltaic panel assembly comprising a base on which is fixed a deflector supporting one side of a photovoltaic panel, the photovoltaic panel resting on the other hand on the base.

The photovoltaic panel is thus disposed at an acute angle to the base. A baffle is, for example placed laterally to avoid a windy hold. Even if an inclination with respect to the horizontal can be adjusted according to the height of the sun, a disadvantage of this type of assembly is however that the orientation of the solar panel with respect to the cardinal points remains identical to the orientation of the solar panel. building. In addition solar panels are poorly integrated into the structure of the building. The integration of photovoltaic panels in the building is, in particular, encouraged by financial measures. The purchase of electricity is for example more expensive per kW if the photovoltaic panels are integrated into the building. As a non-limitative example, the purchase of the kW can go from 30 cents to 56 euro cents in France for the year 2008. According to a decisive criterion, a photovoltaic panel is, for example, considered integrated roof if the waterproofness of the roof is no longer ensured when the photovoltaic panel is removed.

The object of the present invention is to overcome one or more disadvantages of the prior art, by proposing a photovoltaic panel cover device enabling eligibility for integration criteria to the building but also to correct an inclination of the photovoltaic panel with respect to horizontally and according to the latitude of the building or to correct an orientation of the photovoltaic panel with respect to the cardinal points, in order to get closer to the best conditions.

This objective is achieved by means of a solar panel covering device comprising: - an upper border supporting the solar panel and - a junction part resting on a frame of a roof of a building or on elements of roof covering , the joining portion having a profile, compatible or adaptable to the roofing elements, the roof being disposed in a plane having a given inclination relative to the horizontal and a determined orientation relative to the cardinal points or the roof having a zero inclination with respect to the horizontal, characterized in that the joining part is connected to the upper edge by at least one frame comprising a central opening closed by the solar panel, the joining part being connected to a lower edge of said frame and disposed around this lower edge, said frame being arranged relative to the slope of the roof or the orientation of the roof or the orientation of the lower border, so that the solar panel arranged against the upper edge has: - a corrected inclination relative to the horizontal approaching the perpendicular to the sun's rays or - an orientation corrected relative to to the cardinal points in the direction of the south, or respectively of the north, if the building is situated in the northern hemisphere, or respectively in the southern hemisphere. According to another feature, the frame is formed by four structural elements including two lateral structural elements arranged along the line of greater slope of the roof or according to the orientation of the lower border, at least two opposite structural elements of the frame being bevelled, the structural elements being interconnected by their ends, the two-by-two ends being of the same height, for correcting the orientation of the solar panel by beveling the lateral structural elements or for correcting the inclination of the solar panel by bevelling of the other two elements structural.

The solar panel may be made, in a non-limiting manner, of opaque photovoltaic material such as for example the photovoltaic material deposited under the trademark Tedlar. Another objective is to provide a solar panel cover device for performing the function of lighting wells inside the building. According to this objective, the solar panel is of the translucent or semi-transparent photovoltaic panel type. Another objective is to propose a solar panel cover device allowing a variable inclination corresponding to the height of the sun in the sky. According to this objective, the device comprises two frames including an upper frame forming the upper edge and a lower frame forming the lower edge, the upper frame being connected to the lower frame by a hinge and a flexible sealing member or a set of flaps sealing laminates against each other and of determined rigidity, allowing a rotation of the upper frame relative to the lower frame, a positioning member being connected to the upper frame and realizing an adjustment of the inclination of the upper frame with respect to the horizontal. According to another feature, the positioning member is controlled by a computer management device comprising a processing component, a storage component and a communication interface, transmitting to an actuator of the positioning member, by a communication line. at least one determined inclination control of the upper frame, the determined inclination command being calculated according to stored data representative of a date or time or a period of the year, corresponding to at least a certain height of the sun in the sky.

According to another feature, the positioning member comprises a control chamber comprising a fluid expanding under the effect of heat, and heated to an intensity proportional to a heating of the solar panel, the chamber belonging to a jack comprising a cylinder and a piston extended by a cylinder rod, the cylinder being fixed to the lower frame and the cylinder rod coming out of the cylinder downwards, being connected by a hinge to an intermediate bar, the intermediate bar being connected on the other hand, by a hinge, to the upper frame to pull the upper frame and decrease the inclination of the upper edge when the temperature of the chamber increases and causes expansion of the fluid. The invention, its characteristics and its advantages will appear more clearly on reading the description made with reference to the figures given by way of non-limiting example and referenced below: FIGS. 1 and 2 represent perspective views of examples of covering devices according to the invention each comprising a photovoltaic panel with an orientation determined with respect to the cardinal points and an inclination determined with respect to the horizontal; FIG. 3 represents a diagram of an exemplary covering device according to the invention having an inclination with respect to the horizontal, variable and controlled; FIG. 4 represents a perspective view of an exemplary covering device according to the invention having an inclination with respect to the horizontal, variable and controlled; FIG. 5 represents a method of dimensioning a covering device according to the invention; FIG. 6 is a perspective view of an exemplary cover device according to the invention having a variable and controlled inclination; - Figure 7 shows a perspective view of an example of a roofing device in connection with other roof covering elements. The invention will now be described with reference to the previously cited figures. The covering device comprising at least one open frame is installed on a roof of a building. Without limitation, the roof of the building can be made using different elements (11) cover, such as corrugated sheet or tiles or slates or waterproofing membrane or other elements cover. A solar panel covering device (10) in connection with cover elements (11) formed by corrugated metal plates, is shown in particular in FIG. 7. The covering device comprises a joining part (1) arranged according to the roof plane and linked to a lower border (P21, P22, P23, P24) of a frame. The joining part (1), for example of metal or fiberglass, rests in support, on the roof frame or on one or more elements (11) roof cover. The joining portion (1) comprises, for example, a zone in contact with the covering elements (11), this zone being mounted on the covering elements (11) or under the covering elements (11) or adjacent to the covering elements. . This contact zone corresponds, for example, to a covering surface for sealing. A lower zone of the joining part (1) comes for example on the adjacent lower cover elements (11). An upper zone of the joining part (1) comes for example under the upper adjacent cover elements (11). The lateral zones of the joining part (1) come for example below or above the adjacent side cover elements (11). The joining part (1) of the solar panel cover device has for example a complementary or identical profile to the profile of the elements (11) cover or allows their connection which will ensure a sealed assembly. A cover device arranged, without limitation, on a corrugated sheet roof, for example, has a connecting portion with a corrugated profile of the same shape and size as the corrugated sheet used. A solar panel cover device (10) arranged, without limitation, on a roof with slates, for example, has a joining portion making a connection, for example zinc, so as to adapt to the many possible profiles slates and the lap length between the slates which depends on the slope of the roof. Thus, the solar panel covering device (10) provides a watertight junction with adjacent cover elements (11) thereby providing a sealed assembly with adjacent cover members (11). Without limitation, the solar panel cover device (10) may also comprise connecting elements such as brackets for fixing its junction portion or the bottom edge (P21, P22, P23, P24) of its frame. . The lower edge (P21, P22, P23, P24) of the frame (21, 22, 23, 24) is for example fixed by welding, screwing, gluing or embedding with the joining part (1) arranged around the lower border.

The sides (21, 22, 23, 24) of the frame of the solar panel cover device, for example are made by structural elements in the form of bar, beam or crossbar. The structural elements thus form the frame. The solar panel cover device thus comprises at least one open frame disposed opposite an opening in the roof. The structural elements of the frame are, for example, extended upwards to the upper edge (S21, S22, S23, S24) of the solar panel cover device. The upper edge receives for example a solar panel (10), also called photovoltaic panel, resting on the upper edge (S21, S22, S23, S24) and closing the opening of the frame. The solar panel (10) is, for example, of the so-called Bi-glass photovoltaic panel type or of another type of semi-transparent or translucent solar panel, allowing part of the light or an opaque photovoltaic panel not to pass through. light, as the photovoltaic material deposited under the brand Tedlar. Advantageously, the solar panel cover device, equipped with a translucent or transparent solar panel, can combine the functions of zenith lighting and electric generator. The frame (21, 22, 23, 24) and the joining part (1) of the covering device are for example associated with insulating materials providing thermal insulation, while the photovoltaic panel closes the opening of the frame in a sealed manner . The photovoltaic panel is for example glued or pressed against a peripheral seal, on the upper edge. The solar panel can also be recessed in the frame to have a better resistance to theft. A device for storing electrical energy or converting into alternating current for resale or consumption of electrical energy is for example connected to the photovoltaic panel. In a nonlimiting manner, connection wires pass for example photovoltaic panel through the interior of the building or pass through the outside of the building. The open frame facilitates in particular a connection of the solar panel with a device using the electrical energy disposed inside the building. Without limitation, the sides of the frame are made perpendicular to the solar panel inclination and orientation determined relative to the roof. The sides of the frame may also be extended at the upper support edge against the solar panel, by a peripheral clamping portion formed in the thickness of the frame and coming around the panel, the peripheral clamping portion having a leading edge. perpendicular clamping to the panel. Without limitation, according to an exemplary embodiment, the inclination of the solar panel can be corrected relative to the roof, without changing its orientation relative to the roof. According to another embodiment, the orientation of the solar panel relative to the roof can also be corrected without changing its inclination relative to the roof. According to another embodiment, the inclination and orientation of the solar panel can be corrected relative to the roof.

Two opposite sides of the frame are, for example, bevelled. A structural element of the frame forming a beveled side, for example has its two opposite edges, forming in part the lower and upper edges, inclined relative to each other at a non-zero angle. The frame can also have all beveled sides.

On the other hand, the structural elements of the frame are joined together in pairs at their ends to form edges of the frame. Two ends joined together are made of the same height thus allowing a tight junction and forming the edges of the frame. Without limitation, the reference used in Figures 1 and 2 corresponds to the direction (x) of the line of greatest slope of the roof, the horizontal direction (y) and the direction (z) perpendicular to the roof plane. The line of greater slope will for example be taken as a reference to determine the inclination of a plane relative to the horizontal. The orientation of the plane of the roof, with respect to the cardinal points, will be, for example, taken along its line of greatest slope.

According to the example of Figure 1, for each side of the frame, the upper edge is inclined relative to the lower edge and the side edges are of different lengths. In a nonlimiting manner, a beveled structural element of the frame of the covering device has almost a trapezoidal shape whose parallel sides are formed by two edges of the frame. The upper border is made according to a specific plane parallel to the solar panel. The line (P1) of greater slope has in particular a determined orientation along the cardinal points and is not parallel to the lateral sides of the frame. The projection of the line (P1) of greater slope in a plane (x, y) corresponding to the plane of the roof is in particular represented by a straight line (Dc), this projection line (Dc) having an orientation (B1) determined by relative to the direction (x) corresponding to the orientation of the roof. Thus an orientation angle (B1) of the panel relative to the roof, can be added or removed at the orientation of the roof according to the cardinal points, to adjust the orientation of the panel relative to the cardinal points. The angle (B1) orientation of the panel will thus allow the correction of the orientation of the roof to get closer to an ideal situation or even reach the ideal situation. The ideal situation is, for example, a south-facing orientation for a building in the northern hemisphere or a full-north orientation for a building in the southern hemisphere.

In addition the line (P1) of greater slope of the solar panel has an inclination (Al) determined relative to the plane (x, y) of the roof. Thus an inclination can be added or removed with respect to the slope of the roof. The slope of the panel relative to the roof, added to or removed from the slope of the roof, makes it possible to adjust the inclination of the panel relative to the horizontal. The angle (Al) of inclination of the panel will thus allow the correction of the slope of the roof, to get closer to an ideal situation or even to reach the ideal situation. An ideal situation is determined according to needs during the year, for example to promote energy production in winter or summer. The adjustment of the inclination of the solar panel with respect to the horizontal and the adjustment of the orientation of the solar panel with respect to the cardinal points are carried out by determining the dimensions of each of the sides of the frame of the covering device. Without limitation, as shown in Figure 2, the roof can be made with the orientation (x) of its line (P1) of greater slope, for example optimized south-facing for a building in the northern hemisphere. The solar panel cover device performs, for example only a correction of the inclination with respect to the horizontal. The angle (A2) of correction can be added or removed, relative to the plane of the roof. The frame of the cover device includes, but is not limited to, two beveled and for example trapezoidal side sides, a rectangle-shaped upper side and a rectangle-shaped lower side. If the sides of the frame are inclined at an acute angle to the roof, the beveled sides of the frame then have a distorted trapezoid shape. In a nonlimiting manner, the lower border forms a rectangle whose short sides or long sides correspond to the lateral structural elements of the frame. The lateral structural elements of the frame will correspond for example to the long sides of the rectangle, or respectively to the short sides of the rectangle, if the correction of the orientation with respect to the cardinal points is weak, or respectively important. The base of the solar panel cover device is thus arranged in said landscape mode or in said portrait mode. Without limitation, on a slope facing north or south, where only the slope must be corrected, the solar panel devices with a rectangular base -11- will be arranged with the long sides of the horizontal base. In a non-limiting manner, on a slope facing west or east, the solar panel cover devices with a rectangular base will be arranged with the short sides of the horizontal base.

Without limitation, in the case of a roof disposed horizontally, the orientation of the lower border of the frame corresponds, for example, to the orientation of the lateral sides of a rectangular frame. The lower edges of the lateral sides are for example rectangular and horizontal, their orientation corresponding to the direction of the side of the rectangle of greater length. The sides of the frame are thus dimensioned so that the upper edge is disposed in a bearing surface of the solar panel whose line of greater slope points in a given optimized direction, referring, for example to the cardinal points. The slope of the upper surface, taken along the line of greater slope, on the other hand has a determined inclination optimized with respect to the horizontal. The optimized determined direction points, for example, towards the south, for a building in the northern hemisphere, and the inclination is, for example, 60 ° for a building at 50 ° north latitude. Depending on the roof sections facing north or south, and depending on the inclination of the roof sections, a slope will be added or removed. On a slope facing north with a slope of the order of 20%, the panels may for example have a slope opposite to that of the slope and thus have a south orientation and an optimized inclination.

One method of determining the dimensions of the frame is, for example, using a computer workstation equipped with a CAD (Computer Aided Design) program, to grasp the orientation and inclination of the bottom edge when an initialization step (Etp01). The dimensions of the bottom border are for example also entered during the initialization step. After entering and storing (cond01) the orientation and inclination of the bottom border, a subsequent step (Etp02) is, for example, to capture the inclination or orientation of the top border. . Both the inclination and the orientation of the solar panel can be corrected. After storing (cond02) the inclination or the orientation of the upper border or storing both, a next step (Etp03) includes, for example, calculating the dimensions of the sides of the frame of the panel covering device solar. The calculation of the dimensions of the sides of the frame produces for example the heights of the edges for each side of the frame.

After calculating the dimensions of the sides of the frame, the calculated and stored dimensions are for example presented to the user. The user can choose to keep the calculated dimensions which are then archived in a results file or the user can also perform the step (Etp02) of entering the inclination or the orientation of the upper border, to then restart the dimension calculation and analyze new dimensions of the frame. Thus the user can adjust the frame dimensions accordingly to have a tilt and an orientation corresponding to the best compromise without having a frame too high. In a nonlimiting manner, a maximum height can also be stored in the workstation. After the calculation (cond03) of the dimensions of the frame, the calculated and stored heights of the edges are for example compared to the maximum height stored during a (Etp04) next step. If (condO41) the maximum height is not exceeded, the dimensions are for example stored as the final result. If (condO42) the maximum height is exceeded by one or more edges, a step (Etp05) of adjustment of the stored data corresponding to the inclination or the orientation of the upper border, is for example executed. The memorized orientation or the stored inclination is, for example, reduced according to a determined incrementing angle. This incrementation angle is for example 1 ° or a few degrees to have a precise adjustment. After (cond05) the storage of the inclination or orientation adjusted, the step (Etp03) of calculation of the dimensions is, for example, performed again taking into account the adjusted stored data representative of the tilt and orientation of the upper border.

The calculation is, for example, followed by a new adjustment step or a step (Etp06) of storing the final result. According to a nonlimiting example of embodiment, a solar panel cover device, disposed on the north side of a building in the northern hemisphere, can also be corrected according to its inclination. The slope of the solar panel will for example be inverse to the slope of the roof on which the solar panel is arranged. In order not to be bothered by the ridge, the panel protrudes for example above the ridge. By way of non-limiting example, for a slope of the roof oriented to the north in a slope of 20%, the covering device, arranged for example in landscape will have its element of the frame disposed towards the ridge of a height of 30cm and its opposite frame element and arranged down the slope of a height 65cm. The height of 65 cm makes it possible, for example, to take into account: the height of the opposite frame element, for example compensated with a height of 30 cm, the slope of the north slope, for example at 20% and compensated with a height 10cm and - the desired slope for the solar panel, obtained for example with a height of 25cm. The aesthetic or practical aspects or mechanical resistance may in particular be taken into account for determining the maximum dimensions. The sides of the frame of the covering device may in particular be dimensioned to have optimized dimensions to approach at most an optimal orientation according to the cardinal points and to approach at most an optimum inclination with respect to the horizontal. An optimal non-variable inclination corresponds, for example, to the tilt -14- set at 30 ° which would allow the producer of photovoltaic energy to derive the best performance from his installation during the summer months. The photovoltaic panel cover device thus enables electric power generation with optimized efficiency. Advantageously, a photovoltaic panel of translucent or transparent glass type, arranged in front of an opening in the roof and allowing light to pass through, is used to produce the zenith lighting. The solar panel device is thus perfectly integrated into the roof of the building and provides the power generation function, the sealing function and the lighting function. The sides of the frame of the solar panel cover device are, for example, made of fiberglass or metal-filled polyester. For example, fasteners such as glue, metal seals or fasteners prevent the removal of the panel. The profiles of the portion (1) of junction compatible roofing elements, in particular allow to replace the photovoltaic panel device to at least a portion of the cover elements, without a modification of the frame is necessary. In a nonlimiting manner, the lower edge (P21, P22, P23, P24) may also have a profile adapted to the profile of the joining part (1). The roof can be made with timber or steel framing, with or without herringbone and the covering device is placed directly on the roof with or without the addition of additional connecting element or sealing. This is particularly the photovoltaic panel, such as a so-called Bi-glass panel or photovoltaic material filed under the mark Tedlar, which ensures the closure of the open frame. As shown in FIGS. 3 and 4, a positioning member (52) can be linked to an upper frame (41) articulated with respect to a lower frame (42) fixed on the roof. Without limitation, the structural elements of each of the two articulated frames are made straight or bevelled. The structural elements forming the sides of the lower frame (42) are for example straight and two structural elements forming the sides of the upper frame (41) are for example bevelled. The solar panel (10) -15- shown in Figure 3, supported by the articulated upper frame and has a variable inclination. The frames can thus be pressed against each other or apart from each other. In a nonlimiting manner, the articulation (3) between the frames is made by a pivot or a ball joint. To maintain a seal, a flexible membrane (43) or a set of elastic deformable flaps is for example disposed between the two frames (41, 42). In a nonlimiting manner, the positioning control member may be controlled by an actuator controlled by a management device. Without limitation, one or more cylinders or motors allow rotation to adjust the inclination towards the sun. The actuator (6) is for example a central unit supplying liquid or air for supplying a hydraulic or pneumatic cylinder. The jack (52) is for example fixed at its two ends (53, 51) by a pivot-type connection, one end (51) being fixed relative to the roof and the other end (53) being connected to the frame (41). ) superior. The jack comprises for example a piston connected by a hinge and a cylinder linked by a hinge. In a nonlimiting manner, the actuator (6) can also be an electrical circuit providing power control to the positioning member (52) comprising, for example, an electric motor acting on a toothed wheel, the toothed wheel driving, for example , a rack. A cylinder can also be electrically controlled. In a nonlimiting manner, according to another exemplary embodiment, the positioning member (52) can be manually adjusted by a user, in a locking position among several determined locking positions. According to an embodiment shown in Figure 6, the positioning member may also comprise a hydraulic cylinder comprising a liquid or gaseous fluid in a chamber connected by a thermal bridge with the environment of the positioning member. The chamber is, for example, arranged in a metal cylinder exposed to light rays passing through the photovoltaic panel and being in the heated air in the environment of the photovoltaic panel. Thus, the positioning member is more or less heated at the same time as the photovoltaic panel and positions the photovoltaic panel according to its heating. A jack arranged downwardly comprises, for example a mobile piston connected by a pivot with an intermediate bar (55) up to the solar panel to make a pivot connection with the upper frame. The cylinder of the cylinder is for example fixed to the frame (42) below. Thus the cylinder exerts, for example a tensile force driving the solar panel to the roof, when exiting its piston. The output of the piston which corresponds to a heating of the fluid of the cylinder chamber thus lowers the solar panel, when the radiation is the most intense, for example in the middle of the day, the sun being high in the sky. This cylinder also tends to raise the solar panel when the radiation is less important, for example at the end of the day when the sun becomes grazing, to increase the exposure area.

Thus the inclination of the border (S21, S22, S23, S24) greater than the horizontal, can be achieved variable. A variable inclination can be ordered throughout the day to track the movements of the sun. For example, since the solar panel's steepest line is oriented towards the south, the building being located in the northern hemisphere, a variable inclination of the solar panel makes it possible to optimize the efficiency of the solar panel, in order to position the line ( P1) of greater slope at an inclination determined relative to the horizontal. The variable inclination allows in particular to position the panel, continuously, as close to the perpendicular to the sun's rays by adapting to the height of the sun in the sky. In a nonlimiting manner, the maximum variation of the inclination corresponds to a maximum stroke (54) of the member (52) for positioning the upper frame (41). Without limitation, the upper part may be inclined in a horizontal axis rotation, this axis being oriented in the directions East and West. In a nonlimiting manner, the sealing membrane may be connected to three sides of the frame, or respectively four sides of the frame, for a pivot connection arranged along one side of the frame, or respectively for a ball joint connection arranged in a corner of the frame. The sealing membrane may also, without limitation, be replaced by a set of plates overlapping and translating relative to each other while remaining pressed against one another to make a tight connection. The overlapped plates, for example made of plastic, comprise for example a refined part allowing tilting of the plates. The upper plates are for example clamped between lower double plates. The upper plates bonded together comprise for example refined areas allowing deformation of all the upper plates to maintain a seal regardless of their positions. Similarly, the lower plates bonded together can also slightly deform to maintain a seal. With these plates or shutters used in the same way, the solar panel cover keeps the roof watertight and can be used for buildings requiring cold or rain-tightness, such as homes or houses. sheds. Without limitation, the rotation can be controlled automatically, the inclination of the photovoltaic panel being, for example, made according to the height of the sun throughout the day. The management device (7) comprises, for example, stored data representative of the different heights of the sun in the sky, according to the date and according to the time of the day. The management device (7) may also include a program for calculating the height of the sun from stored data corresponding to the latitude and longitude of the building. For example, a user enters data representative of longitude and latitude in the system during an initialization phase of the management device. The initialization phase includes, for example, also the entry and storage of the date and time. The management device calculates, for example, an optimum inclination for positioning the solar panel, as close as possible to a plane perpendicular to the sun's rays. The tilt data calculated and stored are for example exploited to produce a control (C6) of a given inclination corresponding to the calculated inclination. In this way the solar panel cover device can thus be a sun follower device. The efficiency of the solar panel is thus further improved.

It should be obvious to those skilled in the art that the present invention allows embodiments in many other specific forms without departing from the scope of the invention as claimed. Therefore, the present embodiments should be considered by way of illustration but may be modified in the field defined by the scope of the appended claims.

Claims (6)

1. A solar panel covering device comprising: - an upper border (S21, S22, S23, S24) supporting the solar panel and - a joining part (1) resting on a roof structure of a building or on roof covering elements (11), the joining portion having a profile, compatible or adaptable to the roofing elements, the roof being disposed in a plane having an inclination determined in relation to the horizontal and a direction relative to at the cardinal points or the roof having a zero inclination with respect to the horizontal, characterized in that the joining part is connected to the upper edge by at least one frame (21, 22, 23, 24) comprising a central opening closed by the solar panel, the joining part (1) being connected to a lower edge (P21, P22, P23, P24) of said frame and arranged around this lower edge, said frame being arranged, relative to the inclination of the roof, or the orientation of the roof or the orientation of the lower border, so that the solar panel arranged against the upper edge has: - a corrected inclination relative to the horizontal approaching the perpendicular to the sun rays or - an orientation corrected with respect to the cardinal points towards the south, or respectively from the north, if the building is situated in the northern hemisphere, or respectively in the southern hemisphere. 2. Device according to claim 1, characterized in that the frame is formed by four structural elements (21, 22, 23, 24) including two lateral structural elements (23, 24) arranged along the line of greater slope of the roof or according to the orientation of the lower border, the structural elements being interconnected by their ends, the joined ends in pairs being of the same height, at least two opposite structural elements of the frame being beveled to correct the orientation of the solar panel by beveling the lateral structural members (23,24) or correcting the inclination of the solar panel by bevelling the two other structural elements (21,22). 3. Device according to claim 1 or 2, characterized in that the solar panel is of the translucent or semi-transparent photovoltaic panel type. 4. Device according to one of claims 1 to 3, characterized in that the device comprises two frames including an upper frame (41) forming the upper edge and a lower frame (42) forming the lower edge, the upper frame being bound to the lower frame by a hinge (3) 10 and a flexible sealing member (43) or by a set of plastic sealing flaps pressed against each other and of determined rigidity, allowing a rotation of the upper frame with respect to the lower frame, a positioning member (52) being connected to the upper frame and providing adjustment of the inclination of the upper frame relative to the horizontal. 5. Device according to claim 4, characterized in that the positioning member (52) is controlled by a management device (7) comprising a computer processing component, a storage component and a communication interface, transmitting to an actuator (6) of the positioning member, by a communication line, at least one determined inclination control (C6) of the upper frame, the determined inclination control being calculated according to stored data representative of a date or time or time of year, 25 corresponding to at least one specific height of the sun in the sky. 6. Device according to claim 4, characterized in that the member (52) for positioning comprises a control chamber comprising a fluid expanding under the effect of heat, and heated to an intensity proportional to a heating of the solar panel , the chamber 30 belonging to a jack comprising a cylinder and a piston extended by a cylinder rod, the cylinder being fixed to the lower frame and the cylinder rod coming out of the cylinder downwards, being connected by a hinge to a bar-21 - Intermediate, the bar (55) intermediate being linked on the other hand, by a hinge, the upper frame to pull the upper frame and reduce the inclination of the upper edge when the chamber temperature increases and causes expansion of the fluid .