FR2958023A1 - Juxtaposed solar panels e.g. thermal or photovoltaic type rigid solar panels, fixing device for thermal or photovoltaic solar power unit of roof structure of building, has fixture, flap and plate defining two housings - Google Patents

Abstract

The device has an upper fixture (10) extending from an upper end of a planar flap (9) and parallel to a plate (11) of a base (8), where the base includes an omega section. The fixture is extended on both sides of the planar flap to form two overlap extensions, where each of the extensions is opposite to one of two support surfaces formed on the fixture. The fixture, the flap and the plate define two housings (19, 20) that receive an upper edge and a lower edge (4a2) of two juxtaposed solar panels (4). An independent claim is also included for a solar power unit for use on a slope support structure.

Description

The present invention relates to the general field of laying rigid solar panels photovoltaic or thermal type on a sloping support structure, including a building roof. Photovoltaic solar panels, also called photovoltaic solar modules, consist of electric generators consisting of a set of photovoltaic cells interconnected electrically. These solar panels constitute the basic units for photovoltaic solar installations.

Most of the current solar panels are in the form of parallelepipedic rigid plates, generally rectangular in shape, whose surface is of the order of 1 m2 to 1.5 m2. These panels can be placed with their long length in the direction of the slope (pose type "portrait"), or with this great length oriented transversely to the slope (pose type "landscape"). It is provided in some cases a mounting photovoltaic panels in the same plane. In other cases, the mounting of the panels can be said "in the manner of tiles or slates", with a slight overlap of the upper edge of the panels by the lower edge of the panels directly upstream. In all cases, the mounting on the support structure is achieved by means of suitable fastening devices, for example longitudinal profiles, as described in documents DE-102 40 939, or DE-20 2007 008 659.

But the structures of these current profiles are relatively complex and require a lot of material; and these profiles are therefore a relatively high cost. The present invention relates to the mounting of solar panels arranged in the same plane, and it provides simplified fixing means, while being very effective. For this, the fixing device according to the invention comprises a plurality of single-piece profiles intended to be fixed on the support structure, on the one hand in an orientation perpendicular to the slope, and on the other hand in a parallel arrangement and to distance from each other, so as to allow the positioning of the solar panels between two of said profiles opposite, and in the same plane, at least some of these profiles being constituted: - a base section omega, consisting of a plate whose lateral edges include downwardly extending extensions, which themselves are extended by outwardly facing lateral wings, situated in the same plane parallel to said plate, which lateral wings comprise orifices for attachment to said plate; supporting structure, - a plane flap which extends upwards from said plate, perpendicular to it and between its lateral edges, to form two bearing surfaces on said plate, separated by said plane flap, and - an upper plate, extending from the upper end of said flat flap, parallel to said plate, which plate extends from and other said flat flap to form two overlapping extensions, each facing one of said bearing surfaces.

The sets plateau, flap plan and upper platen thus define two housing backed for the reception of the upper and lower borders of two solar panels juxtaposed. According to a preferred embodiment, the plane shutter of the profiles is off-center with respect to the longitudinal axis of the plate, so as to form two bearing surfaces of different length, to obtain two reception houses solar panels, dimensions different, one called "small", and the other said "large". On the other hand, the overlapping extensions each have a length less than the length of the directly underlying bearing surface.

These features facilitate the installation of solar panels, by embedding their upper and lower edges in the dedicated housing profiles. The invention also relates to the solar installation comprising a set of solar panels juxtaposed and held in the same plane by means of a fixing device as defined above. According to a preferred embodiment, the fastening profiles of the solar panels are mounted on their support structure so that their small housing is open towards the top of the slope, and that their large housing is open towards the from the bottom of the slope; in addition, the installation comprises structural locking means in positioning of the solar panels, which locking means provide spacing between the upper edge of said panels which is embedded in said large housing and the plane flap constituting the bottom of this housing.

These locking means are advantageously constituted by spring members mounted on the edge of the upper edge of the solar panels. These spring members preferably each consist of a metal blade whose one end is fixed on the edge of the upper edge of the associated solar panel, and the other part, free, ~ o is shaped protruding to be able to ensure the desired locking function. The invention will be further illustrated, without being limited in any way, by the following description of a particular embodiment, given by way of example only and represented in the accompanying drawings in which: FIG. 1 is a general view, in perspective, a solar installation comprising a juxtaposition of rectangular photovoltaic solar panels, maintained in the same plane by the fixing device according to the invention; FIG. 2 is an enlarged view of a portion of FIG. 1, showing the detail of the mounting of two solar panels juxtaposed in the direction of the slope, on one of the fixing profiles; FIG. 3 is an isolated view, in perspective, of one of the constituent sections of the fixing device according to the invention; Figure 4 is a side view of the profile according to Figure 3; - Figure 5 shows, in isolation and seen from above, one of the solar panels of the installation according to Figures 1 and 2. The sloping support structure 1, shown in Figure 1, for example consists of a roof building; it comprises a frame 2, 30 formed for example of longitudinal metal spars 2a sloping, connected by horizontal wooden splits 2b. To simplify the rest of the description, with respect to a given point, the high and low sides of the slope are designated respectively by "upstream" and "downstream".

This frame 2 is covered, entirely or partially, by a solar installation comprising a set of sealing plates 3 constituting a support base for rigid photovoltaic solar panels 4.

Alternatively, these solar panels 4 could be fixed on any other base support, or directly on the frame 2. These solar panels 4 are each in the form of rectangular parallelepiped plates, whose surface is for example of the order of 1 m2. They consist of a frame-shaped frame 4a surrounding a module 4b integrating a set of photovoltaic cells (FIGS. 1, 2 and 5). The sides of the frames 4a constitute the four borders of the solar panels 4, namely upper edges 4a1 and lower 4a2 (intended to come respectively upstream and downstream sides of the support structure 1), connected by side edges 4a3. The solar panels 4 are fixed on the support plates 3 by means of a fixing device 6 which allows their arrangement in a coplanar arrangement. The fastening device 6 according to the invention consists, for this purpose, of a set of receiving profiles 7, arranged at a distance from each other and perpendicular to the direction of the slope; the solar panels 4 are each carried by a pair of such profiles 7 opposite. One of these reception profiles 7 is shown in detail in FIGS. 2, 3 and 4.

This profile 7 is obtained by extrusion of aluminum or stainless steel for example, on a suitable die. The metal section 7 consists of a base 8 extended upwards by a plane flap 9 which ends with an upper plate 10. The base 8 consists of a plate 11 whose lateral edges 12, 13 comprise extensions 14, 15 facing down. The lower edge of each extension 14, 15 is extended by a side wing 16, 17 oriented externally. The two lateral wings 16, 17 are located in the same plane which is parallel to the plane of the plate 11. They have the same length here and they include orifices 18 for fastening the profile 7 to the support structure 1. It will be noted that the orifices 18 may be machined at the time of installation or during the manufacture of the profile 7. The plane flap 9 extends upwardly from the base plate 11, perpendicular to it and between its side edges 12 , 13.

As can be seen in FIGS. 2, 3 and 4, this plane flap 9 is off-center with respect to the longitudinal axis of the plate 11; it thus defines and separates two bearing surfaces 11 'and 11 ", on said plate 11, which have different lengths, a and b, respectively (the length a being greater than the length b, FIG. 4).

The upper plate 10 extends on either side of the plane shutter 9 from the upper end thereof, and parallel to the base plate 11. It constitutes two overlapping extensions 10 'and 10 ", respectively of different lengths c and d (the length c being greater than the length d).

The overlap extension 10 ', of length c extends on the same side as the bearing surface 11' of length a, and parallel thereto. Note that the length c is a little less than the length a. The overlap extension 10 ", of length d, extends on the same side as the bearing surface 11" of length b, and parallel thereto. The length d is a little less than the length b. The plate assembly 11, plane flap 9 and upper platen 10 thus defines two recesses 19 and 20 for the reception of the upper edges 4a1 and lower 4a2 of two solar panels 4 juxtaposed. In this case, the housing 19, delimited by the bearing surface 11 'of the plate 11, by the plane flap 9 and by the extension of the cover 10', can be qualified as a "large" receiving housing, relative to the housing 20 "of small size", delimited by the bearing surface Il ", the plane shutter 9 and the overlap extension 10". The height of the housings 19 and 20 is expected to be greater than the thickness of the solar panels 4. In practice, as shown in FIG. 2, the reception profiles 7 are secured to the support structure 1 by means of their lateral wings. 16, 17, by means of fastening screws 21 (from being implanted in their orifices 18).

During this fixing, the receiving profiles 7 are oriented so that the opening of their housing 19 of large size and the opening of their housing 20 of small dimensions, are oriented respectively downstream and upstream of slope.

These reception profiles 7 are reported in a perpendicular orientation, or at least substantially perpendicular to the slope of the support structure 1. Their length is advantageously adapted so as to correspond, at least, to the length of the upper edges 4a1 and lower 4a2 of the solar panels 4.

Preferably, the profiles 7 have a length that can receive between three and five solar panels 4. In addition, these profiles 7 are fixed in a parallel arrangement and at a distance from each other, this with a spacing adapted according to the height of the panels 4, corresponding to the distance D between the upper borders 4a1 and lower 4a2. In Figure 1, the sections 7 are spaced apart to receive the solar panels 4 in a landscape orientation, that is to say, to receive their long sides. Each solar panel 4 is attached between two fastening profiles 7 opposite, one upstream of the slope and the other downstream, so that: - on one side, its upper edge 4a1 fits into the housing 19 of large size of the upstream fastening section 7, to rest on its bearing surface 11 ', and - on the opposite side, its lower edge 4a2 fits into the housing 20 of small size of the downstream fastening profile 7, for resting on its bearing surface 11 "and abut against its plane flap 9. The upper edges 4a1 and lower 4a2 are further covered respectively by the overlapping extensions 10 'and 10" associated, which ensures the attachment of the frame 4a solar panels 4 without causing shading on their photovoltaic cells. According to the assembly illustrated in FIGS. 1 and 2, all the reception profiles 7 are identical. The housing 19 of the profile 7 furthest downstream of the slope and the housing 20 of the profile 7 furthest upstream of the slope remain free without receiving solar panels 4.

Laterally, the solar panels 4 are positioned edge to edge, possibly associated with a seal. This mounting operation can be done simply by sliding one after the other of the solar panels 4 along the reception profiles 7 preinstalled. In an alternative and preferred way, the particular structure of the reception profiles 7 and their adapted spacing on the support structure 1 allow operations of assembly / disassembly of the solar panels 4 by direct embedding on the profiles 7, thus allowing a mounting of these ~ o panels 4 independently of each other. For this purpose, the distance between the free edge 10 "has the extension 10" of the downstream profile 7 and the plane flap 9 of the upstream section 7, is greater than the height D of the panel 4. In addition, the distance between the flap plane 9 of the profile 7 downstream and the downstream edge 15 10'a of the extension 10 'of the upstream profile 7 is provided lower than this height D of the panel 4. Thus, for mounting, it suffices for the operator to embed firstly the upper edge 4a1 of the panel 4 in the housing 19 of the upstream profile 7. The panel 4 is then pivoted around its upper edge 4a1 so as to position its lower edge 4a2 facing the housing 20 of the downstream profile. The installation ends with the operation of the panel 4 downstream of the slope until the edge of its lower edge 4a2 comes to bear against the plane flap 9 of the housing downstream. Conversely, for disassembly, it is sufficient for the operator to maneuver the panel 4 upstream of the slope, so as to bring its upper edge 4a1 closer to the plane flap 9 of the section 7 upstream, and then to disengage its lower edge 4a2 and maneuver the panel 4 in the opposite direction downstream of the slope. Alternatively, the receiving profiles 7 may be spaced apart to receive the solar panels 4 in a portrait orientation. In this case, it is the short sides of the panels 4 which form the upper edges 4a1 and lower 4a2, and which are embedded in the housings 19 and 20 of the receiving profiles 7. Furthermore and as shown in FIGS. 2 and 5, to ensure optimal locking of the solar panels 4 between the profiles 7, the edge of the upper edge 4a1 of the panels 4 is equipped, along its length, several spring members 22 (in this case three in number). As shown in Figure 5, these spring members 22 each consist of a metal blade having a compressive elastic deformation capacity. Each leaf spring 22 is fixed on the frame 4a1 by means of a self-drilling screw 23, at one of its ends. Its other part, which is free, is shaped protrude in a curved manner, to form the elastic element capable of providing the desired locking function. ~ o The number of leaf springs 22 depends in particular on their compression characteristics, the weight of the panel 4 and the desired holding force. In practice, these spring members 22 will be compressed against the plane flap 9 when embedded in the housing 19 of the upstream profile 7, 15 for assembly and disassembly operations. When the panel 4 is released, the leaf springs 22 relax and they hold the solar panel 4 effectively on the receiving profiles 7 opposite (the upper edge 4a1 of the panels 4 is spaced from the plane flap 9 of the upstream profile 7; in parallel, their lower edge 4a2 20 is pushed against the plane flap 9 of the downstream profile). In this case, the distance between the bottom of the receiving housings 19 and 20 opposite is between, on the one hand, the height D of the panel 4, and on the other hand, this height D extended by the height of the spring members 22 at rest.

Alternatively, the locking in position of the panels 4 can be achieved by means of removable screws implanted in the covering extensions 10 '. The fixing device according to the invention is of very simple structure and it assures an easy and quick installation and removal of the solar panels 4. This fixing device is adaptable to all dimensions of solar panels and to any degree of slope. roof. This device is still adaptable to receive solar thermal panels (also called solar thermal collectors), so as to constitute a thermal installation.

Claims (1)

1. A device for fixing solar panels (4) in the same plane on a sloping support structure (1), in particular a roof structure, which fastening device (6) comprises a plurality of single-block profiles (7). ) intended to be fixed on said support structure (1), firstly in an orientation perpendicular to the slope, and secondly in a parallel arrangement and at a distance from each other, so as to allow the positioning of said panels solar cells (4) between two of said profiles (7) opposite, characterized in that at least some of said profiles (7) consist of: - a base (8) with omega section, consisting of a plate (11) whose side edges (12, 13) have downwardly extending extensions (14, 15) which themselves extend by outwardly facing lateral wings (16, 17) situated in the same plane parallel to said plateau (11), which side wings the (16, 17) have openings (18) for fixing on said support structure (1), - a flat flap (9) which extends upwardly from said plate (11), perpendicular to that and between its lateral edges (12, 13), to form two bearing surfaces (11 ', 11 ") on said plate (11), separated by said plane flap (9), and - of an upper plate (10), extending from the upper end of said flat flap (9), parallel to said plate (11), which plate (10) extends on either side of said flat flap (9) to form two overlapping extensions (10 ', 10 "), each facing one of said bearing surfaces (11', 11"), said plate (11), plane flap (9) and upper plate (10) defining two housing (19, 20) backed to receive the upper borders (4a1) and lower (4a2) of two solar panels (4) juxtaposed. 2.- Device according to claim 1, characterized in that the plane flap (9) of the profiles (7) is off-center with respect to the longitudinal axis of the plate (11), so as to form two bearing surfaces (11). ', 11 ") of different length, to obtain two housings (19, 20) for receiving solar panels (4), of different size. 3. Fastening device according to claim 2, characterized in that the overlapping extensions (10 ', 10 ") each have a length less than the length of the bearing surface (11', 11") directly underlying . 4.- Solar installation intended to be reported on a sloping support structure (1), in particular a roof, which installation is characterized in that it comprises a set of solar panels (4) juxtaposed and maintained in the same plane at means of a fastening device (6) according to any one of claims 1 to 3. 5.- solar installation according to claim 4, comprising a fixing device (6) according to any one of claims 2 or 3, characterized in that the profiles (7) for fixing solar panels (4) are mounted on their support structure (1) so that their small housing (20) is open towards the top of the slope, and that their housing (19) of large dimension is open towards the bottom of the slope, said installation comprising structural locking means (22) for positioning said solar panels (4), which locking means (22) provide spacing between the upper edge (4a1) of said panels (4) which is embedded in said housing (19) of large dimension and the plane flap (9) constituting the bottom of this housing (19). 6. Solar installation according to claim 5, characterized in that said positioning locking means consist of spring members (22) mounted on the edge of the upper edge (4a1) solar panels (4). 7.- Solar installation according to claim 6, characterized in that the spring members (22) are each in the form of a metal blade whose one end is fixed on the edge of the upper edge (4a1) of the associated solar panel ( 4), and the other part, free, is shaped protruding to be able to provide the desired locking function.