FR2931855A1 - Right and left lateral profiles for integrating photovoltaic panels in roof, has groove and tab for encasing lateral profiles for sequentially and horizontally installing photovoltaic panels in roof to ensure lateral sealing between panels - Google Patents

Abstract

The lateral profiles (4, 5) have an extrusion for inserting a screw (7) to assemble a lower profile (2) without machining the lateral profiles, where the lateral profiles are positioned in a direction of slope of roof. A groove and a tab permit encasing of the lateral profiles in opposite direction for sequentially and horizontally installing photovoltaic panels in the roof to ensure lateral sealing between the photovoltaic panels.

Description

The object of the present invention relates to a frame made of aluminum profiles assembled around a photovoltaic laminate constituting a photovoltaic panel and allowing the installation and maintenance of said panels directly on the frame via another linear aluminum profile fixed on it and thus to ensure the waterproofness of the roof facing the weather.

The frame also has the function of reinforcing and rigidifying said panel so that during the various installation or repair work the photovoltaic panel supports the weight of one or more people without undergoing deterioration.

An object of the present invention is to ensure a simple and fast mounting on the roof without the need to fix, aim, nail or bolt the photovoltaic panels between them or on the frame while ensuring a simple mounting resistant and economical IF . The panels are held together by an interlocking system consisting of aluminum profiles.

Another feature of the invention is that when the photovoltaic panels are nested together and on the linear profile of aluminum, this results in a solid hold suppressing the possible vibrations and tearing of said panels facing the weather. Indeed, each panel by its weight comes to exert pressure by gravity on the covered part of the lower panel and 25- at the same time on the inclined tongue and groove type interlocking which allows the maintenance on the frame of said panels and to seal the roof.

The features of the invention mentioned above, as well as others, will become more apparent upon reading the descriptions of exemplary embodiments, said description being made in connection with the accompanying drawings, among which: FIG. 6/8 is a perspective view in schematic section of two photovoltaic panels and the linear profile.

FIG 2 page 4/8 is a sectional view of FIG 1.

FIG 3 page 3/8 is a schematic perspective view showing the assembly of the profiles of the photovoltaic frame.

FIG 4 page 5/8 is a sectional view of FIG 1.

FIG 5 page 1/8 is a sectional view of the lateral aluminum profile of the photovoltaic frame.

FIG 6 page 7/8 is a sectional view showing the assembly of the end profile.

FIG 7 page 8/8 is a sectional view showing the mounting of the panels together and on the roof.

FIG 8 page 2/8 shows the detail of the rear profile of the frame constituting the photovoltaic panel and the machining at each end of said profile.

FIG 9 page 2/8 shows the detail of the front profile of the frame constituting the photovoltaic panel and the machining at each end of said profile. FIG 5 shows the left and right lateral aluminum profiles which constitute the frame of the photovoltaic panel, being positioned in length in the direction of the slope of the roof and thus allows the lateral interlocking between panels one after the others and thus constitutes the lateral sealing between them.

Still in FIG 5 the right side profiles 4 and left 5 of the photovoltaic frame, characterized in that they are of identical design and in that these profiles fit by groove and tongue one in the other in the opposite direction for the roofing of photovoltaic panels one after the other horizontally. These profiles 4 and 5 are designed to receive by assembly the perpendicular profiles 2 FIG8 and FIG 9 which include machining at the end thereof. Right and left lateral sections 5 and 5, characterized in that an extrusion 13 allows the insertion of a screw for the assembly of the perpendicular sections 2 and 30 without modification with respect to the right or left attachment. These said sections 2 and 30 have an identical right and left machining at their end allowing assembly and fastening by screws 7 on the lateral sections. The fact that one of the lateral sections 4 is in a direction opposite to the section 5, does not affect the proper realization of this assembly.

Said profiles 4 and 5 are identical, in order to reduce the manufacturing stroke, their shape has been designed to promote the nesting of two in each other by a system groove 16 and tongue 14, with sufficient clearance to allow to cope with the expansion and also squares differences that may occur during assembly or assembly of said panel. The covering 15 makes it possible to improve the seal by coming to cover the groove 16. The tongue 14 is slightly set back from the thickness of the profile to allow said sections to fit together without creating a difference in level when the lateral interlocking of the photovoltaic panels with each other. The groove 12 is provided to receive the photovoltaic laminate. This said laminate being inserted and glued into the said groove during assembly of the frame.

The rabbet 11 is designed to receive the portion 34 FIG 8 and 19 FIG 9 and thus strengthen the assembly of the aluminum frame when it includes the photovoltaic laminate (we will see in Figure 3). The extruded form 13 is designed to receive a screw and ensure the clamping hold of profiles 6 FIG 8 and 2 FIG 9 during assembly of the frame.

In FIG 3 we can see the assembly detail of the profiles constituting the photovoltaic frame by interlocking and screwing. The rabbet 11 receives the part 19 of the section 2 which improves the rigidity of the assembly since the said section 2 will be subjected to significant effort and become a centerpiece for the assembly and maintenance of the panel on the linear section 2 fixed on the frame. The photovoltaic laminate takes its place in groove 30 and 31 as well as tS in the rabbet 32 all glued to achieve a good rigidity and tightness of the photovoltaic panel.

Turning to FIG. 2, we see in section the maintenance of the bottom section 2 with the lateral section assembled by screws 7. The top profile 6 of the bottom panel is assembled in the same manner but has two small portions 34 FIG. previously machined and which take place in the rabbet 11 (FIG 3). This device ensures good strength of the whole.

In FIG 3 the portion 18 forming an L is positioned in front of the thickness of the photovoltaic laminate being slightly recessed tS of the outer face of said laminate.

Since the photovoltaic panel will be inclined in the direction of the slope of the roof and that this part 18 will be in the lower position of the panel, this will promote the cleaning and the flow of rainwater since in the absence of 3o overflow by relative to the outer surface no dust or any waste will be able to remain stuck on the laminate.

In FIG 2 The Profile 6 shows in its upper part a special housing for disposing a seal of elastomeric material 21.

The lower panel is slid inside the profile 2 and which bears on the profile 3 during the installation of photovoltaic panel and thus create the seal with said upper panel. s Detail in FIG 4 of a sectional view of the positioning of the photovoltaic panels on the linear section 3.

Returning to FIG 2 where we can see one of the centerpieces 3 of the system which, by design serves as a fulcrum in its lower part to the lower panel and allows the interlocking in its groove 8 of the tongue 9 of the profile 2 which in its upper part of said profile 3, the shape of the groove 8 is slightly conical as can be seen as well as that of the tongue 9 of the profile 2, in order to facilitate an interlocking start when positioning the photovoltaic panel up to a perfect fit in final assembly. This assembly female 8 and male 9 in its design and its inclined orientation allows when it interlocked that the lower part of the upper panel rests on the seal 21 ensuring the seal between the two panels. The further the tongue 9 will go into the groove 8 the more one will tend towards its interlocking without play, this will have the effect of improving the tightness and the maintenance of the assembly.

The rigidity of the assembly is undoubted since the section 2 has a length corresponding to the width of the photovoltaic panel or panels installed. The said panels are thus maintained throughout their width by these said grooves and tongues conical and inclined.

The lower photovoltaic panel is held in its upper part by the panel located above. This is why the space 22 in FIG 7 is provided to be able to eo slip the panel in this space and thus by this action can leave the photovoltaic panel 26 held by the tongue 9 in the groove 8 without being forced to disassemble the other panels. The space 22 must be at least equal to the width of the tongue 9. 2931855 It '

FIG 6 illustrates the fitting of the profile 23 on the section 4 by clipping on concave portions by the convex portions. The small convex lugs 25 are inserted into the concave portion 17. s This profile 23 is designed to ensure the right and left lateral sealing on the photovoltaic installation on the roof, the part 24 designed to make the link with the shelters and thus ensure the tightness of the roof at each end of the installation. The other particularity of this section 23 is that it was invented to be ~ o nested on the section 4 for the left part as shown in FIG 6 but also on the section 5 FIG 5 which is found in the opposite position for the right side of the panel, which reduces manufacturing costs.

FIG 7 is a view that shows the principle of positioning and mounting photovoltaic panels on the roof shown at 29 by the frame. The linear section 3 is fixed on the frame. Said section 3 is a structure of a length necessary for the number of panels to install.

Each row of photovoltaic panel requires the presence in its width of this profile 3 at the bottom for maintaining said panel. The profile 3 was designed with a sufficient thickness so that the photovoltaic panel is distant from the roofing part this to 2s allow the housing of cables and junction boxes without having to build an additional structure which would have the effect of increasing installation costs. Thus one can directly install the profile 3 on a type of truss type farm in its width which alone will be a structure 3o for the installation of photovoltaic panels.

The linear section 2 has been designed to ensure the technical function of horizontal linear structure ensuring the spacing required for the provision of photovoltaic panels in the vertical direction while serving as support and maintenance said panels in the horizontal direction simply by interlocking .

Claims (1)

Claims1 Right lateral profiles 4 and left 5 of identical design of the photovoltaic frame, characterized in that these said sections are positioned along the direction of the slope of the roof and nesting by groove and tongue one inside the other in opposite directions for the roofing of the photovoltaic panels one after the other horizontally, in order to constitute the lateral sealing between them. 2 side profiles right 4 and left 5 identical according to claim 1 characterized in that an extrusion 13 allows the insertion of a screw for assembling the perpendicular sections 2 and 30 without machining these said lateral sections. These profiles 2 and 30 have an identical right and left machining at their end allowing assembly and fastening by screws 7 on the lateral sections. The fact that one of the lateral profiles 4 is in a direction opposite to the profile 5, does not affect the proper realization of this assembly. 3 Profile 2 characterized in that the shape keeps the lower panel on the portion covered by the upper panel while providing the possibility of removing said lower panel by sliding said panel in the empty portion 22 of the internal section 2 of the top panel without removing it. 4 Profile 2 according to claim 3 characterized in that while maintaining the rigidity of the entire panel the upper lower part of the photovoltaic panel is not overcome by an overflow of the profile and that to promote the cleaning and flow of rainwater since in the absence of overflow with respect to the external surface any dust or waste will not be blocked on the laminate. Profile 2 according to claim 3 and 4 characterized in that the conical tapered tongue 9 in its design and inclined orientation, facilitates an interlocking start and that as and when said nesting takes place in this groove 8, the lower part of the upper panel bears on the seal 21 and thus ensures the maintenance of the lower panel in its upper part and by the same the seal between the two panels. 6 Profile 2 according to claim 3,4 and 5 characterized in that the rigidity of the whole is undoubted since this said section 2 has a length corresponding to the width of the photovoltaic panel installed. The said panel is thus maintained throughout its width by the conical tapered tongue 9 which is inserted into the groove 8 of the profile 3 fixed to the frame. 7 Profile 23 characterized by the small convex pins coming to be inserted in the concave portion of the lateral profile of the photovoltaic panel. This profile is designed to ensure the right and left side sealing on the roof photovoltaic system, the inclined side part 24 has been designed to link with the abergements and thus ensure the watertightness of the roof at each end of the installation. 8 Profile 23 according to claim 7 characterized in that another feature of this profile is that it was designed to be fitted on the left side profile 4 but also on the right side profile 5 which is in an opposite position. section 23 is always in the position or the tongue 24 is oriented downwards. 9 linear profile 3 characterized in that its design allows to receive in groove 8 the tongue 9 of the profile 2 and thus by the assembly of the upper panel maintains the lower panel while keeping the possibility of disassembling said lower panel without removing the top panel. Linear section 2 according to claim 9, characterized in that it has been designed to ensure the technical function of horizontal linear structure ensuring the spacing required for the provision of photovoltaic panels in the vertical direction while serving as support and maintenance a these said panels in the horizontal direction simply by interlocking.