FR2959556A1 - Parallelepiped solar panel i.e. photovoltaic rigid solar panel, for use on roof structure of building, has support comprising fixation unit for fixing solar panel on inclined receiving structure, where support is provided with surface - Google Patents

Abstract

The panel has an aluminum support (5) provided with a surface for installing the panel on an inclined receiving structure. The support comprises a frame (7) on which a photovoltaic module (6) is fixed. The frame comprises two pairs of opposite sections e.g. side sections (9, 10) and upstream and downstream transverse sections (11, 12), extended transversely to direction of a slope at top and bottom sides of the slope. The support comprises a fixation unit i.e. longitudinal flap (11c2), for fixing the panel on the inclined receiving structure.

Description

The present invention relates to the field of rigid photovoltaic solar panels, intended to be reported on a sloping receiving structure, including a building roof structure. Photovoltaic solar panels consist of electric generators, constituting the basic units for photovoltaic solar installations. Most current photovoltaic solar panels comprise a photovoltaic solar module which is in the form of a rectangular rigid plate on which are distributed a plurality of photovoltaic cells 1 o interconnected electrically. These photovoltaic solar panels often still include a frame-shaped support, receiving the solar module for its installation on a receiving structure (usually on a slope). Depending on the demand, the panels are installed in the same plane, or with a slight overlap of the upstream edge of the panels by the downstream edge of the panels directly overlying in the direction of the slope. The mounting of the panels on the receiving structure generally requires suitable fastening inserts, for example in the form of profiles or rails interposed between the juxtaposed edges of two solar panels. However, the corresponding fasteners do not always offer the same level of quality and are often problematic. These fastening devices generally have a relatively complex structure and have a relatively high cost price. The mounting of the panels by means of such fasteners is in practice sometimes tedious, because of the number of operations required. And the use of these fasteners requires the manufacture and transport of additional parts. On the other hand, these current means do not always make it possible to guarantee optimum sealing between the solar panels juxtaposed. To overcome these drawbacks, the Applicant has developed a new solar panel structure which has the advantage of being able to quickly and tightly fasten with juxtaposed panels, both in the direction of the slope and transversally to the direction of the slope, this without requiring additional parts (except for a few fastening screws as described below). The solar panel according to the invention comprises for this purpose a support provided with a surface for its installation on a sloping receiving structure, and which support comprises a frame on which is attached a photovoltaic module, which frame comprises two pairs of shaped sections. (i) two lateral sections intended to extend in the direction of the slope, and (ii) two transverse sections, one downstream and the other upstream, intended to extend transversely to the direction of the slope. the slope, respectively on the lower side and on the top side of said slope. The two transverse sections comprise interlocking structures, complementary to one another and provided with sealing means, to allow their tight fitting with an identical solar panel directly above or underlying in the direction of the slope; and the two lateral sections comprise interlocking structures, complementary to each other and provided with sealing means, to enable their tight fitting with an identical solar panel directly juxtaposed transversely with respect to the direction of the slope. The support further comprises means for attachment to said sloping receiving structure. Such solar panels are easy and quick to install; in addition, effective sealing is obtained between the juxtaposed panels. According to a preferred embodiment, the interlocking structures of each pair of profiles comprise at least one set consisting of a tongue and a groove, complementary to one another, which tongue (s) and groove (s) each extend in a plane oriented (i) perpendicularly, or at least approximately perpendicular to, the plane of the solar panel, and (ii) parallel, or at least approximately parallel, to the axis of said profiles . In this case, the sealing means advantageously consist of attached joints (i) in the bottom of the groove or grooves, and / or (ii) at the free longitudinal edge of the tongue or tongues. Still in this case, for each pair of profiles, the interlocking structure of a first profile advantageously comprises one or more grooves opening upwards and / or one or more tabs projecting upwards, in the opposite direction. of the laying surface, and the interlocking structure of a second profile comprises one or grooves opening downwards and / or one or more tabs projecting downwards, in the direction of the laying surface, so that said second section of said panel is adapted to be attached to the first section of an identical solar panel, to ensure the tight fitting of their complementary structures. Other advantageous characteristics, which can be taken in combination or independently of one another, are presented below: the downstream profile comprises, at a distance from the laying surface, a projecting longitudinal flap whose underside is provided with an interlocking structure, and the upstream profile comprises an upper face provided with a complementary interlocking structure, said upper face of the upstream profile being intended to be covered by said longitudinal flap of the downstream profile of a directly overlying panel in the direction of the slope, to ensure their sealing tightness; - The interlocking structure of a first lateral section comprises an upper flap, located at a distance from the laying surface, whose lower face is extended by at least two longitudinal flaps to the square, and the interlocking structure of a second lateral section comprises a lower flap, located on the side of the laying surface, the upper face of which is extended by at least two longitudinal flaps to the square, which longitudinal flaps extend parallel and at a distance one of the other to each form at least one tongue / groove assembly, complementary to each other; in this case, the interlocking structures of the lateral sections advantageously comprise each three longitudinal flaps, arranged parallel and at a distance from one another, to define two complementary grooves; - The transverse profiles further comprise abutment structures complementary to one another, to ensure the locking, in a direction perpendicular to its plane, said panel with an identical panel directly above or underlying, when are placed on the receiving structure; the abutment structures then advantageously each comprise a shoulder oriented parallel, or at least approximately parallel to, the plane of said panel, which shoulders of two juxtaposed panels are intended to bear against one another. In addition, the abutment structure of the downstream section comprises (i) a shoulder, oriented away from the laying surface, and (ii) a chamfer, the slope of which is oriented on the side of said laying surface; and the abutment structure of the upstream profile comprises (i) a shoulder, oriented towards said laying surface, and (ii) a chamfer, whose slope is oriented opposite said laying surface. In addition, the transverse profiles comprise an outer face, oriented perpendicular to the plane of said panel, and the abutment structures are provided at said outer faces intended to come into view during installation; - The means for fixing the support on the sloping receiving structure are formed at its upstream profile; in this case, the upstream section advantageously comprises, on the side of the laying surface, a longitudinal flap provided with orifices for its attachment to the receiving structure, and the downstream profile advantageously comprises, at its lower face, a recess to allow the housing of the fixing means of a directly underlying solar panel; - The frame of the support is extended by a bottom panel whose lower face forms the laying surface, so as to constitute a rigid carrier assembly.

The invention will be further illustrated, without being limited in any way, by the following description of a particular embodiment given solely by way of example, with reference to the appended drawings in which: FIG. 1 is a general view, in perspective, a set of solar panels according to the invention being laid on a sloping receiving structure; - Figure 2 is a view of a detail of Figure 1, showing the assembly of two panels juxtaposed in the direction of the slope; - Figure 3 is a top view of a solar panel according to Figures 1 and 2, - Figure 4 is a sectional view of Figure 3, here according to a transverse sectional plane passing through the side sections; - Figure 5 is also a sectional view of Figure 3, in a longitudinal sectional plane passing through the transverse sections; - Figure 6 is a section passing through two side sections associated with two solar panels juxtaposed transversely to the direction of the slope; - Figure 7 is a section passing through two associated transverse sections, two solar panels juxtaposed in the direction of the slope.

The sloping receiving structure 1, shown in FIG. 1, consists, for example, of a building roof; it comprises a frame 2, formed for example of longitudinal members (defining the slope of said receiving structure 1) connected by horizontal purlins. To simplify the rest of the description, the sides oriented towards the 1 o high and low ends of the slope are designated respectively by the terms "upstream" and "downstream". This frame 2 is covered, wholly or partially, by rigid photovoltaic solar panels 3 according to the invention. The photovoltaic solar panels 3 are here installed directly on the frame 2. They can also be fixed on a dedicated support structure, for example rafters. The solar panels 3 are each in the form of a rectangular or rectangular parallelepiped plate, whose surface is for example of the order of 1 m2. They each still have a general plane 20 extending along their large surface. One of the solar panels 3 is illustrated in detail in Figures 3 to 5. The other solar panels 3 of Figure 1 have an identical structure. This solar panel 3 comprises a support 5 on which is reported a photovoltaic module 6. The photovoltaic module 6 here consists of a rigid panel, a few millimeters or a few tens of millimeters thick, incorporating a set of photovoltaic cells. This module 6 is delimited by a square or rectangular outline, comprising an upstream edge 6a, a downstream edge 6b and two side edges 6c 30 (Figure 3). The support 5 of the solar module 6 consists of a general tray or dish structure, of parallelepipedal general shape and open on top to receive the photovoltaic module 6. This support 5 is made of any suitable material, for example a plastic material or a metallic material (aluminum for example).

The support 5 consists of (i) a square or rectangular frame 7, on which the photovoltaic module 6 is attached, and (ii) a bottom panel 8, extending said frame 7 and whose lower face 8a forms the laying surface on the receiving structure 1.

To simplify the following description, the parts of the panel 3 located towards the bottom panel 8 are designated as "lower", and the parts of the panel 3 located opposite said bottom panel 8 are designated as "superior". The support frame 7 comprises two pairs of facing profiles, to 1 o know: (i) two lateral sections 9 and 10, intended to extend in the direction of the slope of the support structure 1, and (ii) two profiles transverse, one upstream 11 and the other downstream 12, intended to extend transversely to the direction of the slope, respectively the high side 15 and the low side of the slope. The transverse sections 11, 12 and the bottom panel 8 together constitute a one-piece piece; the two lateral sections 9 and 10 are in turn attached to this one-piece piece 8, 11, 12, for example by welding or gluing. The support 5 is provided with orifices 13 to allow the ventilation of its internal volume, and also to allow the passage of electrical cables from the modules 6. These orifices 13 are for example formed at the level of the transverse profiles 11 and 12. 25 The bottom panel 8 makes the solar panel 3 self-supporting. The support 5 also comprises reinforcing profiles 14, here two in number, reported in the interior volume of the photovoltaic panel 3. These reinforcing profiles 14 are arranged parallel to each other 30 and to the lateral sections 9 and 10; they extend from the bottom 8, have an upper edge extending just below the module 6, and connect the transverse sections 11 and 12 opposite. These reinforcing profiles 14 are advantageously provided with orifices 14a, distributed along their length, for ventilation and possibly for the passage of electrical cables.

The structure of the profiles 9, 10, 11 and 12 constituting the frame 7 allows the mounting of the solar panels 3 in the same plane, without the need for an additional fixing device. For this, the lateral sections 9, 10 and the transverse profiles 11, 12 comprise interlocking structures, complementary to one another and provided with sealing means, to allow their tight fitting with an identical solar panel directly. juxtaposed. The two lateral sections 9, 10 are described in more detail below, in connection with FIG. 4. A first lateral section 9, located on the right in the figure, consists of an upper flap 9a, located at a distance from the laying surface 8a and parallel to the plane of the solar panel 3, whose underside is extended here by three longitudinal flaps to the square, namely: - an inner flap 9b, the upper edge, extending the edge inside the upper flap 9a, has a longitudinal groove 9b1 sealingly receiving one of the side edges 6c of the photovoltaic module 6, - an intermediate flap 9c, in the middle of the width of the upper flap 9a, and 20 - an outer flap 9d remote from said module 6 and extending the outer edge of the upper flap 9a. The parallel longitudinal flaps 9b, 9c and 9d are thus projecting downwards; and as detailed below, the intermediate longitudinal louvers 9c and 9d outer are intended to form interlocking tabs. These facing flaps 9b, 9c and 9d extend parallel and at a distance from each other, to define between them two grooves opening downwards, namely: an inner groove 9e between the inner longitudinal flaps 9b and intermediate 9c, and 30 - an outer groove 9f, between the intermediate longitudinal flaps 9c and outer 9d. On the left in FIG. 4, the second lateral profile 10 is constituted by a lower flap 10a, situated on the side of the laying surface 8a and parallel to the plane of the solar panel 3, the upper face of which is also extended by three longitudinal flaps to the square, namely: - an inner flap 10b, the upper edge has a groove 10b1 open facing the groove 9b1 of the first lateral section 9, so as to receive sealingly the other side edge 6c photovoltaic module 6, and whose lower edge extends the inner edge of the lower flap 10a, - an intermediate flap 10g, in the middle of the width of the lower flap 10a, and - an outer flap 10d, remote from said module 6 and extending the outer edge of lower flap 10a. The longitudinal flaps facing 10b, 10c and 10d are projecting upwards; and as detailed below, the intermediate longitudinal flaps 10c and outer 10d are intended to form interlocking tabs. These flaps 10b, 10c and 10d extend parallel and at a distance from each other, to delimit between them two grooves opening upwards, namely: an inner groove 10e between the inner and intermediate flaps 10c, and an outer groove 10f between the intermediate and external flaps 10c. For each of these two lateral sections 9 and 10, the longitudinal flaps and the grooves that separate them extend in a plane oriented (i) perpendicularly, or at least approximately perpendicular, with respect to the general plane of the solar panel 3, and ii) parallel or at least approximately parallel to the axis (or the length) of the respective sections 9 and 10.

Sealing means are also provided at the two lateral sections 9 and 10, here in the form of seals 17 reported in the bottom of each of the grooves 9e, 9f, 10e and 10f. As indicated above, the interlocking structures of the two sections 9 and 10 are complementary, to allow tight fitting of two identical panels 3 juxtaposed laterally. The structure of the transverse sections 11 and 12 is described below in relation to FIG. 5; The upstream profile 11 comprises a generally rectangular section body delimited by a set of faces, namely an upper face 11a, a lower face 11b, an outer face 11c and an inner face 11d. The upper face 11a of this upstream section 11 is provided with an interlocking structure consisting of - a tongue Liai, projecting upwards, and - a groove 11a2, open upwards. This tongue liai and this groove 11 a2 each extend in a plane oriented (i) perpendicularly, or at least approximately perpendicularly, with respect to the plane of the solar panel 3, and (ii) parallel or at least approximately parallel, with respect to the axis (or the length) of the profile 11. The groove 11 a2 is located externally relative to the tongue liai. The outer face 11c comprises an abutment structure 11c1 consisting of (i) a shoulder 11c11, oriented towards the laying surface 8a, and (ii) a chamfer 11c12, whose slope is oriented opposite of said laying surface 8a. On the side of the lower face 11b, this outer face 11c also comprises a longitudinal flap 11c2 for fixing the panel 3 to the receiving structure 2. This longitudinal flap 11c2 extends in a plane oriented parallel to the general plane of the solar panel 3, in the extension of the bottom 8. It has a length corresponding to that of the upstream profile 11 associated (as shown in Figure 3). This longitudinal flap 11c2 is provided with a set of orifices 11c21 (here three in number) for fixing it by means of screws to the receiving structure 2 (FIG. 1). It can be seen that the inner face 11d of this upstream flap 11 is provided with a groove 11d1, in the upper part, in which the upstream edge 6a of the photovoltaic module 6 is attached and fixed in a sealed manner. In FIG. the through holes 13 of the upstream section 11, extending between the inner 11d and outer faces 11c, are still visible. The downstream profile 12 (on the left of FIG. 5) also comprises a generally rectangular section body delimited by a set of faces, namely an upper face 12a, a lower face 12b, an outer face 12c and an inner face 12d .

At its upper face 12a, this downstream profile 12 has a projecting longitudinal flap 12a1 extending parallel to the general plane of the solar panel 3. The lower face of this projecting flap 12a1 is provided with a nesting structure constituted here by - a tongue 12a11, projecting downwards, and - a groove 12a12, opening downwards. This tongue 12a11 and this groove 12a12 further extend each in a plane oriented (i) perpendicularly, or at least approximately perpendicularly, with respect to the plane of the solar panel 3, and (ii) parallel or at least approximately parallel, with respect to to the axis of the profile 12. The groove 12a12 is located externally relative to the tongue 12a11. The downstream edge of the upper flap 12a1 is tapered to avoid or limit shading on a downstream panel.

The outer face 12c has an abutment structure 12c1 consisting of (i) a shoulder 12c11, facing away from the laying surface 8a, and (ii) a chamfer 12c12, whose slope is oriented on the side of said laying surface 8a. The lower face 12b of this downstream profile 12 comprises a kind of longitudinal recess forming a housing 12b1 of rectangular section. As developed later in connection with FIG. 7, this housing 12b1 allows the recessing of the shutter 11c2 equipping the solar panel 3 directly underlying in the direction of the slope. The inner face 12d of the profile 12 comprises an upper groove 12d1 intended to receive, in a sealed manner, the downstream edge 6b of the photovoltaic module 6. There are also the through holes 13 which are formed in the downstream profile 12, opening at its inner faces 12d and outer 12c.

Again, seals 17 are reported in the bottom of the grooves 11 a2 of the upstream profile 11 and 12a12 of the downstream profile 12 to seal during the joining of two panels 3 juxtaposed. As indicated above, the interlocking structures of the two sections 11 and 12 are complementary, to allow tight fitting of two identical panels 3 juxtaposed in the direction of the slope.

The height of the downstream profile 12 (defined by the distance between its upper face 12a and the lower face 8a of the bottom element 8) is greater than the height of the upstream profile 11 (defined by the distance between its upper face 11a and the lower face 8a of the bottom element 8). In addition, the groove 11d1 of the upstream profile 11 is at a lower height relative to the groove 12d1 of the downstream profile 12; this offset allows an inclined mounting of the photovoltaic module 6 in the panel 3, with an upward slope from upstream to downstream relative to the bottom 8 opposite. The lateral sections 9 and 10 are positioned in an inclined manner on the panel 3, with a slope corresponding to that of the photovoltaic module 6, so that their longitudinal grooves 9b1 and 10b1 suitably receive the lateral edges 6c of this module 6 The manufacture of each solar panel 3 consists here of implementing the following succession of steps: - the installation of a photovoltaic module 6 on the one-piece part 8, 11, 12 of the support 5, by sliding its upstream edges 6a and downstream 6b in the opposite grooves 11 d1 and 12d1 of the transverse profiles 11 and 12, then - the attachment of the two lateral sections 9 and 10 to the one-piece piece 8, 11 and 12, so that the grooves 9b1 and 10b1 of said lateral sections 9 and 10 receive the lateral edges 6c of the photovoltaic module 6. The particular structure of the photovoltaic panels 3 makes it possible to lay them in a particularly easy and effective manner on the structure of the photovoltaic module 3. This assembly is obtained by the positioning of a profile 9 or 12 of a panel 3, on the complementary profile 10 or 11 of an identical solar panel 3 already installed, to ensure the tight fitting of their complementary structures. This assembly is described in more detail below with reference to FIGS. 1, 2, 6 and 7. In practice, a first panel 3 is attached to the receiving structure 1, so that its laying surface 8a comes into position. support on the receiving structure 1. This first panel 3 is properly oriented, including its upstream profiles 11 and downstream 12 located respectively on the high and low side of the slope.

This first solar panel 3 is advantageously placed at the lower right corner of the part to be covered, so that its upstream profile 11 or its left lateral profile 10 can receive the complementary profile 12 or 9 of a solar panel 3 reported thereafter. As an illustration, this first solar panel is designated by the reference 3a in Figure 1. Once properly positioned, the solar panel 3 is locked in position by means of screws attached to its mounting flap 11 c2 (by through its orifices 11c21), and fixed in the support structure opposite. 1 o Then, the operator can report an additional solar panel 3, either juxtaposed transversely to the direction of the slope (corresponding to the panel designated by the reference 3b in Figure 1), or directly overlying in the direction of the slope (corresponding to the panel designated by the reference 3c in Figure 1). To transversely juxtapose the additional solar panel 3b, the latter is attached so that its straight section 9 comes to cover the left profile 10 of the panel 3a previously laid. The lateral sections 9 and 10, nested together directly and in a sealed manner, are shown in FIG. 6. It can be seen that the left lateral profile 10 of the first solar panel 3a is covered by the right lateral profile 9 of the second panel 3b, so that: - the intermediate flaps 9c and outer 9d of the second solar panel 3b are introduced over the entire height of the outer grooves 10f and inner 25 10e, respectively, of the first solar panel 3a, and simultaneously - the intermediate longitudinal flaps 10c and outside 10d of the first solar panel 3a are introduced on the height of the outer 9f and inner 9e grooves, respectively, of the second solar panel 3b. The profiles 9 and 10 (and therefore the panels 3a and 3b) are thus locked in spacing in a direction extending in the plane of said panels 3 and perpendicular to said profiles. The free end of the flaps 9c, 9d, 10c and 10d compresses the seals 17 housed in the bottom of the grooves 9e, 9f, 10e and 10f to obtain the desired tight fitting.

To juxtapose the overlying solar panel 3c, the latter is attached so that its downstream profile 12 comes to fit on the upstream profile 11 of the panel 3a previously laid. This interlocking is made slightly by force, by a suitable maneuvering of the panel 3c, so that: its projecting longitudinal flap 12a1 covers the upper face 11a of the upstream profile 11, the tongue 11a of this upstream profile 11 comes to be housed in the groove 12a12 of the downstream profile 12, - the tongue 12a11 of the downstream profile 12 comes to be housed in the groove 11 a2 of the upstream profile 11, and - the abutment structures 11c1 and 12c1 cooperate and lock with each other by contacting and resting on their shoulder 11 and 1 and 12c11 respectively.

Once associated, the upstream 11 and downstream 12 profiles cooperate tightly thanks to the presence of the seals 17 crushed by the ends of the tongues 11 a1 and 12a11 in the bottom of the associated grooves 11 a2 and 12a12, as illustrated in particular in FIG. 7. The profiles 11 and 12 are locked in spacing in a direction extending perpendicularly to their length and in the plane of the panels 3. They are also locked together in a direction perpendicular to the plane of the panels 3, once installed. on a reception structure 2. This lock ensures in particular an "anti-lifting" function, able to withstand winds of greater than 70 km / hour. Note that the chamfered surface 11c12 and 12c12 abutment structures 11c1 and 12c1 can limit friction during the operation of the second panel 3c causing the arrangement of the abutment structure 12c1 under the abutment structure 11 c1.

Moreover, still in FIG. 7, it can be seen that the through orifices 13 of the upstream 11 and downstream 12 profiles are arranged facing, coaxially or at least approximately coaxially with respect to each other. This arrangement of the through orifices 13 allows the ventilation of the interior space of the solar panels 3, by air path between them; it also allows the passage of electrical cables between the same solar panels 3. In Figure 7, we also note that the fixing flap 11 c2 of the first solar panel 3a is embedded in the housing 12b1 formed at the lower face 12b of the downstream profile 12 of the directly overlying solar panel 3c. The fixing of the panels 3 becomes invisible. The other solar panels 3 constituting the installation are reported successively, always in the same manner as described above, so that their profiles 9, 10, 11 and 12 cooperate together in a sealed engagement as shown in FIGS. 7. If necessary, the disassembly of the panels is carried out by removing the fastening screws flaps 1 1 c2, and by forcible removal.

Claims (1)

1.-parallelepiped solar panel comprising a support (5) provided with a surface (8a) for its installation on a sloping receiving structure (1), and which support (5) comprises a frame (7) on which a photovoltaic module (6) is attached, which frame (7) comprises two pairs of facing profiles, namely (i) two lateral sections (9, 10) intended to extend in the direction of the slope, and ii) two transverse profiles, one upstream (11) and the other downstream (12), intended to extend transversely in the direction of the slope, respectively on the upper side and the bottom side of said one slope, characterized in that said two transverse profiles (11, 12) comprise interlocking structures (11a1, 11a2; 12a11, 12a12) complementary to one another and provided with sealing means (17), to allow their tight fitting with a solar panel (3) identical directly 15 overlying or underlying in the direction of the slope , in that said two lateral profiles (9, 10) comprise interlocking structures (9c, 9d, 9e, 9f; 10g, 10d, 10e, 10f), complementary to each other and provided with sealing means (17), to allow their sealed engagement with an identical solar panel (3) directly 20 juxtaposed transversely to the direction of the slope, and in that said support (5) comprises means (11g2) for fixing it to said sloping receiving structure (1). 2. Solar panel according to claim 1, characterized in that the interlocking structures (9c, 9d, 9e, 9f, 10c, 10d, 10e, 10f, 11a1, 11a2, 12a11, 12a12) of each pair of profiles (9, 10; 11, 12) comprise at least one assembly consisting of a tongue (9c, 9d; 10g, 10d; 11a1; 12a11) and a groove (9e, 9f; 10e, 10f; a2; 12a12), complementary to one another, which tongue (s) and groove (s) each extend in a plane oriented (i) perpendicularly, or at least approximately perpendicular to, the plane of said panel solar (3), and (ii) parallel, or at least approximately parallel, with respect to the axis of said profiles (9, 10; 11, 12). 3. Solar panel according to claim 2, characterized in that the sealing means (17) consist of reported joints (i) in the bottom 35 of the groove or grooves (9e, 9f; 10e, 10f; 11a2 12a12) and / or (ii) at the free longitudinal edge of the tongue (s) (9d, 9d, 10d, 10d, 11a1, 12a11). 4. Solar panel according to any one of claims 2 or 3, characterized in that, for each pair of profiles (9, 10; 11, 12), the interlocking structure (10d, 10d, 10e, 10f; 11a, 11a2) of a first profile (10, 11) has one or more upwardly opening grooves (10e, 10f; 11a2) and / or one or more projecting tongues (10d, 10d, 11a1) the top, opposite the laying surface (8a), and the interlocking structure (9c, 9d, 9e, 9f; 12a11, 12a12) of a second section (9, 12) comprises one or more o grooves (9e, 9f; 12a12) opening downwards and / or one or more tongues (9c, 9d; 12a11) projecting downwards towards the laying surface (8a), so that said second section (9, 12) of said panel (3) is adapted to be attached to the first profile (10, 11) of an identical solar panel (3) to ensure the tight fitting of their complementary structures (9c, 9d, 9e, 9f, 10d, 10d, 10e, 10f, 11a, 11a2, 12a11, 12a12). 5. Solar panel according to any one of claims 1 to 4, characterized in that the downstream profile (12) comprises, at a distance from the laying surface (8a), a projecting longitudinal flap (12a1) whose underside is provided with an interlocking structure (12a11, 12a12), and in that the upstream profile (11) has an upper face (11a) provided with a complementary interlocking structure (11a, 11a2), said upper face (11a) of the upstream profile (11) being intended to be covered by said longitudinal flap (12a1) of the downstream profile (12) of a panel (3) directly overlying in the direction of the slope to ensure their waterproof fastening. 25 6. Solar panel according to any one of claims 1 to 5, characterized in that the interlocking structure (9c, 9d, 9e, 9f) of a first lateral section (9) comprises an upper flap (9a). located at a distance from the laying surface (8a), the underside of which is extended by at least two longitudinal brackets (9c, 9d), and that the interlocking structure (10d, 10d, 10e, 10f) of a second lateral profile (10) comprises a lower flap (10a), situated on the side of the laying surface (8a), the upper face of which is extended by at least two longitudinal flaps at right angle ( 10d, 10d), which longitudinal flaps (10d, 10d) extend parallel and at a distance from each other to each form at least one set of tongues / grooves (9c, 9d, 9e, 9f; 10c, 10d, 10c , 10f), complementary to each other. 7. Solar panel according to claim 6, characterized in that the interlocking structures (9c, 9d, 9e, 9f, 10g, 10d, 10e, 10f) of the lateral sections (9, 10) each comprise three longitudinal flaps ( 9b, 9c, 9d, 10b, 10c, 10d) arranged parallel and at a distance from each other, to define two complementary grooves (9e, 9f, 10e, 10f). 8. Solar panel according to any one of claims 1 to 7, characterized in that the transverse profiles (11, 12) further comprise 1 o abutment structures (11c1, 12c1) complementary to each other to ensure the locking of said panel (3), in a direction perpendicular to its plane, with a panel (3) identical directly above or underlying, when placed on a receiving structure (1). 9. Solar panel according to claim 8, characterized in that the abutment structures (11c1, 12c1) each comprise a shoulder (11c11, 12c11) oriented parallel to, or at least approximately parallel to, the plane of said panel , which shoulders (11 ç11, 12c11) of two juxtaposed panels (11 ç1, 12c1) are intended to bear against one another, and in that the abutment structure (12c1) of the downstream profile (12) Comprises (i) a shoulder (12c11) facing away from the laying surface (8a), and (ii) a chamfer (12c12) whose slope is oriented on the side of said laying surface (8a), and in that the abutment structure (11c1) of the upstream profile (11) comprises (i) a shoulder (11c11) facing said laying surface (8a), and (ii) a chamfer (12c12), the slope is oriented opposite to said laying surface (8a). 10. Solar panel according to any one of claims 1 to 9, characterized in that the frame (7) of the support (5) is extended by a bottom panel (8), the lower face (8a) forms the laying surface.