FR3016686A1 - PHOTOVOLTAIC POWER STATION USING PHOTOVOLTAIC PANELS SUPPORTED BY FLOATING MEANS USING A CABLE ASSEMBLY - Google Patents

Abstract

The invention relates to a photovoltaic power plant, of the type employing photovoltaic panels (PV) supported by support means, characterized in that the means comprise: at least two attachment points (100) delimiting between them a line ( L) photovoltaic panels; - For each line (L) of photovoltaic panels, at least two support cables (20), (21) connected to the attachment points (100) and extending between them; for each photovoltaic panel (PV), at least one connecting piece (4) with each support cable (20), (21).

Description

Photovoltaic plant using photovoltaic panels supported by floating means using a set of cables. The field of the invention is that of the design and manufacture of equipment used for the production of energy by photovoltaic means. More specifically, the invention relates to the design and manufacture of a floating assembly forming a support for a plurality of photovoltaic panels. It is now conventional to produce electrical energy by photovoltaic means. Over the years, many solutions have been proposed to install photovoltaic panels on a site, as well as to mechanically and electrically connect the panels together. The configuration of the sites on which the photovoltaic panels are implanted may be of different types. A widespread configuration is that corresponding to the implementation on the roof of photovoltaic panels, whether the roof is inclined or not. While the mounting of photovoltaic panels on individual house roofs has experienced a certain growth, it has become economically more advantageous to use roofs of professional and / or collective sites, such as roofs of buildings, roofs of houses, and buildings. hangar, factory roofs ... Indeed, the available surfaces are significantly more important, providing a renewed interest in the economic plan. The trend is now to seek to implement photovoltaic panels on relatively large surfaces, to create photovoltaic power plants. In this context, in addition to the roof installations, other configurations of photovoltaic panel installations are exploited, mainly with regard to: - photovoltaic plants on the ground; - floating photovoltaic power plants; The invention relates preferentially, but not exclusively, to floating photovoltaic power plants. With regard to these floating photovoltaic power plants, numerous techniques have been proposed for, on the one hand, providing floating means adapted to photovoltaic panels and, on the other hand, for maintaining the photovoltaic panels in an inclined position (this with a view to position the panels in an optimal orientation with respect to the sun's rays, which tends to improve the efficiency of the photovoltaic panels).

Thus, according to a widespread technique, frames are used forming each support of a photovoltaic panel, these frames to be then positioned in a predetermined orientation and fixed on a frame. Conventionally, the frames are made of plastic and the frame 15 is a mechanically welded assembly or assembled by many pieces of hardware. Such a design of the frames and associated chassis causes many drawbacks among which: assembly and assembly operations are long and tedious; the manufacture of different parts generates a relatively high cost, whose profitability is long to achieve; power plants use a large number of metal parts, of course subject to problems related to corrosion; the recyclability rate of the various parts constituting the power plant is relatively low. To overcome these disadvantages, it has been proposed a support assembly 30 of photovoltaic panels, comprising: - a frame formed by the assembly of two pairs of profiles, the frame having a structure adapted to ensure the flotation of the assembly; means for presenting and maintaining in inclined position the photovoltaic panels comprising an extension piece. The extension piece is a piece of plastic material intended to snap onto one of the support profiles of the frame. On the other supporting section of the frame, a curtain also made of plastic material also snaps onto the corresponding profile, this ensuring the maintenance of the frame on this profile. Furthermore, the frame is constituted by the assembly of sections of 10 plastic or extruded composite. It follows from such a technique that all the parts can be made of plastic or composite, to overcome the corrosion problems encountered with the solutions of the prior art. In addition, the parts can be designed to be mass-produced by molding or extrusion techniques, thereby significantly reducing the cost of the parts and, consequently, that of the panel support assembly. PV. However, the realization of the support assembly still involves the manufacture of a number of separate parts. Such a technique also involves assembly and assembly operations which remain relatively long and tedious. In particular, the realization of the frames involves assembly operations profiles between them which must be carried out carefully to achieve sealed connections ensuring the flotation of the frame. The invention therefore aims to overcome the disadvantages of the prior art. More specifically, the invention aims to provide a photovoltaic power plant, which can be mounted and deployed more simply, faster and less expensive than the techniques of the prior art. The invention also aims to provide such a plant that can be mounted on a water surface that can be made to know periods of agitation without risking degrade the support means of the photovoltaic plant. These objectives, as well as others which will appear later, are achieved thanks to the invention which has for object a photovoltaic power plant, of the type implementing photovoltaic panels supported by support means, characterized in that the support means comprise: at least two attachment points delimiting between them a line of photovoltaic panels; - For each line of photovoltaic panels, at least two support cables connected to the attachment points and extending between them; for each photovoltaic panel, at least one connecting piece with each support cable.

Thus, as will become clearer later, the invention makes it possible to install a photovoltaic power plant in a very simple and very fast manner. In fact, according to the principle of the invention, it suffices to tension a pair of cables which will act as structural elements on which the photovoltaic panels are fixed. The cables therefore have the primary function of carrying the photovoltaic panels. In addition, the number of specific parts of the plant is significantly reduced, to reduce manufacturing costs and therefore that of the plant. It is also noted that no prior assembly to the installation is necessary (unlike solutions using floor frames or floating frames implemented in certain techniques of the prior art). According to a preferred solution to floating photovoltaic power plants, the support means are floating means comprising: at least two primary lines delimiting between them a field of photovoltaic panels; - At least two support cables each connected to the primary lines by the attachment points and extending transversely between them. In this case, the primary lines advantageously comprise at least one primary cable carried stretched by perimeter floats. The choice of the implementation of cables also for the primary lines contributes to the simplification of the plant and also the corresponding assembly operations. In addition, the perimeter floats may be quite standard floats and therefore inexpensive. According to a preferred embodiment, for each line of photovoltaic panels, the support cables comprise a bottom cable in a low position and an upper cable in a high position, the support cables being offset with respect to one another so support the photovoltaic panels in an inclined way. According to a preferred embodiment of a plant according to the invention in a floating plant configuration, the floating means comprise a plurality of intermediate floats coupled to the support cables and distributed so that each photovoltaic panel is flanked by a pair of intermediate floats. According to a preferred solution, the floating plant comprises, for each line of photovoltaic panels, means spacers secondary cables between them. Thus, it is ensured that the spacing between the cables over the entire width of the panel field between the primary lines is kept constant, or nearly so. This constant spacing contributes to guaranteeing a satisfactory connection with the photovoltaic panels, particularly with regard to maintaining the panels in position with the desired inclination. In this case, the spacer means are advantageously integrated with the intermediate float. Clearly, it thus implements a single piece performing both functions, that of contributing to the flotation of the assembly and that contributing to the maintenance, through the secondary cables, of the inclined position with the desired angle of the panels PV. According to a particular embodiment, the intermediate floats each comprise a body having: - an upper notch for accommodating the upper cable; a lower notch for accommodating the lower cable. Advantageously, the intermediate floats take the form of floating poles.

Such floating posts allow to obtain floats with a small footprint as it will appear more clearly later. According to a preferred solution, for each line of photovoltaic panels, at least one stabilizing cable extends parallel to the support cables, the intermediate floats having at least one third slot forming a housing for the stabilizing cable. Advantageously, the intermediate floats have a main body and a wing extending from the main body and having the lower and upper notches, the wing having a width, seen from the side, lower than that of the main body. In such an assembly, the wing is the part of the floating pole (also constituting the spacer) which is placed between two photovoltaic panels to support the secondary cables. Consequently, being of reduced width relative to the body of the floating column, the photovoltaic panels can be brought closer to one another and thus create a photovoltaic power plant which optimally exploits the surface of the water body. corresponding. Other features and advantages of the invention will emerge more clearly on reading the following description of a preferred embodiment of the invention, given as a simple illustrative and nonlimiting example, and the appended drawings among which: FIG. 1 is an overall view of a photovoltaic power plant according to the invention; Figure 2 is a detail view of a photovoltaic power plant according to the invention, illustrating the mounting of photovoltaic panels and intermediate floats; Figures 3 and 4 schematically illustrate an intermediate float of a photovoltaic power plant according to the invention, seen respectively side and front; Figures 5 and 6 including schematic representations of the assembly of photovoltaic panels and intermediate floats, respectively viewed from the side and from below; Figures 7 to 9 schematically illustrate a connecting piece of a photovoltaic panel with a cable. As shown in FIG. 1, a photovoltaic power plant according to the invention implements a plurality of photovoltaic panels PV supported by support means, these comprising: at least two support cables 20, 21 each connected to two points latching 100 and extending between these attachment points, a line L of photovoltaic panels corresponding to a pair of support cables 20, 21; 20 for each photovoltaic panel, at least connecting piece (described in more detail below) with each support cable. In the context of a plant mounted on the ground or roof of a building, the attachment points may be provided on poles 25 positioned at the ends of the photovoltaic panel lines. the cables can be stretched between these posts (for example in the case of a roof installation for which it is preferable to avoid drilling and cause descents of loads, the posts then being fixed on the roof edges), or be supported by intermediate posts regularly distributed between the photovoltaic panels of the same line. In an application of the invention to a floating plant, the support means are floating means comprising: at least two primary lines 1, delimiting between them a field of PV photovoltaic panels; at least two support cables 20, 21, each connected to the primary lines by the attachment points and extending transversely between them. According to a preferred embodiment, the floating means further comprise a plurality of intermediate floats 3 distributed along the length of the secondary cables 20, 21 being coupled thereto. In addition, the intermediate floats are distributed in such a way that each photovoltaic panel is framed by a pair of intermediate floats 3 According to the present embodiment, the primary lines themselves are each constituted by a primary cable 11, carried stretched by perimeter floats 10.

As illustrated in FIG. 1, these perimeter floats are arranged at the angles of the photovoltaic panel field PV. In addition, these perimeter floats can be constituted by standard buoys, for example spherical. With reference to FIG. 2, floating means according to the principle of the invention are constituted as follows: the support cables consist of an upper cable 20 and a lower cable 21, the cable 20 occupying a high position relative to the low position occupied by the cable 21, the two secondary cables being offset with respect to each other along the length of the PV photovoltaic panels; for each photovoltaic panel, a series of connecting pieces 4, in this case four in number, described in more detail later, ensuring the connection and maintenance of the photovoltaic panels on the secondary cables. Of course, the connecting pieces ensure the maintenance of the photovoltaic panels on the one hand on the upper cable and, on the other hand, on the lower cable.

In addition, the relative positions of the upper cable and the lower cable, spaced apart from one another in height and offset relative to one another over the length of the photovoltaic panel, ensure the positioning of the photovoltaic panels PV with a predetermined angle of inclination, for example of the order of 12 °. As mentioned previously, each end of the support cables is coupled to one of the primary lines 1. The end of the lower cable 21 is thus fixed offset along the length of the primary line with respect to the end of the upper cable 20. This gives the offset on the length of PV photovoltaic panels. In other words, the secondary cables are spaced apart in a horizontal direction. For the height spacing of the two cables, the installation provides for the implementation of spacer means of the intermediate cables between them. According to the present embodiment, these spacer means are directly integrated on each of the intermediate floats 3 as is explained hereinafter. With reference to FIGS. 3 to 6, the intermediate floats 20 each comprise a body 30 having: at one of its ends, an upper notch 31; at the other of its ends, opposed longitudinally to the first, a lower notch 32. The notch 31 is said upper and the notch 32 is said lower, 25 in that the notch 31 is positioned at a higher height to that of the notch 32, being considered the intermediate float 3 resting horizontally on its base as shown in Figure 3. Note that the notch 31 has the following two parts: an introduction portion 310, substantially horizontal ; A housing portion 311, extending the insertion portion downwardly, forming, in the present embodiment, a right angle with the insertion portion.

The lower notch 32 is similarly formed, also with an insertion portion 320 and a housing portion 321. With such intermediate floats provided with spacer means, the upper cable 20 is housed in the notch 31 and the lower cable in the notch 32. As a result, once the photovoltaic panels installed on the cables through the connecting pieces 4, they occupy a position relative to the intermediate float such as that illustrated by the Figure 5, in which the photovoltaic panel 10 extends inclined. As illustrated in FIGS. 3 to 6, the intermediate floats take the form of floating poles having at one of their longitudinal ends the upper notch and at the other end of their ends the lower notch 32. 15 Further these floating posts have: a main body 300, essentially ensuring the floatation of the intermediate float; a wing 301, extending from the main body 300 and having a width, end view as shown in FIG. 4, smaller than that of the main body 300. Moreover, as is clear from the figures 2 and 6, the installation uses a pair of stabilizing cables 22 extending parallel to the secondary cables 20, 21. In this case, the main body 300 of the intermediate floats has at each of its ends a notch 33, 34 , each intended to house one of the stabilizing cables. Such a configuration of the cables and the intermediate floats makes it possible to arrange the intermediate floats between each photovoltaic panel so that the longitudinal axis of the intermediate floats is kept parallel to that of the photovoltaic panels.

It is noted that the cables in the respective notches can be maintained by additional systems, such as valves and / or retaining screws. Intermediate floats can also carry, all or only some of them, a 35 electrical or electronic junction box, ensuring a connection between the photovoltaic panels. The intermediate floats are plastic or composite parts, made for example by thermoforming, or roto-molding, or extrusion, or by blowing. With reference to FIGS. 6 to 9, the connecting pieces 4 connecting and holding the photovoltaic panels on the secondary cables 20, 21 are described below. These connecting pieces, as already mentioned above, are in number four, or a pair of connecting pieces for each secondary cable. The connecting pieces are mounted on the longitudinal edges of the photovoltaic panels, either directly on the glass part of the photovoltaic panel, or on a metal frame surrounding the glass part of the photovoltaic panel.

In any case, the connecting pieces can each take a shape according to the principle illustrated in FIGS. 7 to 9. As can be seen in these figures, the connecting pieces comprise a housing body 40 from which extends a fixing lug 41 forming with the bottom 401 of the housing a clamp 25 intended to be clipped onto the edge of the photovoltaic panel as shown in FIG. 8. In addition, the housing has, on the opposite side to the bracket , a pair of notches 42 in which a secondary cable 20, 21 is intended to be housed as shown in FIG. 7.

In addition, inside the housing 40, between the notches 42, is formed a tab 43 having a tip-shaped end 430, under which the secondary cable, 20, 21 is intended to extend, the tab contributing thus to ensure the maintenance of the corresponding cable inside the housing and in the notches.

Claims (10)

REVENDICATIONS1. Photovoltaic plant, of the type employing photovoltaic panels (PV) supported by support means, characterized in that the support means comprise: at least two attachment points (100) delimiting between them a line (L) of panels photovoltaic; - For each line (L) of photovoltaic panels, at least two support cables (20), (21) connected to the attachment points (100) and extending between them; for each photovoltaic panel (PV), at least one connecting piece (4) with each support cable (20), (21). 2. Photovoltaic plant according to claim 1, characterized in that the support means are floating means comprising: - at least two primary lines (1) delimiting between them a field of photovoltaic panels (PV); - At least two support cables (20), (21) each connected to the primary lines (1) by the attachment points (100) and extending transversely between them. 3. Photovoltaic plant according to claim 2, characterized in that the primary lines (1) comprise at least one primary cable (11) carried stretched by perimeter floats (10). 4. Photovoltaic plant according to claim 1, characterized in that for each line (L) of photovoltaic panels, the support cables (20), (21) comprise a lower cable (21) in the lower position and an upper cable (20). in the high position, the support cables (20), (21) being offset relative to each other so as to support the photovoltaic panels in an inclined manner. 5. Photovoltaic plant according to any one of claims 2 to 4, characterized in that the floating means comprise a plurality of intermediate floats (3) coupled to the support cables (20), (21) and distributed so that each panel Photovoltaic (PV) is framed by a pair of intermediate floats (3). 10 6. Photovoltaic plant according to any one of claims 2 to 5, characterized in that it comprises, for each line (L) of photovoltaic panels (PV), spacer means of the support cables (20), (21) between them. 7. Photovoltaic plant according to claim 6, characterized in that the spacer means are integrated in the intermediate floats (3). 8. photovoltaic plant according to claims 6 and 7, characterized in that the intermediate floats (3) each comprise a body (30) having: - at least one upper slot (31) for accommodating the upper cable (20); At least one lower notch (32) for accommodating the lower cable (21). 9. Photovoltaic plant according to claim 8, characterized in that, for each line (L) of photovoltaic panels (PV), at least one stabilizing cable (22) extends parallel to the support cables (20), (21) , the intermediate floats (3) having at least one third notch (33), (34) forming a housing for the stabilizing cable (22). 10. Photovoltaic plant according to claims 8 and 9, characterized in that the intermediate floats (3) have a main body (300) and a flange (301) extending from the main body (300) and having the lower notches (32) and upper (31), the wing (301) having a width, viewed from the side, lower than that of the main body (300).