FR2933432A1 - Flat solar panels installing method for horizontal roof of building, involves arranging panels one beside other so that roof is partially covered and panels arranged in side by side manner, share one support, and fixing panels with supports - Google Patents

Abstract

The method involves placing solar panel supports (43) that are adapted for being ballasted and for joining a set of flat solar panels (44) by fixation, on a horizontal roof of a building i.e. edifice. The solar panel supports are ballasted. The solar panels are arranged one beside the other such that roof is partially covered, each solar panel is supported by two different supports and the solar panels arranged in a side by side manner, share one support. The solar panels are fixed with the supports. An independent claim is also included for a support system for roof solar panels, comprising an isolated support.

Description

The present invention relates to the installation of solar panels on the roof of buildings. More particularly, the present invention relates to the installation of solar panels on a horizontal roof of a building. A horizontal roof is a roof with a slope between 0% and 5%. Generally, the roofs of buildings are made according to the diagram shown in Figure 1. The roofs have several layers, each fulfilling a particular technical function of the building. Thus, we can see in Figure 1 a first layer 10 representing the concrete slab of the roof. On this concrete slab, there is a layer 11 sealing. This sealing layer is responsible for protecting the concrete slab from moisture caused by climatic conditions, such as rain. Above this sealing layer, there is a thermal insulation layer 12. This thermal insulation layer is responsible for regulating heat flows between the building and the outside. Conventionally, this insulator is made of extruded polystyrene. Extruded polystyrene, like most thermal insulators, is sensitive to ultraviolet rays. Above the thermal insulation layer, there is a ballast layer 13. This ballast layer has two functions. The first is to keep the thermal insulation layer 12 in contact with the layer directly below. The second function of the weighting layer 13 is to protect the layers directly below, thus the thermal insulation layer 12 of the ultraviolet rays. In general, the ballast layer 13 is a layer of gravel. Recently, with a view to achieving energy savings, it has been proposed to integrate solar panels into the structure of the roof of buildings.

Solar panels make it possible to produce electrical energy for free. This energy can be consumed in the building, or be injected into an electricity distribution network. However, the integration of the solar panels must be done either upstream of the building design, or by modifying the structure of the roof by fixing means for supporting the panels, such as fixing rails. Thus, for old buildings the integration of solar panels involves the modification of the already existing structure. However, the roofs of the buildings are made so as to withstand the wear of time. Thus, modifying the structure involves a high cost which is not necessary from the point of view of the lifetime of this structure. In addition, roof insulation layers constitute a high cost in the construction of buildings. Thus, changing the roof structure of a building can be a very high cost that can discourage the installation of solar panels. The present invention improves the situation by providing a method and a support system for the installation of solar panels, not requiring modification of the roof structure of the building on which they are installed. For this purpose, the present invention provides a method of installing a set of solar panels on a horizontal roof of a building. This method comprises the steps of: providing on the roof supports adapted to be ballasted and for joining a plurality of solar panels together by fixing; to ballast the supports; arranging the solar panels of the assembly adjacent each other so as to cover at least part of the roof, so that each solar panel is supported by at least two separate supports, and so that two panels side by side solar cells share at least one support; and to fix the solar panels to the supports. The supports arranged to receive the solar panels are supports that can be weighted either before installation on the roof or after installation. In order to ballast these supports, it will be possible to use various materials. For example, it will be possible to use discs of metal or cement, gravel, sand, or any other material allowing such ballasting. In particular, we will take care to adapt the weight of the weights according to the weight of the solar panels, their disposition and the climatic conditions. In fact, the solar panels must in particular be able to withstand the tearing by the wind. Thus, with the present invention it is possible to install solar panels on a roof without affecting the structure thereof. In particular, there is no operation deteriorating a possible thermal insulation layer of the roof, or a possible sealing layer may be below the thermal insulation layer. In this case we will also take care to adapt the ballast so as not to damage the thermal insulation layer with too much weight. In addition, with the present invention the solar panels have a technical function to the building. Indeed, the solar panels make it possible, for example, to reinforce the protection of the thermal insulation layer with ultraviolet rays. Thus, with the method of installing solar panels according to the invention, it is possible to install solar panels without changing the structure of the roof of the building, while performing certain technical functions of the building. This method makes it possible to have solar panels, with or without a frame, with their industrially designed supports by fulfilling a technical function of the building, substituting the panels for a building equipment. It will therefore be understood that this process may be eligible for the premium integration of solar panels to the frame offered in France. When the roof has a layer of ballast material disposed over another roofing layer, and the ballast material can be removed for recovery and to ballast the supports, the steps of: at least part of the weighting material of the roof; arranging the supports on the insulation layer and / or on the roof layer disposed beneath the weighting layer; and weigh the supports with the weighting material taken.

In this way, we reuse a material already present on the site of installation of solar panels to ballast the supports. It is therefore avoided to provide specific materials for the ballasting of the supports. In embodiments of the method, the roofing layer disposed below the ballast layer is a thermal insulation layer of the roof. In addition, the panel supports are arranged directly on the insulation layer, after completely removing the ballast material. Thus, the supports of the solar panels are arranged directly on the thermal insulation layer and ensure, with solar panels ballasting of the thermal insulation layer. The thermal insulation layer may consist of an extruded polystyrene layer. However, it may also consist of other types of thermal insulation known in the field of construction. The ballast material constituting the layer disposed above the insulation layer may be gravel or other types of ballast known in the field of building.

Thus, in embodiments of the method according to the invention, the solar panels are arranged on the supports so as to provide a protection of the thermal insulation layer against the sun's rays. The present invention also provides a support system for solar roof panels comprising a plurality of point supports for solar panel. Each support is adapted to receive a weighting means. In addition, each support comprises fixing means for solar panel, these fixing means further allowing to join together at least two solar panels. This support system makes it possible to install solar panels without fixing them to the roof. Indeed, fixing the panels to the roof would require to change the structure of the roof, for example by drilling holes insulation and sealing to screw the solar panels on the concrete slab. In addition, the media can be transported easily. Indeed, it can be expected to ballast at the last moment on the site of installation of solar panels. Thus, they are transported empty, simplifying their transport on site, and their handling by workers. Advantageously, the system supports have a reduced size, facilitating their transport and handling. Thus, the term supports supports such that the contact surface between a support and the solar panel that it supports, in combination with other media, is small relative to the total area of the panel. In one embodiment, a solar panel support includes a housing defining an open chamber. In a variant, this support further comprises means for closing the chamber. Thus, the weighting material of the supports can be protected from, for example, bad weather.

In a particular embodiment, the weightable supports according to the invention comprise a screw rod for clamping a solar panel between the support and a clamping plate by means of a bolt.

In another embodiment of the solar panel mountable support according to the invention, provision may be made for the support to comprise a cover for covering the material with which the support has been weighted. On this cover, one can provide means for stapling a solar panel. It is also possible to provide other fastening means such as a hook, a tab, a nut, or other. In this embodiment, it can be provided that the body of the support is cylindrical and that it comprises, as the cover, a thread to allow a screwing of the cover on the body of the support. One can also provide a means of stapling the cover on the body of the support. Of course, in this case, it is the cover that is in contact with the solar panel. In addition, stapling the solar panels on the support simplifies the installation of solar panels. In the weightable supports according to the present invention, it is possible to provide means enabling them to be adjustable in height. In fact, depending on the configuration of the roof on which the solar panels are laid, and depending on the geographical position of the building on which the solar panels are placed, it may be necessary to adjust the orientation of the solar panels with respect to the solar panels. position of the sun. Similarly, there can be provided a hinge-type connection between a panel support plate and the housing comprising the ballast means, thus allowing an angular adjustment of the positioning of the solar panel relative to the supports. In a particular embodiment, this articulation type link is a ball joint. The support according to the present invention can be made in one piece and be made, for example by molding. The support may also be composed of several parts, for example each molded, which is made integral to form the support. The present invention also provides a solar panel system comprising at least one solar panel and a plurality of supports adapted to be ballasted and to join the solar panels together.

Other features and advantages of the invention will appear on examining the detailed description below, and the accompanying drawings in which, in addition to Figure 1 described above: - Figure 2 illustrates a general context of use of the present invention; - Figure 3 illustrates a plurality of solar panels arranged according to the method of the present invention on a thermal insulation layer of the roof of a building; FIG. 4 illustrates an embodiment of the method according to the invention; FIG. 5 illustrates an embodiment of a support for solar panels according to the present invention; FIG. 6 illustrates another embodiment of a support for solar panels according to the present invention, in which the support comprises a cover; FIG. 7 illustrates stapling means of the solar panels on a support for solar panels according to the present invention; - Figure 8 illustrates a support for solar panels according to the present invention adjustable in height; FIG. 9 illustrates a support for solar panels according to the present invention comprising means for angular adjustment of the positioning of the solar panel relative to the supports; - Figure 10 illustrates a support for solar panels comprising a cylindrical body, a plate, and a screw closure means. Referring to Figure 2, we can see solar panels 20 disposed on the roof 21 of a building 22. The solar panels are arranged on the roof by means of supports adapted to be ballasted 23. As can be seen on the 2, the solar panels 20 are fixed and joined together by means of the supports 23. The building 23 has, for example, an inverted insulation structure, comprising a concrete slab on which is disposed a sealing layer on which a thermal insulation layer is provided on which is disposed a ballast layer 24. According to the method according to the present invention, a part of the ballast layer has been replaced by the solar panels placed on the supports adapted to be ballasted. Of course, it is possible to graft the ballast layer and arrange the supports thereon. Referring to Figure 3, we can see solar panels 30 arranged on the roof of a building. The solar panels are arranged on supports adapted to be weighted 31. These supports rest directly on the thermal insulation layer 32 of the roof. Since the supports 31 are weighted with ballast material, the thermal insulation layer is kept in contact on the sealing layer 33. In addition, the solar panels 30 absorb the sun rays 34, especially the ultraviolet rays. which makes it possible to protect the sealing layer 32 from these ultraviolet rays. When ballasting the panels, care is taken to adapt the weight of the ballast to the conditions of tearing of the solar panels (weight of the panels, and the strength of the wind in the conditions of use of the solar panels), and to the consistency of the layer. insulation. This is to avoid any risk of moving the panels, and any risk of deterioration of the insulation layer. For example, under standard atmospheric conditions, for rectangular panels, each 140cm x 60cm in weight and 12kg in weight, and each supported by four supports adapted to be ballasted identically, between 2 and 10 kilograms of ballast are expected. for each support, approximately 8 to 40 kilograms of ballast per panel. These data are provided by way of example, the skilled person can adapt these data according to the weights and dimensions of the panels as well as climatic conditions (wind, in particular). It will also adapt this data according to the number of supports it uses. The installation method is described with reference to FIG. 4. In a first step, during a step S1, the surface 40 of a roof as described in FIG. 1 is discovered. For this purpose, the ballast material 41 for optionally storing it in a storage means 45. Once the thermal insulation layer 42 has been completely discovered, step S2 has supports adapted to be ballasted 43 on this insulating layer. This arrangement takes into account the geometric configuration of the panels. In the present example, they are rectangular dimensions of 140 cm x 60 cm. Thus, the supports are arranged in rectilinear rows R1, R2, R3. Adjacent rows are 60 cm apart. In each row, the supports are 142 cm apart. Thus, the panels will be supported by their corners. After being arranged, the supports are weighted with the material removed and stored in step S1.

One could also plan to add additional rows, or consider a different spacing. It will also be understood that each support does not support the same number of panels as the others. For example, some media are in contact with 1, 2, or 4 different panels. Then, during a step S3, there are solar panels on the supports 25 adapted to be weighted. Once arranged, the supports are weighted in step S4.

Finally, when the panels are placed, they are fixed to the supports during a step S4, for example, by stapling, screwing a clasping plate, or other. Once the panels attached to the supports, they are integral with each other. Of course, the rectilinear arrangement is presented by way of example, but other arrangements are possible. Similarly, different forms of panel are possible. Referring to Figure 5, there is described an embodiment of a support adapted to be ballasted. This support has a body which has an overall shape of hollow cylinder closed at one end and open at the other. Thus, the ballast support can receive a ballast material 51 such as gravel. A screw rod 52 extends from the bottom of the ballast support towards the open end in the direction of the axis of revolution of the cylinder. This screwing rod 52 makes it possible to grip a solar panel between a clamping plate 53 and the cylindrical body 50 of the support adapted to be ballasted by means of a bolt 54 which is screwed onto the rod 52. Thus, it is it is possible to arrange between the body of the support adapted to be ballasted and the clamping plate 53 a solar panel which is clamped to the support adapted to be ballasted by screwing bolt 54. Referring to FIG. embodiment of the support according to the present invention. This support has a body 60 of generally cylindrical shape closed at one end in a fixed manner and open to the other. On the open end, the body of the support comprises a cover 61 for covering a possible ballast material 62 disposed within the support.

The cover can close on the body of the support by means of a pivot type connection. Other means of closure can be envisaged, such as stapling, screwing, another type of connection, or the like. In order to fix solar panels on the support, means 5 are provided for stapling these panels. These stapling means are arranged on the cover 61. These stapling means are described with reference to FIG. 7. This figure represents a support adapted to be ballasted 70 for solar panels as described with reference to FIG. which can be seen stapling means 71 of solar panels. The support shown in FIG. 7 is adapted to support a corner of four different solar panels. Other configurations could be considered, for example, a configuration in which the support would be adapted to support two solar panels. The stapling means are arranged so as to form a cross. Each of the angles of the cross allows to receive an angle of a solar panel. In this example, the angles are straight. Solar panels are usually flat. An important point of their use, is the exposure of the solar panel to the sun's rays. Thus, when installing solar panels, it is necessary to choose the orientation of the panels according to the configuration of the roof on which the solar panels are placed. For this purpose, it may be useful to adjust the height of the supports on which the solar panels are based, or their orientation. FIG. 8 represents a weightable support for solar panels 80 comprising a closure cover 81 on which is arranged a telescopic arm 82 making it possible to adjust the height of a support plate 83 of solar panels. The plate 83 comprises stapling means 84 for fixing solar panels.

This type of support can be useful, for example, when the roof on which the solar panels are arranged is not quite flat. Thus, it is possible in places to correct a lack of flatness of the roof. The support adapted to be weighted for solar panels shown in Figure 9 allows to adjust the angular disposition between the plate 90 on which can be stapled the solar panels and the cover 92 covering the body of the support adapted to be weighted 93. A mechanism of The ball 91 is disposed between the plate 90 and the cover 92. The support adapted to be weighted for solar panels shown in FIG. 9 also makes it possible to correct flatness defects of the roof. Another embodiment of the support adapted to be ballasted is illustrated in FIG. 1. In this embodiment, the body 100 of the support has two parts. The first bet is a cylinder 101 open at both axial ends. The second part is a plate 102. The cylinder 101 is in contact with the plate so that it closes one of the two axial ends of the cylinder. The cylinder carries an internal thread on its open end. Thus, a cover 103, carrying an external thread 104, can be screwed so as to close the axial end of the cylinder carrying an internal thread. To fix a solar panel to the support, a stapling means 105 is disposed on the plate 103, on the opposite side to the external thread. The plate 102 distributes the weight of the weighted support over a large area. Thus, the risk of punching the thermal insulation layer is reduced. Of course, the present invention is not limited to the embodiments described above by way of example; it extends to other variants.

For example, as a weighting material for the supports, it is possible to provide solid discs of metal or cement, sand, or any other material making it possible to maintain the ballast supports on the roof. Other fixing means may be provided, other forms for the support 5 (parallelepiped, or other ...). It is also possible to provide several materials for producing the supports, such as for example high density polyethylene. The present invention is applicable in old and new buildings.

Claims (10)

REVENDICATIONS1. A method of installing a set of solar panels on a horizontal roof of a building, comprising the steps of: providing (S2) on the roof supports for solar panels adapted to be ballasted and for joining a plurality of solar panels ( 44) between them by fixation; ballast the supports (S3); arranging (S4) the solar panels of the assembly next to each other so as to cover at least part of the roof, so that each solar panel is supported by at least two separate supports, and so that two solar panels side by side share at least one support; and fix (S5) the solar panels to the supports. 2. Method according to claim 1, characterized in that said roof comprises at least one layer of ballast material (13) for ballasting a roof layer disposed below, said ballast material being able to be removed from the layer of weighting to be recovered and to ballast the supports, and in that the method further comprises the steps of: taking (S1) at least a portion of the weighting material from the roof; arranging the supports on the insulation layer and / or on the roofing layer disposed beneath the weighting layer; and ballast the supports with the weighting material removed. 3. Method according to claim 2, characterized in that the layer disposed below the ballast layer is a thermal insulation layer (12) of the roof, in that all the ballast material is removed, and the supports of the solar panels are arranged directly on the thetmic insulation layer and ensure, with the solar panels, the ballasting of the thermal insulation layer. 4. Method according to claim 3, wherein the solar panels are arranged on the supports so as to provide a protection of the thermal insulation layer against the sun's rays. 10 5. Support system for solar roofing panels characterized in that it comprises a plurality of point supports (31) for supporting in combination the same solar panel, in that each support is adapted to receive a ballast means, and each support comprises fixing means for solar panel, said fixing means furthermore enabling at least two solar panels to be joined to each other. 6. support system for solar roofing panel according to the preceding claim, wherein each support comprises a housing defining an open chamber (50). 7. Support system for solar roofing panel according to the preceding claim, wherein each support further comprises a means for closing the chamber (61). 20 8. Support system for solar roofing panel according to one of claims 5 to 7, characterized in that each support comprises a screw rod (52) and a bolt (54) to enclose a solar panel between the support and a clamping plate (53). 9. support system for solar roof panel according to claim 6, wherein each support comprises a cover on which are arranged staple means (71) of a solar panel. 10 Roof solar panel support system according to one of claims 5 to 9, characterized in that each support comprises a hinge-type connection (91) between a solar panel support plate (90) and the housing ( 93) for an angular adjustment of the positioning of the solar panel relative to the support. 15