ITBA20120038A1 - "PHOTOVOLTAIC PLANT AND INSTALLATION METHOD OF THE SAME" - Google Patents

Description

Description

â € œPhotovoltaic system and method of installation of the sameâ €

The invention relates to the sector of systems for the production of alternative energy and more particularly relates to a plant for the installation of photovoltaic modules above or to replace a roof of a building.

A photovoltaic module is a device suitable for converting the light energy emitted by the sun into electrical energy through the photovoltaic effect, that is, through the physical phenomenon that occurs when an electron, present in the valence band of a semiconductor, passes to the conduction band as a consequence of the absorption of a sufficiently energetic photon incident on the material.

As is known, the performance of photovoltaic modules can vary based on various factors including: the efficiency of the materials, the manufacturing tolerance percentage with respect to the plate values, the solar irradiation, their angle with respect to the solar irradiation, the composition of the light spectrum and finally, the operating temperature of the materials that tend to "get tired" in hot environments.

In order to obtain the maximum yield from a photovoltaic system and, at the same time, to prevent its installation from penalizing agricultural production through the subtraction of fertile land, allocating it to the installation of the system, the now recognized solution as the most convenient is to install the new photovoltaic systems above the roofs of homes or, better still, industrial warehouses.

The installation of these systems above the roofs of the buildings and, in particular, those integrated with them, presents a series of drawbacks including, first of all, the impossibility of guaranteeing, with the exception of those that use film plastic solar panels, the impermeability of the roofs to water at angles of less than 15 °, and in fact, in the event of strong wind the water tends to rise on the surface of each photovoltaic module up to their ends, and not finding no obstacle filters through the existing space with the lower part of the contiguous module.

A further drawback of known systems, and in particular, of roofs integrated with polycrystalline modules, is of an aesthetic type, in fact, these systems leave the aluminum frames on which the photovoltaic modules are anchored visible. This drawback also extends to plastic solar films.

Another drawback of the known systems is to be found in the fact that said systems are not designed to allow sufficient ventilation below the photovoltaic modules with the consequence that, when the modules overheat, a lower efficiency of the panels corresponds.

A further disadvantage, specifically, of photovoltaic systems that use solar sheaths applied to roofs, is certainly the limited duration of the system over time, which tends to deteriorate as it is directly exposed to bad weather and sunlight.

Another drawback of known photovoltaic systems is the impossibility of following the formation of the roof as the photovoltaic modules, of the polycrystalline type, require a precise inclination and optimal exposure of the roof in order to obtain a profitable profitability, characteristics rarely found in the roofs of buildings.

Finally, a further disadvantage of the known plants is a consequence of their inability to be walked on, with the consequence of a greater difficulty in providing for their maintenance which involves an accumulation of dirt and sediments which can determine a lower efficiency of the plant.

The purpose of the present invention is to provide a suitable structure to allow the installation of photovoltaic modules that integrate, possibly replacing it, with the roofing of buildings. A further purpose of this model is to provide a suitable structure for the installation of photovoltaic modules of the glass-glass type both on flat roofs and on curved barrel-type surfaces.

A further purpose is to create a photovoltaic roof impermeable to water even in the presence of roofs with inclinations of less than 6 ° degrees, providing a system which, in the event of strong wind, does not allow the water to rise towards the High and, consequently, filter between one photovoltaic module and another.

Another object is to provide a structure for the installation of photovoltaic systems which guarantee optimal performance even in the presence of roofs inclined below 12 ° -30 ° and with azimuth facing south.

Finally, a further purpose is to provide a system that can be walked on if necessary to carry out ordinary and / or extraordinary maintenance.

The system for the installation of photovoltaic panels integrated into the roof of a building, referred to in the present invention, in addition to solving the drawbacks described above, also presents a series of indisputable advantages, first of all the possibility of it can also be installed on existing roofs whose mantle is no longer used as such.

A further advantage consists in the fact that the system, described below, can be installed on a fiber cement or bitumen roof even without proceeding with a preventive restoration of the same, performing the same system as a protective layer.

A further advantage is the duration of the roof which, once restored and protected by the photovoltaic system, increases its life by several years.

Another advantage is to be found in the use of an adhesive to fix the modules to the system, which while guaranteeing the possibility of disassembling and replacing the individual modules without them being damaged, makes theft extremely difficult.

To all these advantages, it must be added that the use of the old roof involves the reduction of waste materials, the installation can take place regardless of the weather conditions, it is cheaper and has better mechanical resistance characteristics, compared to one in tar or with plastic plates. In the case of fiber cement roofs, a better thermal / acoustic insulation is also obtained thanks to the air chambers that are created.

Finally, a final advantage lies in the possibility of integrating the gutters to the photovoltaic system.

Said advantages and other purposes, as will become clearer from the following description, are achieved by the photovoltaic system and its installation method, of the present invention, which is described below in a preferred, non-limiting embodiment of further developments in the Scope of the invention, with the help of the eight attached drawing tables that illustrate:

fig. 1, an axonometric view of a purlin and three brackets for compensating the differences in height found in roofs that are not perfectly flat, according to an example of the invention;

fig. 2, an isometric view of a part of the grid formed by the purlins and the upper profiles;

fig. 3, an axonometric view of a part of the grid on whose upper profiles the support profiles for gluing the photovoltaic modules have been applied;

fig. 4 is a front sectional view of the gutter when engaged with the upper profile;

fig. 5, a sectional view of a purlin;

fig. 6, a sectional view of the upper profile;

fig. 7, a longitudinal section view of the support profiles of the photovoltaic modules;

fig. 8, a plan view of a support profile on which two parallel strips of double-sided adhesive tape and two strips of glue are applied;

fig. 9, a side view of two side profiles, at the junction point;

fig. 10, a side view of two side profiles, at the junction point with installed photovoltaic modules;

fig. 11, a view of the photovoltaic system with some modules applied; fig. 12, a side view of a bracket for hooking the purlins to the roof and to the upper section complete with the support profile, in the case of a flat roof;

fig. 13, a side view of a bracket for hooking the purlins to the roof and to the upper section complete with the support profile, in the case of a barrel-type roof.

Below we will refer to â € œphotovoltaic systemâ € to indicate the support structure of the photovoltaic modules.

With particular reference to the attached drawing tables, a system for the installation of photovoltaic modules above or to replace a roof of a building is now described, according to an example of the invention.

The photovoltaic system, indicated in general with the numerical reference 1, comprises a series of purlins 2 arranged parallel to each other which act as a support for as many upper profiles 3.

The purlins 2, as illustrated in Figures 1, 12 and 13, consist of aluminum profiles comprising an upper cavity 21 and a lower cavity 22 acting as a seat for a nut 82 with which to fix, through a pin 81, a bracket 8. The bracket 8 being also engaged to a screw 83 anchored to the roof or to the cover C. The screw 83 having a pair of data 84 and 85 allows the adjustment of the distance of the purlins 2 from the roof or from the cover C in order to compensate for any unevenness present on non-flat roofs. At the base of the screw 83 there is the use of a gasket 86, to avoid the formation of condensation and as double protection in case of damage to the roof above.

Advantageously, in order to guarantee their duration over time, the brackets 8 are made of stainless steel and the screws 83 are made of galvanized metal.

In the case of perfectly flat roofs, the aluminum purlin 2 can be replaced by a wooden one which will be positioned vertically.

A series of upper profiles 3 are engaged at the top, through pins 87 and nuts 88, and perpendicular to them, to the purlins 2 so as to form a grid that acts as a support element for the photovoltaic modules 7. The use of modules of the type glass-glass makes the cover walkable and long-lasting.

In order to create a greater support surface for the photovoltaic modules and guarantee waterproofness between two modules, support profiles 4 are applied above the upper profiles 3 which act as a cap and surface for applying glues for anchoring the modules. , said profiles resting on projections 32 obtained on the lateral surfaces of the upper profile 3.

As shown in figure 7, in order to obtain a tile effect between one photovoltaic module 7 and the other, the lateral section of the support profiles 4 is not rectangular but inclined, being the height l <2> of the edge 43 higher than that l <1> of border 42.

Two types of adhesives are provided for fixing the photovoltaic modules 7 to the support profiles 4, the first obtained by applying a double-sided tape 5 having the function, in addition to an additional seal, of allowing a first immediate fixing of the module photovoltaic 7 maintaining the level of adhesion constant and ensuring a regular distance between the support and the module in order to facilitate its installation, and a special glue 6 for glass with high tensile strength and impermeable to water. Said adhesive 6 being suitable for compensating for the expansion due to temperature variations between the different materials used and for guaranteeing a solid anchoring of the photovoltaic modules to the structure of the system.

With reference to fig. 10, to avoid water infiltration, especially in roofs with an inclination of less than 20 °, a strip of glue 11 is applied on the junction line of the photovoltaic modules 7.

As shown in figure 4, the photovoltaic system 1 provides for the application of a gutter 9 which acts as a connecting element between the roof made with the photovoltaic modules and the parapet. The gutter 9 with an L-shaped section has a fold 91 on the upper side which acts as a hook for the gutter 9 itself at the end 31 of the upper profile 3.

System 1 requires a sufficiently large central outlet channel to be created at the top of the roof, the purpose of which is to allow the hot air coming from the cavity formed between the protective sheath to escape due to the chimney effect. G and the part below the photovoltaic modules 7. This chimney effect also avoids the formation of condensation.

System 1 also provides for the application of bird grids 10 near the ends of the roof.

As illustrated in figure 13, the photovoltaic system 1 can also be advantageously installed on so-called barrel roofs. In fact, the non-alignment of the upper profiles 3 is compensated by the flexibility of the appendages 44 and 45, thus allowing the creation of a curve that adapts to that of the roof.

Claims

1. Photovoltaic system (1) and method of installation of the same comprising:

- at least two purlins (2) anchored parallel to the cover C of a roof of a building;

- anchoring means (8), of said at least two purlins (2), to said covering C, said anchoring means (8) comprising a system (83, 84, 85) for compensating the unevenness of the covering C;

- at least two upper profiles (3) engaged, by suitable means, to said purlins (2);

- at least two support profiles (4) engaged to at least two upper profiles (3);

said photovoltaic system (1) being characterized by the fact that the upper profiles (3) are closed at the top by means of a support profile (4), with the function of hooking the photovoltaic modules (7), having a C-shaped cross section, whose walls sides (41) are of increasing height from left to right, so that the lateral edges (42, 43) are of different height, in order to create a difference in height, in the longitudinal direction, between each photovoltaic module (7) installed.

2. Photovoltaic system (1) according to claim 1, characterized in that the upper face of said support profile (4) has an appendix (44) facing upwards at the edge (42), and on the edge opposite (43) an appendix (45) facing downwards.

3. Photovoltaic system according to claims 1 and 2 characterized in that the support profile (4) rests on a pair of projections (32) obtained at about 3⁄4 in height on the side faces (33) of the upper profile (3) .

4. Photovoltaic system as per the preceding claims characterized in that, in order to allow perfect alignment of the photovoltaic modules (7), the support profiles (4), during the installation phase, can move on the upper profiles (3).

5. Photovoltaic system as per the preceding claims characterized in that the photovoltaic modules (7), according to the type, when installed, are anchored laterally or in the center of the support profiles (4) and below the upper edge of the photovoltaic module (7 ) contiguous.

6. Photovoltaic system as per the preceding claims characterized by the fact that each photovoltaic module (7) is anchored for the lateral edges to the support profiles (4) by means of at least one strip of double-sided adhesive tape (5) and at least one strip of glue ( 6), the latter having the function of both stabilizing the union and distance of said photovoltaic modules (7) to said support profiles (4) and of compensating, through its plasticity, the thermal expansion acting on the ™ photovoltaic system (1).

7. Photovoltaic system as per the preceding claims characterized in that the lower edge (71) of the non-exposed face of each photovoltaic module (7) rests on the upper edge (72) of the exposed face of the adjacent module, for this purpose, the height difference between the long edge (43) and the short edge (42) (L <2> -L <1>) of the support profile (4) corresponds to the sum obtained from the thickness of a photovoltaic module (7) and from the thickness of the glue layer (6).

8. Photovoltaic system as per claim 1 characterized by the fact that the purlins (2) are anchored to the cover C by means of at least two brackets (8) engaged on one side, to the lower cavity (22) of said purlins (2) by means of a system peno and nut (81, 82), and on the other, to said cover C, by means of a screw (83) and nuts (84,85); the nut (82) being free to slide, when the pin (81) is not tightened, inside the cavity (22) in order to allow the optimization of the anchoring of the photovoltaic system (1 ) to cover C,

9. System according to claims 1 characterized by the fact that the upper profile (3) is equipped with a C-shaped base for hooking a gutter (9).

10. Method for the installation of a photovoltaic system (1), characterized by the following phases:

- application of a protective sheath G, in tarred cardboard or a plastic film, or fiber cement sheets, on the roof C;

- anchoring the purlins (2) to the cover C by means of brackets (8) taking care, before tightening the nut pin system (81, 82), to identify the most suitable area for inserting the screw (83), this system being adaptable, both vertically and horizontally, to all types of roofs C with different spans, for which fixing is required;

- fixing the upper profiles (3) to the purlins (2) and fixing them to the latter by means of a screw or bolt;

- application of the side gutters (9);

- application of the support profiles (4) above the upper profiles (3);

- fixing said support profiles (4) to the upper profiles (3) by means of rivets or other similar means;

- construction of at least one drainage channel for stagnant waters in the part of the roof corresponding to the ridge of the roof;

- application of bird grids (10);

- application of at least one strip of double-sided tape (5) on the upper face of the support profiles (4) and on each exposed upper edge (72) of the photovoltaic modules (7), called double-sided tape (5) with the function of facilitating Exact installation of said modules (7) which would otherwise tend to slide downwards until the glue (6) solidifies;

- application of a layer of glue (6) for high tensile strength glass, parallel to the double-sided tape (5);

- placement of glass-glass photovoltaic modules;

- application of a strip of glue (11) to connect each module (7) in order to prevent water infiltrations.

Claims (5)

Claims 1. Photovoltaic system (1), comprising: - at least two purlins (2) anchored parallel to the cover C of a roof of a building; - anchoring means (8), of said at least two purlins (2), to said covering C, said anchoring means (8) comprising a system (83, 84, 85) for compensating the unevenness of the covering C; - at least two upper profiles (3) engaged, by suitable means, to said purlins (2); - at least two support profiles (4) engaged to at least two upper profiles (3); said photovoltaic system (1) being characterized by the fact that the upper profiles (3) are closed at the top by means of a support profile (4), with the connection finish of the photovoltaic modules (7), having a C-shaped cross section, whose walls side edges (41) are of increasing height from left to right, so that the lateral edges (42, 43) are of different height, in order to create a difference in height, in the longitudinal direction, between each photovoltaic module (7) installed; said support (4) resting on a pair of projections (32) obtained at about 3⁄4 of the height of the side faces (33) of the upper profile (3). 2. Photovoltaic system (1) as per claim one characterized by the fact that, in order to allow perfect alignment of the photovoltaic modules (7), the support profiles (4), during the installation phase, can move on the upper profiles (3 ). 3. Photovoltaic system (1) as per the preceding claims characterized by the fact that each photovoltaic module (7) is anchored for the lateral edges to the support profiles (4) by means of at least one strip of double-sided adhesive tape (5) and at least one strip of glue (6), the latter having the function of both stabilizing the union and distance of said photovoltaic modules (7) to said support profiles (4) and compensating, through its plasticity, the thermal expansion agents on the photovoltaic system (1). 4. Photovoltaic system (1) as per the preceding claims characterized in that the lower edge (71) of the non-exposed face of each photovoltaic module (7) rests on the upper edge (72) of the exposed face of the adjacent module, to such purpose, the difference in height between the long edge (43) and the short edge (42) (L2-L1) of the support profile (4) corresponds to the sum obtained from the thickness of a photovoltaic module (7) and the thickness of the layer of glue (6). 5. Photovoltaic system (1) according to claim 1 characterized by the fact that the upper profile (3) is equipped with a C-shaped base for the attachment of a gutter (9).