ITMO20120063A1 - PHOTOVOLTAIC PANEL - Google Patents

Description

Description of Patent for Industrial Invention entitled:

â € œPHOTOVOLTAIC PANELâ €.

DESCRIPTION

The present invention refers to a photovoltaic panel.

Currently known photovoltaic panels are generally parallelogram-shaped and comprise a plurality of square-shaped cells connected together in series.

Photovoltaic panels are nowadays also widely used to cover roofs in order to exploit their large surfaces, which are constantly exposed to the sun and have no other functional purposes in addition to coating, in order to obtain electricity.

It follows, therefore, that the parallelogram conformation of the photovoltaic panels does not allow to accurately follow the profile of the roofs and, therefore, does not allow covering their entire surface.

It follows, therefore, that the parallelogram-shaped photovoltaic panels do not allow to fully exploit the surface of the roofs on which they are applied, consequently significantly limiting the energy that can be obtained. This limit of parallelogram-shaped photovoltaic panels is particularly evident in the case of prism-shaped roofs, or having a plurality of contiguous and converging triangular faces, or in the case of roofs having one or more oblique sides.

For this reason, photovoltaic panels have also been developed with conformations different from the one just mentioned.

In particular, the patent EP 2291863 describes a photovoltaic panel provided with a frame having an almost triangular conformation, in particular of the type of a right triangle, where the vertices connecting the sides to the hypotenuse are cut by straight sections. The triangular panels described by EP 2291863 comprise a plurality of square cells connected together in series.

However, this type of panel also has some drawbacks.

More specifically, the energy produced by these photovoltaic panels is considerably lower than that which would be obtained by completely covering the available area of their frame.

This is due to the fact that the square cells that compose it are unable to accurately reproduce the profile of the frame, inevitably leaving empty spaces between them and the frame itself.

It follows, therefore, that this type of known panels is characterized by low energy efficiency.

The main task of the present invention is to devise a photovoltaic panel which allows to overcome the drawbacks of the known art.

Within this aim, an object of the present invention is to devise a photovoltaic panel which allows to completely cover the surface of the roofs following their profile precisely, in particular in cases where the roofs they have a triangular conformation or oblique sides.

Another object of the present invention is to provide a photovoltaic panel which, in addition to having a wide flexibility of use, also has a high energy efficiency.

Another object of the present invention is to devise a photovoltaic panel which allows to overcome the aforementioned drawbacks of the prior art within the ambit of a simple, rational, easy and effective use and low cost solution.

The above purposes are achieved by the present photovoltaic panel comprising a frame and a plurality of photovoltaic cells associated with said frame and operatively connected to each other to convert the absorbed solar energy into electrical energy, each of said photovoltaic cells having a relative face in view facing outwards, characterized in that said photovoltaic cells comprise one or more cells substantially shaped like a parallelogram and one or more cells with a substantially triangular conformation.

Other characteristics and advantages of the present invention will become more evident from the description of a preferred, but not exclusive, embodiment of a photovoltaic panel, illustrated by way of indication, but not of limitation, in the accompanying drawings in which:

Figure 1 is a top plan view of a photovoltaic panel according to the invention, in a first embodiment;

figure 2 is an enlargement of a detail of figure 1;

Figure 3 is a top plan view of a photovoltaic panel according to the invention, in a second embodiment;

figure 4 is an enlargement of a detail of figure 3;

figure 5 is an axonometric view of a photovoltaic panel according to the invention, in a third embodiment;

figure 6 is a top plan view of a roof made with the panels of figure 3.

With particular reference to these figures, the reference number 1 globally indicates a photovoltaic panel according to the invention.

The panel 1 comprises a frame 2 and a plurality of photovoltaic cells 3, 4 associated with the frame 2 and electrically connected to each other to convert solar energy into electrical energy.

Advantageously, the frame 2 has a polygonal profile comprising a plurality of sides 2a, 2b, 2c, of which at least one side 2c is oblique with respect to the others. More precisely, the frame 2 comprises at least two sides arranged substantially orthogonal to each other, identified in the figures with the reference numbers 2a and 2b, and at least one oblique side 2c with respect to the orthogonal sides 2a and 2b.

In the preferred embodiment shown in Figures 1 and 3, the frame 2 is substantially shaped like a right-angled triangle and, more particularly, an isosceles right-angled triangle. The orthogonal sides 2a and 2b and the oblique side 2c therefore correspond, respectively, to the catheti and the hypotenuse of the frame 2 thus shaped.

However, alternative embodiments are not excluded in which the frame 2 is shaped like a rectangle trapezoid or, as shown in figure 5, in which the frame 2 has four consecutive orthogonal sides and an oblique side joining the two extremal sides of these orthogonal sides to define a closed profile.

The cells 3, 4 each have a relative visible face which is, in use, turned towards the outside and therefore exposed to the sun's rays. The cells 3, 4 can be of the monocrystalline type or, preferably, of the polycrystalline type.

According to the invention, the panel 1 comprises one or more cells substantially shaped like a parallelogram 3 and one or more cells with a substantially triangular conformation, identified in the figures with the reference number 4. The term `` substantially '' used herein means unless machining tolerances or slight variations in shape that do not significantly modify the geometry of the relative element. For example, the parallelogram cells 4 of the monocrystalline type have their respective rounded vertices; similarly, the triangular shaped frame 2 can provide for the presence of two rectilinear sections, significantly smaller than those of the other sides, which connect the legs of the frame itself to the hypotenuse.

Preferably, the panel 1 comprises a plurality of parallelogram cells 3 and a plurality of triangular cells 4 electrically connected to each other. More in detail, also the triangular cells 4 are shaped like a right triangle and, preferably, an isosceles right triangle. The cathets and the hypotenuse of the triangular cells 4 are identified in the figures, respectively, with the reference numbers 4a, 4b and 4c.

Advantageously, the triangular cells 4 are arranged in correspondence with the oblique side 2c, ie the hypotenuse of the frame 2 in the embodiment shown in the figures.

More particularly, the triangular cells 4 are arranged with their hypotenuse 4c substantially parallel to the oblique side 2c, that is to the hypotenuse of the frame 2 in the embodiment shown in the figures.

Preferably, all the triangular cells 4 are arranged adjacent to each other at the oblique side 2c and in such a way that their hypotenuses 4c are substantially aligned with each other and parallel to the oblique side itself. The triangular cells 4 are therefore arranged with their sides substantially parallel to the sides of the frame 2, or with their cathets 4a and 4b parallel respectively to the orthogonal sides 2a and 2b, thus allowing to optimize the available surface of the frame itself.

Conveniently, the cells 3 and 4 are arranged along rows, identified in the figures with the reference number 5, which extend along a direction substantially parallel to one of the orthogonal sides 2a, 2b of the frame 2, in particular to the side identified in the figures with the number 2a. In the embodiments of Figures 1 and 3, the rows 5 therefore develop parallel to the catheter 2a of the frame 2.

The rows 5 are electrically connected in series with each other and each of them comprises at least one triangular cell 4.

More in detail, some of the rows 5 include one or more parallelogram cells 3 and, in these rows 5 the triangular cells 4 are arranged between the last parallelogram cell 3 (i.e. the one closest to the hypotenuse of frame 2 ) and the oblique side 2c. The parallelogram cells 3 and the triangular cells 4 of each row 5 are therefore arranged aligned with each other in the direction of development of the row itself. It follows, therefore, that the sides 3 a of the parallelogram cells 3 substantially parallel to the direction of development of the rows 5 are aligned with each other and that one of these sides 3a is also aligned with the catheter 4a of the triangular cells 4 developing parallel to the row itself.

Advantageously, the triangular cells 4 have the same width as the parallelogram cells 3, i.e. their cathetus 4b arranged orthogonal to the direction of development of the rows 5 has the same length as the side 3b of the parallelogram cells 3 also arranged orthogonal to the direction development of rows 5.

The attached figures show two alternative embodiments of the panel 1.

In the first embodiment, shown in Figures 1 and 2, the parallelogram cells 3 have a substantially square conformation and the area of their visible face is greater than the area of the visible face of the triangular cells 4. It follows , therefore, that the triangular cells 4 are capable of generating and conducting an electric current lower than that of the parallelogram cells 3.

In this first embodiment, the parallelogram cells 3 of each row 5 are connected in series with each other while the triangular cells 4 are connected in parallel to one or more other triangular cells 4 and are connected in series to the parallelogram cells 3 of the respective rows 5. More particularly, the number of triangular cells 4 connected in parallel to each other is a function of the area of their face in view, since the electric current generated by the triangular cells 4 connected in parallel must be substantially equal to that parallelogram cells 3 connected in series thereto.

In the embodiment shown in Figures 1 and 2, in which the area of the visible faces of the triangular cells 4 corresponds to approximately half of the area of the visible surfaces of the parallelogram cells 3, the triangular cells 4 are connected in parallel two by two.

Preferably, as can be seen from the figures, each row 5 comprises a single triangular cell 4 positioned in correspondence with the oblique side 2c of the frame 2. The triangular cells 4 of each row 5 are then connected in parallel to the triangular cell 4 of a single adjacent row 5 and in series with the parallelogram cells 3 of the relative rows 5.

Figure 2 shows in detail the reciprocal connections of the triangular cells 4 of the first two rows 5 of the panel 1 and the connections of the same to the adjacent parallelogram cells 3. In particular, in figure 2 the connections that electrically connect the negative electrodes of the triangular cells 4 are identified with the reference number 6 (in the figures the `` tracks '' placed on the visible faces and suitable for collecting the negative electric charges are visible) to the positive electrode of the parallelogram cell 3 arranged downstream of the same in the direction of flow of the current, and with the reference number 7 the connections that electrically connect the positive electrodes of the triangular cells 4 (placed on their face not in view) in turn connected to the negative electrode of the parallelogram cell 3 placed upstream in the direction of flow of the current.

Both connections 6 and connections 7 are arranged on the non-visible face of cells 3 and 4.

In the second embodiment shown in Figures 3 and 4, the parallelogram cells 3 have a substantially rectangular conformation, where the catheter 3 a is approximately half the length of the catheter 3b. In this second embodiment, therefore, the area of the visible face of the parallelogram cells 3 and that of the triangular cells 4 is substantially the same, so that the cells 3 and 4 are able to generate the same current.

In this second embodiment, the cells 3, 4 of each row 5 are connected to each other in series and are connected in series to the cells 3, 4 of the adjacent rows 5. Therefore, each cell 3, 4 is connected in series to the cells 3, 4 arranged upstream and downstream in the direction of flow of the current.

As for the first embodiment, Figure 4 shows in detail the reciprocal connections of the triangular cells 4 of two adjacent rows 5. In particular, in Figure 4, the reference number 8 indicates the connections which electrically connect the negative electrode of a triangular cell 4 to the positive electrode of the adjacent triangular cell 4.

It is easy to understand for those skilled in the art that the connections shown in Figures 2 and 4 can be replaced with others arranged in a different way but completely equivalent from the functional point of view. In a preferred but not exclusive embodiment, the legs of the frame 2 have a length of approximately 133 cm, the distance of the cells 3 and 4 from the legs of the frame 2 is approximately 2.5 cm and the distance of the hypotenuses of the triangular cells 4 from the hypotenuse of frame 2 is equal to about 2 cm. It is therefore evident that the cells 3 and 4 that make up the panel 1 substantially cover the entire area of the frame 2.

Figure 6 represents a photovoltaic system 10 comprising a plurality of square-based photovoltaic panels, identified in the figure with the reference number 9, and a plurality of photovoltaic panels 1.

Conveniently, the cells that make up the panels 9 have the same dimensions and electrical characteristics (voltage, current and peak power) as the parallelogram cells of the panels 1. In particular, in the photovoltaic system 10 of figure 6, the panels 1 are of the type of the second embodiment described above, ie the relative parallelogram cells 3 have a rectangular shape and the area of their visible surface substantially corresponds to the area of the triangular cells 4.

Preferably, the panels 9 comprise a double number of cells than the panels 1, so that the current generated is substantially the same but that the voltage of the panels 9 is substantially double that of the panels 1.

As clearly visible from this figure, this photovoltaic system allows a surface with a triangular profile to be covered in a precise manner. In practice it has been found that the described invention achieves the intended purposes and in particular it is emphasized that the photovoltaic panel according to the present invention, in addition to allowing the surfaces of the roofs having oblique sides to be covered in a precise way, has a High energy efficiency thanks to the use of triangular shaped cells that allow to fully exploit the entire available surface of the panel itself.

Furthermore, the device according to the invention allows the rear wall of the panels to be made in white, in order to contain the heating temperatures of the panels themselves and consequently improve the efficiency, without compromising at the same time their aesthetic impact thanks to the complete covering of the panels. available surface.

Furthermore, the device according to the invention allows identical strings to be connected in parallel, thus avoiding phenomena of mismathcing.

Claims (12)

CLAIMS 1) Photovoltaic panel (1) comprising a frame (2) and a plurality of photovoltaic cells (3, 4) associated with said frame (2) and operationally connected to each other to convert the absorbed solar energy into electrical energy, each of said photovoltaic cells (3, 4) having a relative visible face facing outwards, characterized by the fact that said photovoltaic cells (3, 4) comprise one or more cells substantially shaped like a parallelogram (3) and one or more cells substantially triangular in shape (4). 2) Panel (1) according to claim 1, characterized in that said frame is provided with a plurality of sides of which at least one side is oblique (2c) with respect to the others and that said triangular cells (4) are arranged in correspondence with called the oblique side (2c). 3) Panel (1) according to claim 2, characterized in that the hypotenuse of said triangular cells (4) is substantially parallel to said oblique side (2c). 4) Panel (1) according to one or more of the preceding claims, characterized in that it comprises a plurality of said triangular cells (4) arranged adjacent to each other at said oblique side (2c), the hypotenuses of said triangular cells (4 ) being substantially aligned with each other and parallel to said oblique side (2c). 5) Panel (1) according to one or more of the preceding claims, characterized in that said frame (2) comprises at least two sides arranged substantially orthogonal to each other (2a, 2b) and that said triangular cells (4) are shaped like a right-angled triangle , said triangular cells (4) being arranged with their hypotenuses (4c) and their cathets (4a, 4b) substantially parallel, respectively, to said oblique side (2c) and to said orthogonal sides (2a, 2b) of said frame (2). 6) Panel (1) according to one or more of the preceding claims, characterized in that it comprises a plurality of rows (5) of said photovoltaic cells (3, 4) which develop along a direction substantially parallel to at least one of said orthogonal sides (2a, 2b), where said rows (5) are connected together in series and where each of them comprises at least one of said triangular cells (4). 7) Panel (1) according to one or more of the preceding claims, characterized in that at least one of said rows (5) comprises at least one of said parallelogram cells (3) and that said triangular cells (4) are interposed between the cell parallelogram (4) closer to said oblique side (2c) and the oblique side itself. 8) Panel (1) according to claim 7, characterized in that each parallelogram cell (3) arranged along one of said rows (5) has a side (3 a) substantially parallel to the direction of development of the row itself and substantially aligned to one side (4a) of at least one triangular cell (4) belonging to the same row (5). 9) Panel (1) according to one or more of the preceding claims, characterized in that the area of the face in view of said triangular cells (4) substantially corresponds to the area of the face in view of each of said parallelogram cells (3), said cells (3, 4) being connected in series with each other. 10) Panel (1) according to one or more of claims 1 to 8, characterized in that the area of the face in view of said triangular cells (4) is smaller than the area of the face in view of each of said parallelogram cells (3), said parallelogram cells (3) being connected to each other in series and said triangular cells (4) being connected in parallel to at least one other triangular cell (4) and in series to the parallelogram cells (3) arranged upstream and downstream of the same in the direction of flow of the current. 11) Panel (1) according to claim 10, characterized by the fact that each of said rows (5) comprises a single triangular cell (4) and by the fact that each of said triangular cells is connected in parallel to the triangular cell of a row adjacent and in series to the parallelogram cells of the same row, the area of the face in view of said triangular cells substantially corresponding to half of the area of the face in view of said parallelogram cells. 12) Panel (1) according to one or more of the preceding claims, characterized by the fact that said frame (2) has a substantially triangular conformation, said orthogonal sides (2a, 2b) and said oblique side (2c) corresponding respectively to the catheti and the ™ hypotenuse of the frame itself, said triangular cells (4) being arranged with their hypotenuses (4c) substantially aligned with each other and parallel to said oblique side (2c) and with their cathets (4a, 4b) substantially parallel to the catheti (2a , 2b) of said frame (2).