ES1295949U - PHOTOVOLTAIC GENERATION DEVICE (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Photovoltaic generation device, characterized in that it comprises: - a first photovoltaic cell (1) with a flat configuration, with four sides, an active face (1.1) and an inner face (1.2), opposite the active face (1.1). ; - A second photovoltaic cell (2) with a flat configuration, with four sides and an active face (2.1), and an inner face (2.2), opposite the active face (2.1), where the second photovoltaic cell (2) is arranged parallel to the first photovoltaic cell (1) and spaced from the first photovoltaic cell (1), with the active face (2.1) of the second photovoltaic cell (2) facing the inner face (1.2) of the first photovoltaic cell (1), and where one side of the first photovoltaic cell (1) and one side of the second photovoltaic cell (2) are parallel and are joined by means of a wall (3), defining a space between the first and the second. second photovoltaic cells (1, 2); - a first reflective surface (4) adjacent to the side of the second photovoltaic cell (2) opposite the wall (3), and configured to reflect an incident light beam towards a second reflective surface (5) arranged on the wall (3) through the space between the photovoltaic cells (1, 2), - wherein the second reflective surface (5) is a curved surface configured to reflect the beam reflected from the second reflective surface (5) towards a third reflective surface (6) arranged on the inside face (1.2) of the first photovoltaic cell (1), - where the third reflective surface (6) is a curved surface configured to reflect the beam reflected on the third reflective surface (6) towards the active face (2.1) of the second photovoltaic cell (2). (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

PHOTOVOLTAIC GENERATION DEVICE

Technical field of the invention

The present invention is aimed at a photovoltaic generation device that allows the capture of unused solar radiation by direct incidence of light on a photovoltaic cell arranged in a conventional manner. More specifically, the photovoltaic generation device comprises a main photovoltaic cell arranged in a conventional manner to take advantage of the directly incident solar radiation, and a secondary photovoltaic cell arranged below the main cell, with the same orientation as the main cell, and separated of this, so that between the main cell and the secondary cell a space or hole is formed through which the solar radiation that is not used by the main photovoltaic cell is diverted.

Background of the invention

At present, awareness of respect for the planet, nature and the environment must be consolidated in our ways of living. It is increasingly observed how we try to consume products from our closest ecosystem, recycle waste and how the consumption of renewable energies is consolidated in society.

The increase in the current demand for renewable energies is known, and within these, for solar energy, both photovoltaic and thermal. Current construction techniques for photovoltaic solar panels or panels have achieved an increase in efficiency of up to 28 or 29% by improving the chemical-physics of solar cells, or up to 40% in panels that take advantage of diffuse light reflected from the I usually. This increase in power per unit area entails a lower environmental impact in large projects of photovoltaic solar platforms by being able to reduce the area affected in their development.

Currently, the use of roofs, roof terraces, etc., of industrial warehouses and buildings for the installation of photovoltaic panels is subject to surface limitations. The current reduction in the production costs of solar panels poses a possible adaptation to make profitable the square meter of collector surface in all these cases. Therefore, there is a wide margin for improvement in the field of photovoltaic generation.

Description of the invention

The present invention proposes a solution to the above problems by means of a photovoltaic generation device and a photovoltaic generation system as described below.

In a first inventive aspect, the invention provides a photovoltaic generation device, characterized in that it comprises:

- a first photovoltaic cell with a planar configuration, with four sides, an active face and an inner face, opposite the active face;

- a second photovoltaic cell of flat configuration, with four sides and an active face, and an inner face, opposite to the active face, wherein the second photovoltaic cell is arranged parallel to the first photovoltaic cell and spaced from the first photovoltaic cell , with the active face of the second photovoltaic cell facing the inner face of the first photovoltaic cell, and wherein one side of the first photovoltaic cell and one side of the second photovoltaic cell are parallel and joined by means of a wall, defining a space between the first and second photovoltaic cells;

- a first reflective surface adjacent to the side of the second photovoltaic cell opposite the wall, and configured to reflect an incident light beam towards a second reflective surface arranged on the wall through the space between the photovoltaic cells,

- where the second reflective surface is a curved surface configured to reflect the beam reflected from the second reflective surface towards a third reflective surface arranged on the inside face of the first photovoltaic cell, - where the third reflective surface is a configured curved surface to reflect the beam reflected from the third reflective surface towards the active face of the second photovoltaic cell.

By planar configuration photovoltaic cell, photovoltaic cell or cell, is to be understood a conventional photovoltaic cell capable of transforming light energy into electrical energy, substantially flat, and preferably rectangular or square. It should be understood that light beam, light beam, sunlight, solar radiation or radiation Light are equivalent terms to define the light energy that can be transformed by the device. By active face of the photovoltaic cell is meant the face of the cell that is sensitive to radiation and which is normally exposed to the light source. By reflective surface is meant any surface capable of producing the specular reflection of an incident light beam, preferably a mirror or a sheet of polished metal.

The invention makes it possible to take advantage of the radiation that falls beyond the edge of a conventional photovoltaic cell, the first photovoltaic cell, and that cannot be transformed into electrical energy by it. To achieve this effect, the proposed invention comprises another photovoltaic cell, the second photovoltaic cell, arranged with the same orientation as the first cell, and separated from it, forming a space between both cells. To maintain the separation between the two cells, and the space they form, a structural element, the wall, is provided to relate the cells to each other.

The space formed between the cells has at least one opening on the opposite side to the wall; Adjacent to this opening is provided a first reflective surface arranged configured to reflect or redirect a light beam incident beyond the edge of the first cell into the space formed between the two photovoltaic cells. In a preferred embodiment, the first reflective surface can be a flat mirror, a curved mirror, an elliptical mirror, or a plurality of curved mirrors.

The space formed between the cells comprises two curved reflective surfaces arranged and oriented so that the light reflected by the first reflective surface passes through the space and is reflected successively on the second one, arranged on the wall, and on the second reflective surface, arranged on the the inner face of the first cell, to finally affect the active face of the second cell. In a preferred embodiment, the second reflective surface is a parabolic mirror, and the third reflective surface is a parabolic mirror.

Advantageously, the present invention allows the use of sunlight that falls beyond the edge of a photovoltaic cell arranged in a conventional manner. In addition to solar radiation, the device of the present invention can be applied to any other source of radiation to which the photovoltaic cells are sensitive, as well as to any orientation.

In a particular embodiment, the device comprises at least a third photovoltaic cell identical to the second photovoltaic cell, with an active face and an inner face opposite to the active face, wherein the third photovoltaic cell is arranged parallel to the second photovoltaic cell. , with the active face of the third photovoltaic cell spaced from and facing the inner face of the second photovoltaic cell, and further comprises a further wall, a second reflective surface, and a third reflective surface correspondingly arranged on the third photovoltaic cell. Advantageously, the arrangement of additional cells in parallel allows a better use of light radiation and a minimum occupation of the ground. In one embodiment, the device comprises a plurality of additional photovoltaic cells arranged in parallel to the third photovoltaic cell.

In a particular embodiment, the first reflective surface is a flat mirror arranged at an angle a that is not zero with respect to a reference plane parallel to the photovoltaic cells. The reference plane of the photovoltaic cells must be understood as the imaginary reference plane parallel to at least one of the faces of the flat photovoltaic cells, and the angle a is defined as the angle formed by the lines resulting from intersecting the plane of the first reflective surface and the reference plane with a plane perpendicular to the reference plane and parallel to a side of a cell adjoining the wall. Advantageously, the flat mirror makes it possible to reflect an incident light beam towards the second reflective surface.

In a particular embodiment, the device also comprises an articulated support for the first reflective surface configured to allow the rotation of the first reflective surface so that the angle a varies. Advantageously, the articulated support makes it possible to adapt the orientation of the first reflective surface to any angle of incidence of the incident beam.

In a particular embodiment, the device also comprises drive means for the first reflective surface, configured to modify the angle a as a function of the angle of incidence of the incident light beam . Advantageously, the drive means make it possible to automate monitoring of solar radiation, the angle of incidence of which is constantly changing.

In a particular embodiment, the first reflective surface is a curved mirror. Advantageously, the curved mirror makes it possible to reflect the incident radiation towards a focus.

In a particular embodiment, where the second reflective surface and/or the third reflective surface are quadric surfaces. In particular embodiments, the second reflective surface is a parabolic mirror, and the third reflective surface is a parabolic mirror.

In a particular embodiment, the device also comprises side enclosures with at least one reflective surface, arranged parallel to each other, on both sides of the wall and between the sides of the photovoltaic cells . Advantageously, the enclosures offer greater protection to the second, third or additional photovoltaic cells; In addition, the reflective surfaces allow diffuse light to be redirected towards the photovoltaic cell.

In a second inventive aspect, the invention provides a photovoltaic generation system characterized in that it comprises a plurality of devices according to the first inventive aspect.

These and other features and advantages of the invention will become apparent from the description of the preferred, but not exclusive, embodiments, which are illustrated by way of non-limiting example in the accompanying drawings.

Brief description of the drawings

Figures 1a, 1b These figures show two profile views of two preferred embodiments of the invention.

Figures 2a, 2b, 2c These figures show three profile views of three preferred embodiments of the invention.

Detailed description of an exemplary embodiment

In the following detailed description, numerous specific details are set forth in the form of examples to provide a thorough understanding of the relevant teachings. However, it will be apparent to those skilled in the art that present teachings can be carried out without such details.

Figure 1a shows a profile view of an exemplary embodiment. In this example, the device is intended for the use of solar radiation and comprises a first photovoltaic cell (1) arranged horizontally with its active face (1.1) facing upwards, and a second photovoltaic cell (2) arranged parallel and below of the first photovoltaic cell (1), with an active face (2.1) and an inner face (2.2) opposite the active face (2.1).

The photovoltaic cells (1, 2) are conventional flat photovoltaic cells, schematically represented in profile, whose wiring and auxiliary equipment are not shown in the figures. The photovoltaic cells (1, 2) are separated by a wall (3) that extends between both photovoltaic cells (1, 2) along one of their sides, shown on the right in the figure. In this example, the wall (3) is formed by the substrate of the second reflective surface (5), which is a conventional parabolic mirror, and which in the figures is shown in a simplified manner with a polygonal shape.

On the opposite side of the second photovoltaic cell (2), shown on the left in the figure, the first reflective surface (4) is arranged, which in this case is a conventional flat mirror articulated to the second photovoltaic cell ( 2) by means of an articulated support, and which allows the orientation of the first reflective surface (4) to be modified depending on the angle of incidence of the sun's rays, which varies throughout the day; the angle a represents the angle formed by the plane of the first reflective surface (4) with a reference plane parallel to the second photovoltaic cell (2).

On the inside face (1.2) of the first photovoltaic cell (1) the third reflective surface (6) is mounted by conventional means, which in the embodiment shown is a conventional parabolic mirror, and which is shown in the figures in simplified form as a polygonal shape.

In this way, when a beam of solar radiation falls substantially vertically on the device, the entire surface of the active face (1.1) of the first photovoltaic cell (1) receives a part of the radiation, generating electrical energy, while that at least a part of the radiation that falls beyond the edge of the active face (1.1) is reflected by the first reflective surface (4); the beam reflected by the first reflective surface (4) passes through the space formed between the photovoltaic cells (1, 2) substantially parallel to the reference plane of the second photovoltaic cell (2) and falls on the second reflective surface (5). In turn, the second reflective surface (5) reflects the light beam in the direction of the interior face (1.2) of the first photovoltaic cell (1) in which the third reflective surface (6) is located, which reflects the beam. towards the active face (2.1) of the second photovoltaic cell (2), and in this way generates electricity. To maintain high performance throughout the day, the orientation of the first reflective surface (4) can be changed, adjusting it to the position of the sun at any time.

Figure 1b shows a variation of the embodiment of the device shown in Figure 1a, with a third photovoltaic cell (7) arranged in parallel and under the second photovoltaic cell (2). The embodiment of Figure 1b further comprises an additional set of wall (3), second reflective surface (5) and third reflective surface (6), with a configuration analogous to those of the first set, and which function in the manner described above. In the embodiment shown, the first reflective surface (4) is common to the second and third photovoltaic cells (2, 7), and is articulated to the third photovoltaic cell (7) by means of an articulated support. In other embodiments, not shown in the figures, the device comprises additional photovoltaic cells and assemblies of reflective surfaces and walls as described.

Figure 2a shows another example of embodiment, which differs from the example of Figure 1b only in that the first reflective surface (4) is a curved mirror rigidly attached to the device. Figure 2b shows an alternative embodiment, in which the first reflective surface (4) is a doubly curved mirror.

Finally, Figure 2c shows an improvement of the embodiment described in Figure 1b, which includes drive means for the first reflective surface (4) attached to the articulated support to modify the angle a as a function of the angle of incidence of the light beam. incident; These drive means are, in one embodiment, a stepper electric motor that allow the change of orientation of the first reflective surface (4) to be automated depending on the movement of the sun throughout the day. In an embodiment, not shown in the figures, the invention provides a system for photovoltaic generation formed by a plurality of photovoltaic generation devices arranged next to each other to form a photovoltaic panel with multiple layers of photovoltaic cells.

Claims (9)

1. Photovoltaic generation device, characterized by comprising: - a first photovoltaic cell (1) with a flat configuration, with four sides, an active face (1.1) and an inner face (1.2), opposite the active face (1.1); - A second photovoltaic cell (2) with a flat configuration, with four sides and an active face (2.1), and an inner face (2.2), opposite the active face (2.1), where the second photovoltaic cell (2) is arranged parallel to the first photovoltaic cell (1) and spaced from the first photovoltaic cell (1), with the active face (2.1) of the second photovoltaic cell (2) facing the inner face (1.2) of the first photovoltaic cell (1), and where one side of the first photovoltaic cell (1) and one side of the second photovoltaic cell (2) are parallel and are joined by means of a wall (3), defining a space between the first and the second. second photovoltaic cells (1, 2); - a first reflective surface (4) adjacent to the side of the second photovoltaic cell (2) opposite the wall (3), and configured to reflect an incident light beam towards a second reflective surface (5) arranged on the wall (3 ) through the space between the photovoltaic cells (1,2), - where the second reflective surface (5) is a curved surface configured to reflect the beam reflected on the second reflective surface (5) towards a third reflective surface (6) arranged on the inside face (1.2) of the first photovoltaic cell ( one), - wherein the third reflective surface (6) is a curved surface configured to reflect the beam reflected from the third reflective surface (6) towards the active face (2.1) of the second photovoltaic cell (2). 2. Device according to the preceding claim, wherein the device comprises at least a third photovoltaic cell (7) identical to the second photovoltaic cell (2), with an active face (7.1) and an inner face (7.2) opposite the face active (7.1), where the third photovoltaic cell (7) is arranged parallel to the second photovoltaic cell (2), with the active face (7.1) of the third photovoltaic cell (7) distanced and facing the inner face ( 2.2) of the second photovoltaic cell (2), and further comprises a wall (3), a second reflective surface (5), and a third additional reflective surface (6) arranged correspondingly in the third photovoltaic cell (7). Device according to any of the preceding claims, wherein the first reflective surface (4) is a flat mirror arranged at a non-zero angle to a reference plane parallel to the photovoltaic cells (1, 2, 7). Device according to the preceding claim, wherein the device further comprises an articulated support for the first reflective surface (4) configured to allow rotation of the first reflective surface (4) so as to vary the angle a. Device according to the preceding claim, wherein the device further comprises drive means for the first reflective surface (4), configured to modify the angle a as a function of the angle of incidence of the incident light beam. Device according to any of the claims 1-2, wherein the first reflective surface (4) is a curved mirror. Device according to any one of the preceding claims, wherein the second reflective surface (5) and/or the third reflective surface (6) are quadric surfaces. 8. Device according to any of the preceding claims, wherein the device further comprises lateral enclosures with at least one reflective surface, arranged parallel to each other, on both sides of the wall (3) and between the sides of the photovoltaic cells (1 , 2, 7). 9. Photovoltaic generation system characterized in that it comprises a plurality of devices according to any of claims 1-8