FR3079349A1 - SOLAR PANEL - Google Patents

Abstract

The invention relates to a solar panel comprising a plurality of photovoltaic cells (1), and wherein: - the panel (P) has cells (3) delimited by at least one side wall (31), - at least one photovoltaic cell (2). ) is fixed in each cell (3) so that said at least one cell forms the bottom of said cell, - said at least one side wall (31) of each cell (3) is covered with a reflective material and inclined in order to concentrate the solar radiation on said at least one photovoltaic cell (2) fixed in the bottom of said cell.

Description

Technical field of the invention.

The subject of the invention is a solar panel.

It concerns the technical field of solar panels comprising photovoltaic cells adapted to capture solar radiation and transform it into electrical energy.

State of the art.

Solar panels are generally formed by several photovoltaic cells linked together in series or in parallel. They can be installed on fixed supports on the ground or on a roof, or be carried by a solar tracker, commonly called a “tracker”, controlled by an actuator connected to a solar sensor for a rotation of said panel making it possible to follow the sun during its rise and its descent from east to west. In the latter case, electricity production increases by around 30% compared to a fixed installation.

Photovoltaic cells, or solar cells, are electronic components which, exposed to light (photons), produce electricity through the photovoltaic effect. They produce approximately 60 Watt peak per m ² (Wp / m ² ) for amorphous silicon cells, approximately 100 Wp / m ² for cells based on polycrystalline silicon, and approximately 150 Wp / m ² for cells with mono-crystalline silicon base. Their yield (share of transformed solar radiation

-2 in electricity) is between 5% and 25% depending on the material used. Also, the average yield of current photovoltaic solar panels is around 15%.

An objective of the invention is to improve the efficiency of a solar panel. Another objective of the invention is to propose a solar panel of simple design, inexpensive and whose size is reduced.

Disclosure of the invention.

The solution proposed by the invention is a solar panel comprising several photovoltaic cells. This panel is remarkable in that:

the panel has cells delimited by at least one side wall,

at least one flat photovoltaic cell is fixed in each cell so that said at least one cell forms the bottom of said cell,

- Said at least one side wall of each cell is covered with a reflective material and inclined so as to concentrate the solar radiation on said at least one photovoltaic cell fixed in the bottom of said cell.

Thanks to this particular topology, the applicant has been able to observe that, for an equal surface and for the same type of cells, the efficiency of the solar panel increased considerably.

Other advantageous features of the invention are listed below. Each of these characteristics can be considered alone or in combination with the remarkable characteristics defined above, and be the subject, if necessary, of one or more divisional patent applications:

Advantageously, the at least one side wall of each cell is inclined at an angle between 60 ° and 70 ° relative to the surface of the at least one photovoltaic cell fixed in the bottom of said cell.

Advantageously, the bottom of each cell has a square shape so that the at least one photovoltaic cell is surrounded by four side walls, the height of said side walls being equal to half the length of the side of said bottom.

- According to an alternative embodiment, the bottom of each cell has a circular shape so that the at least one photovoltaic cell is surrounded by a conical side wall, the height of said wall being equal to half the diameter of said bottom.

Advantageously, the cells are grouped in modules.

Advantageously, each module is carried by a solar follower connected to a solar collector, which follower is controlled by means of actuators for a rotation of said module making it possible to follow the sun during its rise and its descent from East to West.

- The solar trackers can be synchronized so that the modules move at the same time and in the same way.

- The solar trackers can be desynchronized so that the modules move independently of each other.

Advantageously, each cell is hermetically sealed by a transparent plate, an air vacuum being created in each of said cells.

Advantageously, the transparent plate is concave or convex.

Description of the figures.

Other advantages and characteristics of the invention will appear better on reading the description of a preferred embodiment which will follow, with reference to the appended drawings, produced by way of indicative and nonlimiting examples and in which:

FIG. 1 is a schematic front view of a solar panel according to the invention, according to a preferred embodiment,

FIG. 2 is a schematic front view of a solar panel according to the invention, according to another embodiment,

FIG. 3 illustrates a module grouping together four cells,

FIG. 4 is a cross-sectional view of the module of FIG. 3,

FIG. 5 shows schematically a sectional view of a solar panel according to the invention in which the cells are carried by a solar follower, and are oriented in a first direction,

FIG. 6 shows the panel of FIG. 5 where the cells are oriented in a second direction,

- Figure 7 is a schematic back view of the panel of Figure 5.

Preferred embodiments of the invention.

In FIG. 1, the solar panel P comprises a rigid frame or chassis 1, for example made of metal or plastic, of parallelepiped shape in which are installed photovoltaic cells 2 arranged in several parallel rows. The panel P can comprise from 1 to more than 100 cells 2. By way of example, its length is between 50 cm and 4 m, its width is between 20 cm and 3 m.

The frame 1 is preferably rectangular, but may be of any other shape, in particular of triangular shape as illustrated in FIG. 2.

Panel P can be used alone or be combined with one or more other similar panels within the framework of a photovoltaic farm. It can be installed on the ground, on roofs, covering residential or office facades, and generally on any vertical, horizontal or oblique surface.

-5Cells 2 are advantageously grouped into modules M. In FIG. 1, the panel P comprises 20 square modules M each integrating four cells 2. The modules M can have different shapes whose sides are equal (polygon, equilateral triangle, .. .), cylindrical, etc.

The cells 2 are flat and preferably square or substantially square in shape (for example with bevelled edges). For example, their length is between 2 cm and 50 cm, and their width is between 2 cm and 50 cm. The cells 2 may however have another shape, for example rectangular, polygonal or circular. Preferably, cells 2 based on monocrystalline or polycrystalline silicon are used, for example sold by the company Aoshike.

Referring to Figures 3 and 4, the panel P, and more particularly the module M, has cells 3 at the bottom of which are installed the photovoltaic cells 2. According to a preferred embodiment, the cells 3 are all identical, which simplifies the design of module M and panel P.

Each cell 3 has a bottom 30 and side walls 30. In FIGS. 3 and 4, the cells 3 have a square section and are delimited by four side walls 31. The cells 3 may however have another section, for example rectangular or polygonal with equal sides, or circular. In this case, the cell 3 has only one cylindrical side wall 31 which surrounds the bottom 30.

The cells 3 can be obtained by molding, or by stamping or stamping a metal plate 300, for example aluminum or any other light material resistant to corrosion. This plate 300 also delimits the walls of the module M.

At least one flat photovoltaic cell 2 is fixed in each cell 3 so as to form the bottom of said cell. For clarity, the following description refers to a single cell 2 per cell 3. However, several cells 2 can be accommodated in the same cell 3, for example 4 cells arranged in a square.

In practice, the cell 2 is fixed by gluing or welding against the bottom 30 of the cell 3. Also, the bottom 30 has a shape and dimensions corresponding to those of the cell 2.

The side walls 31 come flush with the edges of the cell 2. They are inclined at an angle "a" of between 60 ° and 70 °, preferably 65 °, relative to the surface of cell 2. When the cell 3 has a square section, it is thus delimited by four side walls 31 in the form of an inverted pyramid. And when the cell 3 has a circular section, it is delimited by a side wall 31 in the form of an inverted cone.

The walls 31 are covered with a reflective material. The face of the walls 31 which is located inside the cell 3, can for example be covered with a metallic material to form an optical reflection layer on which the solar radiation will rebound (shown diagrammatically by the dotted arrows on the figure 4). The reflective metallic material is preferably chosen from the following group: gold, cobalt, silver, nickel, copper, aluminum, chromium, zinc. It can be deposited by bonding, by electrochemical deposition, by electrolytic deposition, by printing, by screen printing, heating, or by any other thin layer adhesion process. The walls 31 may also consist of mirror glasses of the progressive glass type.

The inclination of the walls 31 and the reflective material make it possible to concentrate the solar radiation on the cell 2, thereby favoring a

-7amplification of photons from solar radiation. Thus the photovoltaic effect is accentuated.

For the same surface area of photovoltaic cells, with identical cells, and under the same sunshine and exposure conditions, the applicant was able to note a significant increase in the yield of the panel P. With cells 3 in accordance with the invention, photovoltaic cells can produce up to 180 Wp / m ² against 150 Wp / m ² without the alveolar system.

When the cell 2 forming the bottom of the cell 3 has a square shape, the best results are obtained when the height of the walls 31 is equal to half the length of the side of said cell 2. For example, if cell 2 at sides 10 cm long, the walls 31 preferably have a length of 5 cm. Similarly, when the cell 2 forming the bottom of the cell 3 has a circular shape, the best results are obtained when the height of the side wall 31 in the shape of an inverted cone is equal to half the diameter of said bottom.

Each cell 3 is hermetically sealed by a transparent plate 4 providing protection and sealing to the cells 2. Advantageously, an anti-reflective glass is used which allows a maximum of solar rays to pass through the cells 3. An air vacuum is created in each of the cells so as to improve the thermal insulation of the cells 2.

To simplify the design, the plate 4 is flat. However, it can be concave or convex. A concave or convex shape allows the plate 4 to absorb some of the ambient noise so that the panel P can be used as a soundproofing element.

As indicated above, the cells 3, and in fact the cells 2, are grouped in modules M installed on the panel P.

-8Each module M can be carried by a solar follower connected to a solar collector, which follower is controlled by means of actuators for a rotation of said module making it possible to follow the sun during its rise and its descent from East to West. It is therefore possible to orient the modules M in space as a function of the position of the sun, thus promoting a substantial increase in the production of electrical energy of each of said modules, and therefore of the panel P, relative to a fixed panel.

Each solar tracker is advantageously integrated into frame 1 of the panel P to improve the compactness of the latter. The kinematics of this solar tracker will now be explained with reference to FIGS. 5 to 7. Each module M is engaged with two ball joints, an upper ball joint 60 and a lower ball joint 61. These ball joints ensure a 90 ° rotation of the modules M ( shown schematically by the arrows F1 in Figure 5). These ball joints 60, 61 can be motorized.

The ball joints 60, 61 are mounted on a chassis 62. The latter is engaged with a gear system 63 whose kinematics allows vertical tilting of said chassis (arrow F2 in FIG. 6), and therefore of the corresponding module M, by example a vertical tilting of 45 °. This gear system 63 is advantageously driven by a motorization 630.

The chassis 62 is also engaged with another gear system 64 whose kinematics allows a longitudinal pivoting of the chassis (arrow F3 in FIGS. 5 and 6), and therefore of the module M. This pivoting is for example 90 °. This gear system 64 is advantageously driven by a motorization 640.

The various aforementioned motorizations are for example in the form of stepper motor with low energy consumption. They are

-9piloted by a central processing unit bearing the reference 65 in FIG. 7. This unit 7 integrates one or more processors and a memory in which one or more computer applications are recorded, the instructions of which, when executed by said processor, allow the various functions described in this description to be carried out. For the sake of clarity, it should be understood within the meaning of the invention that "the unit 7 does something" means "the computer application executed by the processor or microprocessor of the unit 7 does something".

The solar trackers can be synchronized so that the M modules move at the same time and in the same way. For this, the unit 7 is connected to a solar sensor 66 installed for example on the frame 1 of the panel P. This sensor 66 is adapted to detect the position in which the reception of the solar radiation is optimal. Depending on the data from this sensor 66, the unit 7 will control the movement of the solar trackers so that the modules all move along the same path.

In an alternative embodiment, the solar trackers can be desynchronized so that the modules M move independently of each other. For this, the unit 7 is connected to several solar collectors (not shown) which are each installed on a module. Depending on the data from these sensors, the unit 7 will independently control the movement of the solar trackers so that the modules move according to their own trajectory and allowing each of them to obtain optimal reception of the solar radiation.

The surface of panel P varies depending on the installation. For example, a panel P having a surface of photovoltaic cells of 3 m ² could comprise a hundred modules M of square shape with a side of 15 cm, ie a surface of 225 cm ² each.

- 10Between each adjacent module M, it is advantageous to provide a distance, for example of about 1 cm, to facilitate the different movements of the modules.

The exterior sides of the M modules can be decorated in any form of works of art, frescoes, paintings or other, showing, when they move, a change of decor on the sides of the modules.

The arrangement of the different elements and / or means and / or steps of the invention, in the embodiments described above, should not be understood as requiring such an arrangement in all implementations. In any event, it will be understood that various modifications can be made to these elements and / or means and / or stages, without departing from the spirit and scope of the invention.

Claims (10)

5 1. Solar panel comprising several photovoltaic cells (1), characterized by the fact that: your panel (p) has cells (3) delimited by at least one side wall (31), - at least one flat photovoltaic cell (2) is fixed in each cell (3) so that said at least one cell forms the bottom of said cell, - Said at least one side wall (31) of each cell (3) is covered with a reflective material and inclined so as to concentrate the solar radiation on said at least one photovoltaic cell (2) fixed in the bottom of said cell. 2. Solar panel according to claim 1, wherein the at least one side wall (31) of each cell (3) is inclined at an angle between 60 ° and 70 ° relative to the surface of the at least one cell photovoltaic (2) fixed in the bottom of said cell. 3. Solar panel according to one of claims 1 or 2, in which the bottom of each cell (3) has a square shape so that at least one photovoltaic cell (2) is surrounded by four side walls (31), the height of said side walls being equal to half the length of the side of said bottom. 4. Solar panel according to one of claims 1 or 2, wherein the bottom of each cell (3) has a circular shape so that the at least one photovoltaic cell (2) is surrounded by a side wall (31) conical , the height of said wall being equal to half the diameter of said bottom. 5. Solar panel according to one of the preceding claims, in which the cells (3) are grouped in mobile modules (M). 6. Solar panel according to claim 5, wherein each module 5 (M) is carried by a solar follower connected to a solar collector, which follower is controlled by means of actuators (60,61,62,63,630,640) for rotation of said module making it possible to follow the sun during its elevation and its descent from East to West. 10 7. Solar panel according to claim 6, wherein your solar trackers are synchronized so that the modules (M) move at the same time and in the same way. 8. The solar panel of claim 6, wherein your followers 15 solar are desynchronized so that the modules (M) move independently of each other. 9. Solar panel according to one of the preceding claims, wherein each cell (3) is hermetically sealed by a plate 20 transparent (4), an air vacuum being created in each of said cells. 10. Solar panel according to claim 9, wherein the transparent plate (4) is concave or convex.