阅读说明：本技术 浮置光伏模块 (Floating photovoltaic module ) 是由 吉尔伯特·埃尔·哈杰 马西厄·奇奥代蒂 雷米·莱·贝雷 弗雷代里克·瓦埃尔 于 2018-12-05 设计创作，主要内容包括：本发明涉及一种用于发电的浮置模块(1),所述浮置模块包括：-至少一个光伏面板(10),以及-浮置框架(20),所述面板(10)安装在所述浮置框架上,其特征在于,所述光伏面板(10)包括上部面和下部面,所述上部面和所述下部面能够通过光伏效应生成电力,并且其特征在于,所述浮置模块(1)进一步包括反射装置(40),所述反射装置能够朝所述面板的所述下部面(11)反射光线,所述反射装置(40)包括多个浮置反射球(41)和/或防水布(42),所述防水布附接到所述框架(20)。(The invention relates to a floating module (1) for generating electricity, comprising: -at least one photovoltaic panel (10), and-a floating frame (20) on which the panel (10) is mounted, characterized in that the photovoltaic panel (10) comprises an upper face and a lower face, which can generate electricity by the photovoltaic effect, and in that the floating module (1) further comprises reflecting means (40) capable of reflecting light rays towards the lower face (11) of the panel, the reflecting means (40) comprising a plurality of floating reflecting balls (41) and/or a tarpaulin (42) attached to the frame (20).)

1. A floating module (1) for power generation, the floating module comprising:

at least one photovoltaic panel (10), and

a floating frame (20) on which the panel (10) is mounted,

characterized in that the photovoltaic panel (10) comprises an upper face (11) and a lower face (12) capable of generating electricity by the photovoltaic effect, and wherein the floating module (1) further comprises reflecting means (40) capable of reflecting light towards the lower face (11) of the panel, the reflecting means (40) comprising a plurality of floating reflecting balls (41) and/or a tarpaulin (42) attached to the frame (20).

2. Floating module (1) according to claim 1, characterised in that said reflecting means comprise a plurality of floating reflecting balls (41), said floating frame (20) comprising a plurality of tubular elements (21) connected to each other to define at least one closed cell (24), said floating reflecting balls (41) being arranged in said at least one closed cell (24), said frame being further capable of retaining said balls inside said cell.

3. Floating module (1) according to claim 1, characterised in that the reflecting means comprise a tarp (42) fixed to the frame, and that the tarp (42) is reflective.

4. Floating module (1) according to claim 5, characterised in that the tarpaulin (42) is stretched over the frame (20) to extend above the surface of the water when the module (1) is placed on the water.

5. A floating module (1) according to any of the claims 1-3, characterized in that the tarp (42) is shaped to receive ballast water (B) and that the reflection means (40) further comprises a plurality of floating reflection balls (41), which plurality of floating reflection balls (41) are accommodated by the edge of the tarp and/or the floating frame.

6. Floating module (1) according to any of the previous claims, further comprising a solar azimuth tracking device (50) able to rotate the module (1) or the panel (10) according to the azimuth of the sun.

7. Floating module (1) according to any of the preceding claims, characterised in that each photovoltaic panel (10) extends at an angle between 0 ° and 40 ° with respect to the horizontal plane, and preferably at an angle between 25 ° and 35 ° with respect to the horizontal plane.

8. A photovoltaic power plant comprising a plurality of floating modules (1) according to any of the preceding claims.

Technical Field

The present invention relates to a floating module for power generation by means of photovoltaic panels, and to a power plant comprising several modules.

Background

Floating photovoltaic systems comprising one or more photovoltaic panels mounted on a floating frame are known. These systems are considered advantageous for several reasons, particularly as compared to conventional photovoltaic systems (meaning those mounted on the ground or on buildings).

On the one hand, the presence of water in the immediate environment of the photovoltaic system enables the panel to cool naturally and thus increase the efficiency. In addition, floating photovoltaic systems can bring benefits to their environment because they can limit unwanted algae growth or evaporation in, for example, lakes by blocking some light from reaching the water.

As an example, document US2006/0090789 discloses a floating photovoltaic module comprising a tubular frame comprising a cylindrical flotation element and connecting tubes connected to other identical structures. On this frame a photovoltaic panel is arranged, which comprises a single face provided with photovoltaic cells, this face being directed skyward.

This type of structure has limited effectiveness that cannot be increased by using double-sided panels because the water reflectance of about 7% is too low to justify the additional costs associated with such panels.

Document US2009/0120486 is also known, which describes a double-sided photovoltaic panel arranged parallel to the ground surface, on which a reflective coating is arranged. This structure is also limited from an efficiency point of view for several reasons.

On the one hand, no system for cooling the panel is described, so that a significant increase in the temperature of the panel, associated with direct and reflected light, can be predicted, which tends to reduce its efficiency.

Furthermore, in order to allow sufficient light to reach the reflective coating, the panels are positioned at a distance from each other, which increases the surface area required for the system.

Disclosure of Invention

In view of the above, it is an object of the present invention to at least partly overcome the drawbacks of the prior art.

In particular, it is an object of the present invention to provide a photovoltaic installation with an improved efficiency compared to the prior art.

Another object of the invention is to propose a plant with a reduced footprint.

In this respect, the invention proposes a floating module for power generation, comprising:

-at least one photovoltaic panel, and

-a floating frame on which the panels are mounted,

characterized in that the photovoltaic panel comprises an upper face and a lower face, the upper face and the lower face being able to generate electricity by the photovoltaic effect, and the floating module further comprises reflecting means able to reflect light towards the lower face of the panel, the reflecting means comprising a plurality of floating reflecting balls and/or a tarpaulin attached to the frame.

The floating frame of the floating module may comprise a plurality of tubular elements connected to each other to define at least one closed cell in which the floating reflective sphere is then arranged, the frame being further capable of retaining the sphere within the cell.

In embodiments where the reflective means comprises at least one tarp attached to the frame, the tarp is preferably reflective.

In one embodiment, the tarpaulin is stretched over the frame to extend over the surface of the water when the module is placed on the water. Alternatively, the tarp is shaped to receive ballast water, and the reflective device further comprises a plurality of floating reflective spheres accommodated by an edge of the tarp and/or the floating frame.

Advantageously, but optionally, the floating module may further comprise a solar azimuth tracking device capable of rotating the module or the panel according to the azimuth of the sun.

Preferably, each photovoltaic panel extends at an angle comprised between 0 ° and 40 ° with respect to the horizontal plane, and preferably at an angle comprised between 25 ° and 35 ° with respect to the horizontal plane.

The invention also relates to a photovoltaic power plant comprising a plurality of floating modules according to the above description.

The floating module according to the invention has a high efficiency. In fact, the use of double-sided photovoltaic panels and reflecting means on the floating modules enables the preservation of the advantages associated with floating modules (natural cooling, reduced evaporation, etc.) while increasing the efficiency of conventional photovoltaic barges.

In some embodiments, the reflective device comprises floating reflective spheres contained by tarpaulins or cross members that stiffen the frame. The spherical nature of the sphere allows to obtain a diffuse reflection of the incident light, so that the reflected light is better distributed on the lower face of the panel.

In certain embodiments, the reflective device comprises a tarp attached to the frame, which tarp is capable of stretching or receiving ballast water above the water. This stabilizes the module, which results in a good efficiency and a long service life of the module.

In the case of a tarp that is reflective, both the mechanical stabilization and the optical reflection function are achieved without additional costs.

In case the floating module further comprises a solar azimuth tracking device, the generation of electrical energy during the day is maximized.

Drawings

Other characteristics, objects and advantages of the invention will emerge from the following description, purely illustrative and not limitative, which is to be read with reference to the accompanying drawings, in which:

figure 1 shows an example of a floating module according to a first embodiment of the invention,

figures 2a and 2b show an example of a floating module according to a second embodiment of the invention,

figure 3 shows an example of a floating module according to a third embodiment of the invention,

figure 4 shows an example of solar azimuth tracking of a floating module,

figures 5a and 5b represent the relative gains in monthly and annual electrical energy production of a floating photovoltaic power plant according to an exemplary embodiment of the invention compared to a ground photovoltaic power plant provided with single-sided panels.

Detailed Description

With reference to fig. 1 to 3, a floating module 1 for power generation according to various embodiments of the present invention will now be described.

The floating module 1 is adapted to be mounted on a water surface. This surface may be, for example, a natural or artificial lake, a pond or even an ocean surface, preferably located in a location that is hardly exposed to waves and currents, such as a port, a small bay, a lagoon or the like.

The floating module 1 comprises at least one, and preferably several double-sided photovoltaic panels 10, for example up to ten double-sided photovoltaic panels 10. A "double-sided photovoltaic panel" is understood to mean a panel having photovoltaic cells suitable for generating electricity from photons by the photovoltaic effect, covered on two surfaces. In the present case, the surfaces covered with photovoltaic cells are opposite each other and comprise a so-called upper face 11 directed towards the sky in order to receive light directly from the sun, and a so-called lower face 12 (referenced in fig. 2 b) directed towards the water surface on which the module is placed in order to receive photons reflected on this water surface or on other reflective elements arranged on this surface, as described in detail below.

Advantageously, each photovoltaic panel 10 extends in a plane forming an angle comprised between 0 ° and 40 ° with respect to the plane of the water surface. Preferably, for better photovoltaic conversion efficiency, this angle is between 25 ° and 35 °. In practice, this angle is lower than 25 °, preferably 30 °, this angle corresponding to the position of maximum photovoltaic conversion efficiency.

The floating module 1 further comprises a floating frame 20 on which one or more photovoltaic panels 10 are mounted. This floating frame advantageously comprises a plurality of rectilinear and/or curvilinear tubular elements 21 suitable for assembly. To enable the module to float, the floating frame is preferably made of a lightweight material such as, but not limited to, polyethylene.

According to a preferred embodiment, the tubular elements connected to each other define at least one closed cell. For example, the frame may define a square or rectangular frame 22. As a variant, the frame may also comprise one or more cross-members 23 inside the frame, which define several closed cells 24 with the tubular elements forming the frame 22 (see fig. 2 a).

This structure, which comprises one or several closed cells, provides good stability of the module 1. To further increase this stability, the photovoltaic panel 10 carried by the frame advantageously does not extend beyond the cell or cells defined by the frame 10, in other words, said cell or cells are contained within the volume whose lateral edges are defined by the frame, as is the case in fig. 1 to 3.

As a variant, other forms of frame, such as a cross, can be produced by assembling the tubular elements.

Advantageously, but optionally, the floating module 1 may also comprise a platform 30 for accessing the panel 10, this platform being mounted on the frame 20. Such a platform is shown, for example, in fig. 3. In order to preserve the buoyancy of the module, the platform 30 is preferably made of a grid, in other words in the form of a lattice or grid. This platform is advantageously removable to be installed only in the context of maintenance and repair operations.

Floating module 1 further comprises reflection means 40 adapted to increase the albedo of the water surface on which the module is positioned.

In this way, the amount of incident light reflected towards the lower face of the photovoltaic panel is greater than without the reflecting means.

Figures 1 to 3 show different embodiments of such reflecting means.

According to the embodiment represented in fig. 3, the reflecting means 40 comprise a floating reflecting sphere 41. The ball is disposed on the surface of the water within each cell defined by the floating frame 20, and the frame 20 is advantageously shaped to contain a bead within the cell. For example, when the module 1 is positioned on a water surface, the height of the non-immersed portion of the tubular elements defining the frame 22 and the cross-member 23 with respect to the horizontal plane must be at least equal to one third of the height of the ball, and preferably at least equal to half the height of the ball. For example, the diameter of the ball may be between 20cm and 40cm, and the height of the tubular element and the non-immersed portion of the cross-member may be greater than 10cm, preferably greater than 15 cm.

The ball is preferably spherical to ensure better diffuse reflection of incident light. The balls are preferably white or coated with a reflective material, such as Mylar^TM. Alternatively, the ball may instead be coated with a white paint, or have a silver or gold colored surface provided by a coating or directly by the ball's constituent material (e.g., metal).

In this embodiment and as can be seen in fig. 3, the floating frame 20 preferably comprises a frame 22 and a plurality of cross members 23, enabling the use of frame 20 for stiffening while defining several cells where the balls are located. Good stability is then obtained for the module.

This embodiment is very attractive economically, since it enables good photovoltaic conversion efficiency to be obtained while reducing the number of components of the module.

As a variant, the reflecting means 40 are suitable for stabilizing the floating module 1 themselves. In this regard, the reflective device 40 may include a tarp 42 secured to the frame 20.

The tarpaulin 42 is preferably highly reflective. For example, the tarpaulin may be white by weaving with white thread or by painting to white; or may be made of highly reflective material (e.g., Mylar @)^TM) And (4) preparing.

Preferably, the reflective spheres and/or one or more tarpaulins are made of or coated with a non-contaminating material. For example, materials containing titanium oxide TiO are avoided.

According to a first embodiment, the tarpaulin 42 is stretched over the floating frame so as to extend above the water surface when the module 1 is placed on said water surface.

As in the example shown in fig. 1, the floating frame may comprise several cells defined by a frame formed by tubular elements and further cross members (not visible in the figure). In this case, the reflection means 40 may comprise several kinds of tarpaulins 42, each sized to cover and stretch over a respective battery.

The fact that the reflective tarpaulin is stretched over the frame makes it possible to both significantly increase the reflection of the light rays towards the lower face of the photovoltaic module and stiffen the frame and thus stabilize the module.

According to an alternative embodiment represented in fig. 2a and 2B, the tarpaulin 41 (not visible in fig. 2a) is sized and fixed to the floating frame 20 so as to be able to receive ballast water B, which makes it possible to stabilize the module. In this case, the tarpaulin is sized so that it can be stretched once the ballast water (preferably between 5 and 15cm in thickness, for example between 10 and 15 cm) is positioned on the tarpaulin. This enables the module to be stabilized while limiting the loss of the water-related reflection properties (albedo) of the tarpaulin.

However, in order to compensate for the loss of albedo of the tarp associated with the presence of ballast, the reflection means 40 very advantageously comprise floating reflection balls 42 placed on the ballast water and contained by the edges of the tarp 30 and, where appropriate, by the edges and/or cross-members of the floating frame 10. For example, the floating ball 42 may be contained on two opposite sides by the edges of the tarp 30 and on the other two sides by the edges or cross members of the floating frame 10.

In this embodiment, the reflection amount of light on the lower face of the panel is increased by the tarp and the reflection balls, and the module 1 is stabilized by the ballast water received on the tarp.

The choice of one of the previously described embodiments is derived from the compromise between the mechanical stability obtained (which is optimal in the case of the use of tarpaulins), the magnification of the reflection (which is optimal in the case of the use of spherical balls) and the economic criteria, the solution of combining a tarpaulin with a ball being the most advantageous, but also the most expensive, from the point of view of the previous standards.

With reference to fig. 4a and 4b, the module 1 advantageously comprises means 50 for tracking the solar azimuth. This device 50 makes it possible to rotate the module 1 during the day, so that the upper face of the panel is always directed towards the sun, in order to maximize the electrical energy produced from the panel.

Thus, as can be seen in fig. 4a, the solar azimuth tracking device enables positioning of the module such that the panel faces east in the morning, south in the midday, and west in the evening.

The azimuth tracking device 50 is well known to those skilled in the art and is sold by companies such as Upseatia new energy company (Upsolars), Mecasolar, Jsolar, and the like.

Depending on the amount of power desired to be produced, several modules may be grouped to form a photovoltaic power plant (not shown). In this case, the modules may be physically connected to each other by (possibly removable) attachment members and may be connected to a shared conversion device adapted to convert the direct current generated by the photovoltaic panels into alternating current suitable for injection into the power grid.

Referring to fig. 5a, a theoretical efficiency gain between a photovoltaic power plant created using floating modules according to an embodiment of the invention and a ground power plant comprising equivalent power of single sided panels is shown.

This efficiency gain has been modeled for an installed electrical power of 1 megawatt peak. The plant had 175 rows, each comprising 18 crystalline silicon double-sided photovoltaic panels, each having a peak power of 350 watts. The 18 panels of the row are distributed over 4 floating modules, for example two modules carrying 4 panels and two modules carrying 5 panels.

The floating plant was modeled for the following parameters:

-the plant is placed on a lake with a water temperature of 16 ℃,

the module comprises a reflective tarpaulin stretched over a frame according to the example in figure 1,

-the tarnish of the tarpaulin is 60%,

-the photovoltaic panel is inclined by 30 DEG with respect to the surface of the water,

-the panels are spaced apart by 2.85 meters,

-said module comprises a solar azimuth tracking device.

The ground power stations used for comparison have the same power and comprise the same number of rows and panels. The air temperature is considered to be one degree higher than the lake temperature. In addition, the station characteristics are as follows:

-the panel is one-sided,

-the panel is inclined 15 DEG relative to the ground surface,

-a soil albedo of 20%,

-the panels are spaced apart by 2.5 meters,

-the device does not comprise a sun azimuth tracking means.

In fig. 5a, an efficiency gain of 27% for february and 35% for february was observed, with an average efficiency gain of 31.2% for the year.

It is important to note that these figures are obtained for a tarp albedo of 60%, but this albedo may be even higher depending on the choice of material and/or coating of the tarp or reflective spheres.

In fig. 5b, the gain obtained by using the floating module according to the invention has been decomposed according to different parameters of the module. In particular, the importance of the double-sided aspect of the panel and the use of reflective means will be noted, as this is why an efficiency gain of 10.84% is produced.

Tilting the faceplate to 30 ° may also allow for a 10.98% increase in efficiency.

The solar azimuth tracking device allows a gain of 5.72% compared to the ground station.

Finally, it will be noted that the gain in productivity is not the sum of the gains produced by the different parameters, but is greater than this sum, so that it can be inferred therefrom that there is a synergistic effect between the factors that influence the overall gain in photovoltaic energy production.