ITBS20120080A1 - FLOATING PHOTOVOLATIC MODULE - Google Patents

Description

FLOATING PHOTOVOLATIC MODULE

DESCRIPTION

Scope of the invention

The present invention is placed in the field of renewable energies, and in particular it refers to a photovoltaic module able to be applied in an aquatic environment, such as for example the marine one.

State of the art

As is known, a photovoltaic module is a device composed of photovoltaic cells capable of converting solar energy directly into electricity by means of a photovoltaic effect and is used as a current generator in a photovoltaic system.

Photovoltaic systems are commonly divided into "grid-connect" systems, that is systems connected to an existing distribution network, or "stand-alone" systems, that is, not connected to any distribution network, for which they exploit the electricity produced directly on site.

The components of an off-grid photovoltaic system are generally a photovoltaic field, appointed to collect energy through photovoltaic modules suitably arranged in favor of the sun, a charge controller, appointed to stabilize the collected energy and manage it within the system and a battery accumulation, consisting of one or more rechargeable batteries suitably connected and designed to conserve the electrical charge supplied by the modules in the presence of sufficient solar radiation to allow their deferred use by the electrical appliances.

This type of "stand-alone" installation has also been developed for applications in the aquatic field, as described for example in EP-A-2287544.

In such systems the problem arises of regulating the position of the photovoltaic panels according to the solar irradiation.

To solve this problem, panels have been developed which include an actuation system capable of moving and adjusting the panel. This is because the surface of the water is subject to wave movements which can affect the optimal orientation of the panel. An example is described in US 2008/029148.

A further problem to which the panels in aquatic installations are subject are the climatic conditions and in particular the wind.

In fact, it appears that when the wind blows at high speed, the extended surface of the panel gives rise to a â € œsail effectâ € which can lead to damage to the supporting structure of the panel and associated equipment.

In DE 102006019753 a photovoltaic panel structure arranged on a floating platform is described. In particular, the panel is rotatably connected at one end in such a way as to be able to vary its inclination with respect to the surface of the water. To vary the inclination, the panel includes a balancing system with a floating body that provides an adjustment opening through which a desired quantity of water permeates inside the floating body, so as to make the body sink more or less with respect to the surface of water. In this way, when the lift of the wind acting on the face of the panel overcomes the buoyancy force of the floating body, it tends to sink, bringing the panel to a more flattened and aerodynamic position with respect to the surface of the water.

On the other hand, a wind blowing in the opposite direction with respect to the face of the panel leads also in this case to a sail effect that tends to bring the floating body towards the surface, and push the panel towards a configuration opposite to the desired one in which the impact of the wind increases instead of decreasing.

Summary of the invention

It is therefore an object of the present invention to provide a floating photovoltaic module which is self-regulating as a function of the climatic conditions to which it is subjected and in particular of the wind and which solves the drawbacks present in the known art.

It is another object of the present invention to provide a floating photovoltaic module which is modular and which is constructively simple and economical to produce.

It is a further object of the present invention to provide a floating photovoltaic module which allows to increase the quantity of perceived solar irradiation and therefore the electric energy produced through an optimal regulation with respect to the solar source.

These and other purposes are achieved by a photovoltaic module floating on a water surface of an aquatic environment, called floating photovoltaic module comprising:

a floating platform;

a first photovoltaic panel arranged on said floating platform, said first photovoltaic panel being rotatably connected to said platform about a first axis of rotation in such a way as to be able to vary its angle of inclination with respect to the surface of the water;

a second panel, preferably also photovoltaic, rotatably connected to said first photovoltaic panel, e

guide means associated with said second panel arranged on the floating platform in such a way that when a threshold value of the wind acting on the photovoltaic module is exceeded, the first and second panels can selectively pass from a first configuration in which the two panels are inclined to each other by a predetermined angle, to a second configuration in which the panels are substantially coplanar. In this way, the predisposition of the second panel means that the wind can blow indifferently in both directions avoiding the `` sail effect '' and obtaining an adjustment of their position towards a more flattened configuration so that the floating photovoltaic module does not suffer damage in adverse weather conditions of strong wind.

Preferably, the two panels are hinged at corresponding sides. The second panel is in turn guided in translation by the floating platform in correspondence with the side opposite to that of coupling with the first panel.

Advantageously, the second panel is also a photovoltaic panel. In a preferred embodiment, the first and / or the second photovoltaic panel are double-sided photovoltaic panels, capable of converting the light reflected and or diffused from the surface of the water into electrical energy.

Advantageously, a floating body is provided associated with the first photovoltaic panel, or with the second panel, able to support said first and second panels in said first configuration with a predetermined inclined position with respect to said water surface. In this way, it is possible to obtain a self-regulation without actuation systems given by a balance that is created between the hydrostatic thrust acting on the floating body and the force acting on the face of the panel or second photovoltaic panel by the wind. On the other hand, when the wind decreases in intensity, the panel and the second photovoltaic panel assume a new position of equilibrium with a predetermined inclination between them.

In particular, said floating body is mounted on a support arm which extends from said first axis of rotation of said panel and which forms a constant angle with said panel. Preferably the arm is fixed to the first photovoltaic panel and rotates integrally with it. In this way, the support arm, at the end of which there is the floating body, creates a lever effect on the rotation axis of the panel which generates a respective rotation torque, so that as the depth of the floating body varies in the water, the angle of inclination of the first photovoltaic panel and the second panel with respect to the surface of the water may vary.

Advantageously, said support arm comprises removable locking means adapted to allow relative rotation between the arm and the first photovoltaic panel during transport. In particular, the locking means allow the fixing of the support arm between an open position in which said support arm forms with said first photovoltaic panel a predetermined angle, i.e. the constant angle to which reference has been made above, and a closed position in which said support arm is substantially joined to said first photovoltaic panel, ie the angle between them is substantially zero. In this way, it is possible to transport each floating photovoltaic module with minimum space. In addition, this solution allows multiple photovoltaic modules to be stacked together for transport.

Alternatively, said floating photovoltaic module can comprise actuation means powered by the electrical energy produced by the module itself, associated with sensor means suitable for allowing the selective passage between said first and second configuration according to the data measured by said means to sensor. In other words, the electric and motorized actuation means operate in feedback on the basis of the signals sent by the sensors.

Preferably, said second panel is a second photovoltaic panel.

In particular, said floating platform comprises a plurality of floating tubular elements adapted to form a polygonal floating support frame, in particular rectangular, on which at least one floating photovoltaic module is arranged.

Preferably, said first axis of rotation of said first photovoltaic panel is coaxial with a tubular element at the end of said rectangular floating structure, while said guide means are arranged on the opposite side to said tubular end element on a corresponding pair of tubular elements between which translates said second photovoltaic panel. In this way, the first photovoltaic panel and the second panel rotatably connected to each other forming a book connection, are able to pass from the first configuration in which they are inclined to each other, to the second configuration in which they are substantially coplanar respectively by rotating around said axis of rotation and translating along the guide.

Advantageously, each floating photovoltaic module comprises cooling means suitable for spraying a flow of cooling fluid, in particular water, on the surface of said first photovoltaic panel in order to maintain its temperature within a preferential threshold.

In particular, each floating photovoltaic module further comprises washing means suitable for washing the surface of said first photovoltaic panel.

According to another aspect of the invention, a photovoltaic system comprising a plurality of said photovoltaic modules connected together by means of connection suitable to form a matrix of photovoltaic modules. In this way, a photovoltaic system with the desired power and with a predetermined composition according to the type and place of application can be obtained.

In particular, said connection means comprise a plurality of inextensible cables, for example steel cables, suitable for forming a weft and a warp, or a grid, depending on the desired matrix pattern. In detail, said plurality of cables keep said photovoltaic modules adjacent to each other through a compression force, or act as tie rods.

Preferably, said plurality of cables pass through said tubular elements of the floating support frame. In particular, each floating tubular element comprises in both its ends a guide bush for said connection cable. In this way, the bushing allows the cable to be kept in a substantially concentric position with respect to the tubular element.

In particular, said plurality of cables also has the advantage of being able to keep the photovoltaic modules in a stacked configuration, arranged in the closed position of the floating body, during transport. This brings a considerable advantage in reducing the overall dimensions and therefore leads to an appreciable saving in installation costs.

A filling material, for example expanded polyurethane, is preferably provided inside the tubular element.

Alternatively, electronic and / or electrical components can be arranged inside the tubular element for the operation of each floating photovoltaic module and / or energy storage batteries.

Advantageously, each floating support frame comprises damping means suitable, in use, to allow relative movement between the various photovoltaic modules connected to each other. In this way, the plurality of photovoltaic modules is able to follow and support the wave movement of the water surface.

In particular, said shock-absorbing means comprise an elastic shock-absorbing element arranged at the ends of a respective support frame able to come into contact with a corresponding end of an adjacent floating support frame. In this way, the deformation of the elastic element allows to attenuate relative movements between the various modules due to the wave motion of the water surface. In practice, the elastic response of each damping element balances the force exerted by the corresponding connection cable of adjacent modules.

According to a further aspect of the invention, the use of the aforementioned floating photovoltaic module or system in the field of fish farming includes or is associated with means of feeding fish food, operated by means of the electricity produced by said first photovoltaic panel. In particular, said means for administering food are associated with a timer which allows them to be activated at a predetermined rate.

Preferably, the module or the photovoltaic system can also be associated with oxygenation means for the water, also powered by the electricity produced, in such a way as to form a self-supplying system capable of operating autonomously.

In other words, the module according to the invention can be associated with the livelihoods of the fish that live in the body of water on which the module is positioned. This feature creates a synergistic effect, in the sense that the photovoltaic module associated with fish livelihoods allows to obtain a structure particularly suitable for fish farming or to grow pints or vegetables compatible with fish farming, in particular a structure that allows to maximize fish production. This feature is independent from the structure of the photovoltaic module and the Applicant reserves the right to file a corresponding divisional patent application.

Advantageously, said module or said photovoltaic system can comprise or be associated with means for recovering fishing nets for collecting fish.

In particular, said module or said photovoltaic system can also comprise or be associated with lighting means, in particular LED lighting means designed to illuminate the fish farming area to increase the hours of light to which the fish are exposed and therefore maximize it. their growth.

In particular, the system integrated with said module or said photovoltaic system which comprises said means of feeding the feed, said means of oxygenation, said means of lighting, said means of recovery of the nets for the collection of fish is an autonomous system energetically, with zero environmental impact named by the applicant Power Aquaponics.

Description of the drawings

Further characteristics and advantages of the invention will be better highlighted by examining the following detailed description of a preferred but not exclusive embodiment, illustrated by way of non-limiting example, with the support of the attached drawings, in which:

Figure 1 shows a perspective view of a floating photovoltaic module, according to the invention, in a first configuration of use, in which a first and second panel are inclined to each other due to the support given by a floating body;

- figure 2 shows a perspective view of the floating photovoltaic module of figure 1, in which a second folded configuration is shown, in which the first and second panels are coplanar with each other;

ï € Figures 2A and 2B show a perspective view of the floating photovoltaic module of figure 1, in which an intermediate configuration is shown, in which the first and second panels move towards the folded configuration due to the wind exceeding a value of predetermined threshold;

- figure 3 shows a perspective view of the floating photovoltaic module of figure 1, in a transport configuration in which the floating body is joined to the first panel to reduce its size; - Figure 4 shows a perspective view of a photovoltaic system composed of a plurality of photovoltaic modules connected together with cable connection means so as to form a matrix of photovoltaic modules of any size;

ï € figure 5 shows a detailed view of a tubular element that makes up the floating platform inside which a connection cable passes between different photovoltaic modules;

- Figure 6 shows a perspective view of a series of photovoltaic modules stacked together in a transport configuration;

Figure 7 shows a schematic perspective view of the array of photovoltaic modules implemented with washing means, cooling means, feeding means for fish and oxygenation means.

Detailed description of the invention

With reference to Figure 1, a floating photovoltaic module 100 is shown, able to float on the surface of the water 150 in an aquatic environment 250. In particular, the floating photovoltaic module 100 comprises a floating platform 10 and a first photovoltaic panel 20 arranged on the floating platform 10. The first photovoltaic panel 20 is rotatably connected to the floating platform 10 around a first axis of rotation 21 by means of a hinge 21a (Fig. 5), so as to be able to vary its angle of inclination ï ¢ with respect to the water surface 150.

In addition, the floating photovoltaic module 100 comprises a second panel 25 rotatably connected to the first photovoltaic panel 20 around a second axis of rotation 26, and guide means 30 associated with the second panel 25 arranged on the floating platform 10 so that, at the exceeding a threshold value of the wind acting on the floating photovoltaic module 100, the first photovoltaic panel 20 and the second panel 25 can selectively pass from a first configuration A in which the first photovoltaic panel 20 and the second panel 25 are inclined to each other of a predetermined angle ï ¡(Fig.1), to a second configuration B in which the first photovoltaic panel 20 and the second panel 25 are substantially coplanar with each other ï ¡= 180 ° (Fig.2).

Figures 2A and 2B show intermediate configurations of passage between the first A and second configuration B. In this way, the second panel 25 acts as a deflector panel and ensures that the wind can blow indifferently in both directions, avoiding the â € ™ â € sail effectâ €, as in the case of the known technique, and obtaining an adjustment of their position towards a more flattened configuration in an indifferent way. In the representations of figures 1 and 2, three photovoltaic modules are provided aligned with each other and mounted on the same floating platform 10, as subsequently described.

Advantageously, the second panel 25 is also a photovoltaic panel. In a preferred embodiment, the first and / or the second photovoltaic panel 20,25 are double-sided photovoltaic panels, capable of receiving reflected and or diffused light from the surface of the water 150.

In particular, in a preferred embodiment, each photovoltaic module comprises a floating body 40 associated with said first 20 and second photovoltaic panel 25 adapted to support the first 20 and second photovoltaic panel 25 in a predetermined inclined position with respect to the surface of the water 150. In this way, it is possible to obtain a self-regulation given by a balance that is created between the hydrostatic thrust acting on the floating body 40 and the force acting on the face of the first 20 or second 25 photovoltaic panel by the wind . On the other hand, when the wind drops below the threshold value, the first panel 20 and the second photovoltaic panel 25 assume a corresponding equilibrium position with a predetermined inclination between them. In other words, such a photovoltaic module can self-adjust according to the intensity of the wind even in an intermediate position between the normal operating position and the fallback position it assumes when the wind exceeds the threshold value.

In particular, the floating body 40 is mounted on a support arm 42 which extends starting from the first axis of rotation 21 of the first panel 20 and which forms a predetermined angle ï with the panel. The angle ï ¢ can also be adjusted according to the type of application for which the photovoltaic module is intended. In this way, the support arm 42, at the end of which the floating body 40 is present, creates a lever effect on the first axis of rotation 21 of the first panel 21 which generates a respective rotation torque, so that as the depth of the floating body 40 can vary the angle of inclination between the first panel 20 and the second panel 25 with respect to the surface of the water 150. The floating body 40 preferably has a predetermined buoyancy so that you are the wind exceeds the threshold value this sinks, and then resurfaces proportionally when the wind intensity falls below the threshold value.

In particular, as shown in Figure 3, the support arm 42 comprises removable locking means 45 adapted to allow the fixing of the support arm 42 between an open position C (Fig. 2) in which the support arm 42 forms with the first photovoltaic panel 20 the predetermined angle ï ¢, and a closed position D (Fig. 3) in which the support arm 42 is substantially joined to the first photovoltaic panel 20. In this way, it is possible to transport each floating photovoltaic module 100. Furthermore, this solution allows several photovoltaic modules to be stacked together for transport, as subsequently shown with reference to figure 6.

On the other hand, the floating photovoltaic module 100 can comprise actuation means powered by the electricity produced, associated with sensor means capable of allowing the selective passage between the first A and second B configuration according to the data measured by the sensor means (not shown). This solution can be adopted, for example, in combination with the floating body 40 in order to facilitate the closure of the two panels in adverse weather conditions in which the wind has a strong intensity. In addition, the actuators can be used to adjust the inclination of the two panels 20 and 25 to optimize the orientation and collection of solar radiation.

Constructively, the floating platform 10 comprises a plurality of floating tubular elements 12,12â € ™, 13,13â € ™ suitable to form a polygonal floating support frame, in particular rectangular, on which at least one floating photovoltaic module 100 is arranged. Preferably, the tubular elements 12,12â € ™, 13,13â € ™ are made of plastic material.

In particular, always with reference to Figures 2 and 2A, the first axis of rotation 21 of the first photovoltaic panel 20 coincides with an end tubular element 13 of the floating support frame, while the guide means 30 are arranged on the opposite side with respect to the end tubular element 13 between a corresponding pair of tubular elements 12, 12a or 12a, 12b or 12b, 12â € ™ between which the second photovoltaic panel 25 moves. In this way, the first photovoltaic panel 20 and the second photovoltaic panel 25 rotatably connected to each other forming a book connection, are able to pass from the first configuration A in which they are inclined to each other, to the second configuration B in which they are substantially coplanar, rotating respectively around the first axis of rotation 21 and translating along the guide 30.

In particular, as evident in Figure 2A, the guide means 30 extend for a determined length L in such a way as to act as an end stop for the sliding of the second panel 25. In this way, when the floating body 40 is substantially at the level of the water surface 150 a configuration is obtained in which the first 20 and the second 25 panels form an angle ï ¢ of approximately 45 °. (Fig.1)

As shown in Figure 7, each floating photovoltaic module 100 can comprise cooling means 160 adapted to spray a flow of cooling fluid, in particular water, on the surface of the first and / or second photovoltaic panel 20,25 in order to reduce its temperature. This solution can be the subject of an independent invention with respect to that relating to the photovoltaic module described above.

In addition, each floating photovoltaic module 100 can comprise washing means 170 adapted to wash the surface of the first and / or second photovoltaic panel 20,25.

In a preferred embodiment, as shown in Figure 4, a photovoltaic system can be made comprising a plurality of photovoltaic modules 100 connected to each other by means of connection 50 adapted to form a matrix 200 of photovoltaic modules 100. In this way, it can be obtained a photovoltaic system of desired power and with a predetermined composition according to the type and place of application.

In particular, the connecting means 50 comprise a plurality of inextensible cables 52 suitable for forming a weft and a warp which is a function of the desired matrix composition. In detail, the plurality of cables 52 keep the photovoltaic modules 100 adjacent to each other, generating a compression force. In addition, the cables 52 can provide connection ends 53 in such a way as to be able to anchor the floating platform, for example, to a dock on the ground.

More specifically, the plurality of cables 52 pass through the tubular elements 12,12â € ™, 13,13â € ™ of the floating support frame. In particular, as shown in Figure 5, each floating tubular element 12 and 12â € ™ includes in both its ends a guide bush 14 for the connection cable 52. In this way, the guide bush 14 allows to keep in position substantially concentric the cable with respect to the tubular element 12.

Inside the tubular element there is preferably a tubular guide portion 15 aligned with the guide bushing 14 in which the cable 52, shown schematically, is inserted. A filling material, for example expanded polymer, can be provided outside the tubular guide portion 14.

Alternatively or in combination, electronic and / or electrical components can be arranged inside the tubular element 12 for the operation of each floating photovoltaic module 100 and / or energy storage batteries.

In addition, each floating support frame comprises damping means 60 suitable, in use, to allow relative movement between the various photovoltaic modules 100 connected to each other. In this way, the plurality of photovoltaic modules is able to follow and support the wave movement of the surface of the water 150. More particularly, the damping means 60 comprise an elastic shock-absorbing element 62 arranged at the ends of a respective element tubular 12, 12â € ™ (Fig.2) adapted to come into contact with a corresponding end of a tubular element 12, 12â € ™ of an adjacent floating support frame, so as to act as a buffer. In particular, the elastic element 62 is made of elastomer and has a through hole 63 so that the connection cable 52 can pass inside it. In this way, the deformation of the elastic element 62 allows to attenuate relative movements between the various photovoltaic modules 100 due to the wave motion of the water surface 150. The elastic element 62 is also used for tensioning the frames support each other.

In particular, the aid of the plurality of cables 52, as shown in Figure 6, has the advantage of being able to keep the photovoltaic modules 100 in a stacked configuration, arranged in the closed position D of the floating body 40, during their transport. This brings a considerable advantage in reducing the overall dimensions and therefore leads to an appreciable saving in installation costs.

In a preferred embodiment, the floating photovoltaic module 100 is used in the field of fish farming and comprises feeding means 180 for fish feed, operated by means of the electrical energy produced by said first photovoltaic panel 20. In particular, the means for administering the food 180 are associated with a timer 190 which allows them to be activated at a predetermined rate. In other words, the module according to the invention can be associated with the livelihoods of the fish that live in the body of water on which the module is positioned. This feature creates a synergistic effect, in the sense that the photovoltaic module associated with fish livelihoods allows to obtain a structure particularly suitable for fish farming or to grow pints or vegetables compatible with fish farming, in particular a structure that allows to maximize fish production. This feature is independent from the structure of the photovoltaic module and the Applicant reserves the right to file a corresponding divisional patent application.

Still in addition, again with reference to figure 7, the module 100 or photovoltaic system 200 can be associated with oxygenation means 195 of the water also fed by means of the electricity produced, in such a way as to form a self-supplying system. able to function autonomously.

Advantageously, the module 100 or said photovoltaic system 200 can comprise or be associated with means 220 for recovering fishing nets for collecting fish. That is, below the photovoltaic system where schools of fish are collected, perimeter networks can be provided operated by means of dedicated actuators, also powered by the electricity produced by the module or by the photovoltaic system, capable of moving the networks for the collection of fish.

In addition, said module 100 or said photovoltaic system 200 can also comprise or be associated with lighting means 230, in particular LED lighting means 230 suitable for illuminating the fish farming area to increase the hours of light to which the fish are exposed. fish and thus maximize their growth.

In particular, the system integrated with said module 100 or said photovoltaic system 200 which comprises said means of feeding the feed, said means of oxygenation, said means of lighting 230, said means of recovery 220 of the nets for the collection of fish is a autonomous system energetically, with zero environmental impact named by the applicant Power Aquaponics.

Claims (19)

CLAIMS 1. A floating photovoltaic module (100) able to float on the surface of the water (150) in an aquatic environment (250), called floating photovoltaic module (100) comprising: ï € a floating support platform (10); ï € at least a first photovoltaic panel (20) arranged on said platform, said first photovoltaic panel (20) being rotatably connected to said platform around a first axis of rotation (21) in such a way as to be able to vary its angle of inclination ï ¡With respect to the surface of the water (150); characterized in that said floating photovoltaic module (100) further comprises: a second panel (25) rotatably connected to said first photovoltaic panel (20), e Guide means (30) associated with said second panel (25) arranged on said floating platform in such a way that when a wind threshold value is exceeded, said first photovoltaic panel (20) and said second panel (25) can selectively switch from a first configuration (A) in which said first photovoltaic panel (20) and said second panel (25) are inclined to each other, to a second configuration (B) in which said first photovoltaic panel (20) and said second panel (25) are substantially coplanar. 2. Photovoltaic module (100) according to claim 1, comprising a floating body (40) associated with said first photovoltaic panel (20) and said second panel (25) to support them in a predetermined inclined position with respect to said water surface (150), in particular, said floating body (40) is mounted on a support arm (42) which extends from said first axis of rotation (21) of said first photovoltaic panel (20) and which forms with said first photovoltaic panel (20) a predetermined angle (ï ¢). Photovoltaic module (100) according to claim 2, wherein said support arm (42) comprises removable locking means (45) adapted to allow the fixing of the support arm (42) between an open position (C) in which said support arm (42) forms with said first photovoltaic panel (20) said predetermined angle (ï ¢), and a closed position (D) in which said support arm (42) is substantially joined to said first photovoltaic panel ( 20). 4. Photovoltaic module (100) according to claim 1, wherein said second panel (25) is also a photovoltaic panel, in particular said first photovoltaic panel is a double-sided photovoltaic panel, capable of receiving reflected light and or diffused from the surface of the water, in particular, said first (20) and second (25) photovoltaic panels are double-sided panels. 5. Photovoltaic module (100) according to claim 1, comprising actuation means powered by the electrical energy produced by the module itself, associated with sensor means suitable for allowing the selective passage between said first and second feedback configuration on the basis of the data measured by said sensor means, in particular said actuation means are also used to adjust the inclination of said first and second panels in order to optimize their exposure to solar radiation. 6. Photovoltaic module (100) according to claim 1, wherein said floating platform (10) comprises a plurality of floating tubular elements (12, 12â € ™, 13, 13â € ™) adapted to form a polygonal floating support frame. 7. Photovoltaic module (100) according to claim 5, wherein said first axis of rotation (21) is coincident or coaxial with an end tubular element (13) of said rectangular floating structure, while said guide means (30) are arranged on the opposite side to said tubular end element (13) on a corresponding pair of tubular elements (12, 12 ', 13, 13', 12a or 12a, 12b or 12b, 12) between which one side moves of said second photovoltaic panel (25). Photovoltaic module (100) according to claim 1, comprising cooling means (160) suitable for spraying a flow of cooling fluid, in particular water, on the surface of said first photovoltaic panel (20) in order to control its temperature. Photovoltaic module (100) according to claim 1, further comprising washing means (170) adapted to wash the surface of said first photovoltaic panel (20). Photovoltaic system comprising a plurality of photovoltaic modules (100) according to any one of the preceding claims 1-8, connected to each other by means of connection (50) adapted to form a matrix of photovoltaic modules. 11. Photovoltaic system according to claim 9, wherein said connecting means (50) comprise a plurality of inextensible cables (52) adapted to form a weft and a warp depending on the desired matrix composition, in particular said plurality of cables (52 ) pass through said tubular elements (12, 12â € ™, 13, 13â € ™) of said floating support frame, in particular, each floating tubular element (12) comprises in both its ends a guide bushing (14) for said connection cable (52). Photovoltaic system according to claim 10, wherein said plurality of cables (52) allows said photovoltaic modules (100), arranged in the closed position (D) of the floating body (40), to be kept in a stacked configuration during transport. 13. Photovoltaic system according to claim 9, in which electronic and / or electrical components can be arranged inside each of the tubular elements (12) for the operation of each floating photovoltaic module (100) and / or storage batteries power. Photovoltaic system according to claim 9, wherein each floating support frame comprises damping means (60) adapted, in use, to allow relative movement between the various photovoltaic modules connected to each other. 15. Photovoltaic system according to claim 13, wherein said damping means (60) comprise an elastic damping element (62) arranged at the ends of a respective support frame able to come into contact with a corresponding end of an adjacent support frame floating. 16. Use of the photovoltaic module or system according to any of the preceding claims for fish farming by associating at least one photovoltaic module (100) means (180) for feeding fish food, operated by means of electricity produced by said first photovoltaic panel (20). 17. Use of the photovoltaic module or system according to any of the preceding claims for fish farming by associating at least one photovoltaic module (100) with oxygenation means (195) of the water fed by the electricity produced , in such a way as to form a self-powered system capable of operating autonomously. 18. Use of the photovoltaic module or system according to any one of the preceding claims by associating with at least one photovoltaic module (100) means of recovery 220 of fishing nets for the collection of fish. 19. Use of the photovoltaic module or system according to any one of the preceding claims by associating lighting means (230) with at least one photovoltaic module (100), in particular LED lighting means (230) suitable for illuminating the breeding area to increase the hours of light to which the fish are exposed and thus maximize their growth.