BG113599A - Floating photovoltaic platform - Google Patents

Abstract

The created floating photovoltaic platform includes a supporting metal structure, on the underside of which main supporting element (2) pontoon bodies (1) formed in groups (10) are established. On the upper side of the main supporting element (2) are located movable photovoltaic modules (5), composed of a frame (7) in which photovoltaic panels (6) are placed and are able to change their angle relative to the horizon from -15° up to +45° via a lever assembly comprising an upper arm (9), a lower arm (4) and a linear actuator (8). The upper arm (9) and the lower arm (4) at one end are connected to the working body of the linear actuator (8), and the other end of the upper arm (9) is connected to one end of the frame (7), as the other end of the lower arm (4) is connected to a supporting beam (12) of the supporting metal structure. The opposite end of the frame (7) is connected to a bearing body (15) fixed to the main support element (2). The movable photovoltaic modules (5) are arranged on the main supporting element (2) in two oppositely located photovoltaic fields (13.a and 13.b), separated from each other by a service path (11), as each photovoltaic field (13.a and 13.b) is composed of the photovoltaic modules (5) arranged in rows.

Description

Floating photovoltaic platform

Field of technique

The present invention relates to a floating photovoltaic platform, which will find application in the field of solar energy and more specifically in the construction of floating photovoltaic installations.

Prior art

Floating photovoltaic systems are an emerging market with the potential for rapid growth. Demand for floating photovoltaic systems is increasing, especially in island and other land-limited countries, as the cost of water surface is generally cheaper than that on land. Such floating solar systems are particularly suitable for Asia, where land area is scarce but there are many dams for hydropower generation with ready transmission infrastructure. Europe also has huge potential for the application of floating photovoltaic systems, especially in the Netherlands and France. The engineering challenges to be overcome in these systems are, for example, the anchoring systems that must be designed to withstand the dynamic forces of waves and strong winds, but experts in the field still lack sufficient experience to implement such floating plant systems, therefore these installations are always mobile to some extent.

Providing additional space, floating PV systems are relatively easy to install and their efficiency is aided by additional water cooling. In addition, if necessary, they can also change their place. Photovoltaic systems themselves include photovoltaic modules, each of which is a system of modules of photovoltaic panels mounted on a common panel and connected in series or parallel, depending on the desired values of current and voltage at a given power.

International patent application WO2020/225382A1 is known, relating to a floating support device which is intended for the production of solar energy. The floating device includes a supporting metal structure composed of a main supporting element, on the underside of which a pontoon body is established at each of its two ends. Photovoltaic modules are located on the upper side of the support element, each of which is fixedly attached to an arm fixed on the main support element. Photovoltaic modules include a frame in which photovoltaic panels are housed. In this way, the photovoltaic modules are stationary and are fixed at a certain degree on the stationary metal structure, and the angle between the photovoltaic panels and the surface of the supporting element always remains constant with respect to the horizon, therefore the modules are in the same position regardless of the change in the meteorological situation. Photovoltaic modules are mechanically fixed, whereby opposite panels are located in close proximity and form a common "edge", with the distance between them being within a few centimeters. The lower edge of the photovoltaic module, which is closest to the water surface, is a few centimeters above the pontoon bodies and above the supporting structure.

With the floating support device constructed in this way, there is no reflective surface under the photovoltaic modules and it relies only on the natural reflection of light from the water surface, it is extremely weak and low-intensity - about 4-5%.

Technical essence of the invention

The task of the invention is to create a floating photovoltaic platform that provides both increased productivity due to more efficient utilization of solar energy and longer life due to the elimination of the possibility of accidents caused by changing climatic conditions.

The task was solved by creating a floating photovoltaic platform, which includes a supporting metal structure on the underside of which pontoon bodies are established as the main supporting element. Photovoltaic modules are located on the upper side of the main support element, each of which is composed of a frame in which photovoltaic panels are placed.

According to the invention, groups of pontoon bodies are formed from the pontoon bodies, and each group of pontoon bodies is fixed to a metal frame of the supporting metal structure. Photovoltaic modules are movable with the possibility of changing their angle relative to the horizon from - 15° to + 45° using a lever module. The lever assembly is composed of an upper arm, a lower arm and a linear actuator. The upper arm and the lower arm are connected at one end to the working member of the linear actuator. The other end of the upper arm is connected to one end of the frame of the photovoltaic modules, and the other end of the lower arm is connected to a supporting beam of the supporting metal structure. The opposite end of the frame is connected to a bearing body fixed to the main support member.

The exact positioning of the movable photovoltaic modules and their movement in relation to the change of the solstices is controlled by a system including sensor devices for reading the intensity of the sun, its location, for reading the indicators of h

environment and others. Shielding elements are established between the supporting beam and the main supporting element. The movable photovoltaic modules are arranged on the main support element in two oppositely located photovoltaic fields, separated from each other by a service path. Each photovoltaic field is composed of the photovoltaic modules arranged in rows, where each row is composed of three to four photovoltaic modules and the rows are one to three. The service path is composed of two elements, movably connected to each other and covered with a light-reflective coating.

In the preferred embodiment of the invention, the photovoltaic panels arranged in each photovoltaic module are arranged with their long side parallel to the horizon. The distance between the nearest edges of the frames of the movable photovoltaic modules is determined for each specific case and is in the range of 0.5 to 3 cm. In the preferred embodiment, the linear actuator is a linear actuator.

A variant embodiment of the invention is possible, in which reflective elements are located under the lower surface of the photovoltaic panels. The light-reflecting coating of the service path is a reflective paint, and the shielding elements are made of PVC, or of high-density polyethylene, or of textile, or of fiberglass, or of another material with increased light-reflecting ability.

An advantage of the created floating photovoltaic platform is its increased productivity thanks to the efficient utilization of solar energy due to the possibility of optimal orientation of the photovoltaic modules in relation to the sun through the application of a tracker system that ensures their management. The presence of a reflective coating focuses the reflected light to the underside of the photovoltaic modules, which also leads to an increase in the overall performance of the platform. On the other hand, the presence of a service path located in the central part of the platform leads to an increase in the air flow between the modules, thus lowering their operating temperature. The maintenance of the platform is relatively cheap, and it is provided with a longer life due to the possibility of bringing the photovoltaic modules to a horizontal position in strong winds. This reduces wind resistance, which is a prerequisite for fewer accidents and broken anchors.

Description of attached figures

The present invention is illustrated in the accompanying figures, wherein:

Figure 1 is a top view of a plurality of an unlimited number of floating photovoltaic platforms arranged in rows and columns connected to each other and forming a photovoltaic power generation park;

Figure 2 is an enlarged view A showing arrangement of elements of Figure 1;

Figure 3 is an axonometric view of the main supporting metal structure of a floating photovoltaic platform with arrangement of groups of pontoon bodies;

Figure 4 is an axonometric view of a pair of symmetrically located closed movable frames of photovoltaic modules of a floating photovoltaic platform;

Figure 5 is an enlarged view B showing arrangement of elements of Figure 4;

Figure 6 is an axonometric view of both a pair of symmetrically located and open at 5° to the horizon mobile frames of the photovoltaic modules of a floating photovoltaic platform, as well as service paths located in a horizontal position and those at an angle;

Figure 7 is a side view of a pair of symmetrically located photovoltaic modules closed at -15° to the horizon from a floating photovoltaic platform;

Figure 8 is a side view of a pair of symmetrically located 45° horizontal movable frames with photovoltaic panels from a floating photovoltaic platform and service paths; and

Figure 9 is a side view of a pair of movable PV panel frames from a floating PV platform, with one PV array translated to -15° and the other PV array elevated 45° to the horizon by means of a lever module driven by a linear actuator .

Examples of implementation of the invention

The created floating photovoltaic platform shown in the attached figures includes a supporting metal structure on the underside of whose main supporting element 2 pontoon bodies 1 are established. The pontoon bodies 1 are formed into groups 10 of pontoon bodies 1, and each group 10 of pontoon bodies 1 is fixed to a metal frame 14 of the supporting metal structure shown in figure 3. On the upper side of the main supporting element 2 are located mobile photovoltaic modules 5, each of which is composed of a frame 7 in which photovoltaic panels 6 are placed.

The photovoltaic panels 6 arranged in each photovoltaic module 5 are located with their long side parallel to the horizon, shown in figures 1 and 2. The distance between the nearest edges of the frames 7 of the movable photovoltaic modules 5 is determined for each specific case and is in the range from 0.5 to 3 sh. This allows the passage of a larger volume of air mass, as a result of which the cooling of the photovoltaic panels 6 is improved. Cooling them with each degree lower operating temperature of the panel 6 leads to a 0.5% higher efficiency of electricity production. Furthermore, the distance between the frames 7 allows more direct and diffused light to enter, thereby increasing the energy absorbed by the photovoltaic panels 6. An embodiment is possible in which reflective elements are placed under the lower surface of the photovoltaic panels 6, i.e. the panels 6 have two working surfaces, as a result of which the electrical performance of the platform increases. The created movable photovoltaic modules 5, shown in figures 6 to 9, are capable of changing their angle relative to the horizon from - 15° to + 45° by means of a lever module. The lever module, as can be seen from the indicated figures, is composed of an upper arm 9, a lower arm 4 and a linear actuator 8, which in the considered preferred embodiment is a linear actuator including a working body driven by an electric motor, which is designed to realize an axial movement of the working body. The upper arm 9 and the lower arm 4 at one end are connected to the working body of the linear actuator 8. The other end of the upper arm 9 is connected to one end of the frame 7 of the photovoltaic modules 5, and the other end of the lower arm 4 is connected to supporting beam 12 of the supporting metal structure. The opposite end of the frame 7 is connected to a bearing body 15 fixed to the main support element 2. In the created structure, there is an option where the used linear actuator 8 is connected to the support beam 12 of the support metal structure, and its working body is directly connected with the frame 7 of the photovoltaic modules 5.

The change in the angle relative to the horizon of the movable photovoltaic modules 5 is the result of interaction between the linear actuator 8, whose working body is connected to the upper 9 and lower 4 arms, the frame 7, the bearing body 15, and the described elements in their entirety constitute a tracker system. For the precise positioning of the movable photovoltaic modules 5 and their movement in relation to the change of the solstices, the thus formed tracker system is controlled by a system including sensor devices for reading the intensity of the sun, its location, for reading environmental indicators and others. Thus, it is possible to simultaneously bring the metal frames 7 with the panels 6 to a horizontal position or to another suitable angle, in case of strong or hurricane winds. This allows securing the platform in emergency weather situations and reduces the risks of its breakdown and/or destruction.

The movable photovoltaic modules 5 shown in Figures 1 and 2 are arranged on the main support element 2 in two oppositely located photovoltaic fields 13a and 136, separated from each other by a service path 11. Each photovoltaic field 13a and 136 is composed of the movable photovoltaic modules 5, arranged in rows, where each row is composed of three to four photovoltaic modules 5, and the rows are from one to three, and between the supporting beam 12 and the main supporting element 2, shielding elements made of PVC or of high density are established polyethylene, or from textiles, or from fiberglass, or other material with increased light-reflecting ability.

It can be seen from figure 9 that the service track is composed of two elements movably connected to each other, and the angle that the two elements form is in the range from 90° to 180°. The elements of the service path 11 are covered with a light-reflecting coating 3, which is a reflective paint, the light-reflecting ability of which and the position of the elements relative to the horizon further increase the solar energy that falls on the lower working surface of the photovoltaic panels 6 and, in this way, a higher efficiency is achieved of electricity generation. When it is necessary to service the photovoltaic panels 6 or another element of the floating photovoltaic platform, the elements of the service track are brought to an angle of 180° relative to each other, with the aim of the more comfortable and safe work of the service personnel.

Claims (6)

1. A floating photovoltaic platform comprising a supporting metal structure on the underside of whose main supporting element pontoon bodies are established, and on the upper side of the main supporting element photovoltaic modules are located, each of which is composed of a frame in which photovoltaic panels are housed , characterized in that groups (10) of pontoon bodies (1) are formed from the pontoon bodies (1), and each group (10) of pontoon bodies (1) is fixed to a metal frame (14) of the supporting metal structure , in which the photovoltaic modules (5) are movable with the possibility of changing their angle relative to the horizon from - 15° to + 45° through a lever module composed of an upper arm (9), a lower arm (4) and a linear actuator (8) ), wherein the upper arm (9) and the lower arm (4) at one end are connected to the working member of the linear actuator (8) and the other end of the upper arm (9) is connected to one end of the frame (7 ) of the photovoltaic modules (5), the other end of the lower arm (4) being connected to a supporting beam (12) of the supporting metal structure, and the opposite end of the frame (7) being connected to a bearing body (15) installed to the main a supporting element (2), in which the precise positioning of the movable photovoltaic modules (5) and their movement relative to the change of the solstice is controlled by a system including sensor devices for reading the intensity of the sun, its location, for reading environmental indicators and others , with shielding elements established between the supporting beam (12) and the main supporting element (2), whereby the movable photovoltaic modules (5) are arranged on the main supporting element (2) in two oppositely located photovoltaic fields (13.a and 13.6) , separated from each other by a service path (11), and each photovoltaic field (13.a and 13.6) is composed of the photovoltaic modules u (5) arranged in rows, where each row is composed of three to four photovoltaic modules (5) and the rows are from one to three, the service path (11) is composed of two elements movably connected to each other and covered with a reflective coating (3). 2. A floating photovoltaic platform according to claim 1, characterized in that the photovoltaic panels (6) arranged in each photovoltaic module (5) are located with their long side parallel to the horizon. 3. Floating photovoltaic platform, according to claim 1, characterized in that the distance between the nearest edges of the frames (7) of the movable photovoltaic modules (5) is determined for each specific case and is in the range of 0.5 to 3 sh. 4. A floating photovoltaic platform according to claim 1, characterized in that reflective elements are located under the lower surface of the photovoltaic panels (6). 5. A floating photovoltaic platform according to claim 1, characterized in that the linear actuator (8) is a linear actuator. 6. Floating photovoltaic platform, according to claim 1, characterized in that the light-reflecting coating (3) is a light-reflecting paint, and the shielding elements are made of PVC, or of high-density polyethylene, or of textile, or of fiberglass, or of another material with increased light reflectance.