DE10156184A1 - Buoyant solar cell system has anchor plane and cell modules provided above water and pontoon arms with propellers, which turn solar cell system with sun - Google Patents

Abstract

The system is positioned in to planes, of which the anchor plane (1) is under water and the cell modules (9) are above water. The cell modules are provided on an elastic skin (10), which has openings (12) for a bell shaped frame (13) forming a box (14) open at the bottom and consisting from a buoyant material. The box is covered by a solar cell panel. Pontoon arms have each a propeller, which turns the solar cell system with the sun. Anchor ropes (16) keep open the navigation channel for the working ships between adjacent cell modules.

Description

The relatively low output of the solar cell means that large usable areas in sunny, weather-resistant regions must be available for use in large industrial plants. Solar farms of 200 megawatts as the basic unit would require approximately 4 km ^{2 of} system area with an output of 100 W / m ² and 2 km ^{2 of} effective cell area. For their use in the hydrogen energy industry, 100 to 130 such basic units with a total area of 400 to 520 km ^{2 would have} to be combined to form a solar cell plantation. In addition, large amounts of fresh water would be required to produce hydrogen and ten times the amount of at least slightly salty cooling water would have to be available. In Western Europe, these conditions should not be met due to a lack of space. Desert regions, on the other hand, can be viewed as optimal in terms of space and the amount of sunshine. However, possible sandstorms, overly hot air temperatures and the difficulties in providing the process water severely restrict the use of solar systems in the desert. In addition, the cell panels stored on stable racks would have to stand on secure foundations, which could be complex and expensive in these regions.

Alignment of the solar cells with the most direct possible solar radiation requires constant tracking of the cell panels around their vertical axis and theirs Vertical axis. The devices required for this are mechanically complex and would Many panel frames lead to considerable maintenance work and high construction costs. The The performance of the solar cell depends on the temperature. In desert regions can Rapidly heat up solar cells to over 75 ° C and thus lose up to 20 percent of their performance. It is therefore economical to ventilate solar cells with suitable devices. For the Flat horizons are cheap because they take them Sun exposure immediately after sunrise and before sunset.

It is known that solar cells are assembled and assembled on panels to form modules Racks can be put together for solar farms and solar cell plantations. These modules are aligned to the respective position of the sun by tilting their frames. Mechanically operating actuators guide the solar cell modules around the vertical axis and the horizontal axis according to the position of the sun. When the sun is low, the Self-shading of the cell modules balanced by correspondingly large frame distances. The solar cells the large voltaic systems are usually only cooled by the ambient air. It is furthermore known that in biological sewage plants planted substrate baskets for the To keep it clean and to detoxify the waste water. It is also known that Large airships are under development, with which the transport of large plant parts is possible would.

The object of the invention is to turn solar cell modules into large, floating systems Inland lakes or on open water protected from waves and thus to protect valuable usable and natural areas, to reduce the heating of the solar cells and to use the air cooled by the sea water, the mutual shading of the To avoid solar cell panels by regulated inclination of their frames and thus the To be able to train the system to save space, to simplify the final assembly on the lake Cooling water from external hydrogen generation systems to prevent ice formation on the To use the lake, to simplify the tracking of the sun, the lake when the water is polluted to regenerate the assembly of the system through the possibility of using To rationalize work ships, the advantages of large for the transport of the plant parts To use airships.

A performance example is shown in the drawings and is described below described.

Show it:

Fig. 1 is a plan view of the anchor grid module

Fig. 2 is a plan view of the cell module

Fig. A cross-section of the assembled bulk modulus in the normal position and in the transport position (dashed) 3

FIG. 4 shows a cross section of the large module along the line IV-IV in FIG. 5

Fig. 5 is a cross-section of the Paneelglocke (flat Paneelstellung) along the line VV in Fig. 4

Fig. 6 shows a cross-section of the bulk modulus (in capped Paneelstellung) along the line VI-VI in Fig. 7

Fig. 7 is a cross-section of the Paneelglocke (in capped Paneelstellung) along the line VII-VII in Fig. 6

Fig. 8 shows a cross section of the fairway between the large modules

Fig. 9 shows a connection point of the anchor grid modules in the fairway

Fig. Is a plan view of the anchor grid modules of the overall system (partially drawn without struts) 10

Fig. 11 shows a cross section through the connecting pontoons along the line XI-XI in Fig. 10

This object is achieved by assembling the floatable anchor grid modules 1 to the grid level 2 below the water level, which can be rotated around the tower 4 with the turnstile 3 at different heights. Each anchor grid module 1 is designed as a truss, which absorbs the horizontal forces and whose weight corresponds to the displaced water of the pipe construction. The individual anchor grid modules 1 are mutually assembled with easily detachable connecting pieces 5 to form a grid network that cannot be displaced in the plane ( FIG. 10). On the turntable 3 , the two pontoon arms 6 are fixed parallel to the direction of the sun and perpendicular to it, the two pontoon arms 7 are fixed on the turntable 3 . The pontoon arms 6 and 7 form right angles to each other, which are fixed by the diagonal cables 8 .

The anchor grid modules 1 are firmly connected to the pontoon arms 6 and 7 and together form the framework for fixing the cell modules 9 floating on the water surface. The cell modules 9 are flexibly connected to the anchor grid module 1 by the anchor cables 16 and the stop eyes 17 . The anchor cables 16 determine the immersion depth of the anchor grid modules 1 . It is set so low that work ships 43 can travel over it.

Each cell module 9 is built on a tear-resistant, elastic skin 10 , which is underlaid with a buoyant foam carpet 11 ( FIGS. 5 and 7). The openings 12 are recessed in the skin 10 , into which the frame bells 13 are inserted, held by joints 18 . The frame bell 13 forms a downwardly open box 14 made of buoyant material, which is covered airtight with the solar cell panel 15 .

Between the solar cell panel 15 and the water level, the free space 19 is formed, into which, according to its function as a lifting force for the solar cell panel, compressed air flows in or out of the opening 20 . The opening 20 communicates with the air duct 21 , which is connected to the compressed air hose 23 with the flange 22 . The compressed air hose 23 is connected with the flange 24 to the compressed air network 25 which is supported by the anchor grid modules 1 and by the pontoon arms 7 and which is filled with compressed air by a compressed air generator 26 installed in tower 4 .

With the change in pressure in the compressed air network 25 , the inclination of the frame bells 13 is controlled in the entire system. Only such air pressure can be built up under the rack bell 13 as the water pressure at the greatest immersion depth 28 of the rack bell 13 allows. Thus an optimal water pressure can be effectively drawn from an annular bead 30 downwardly and here the gravure cross-section 27 become effective at the lower edge of the box 14, the flexible skirt 29 under hung leaves (Fig. 4 and Fig. 6).

The overall length of the anchor grid modules 1 and the cell modules 9 is determined by their manufacture and the transport performance of the transport airships 45 . So that the sea surface is fully used on site and no unused open spaces are created, the modules 9 are provided on the end faces with the connecting strips 31 and assembled into long rows of modules.

On both long sides of the cell modules, the connecting struts 33 hold the floating hose 32 , which has the task with the anchor cables 16 to keep the anchor grid modules 1 floating below the water surface at the required depth, the cell modules 9 on the carriageway 38 from driving dirt and in front Protect bumps of the work ships 43 and carry the masts 34 for the electrical system. With the current discharge cables 36 , the current generated in the solar cells is delivered to the collector cable 35 and further discharged into the tower 4 . The lightning protection system 37 is placed on the masts 34 .

Between adjacent cell modules 9 , the fairway 38 is held open by anchor cables 16 for work ships 43 , which are fastened to the anchor grid modules 1 at an appropriate distance. In the middle of the fairway, the anchor grid modules 1 are connected to one another by the connecting pieces 5 and are accessible from above for assembly work ( FIG. 8). At the edges of the fairway 38 , the water pipes 39 are fastened on the anchor grid module 1 , in which cooling water enriched with air is transported from the electrolysers of the external hydrogen plants and is released into the sea surface water via the holes 49 . The floatable plant troughs 40 are held by the anchor cables 16 via the water pipes 39 , under which the air rising from the cooling water collects and is released via the openings 41 to the root system of the plant troughs 40 . In addition, the ascending, warm cooling water heats the surrounding sea water and thus prevents possible ice formation on the surface. The stops 42 on the anchor cables 16 prevent the planting troughs 40 from rising and thus the fairway 38 remains open for the use of the work ships 43 .

The pontoon arms 6 are buoyant hollow bodies, the buoyancy of which is so large that they can also be used as a driveway to the tower 4 . The pontoon arms 7 are also floating hollow bodies, the upper cover 48 of which is covered step-by-step in the region of the fairways 38 corresponding to the fairway depth and in which the compressed air pipes 25 are brought out of the tower 4 up to the compressed air pipe network on the anchor grid modules 1 . Likewise, the cooling water pipes 39 are received in the pontoon arms 7 and continued on the anchor grid modules 1 . At the ends of the pontoon arms 6 and 7 , the drive propellers 44 are held, with the drive force acting tangentially to the slewing ring 3, the solar cell system is rotated in accordance with the direction of the sun ( FIG. 10).

For transport with the airship 45 , the cell module 9 is placed on the anchor grid module 1 to reduce the transport cross section ( FIG. 3), by anchoring the anchor cables 16 with their fixing eyelets 17 into the transport hooks 46 of the transport airship and the anchor cables 16 as a lifting cable for the Anchor grid modules 1 take effect. For this purpose, the anchor cables 16 are passed through the skin 10 and the floating hose 32 in the flow sleeves 47 .

Claims (7)

1. Floatable solar cell system with sun position, rear ventilation and biological water clarification stage, characterized in that the system is positioned in two levels, of which the anchor grid level 1 is immersed and above which the cell module level 9 floats on the water, so that each cell module 9 has a flexible skin 10 is built with underlying buoyant foam carpet 11 that in this foam carpet 11, the openings 12 are excluded, in which, held by joints 18 , the rack bells 13 are inserted, that between the solar cell panel 15 and the water level, the compressed air cushion 19 is built, which the rack bell 13 pivoted about the joints 18 and thus tracking the position of the sun, that the air cushion 19 cools on the water surface and thus also cools the solar cell panel, that a propeller 44 is held on each of the pontoon arms 6 and the pontoon arms 7 , of which the solar cell system accordingly the Sun position is rotated that the anchor cables 16 are attached to the anchor grid modules 1 so that the channel 38 is formed in the work ships 43 between adjacent cell modules 9 , that the submerged, buoyant planting troughs 40 are held in depth by the spacer cables 16 , with which the polluted sea water is regenerated and that the anchor grid module 1 is connected to the cell module 9 as a compact unit for transport by airship. 2. Floatable solar cell system with sun position, rear ventilation and biological water clarification stage, according to claim 1, characterized in that the buoyant anchor grid modules 1 , the pontoon arms 6 and the pontoon arms 7 are coupled together with connectors 5 to form a grid level 2 , in the center of which the rotating ring 3 is accommodated , which adapts to the changing water level and which is supported on the tower 4 . 3. Floatable solar cell system with sun position, rear ventilation and biological water clarification stage, according to claim 1, characterized in that the cell modules 9 are put together with the connecting strips 31 to rows of cell modules and thereby unused free spaces in the direction of the sun are avoided and that on the flank sides of the cell modules 9 the swimming hoses 32 are connected at a distance by the connecting struts 33 with which the cell modules 9 are protected from accidents with the work ships 43 and that the immersion depth of the raster plane 2 is determined with the length of the spacer cables 16 . 4. Floating solar array with the sun alignment, ventilation and biological Wasserklärstufe as claimed in claim 1, that a pressure-variable volume of air is built up by a built-in the tower 4 compressed air generator 26, with which a pipe network 25 to the pressure air hose 23 and the duct 21, the required operating pressure for the inclination of the solar cell panels 15 is guided to the air cushion 19 and the pipe network 25 is carried by the anchor grid modules 1 . 5. Floatable solar cell system with sun position, ventilation and biological water clarification stage, according to claim 1 and 4, characterized in that each solar cell panel 15 rests on a buoyancy-effective box 14 in the water, the side walls with the flexible apron 29 and the annular bead 30 extended as far down into the water is until a water pressure prevails with which the air cushion 19 can press the solar cell panel 15 into the required inclined position. 6. Floatable solar cell system with sun position, rear ventilation and biological water clarification stage, according to claim 1 and 3, characterized in that the masts 34 are carried by the floating hose 32 , to which the current collecting cable 35 is attached, to which all outgoing from the solar cell modules power cable 36 are connected and the lightning arrester system 37 is attached to the mast tip. 7. Floatable solar cell system with sun position, rear ventilation and biological water clarification stage, according to claim 1, characterized in that in the channel 38, the water pipes 39 rest on the anchor grid module 1 , in which cooling water is transported from external hydrogen generation systems, which has been enriched in the tower 4 with air and that is released through the outlet holes 49 in to the surface water, that the buoyant plant troughs 40 are held by the spacer cables 16 via the water pipes 39 , the bodies of which are formed by half-shells attached to one another at the apices, the flanks of which are closed by side walls, that on The apex of the trough shells has the openings 41 for the air outlet and that substrates and suitable pollutant and salt-absorbing water plants are used in the upper trough shell, from which the contaminated sea water is cleaned.