DE3643487A1 - Installation for obtaining electrical energy - Google Patents

Abstract

The installation for obtaining electrical energy at high power from photovoltaic cells (photocells) 2 which are arranged over a large area makes it possible to use the ground areas 12 located underneath since the cells 2 are arranged in a light transmissive manner at a height above the respective buildings 9 or the respective natural growth 8. Part of the sunlight reaches the solar cells 2 while another part reaches the buildings 9 or the natural growth 8 located underneath, without hindrance, so that it is also possible to continually use the areas located under the cells 2. <IMAGE>

Description

The invention relates to a plant for the production of electrical High-performance energy from large-scale photovol taischen cells.

The search for alternative energy sources has grown in the significantly increased in recent years. A way to Use of alternative energy sources offer photovoltaic Cells that emit light, such as sunlight, directly convert into electrical energy. Because the natural energy density of sunlight is low and the efficiency of the photovoltaic cells known today numerous such cells must be arranged over a large area to achieve high electrical outputs. Such, plants claimed as solar power plants considerable space. Especially in densely populated Regions, such as B. in Central Europe this place stands up the floor surface is often not available or is as a result of the high property prices cannot be obtained economically.

A system of this type is, for example, the photovoltaic pilot power plant built on the Greek island of Kythnos, which has an output of around 100 kW on a total plot area of 7500 m ² with medium solar radiation. In order to replace a conventional power plant, for example with a nominal output of 100 MW, an area of at least 7.5 km ² would be required, which would then no longer be usable in any other way.

Proceeding from this, the object of the invention is train a generic system so that the effective Space requirements are significantly reduced. Taking effective Space requirement is to be understood as the area that excludes is usable for the system.

This task is electri in a plant for the extraction high-performance energy from large-scale arrangement solved according to the invention by photovoltaic cells, that the cells at a height above the respective cultivation or the respective vegetation are arranged.

Through the solution according to the invention, the actual one Space requirements of such a system are not reduced, but rather increased, but the big advantage is that the under Areas in the plant are still largely usable stay. The effective space requirement of such a system is thus reduced to a minimum. The photovoltaic Cells can be arranged side by side. Another embodiment provides that the photovoltaic cells with spaces are provided.

Depending on the needs, the percentage of the let through Light and that of the light hitting the cells Distance, size and arrangement of the cells can be varied. The photovoltaic cells can be in one level stretch. An embodiment is also conceivable, however which troughs the cells between e.g. ropes are arranged. This has the advantage that the light-receiving area can be enlarged even more can.  

An embodiment according to claim 2 is particularly advantageous, in which the photovoltaic cells are arranged in a network are. This results in a particularly uniform light transmission let reached.

According to claim 3, the photovoltaic cells are advantageous with lateral, preferably all-sided spacing from each other arranged, which on the one hand makes a good and even Light transmission and on the other hand a relatively low Wind and / or snow load is reached.

One particularly good in terms of assembly and disassembly Stige execution according to claim 4 is that the photovoltaic cells to ready-to-connect groups are arranged in supporting frames. Such frames can be factory ready to be connected mass-produced. You then just need to put it in place Support structures hooked in and connected to the electrical wiring device can be connected. Even if individual cells are defective can with an arrangement of the cells in support frame easily replaced the corresponding support frame be, the actual repair then by specialist is carried out in the workshop.

In the arrangement of the cells in the supporting frame can for the purpose the cells in the frame itself with the light transmission arranged laterally or preferably with all-round spacing be net, so that the individual support frame without any distance directly can be arranged side by side. Another solution according to the invention consists in that the Support frame itself densely populated with photovoltaic cells are, but at a distance from each other, for example network-like are arranged. This results in a larger grid, which, however, in terms of light transmission (light and shadow effect) is unproblematic if the Tragrah sufficiently small or at a sufficient distance above the development or vegetation are arranged.  

According to a further embodiment of the invention according to claim 6, the photovoltaic cells are indirect, that is for example in their support frame, or immediately Ropes suspended between structures.

In a further development according to the invention according to claim 7 can not only the ropes in the area between the truss ken are used, but also in the guy area, e.g. B. from the structure to the floor. This creates another area developed above the vegetation for the use of solar energy. Furthermore, the structures, such as masts, can be dimensioned more easily. In this context, it may make sense to work on a single mast to hang ropes on all sides, so that with con structurally simple means a large usable area for solar energy use above the vegetation is developed. The guy angle (angle between the horizontal and the rope running to the mast) so chosen that the attached photovoltaic cells get a favorable light incidence angle.

According to an embodiment of the invention according to claim 8 can the efficiency of the plant for the extraction of electrical Energy can be increased in that the photovoltaic Cells according to the changing with the position of the sun Light incidence angles are adjustable. By a suitable one Device can then constant readjustment of the cells according to the position of the sun.

A particularly advantageous embodiment of the invention results according to claim 9, in which the cables provided for hanging up the cells or groups of cells are simultaneously designed as electrical conductors and are arranged accordingly.

The invention is based on in the drawings illustrated embodiments explained in more detail. It shows

Fig. 1 a plant for production of electric energy, for example in a schematic representation a high performance according to a first execution,

Fig. 2 shows an embodiment of such a system with single mast construction and

Fig. 3 shows another embodiment of such a plant.

In Fig. 1, two sections a, b of a plant for the generation of electrical energy high power from photovoltaic cells 2 are shown, namely a section a, the arrangement of the system in the plane and a section b , the system in increasing terrain shows.

A network 6 , which is equipped with photovoltaic cells 2 , is suspended between two supporting structures 1 , masts in this embodiment. The cells 2 are arranged approximately in a checkerboard shape, so that an intermediate space 3 is formed between two adjacent cells 2 , which in this embodiment is approximately as large in area as a cell 2 . By this arrangement, about 50% of the network area 6 are covered with photovoltaic cells 2 , which convert the solar energy radiating thereon into electrical energy. Another part of the sunlight can pass through the spaces 3 unhindered, so that the vegetation 8 located under the network 6 and the buildings 9 are also reached by sunlight. This arrangement ensures that the area below the networks 6 equipped with photovoltaic cells 2 is also reached by sunlight and is thus available for building or other uses.

In the embodiment of FIG. 1, the masts 1 generally have heights of more than 50 m and are arranged at a distance of about 150 m from one another. By arranging the nets 6 at a considerable distance above the natural vegetation 8 and the buildings 9 , a naturally incidental incidence of light is achieved which is free of direct shade and is roughly comparable to the incidence of light in a clear leaf forest.

The masts 1 are connected to one another by a support structure 7 , which in this embodiment consists of support cables 10 which are braced similarly to a suspension bridge. Brackets 4 are attached to the side of the masts 1 and are part of an adjusting device (not shown in detail). A band-like network 6 , which carries the photovoltaic cells 2 , extends between two brackets 4 . The boom 4 are pivotally attached to the associated mast 1 , so that the cells 2 can be optimally aligned according to the sun radiation. The arms 4 with the nets 6 attached to them can be pivoted, for example, by approximately 180 °. The position shown in Fig. 1a shows a mesh 6 in an approximately vertical position, while the mesh 6 shown in Fig. 1b is inclined by approximately 30 ° to the horizontal.

The actual carrying function is carried out by the supporting cables 10 stretched between the masts 1 , with which each net 6 is suspended. As a result, the networks 6 themselves can be designed without sag.

The longitudinal cables 11 of a network 6 can also serve as an electrical conductor, so that an additional construction which increases the cost of electrical wiring is unnecessary. The support cable 10 arranged above the nets 6 simultaneously assumes a lightning protection function.

Instead of the band-like networks 6 , an approximately square or rectangular network with photovoltaic cells 2 can be stretched between four supporting structures in a mat-like manner, any height differences in the landscape being compensated for by different mast heights.

The embodiment according to FIG. 2 shows an arrangement in which the networks 6 populated with photovoltaic cells 2 are stretched from the top of a mast 1 a to the floor 12 . The mast 1 a shown here consists of a specialist steel structure. The mast 1 a is guyed over ropes 5 to the bottom 12 , so that it can be made relatively light and a complex foundation is not necessary tion. The bracing may be either universally carried out in a star shape around the mast with several ropes 5, or, as in the illustrated embodiment, only the side, wherein, before and behind the mast 1 a (in the drawing-voltage level into or addition seen) a wide rer mast 1 a is arranged, the z. B. is connected via horizontal ropes to the mast 1 a shown . In this way, a plane spanned by the ropes 5 inclined surface results in both sides of the masts 1 a, which, in turn, are covered by nets 6, which are covered with photovoltaic cells. 2 In this embodiment, nets 6 would only be tensioned on one side, these not reaching down to the floor 12 , but only up to the vegetation 8 , in order to avoid a hard shadow effect in the floor area. The networks 6 covered with cells 2 and described with reference to FIG. 1 can each be suspended between two ropes 5 .

The masts 1 a can, however, also be part of supporting constructions, as shown with reference to FIGS . 1a and 1b.

Instead of a network 6 , to which the photovoltaic cells 2 are directly attached, support frames 13 according to FIG. 3 can also be suspended between two cables 5 ( FIG. 2) or on the support structure 7 ( FIG. 1). Such support frames 13 offer advantages in terms of manufacture, since a surface covered with cells 2 of , for example, 5 m ^{2 is} produced on the factory side in a plate-like manner as a support frame 13 which is self-supporting and which is only suspended in place in the corresponding support structure. Such support frames 13 can be inexpensively manufactured in large numbers. They have numerous photovoltaic cells 2 arranged next to one another and are fully wired for connection. The cells 2 can be arranged with intermediate spaces 3 within the support frame 13 , so that the support frame 13 itself can be arranged without closing to each other. If the support frame 13 , as shown in Fig. 3, are densely occupied with cells 2 , the light transmission can be achieved in that support frame 13 are arranged at appropriate distances from each other, for example checkerboard like in Fig. 3. Here is usually a higher arrangement above the floor 12 or the vegetation 8 or the building 9 is necessary to ensure a natural lighting effect and to avoid a light-shadow effect on the floor 12 .

In the embodiment of FIG. 3, equipped with the photovoltaic cells 2 supporting frames 13 are frame suspended from a stable support 14 by means of ropes, not shown. The support frame 14 consists of two masts 1 b , which are interconnected by cross members 15 . To stabilize a truss between the cross members 15 and the masts 1 b is arranged in this embodiment. Furthermore, the support frame 14 is braced in the transverse direction by means of ropes 5 .

The support frame 13 are suspended in long rows between two spaced apart support frames 14 . In the embodiment according to FIG. 3, four rows of support frames 13 are arranged side by side and in a checkerboard pattern. The masts 1 b are of different heights, so that the support frame 13 runs inclined ver with the solar cells 2 .

The solar energy explained with reference to FIGS. 1 to 3 plants are connected in a known manner and wired ver. The state of the art is used here, which is also used in ground-level solar power plants.

The numerical data given on the basis of the exemplary embodiments are only to be understood as examples and represent neither a lower nor an upper limit, and there are almost no limits with regard to the supporting structures for the solar cells 2 . Common to all constructions, however, is that the photovoltaic cells 2 are arranged at such a height above the building 9 or the vegetation 8 that the areas below or next to them remain usable since they are reached by natural sunlight.

• Reference number list 1 - mast
  2 - photovoltaic cells
  3 - spaces
  4 - boom
  5 - rope
  6 - network
  7 - supporting structure
  8 - vegetation
  8 - Buildings
  10 - suspension ropes
  11 - longitudinal rope
  12 - floor
  13 - support frame
  14 - support frame
  15 - cross member
  1 a - mast
  1 b - mast
  α - angle between 5 u. 12

Claims (9)

1. Plant for the production of electrical energy high power from large-area photovoltaic cells, characterized in that the photovoltaic cells ( 2 ) are arranged at a height above the respective building ( 9 ) or the respective vegetation ( 8 ). 2. Plant according to claim 1, characterized in that the photovoltaic cells ( 2 ) a single or grouped together are arranged in a network. 3. Plant according to claim 1 or 2, characterized in that the photovoltaic cells ( 2 ) are arranged with a lateral, preferably with all-round spacing from one another, such that light-transmitting spaces ( 3 ) are formed. 4. Installation according to one of claims 1 to 3, characterized in that the photovoltaic cells ( 2 ) are arranged to ready-to-connect groups in the support frame ( 13 ). 5. Plant according to one of claims 1 to 4, characterized in that a plurality of support frames ( 13 ) with a lateral, preferably all-sided spacing, are arranged in such a way that light-transmitting spaces are formed. 6. Installation according to one of claims 1 to 5, characterized in that the photovoltaic cells ( 2 ) are at least indirectly suspended on ropes ( 10, 11 ) which are tensioned between structures ( 1, 1 a , 1 b) , such as masts are. 7. Installation according to one of claims 1 to 5, characterized in that the photovoltaic cells ( 2 ) are at least indirectly suspended on ropes ( 5 ) with which the structure ( 1 a , 1 b) is tensioned, the guy angle ( α ) is preferably adapted to a light incidence angle favorable for the photovoltaic cells ( 2 ). 8. Installation according to one of claims 1 to 7, characterized in that the photovoltaic cells ( 2 ) are arranged adjustable according to the changing incidence of light. 9. Plant according to claim 6 or 7, characterized in that the cables ( 11 ) on which the photovoltaic cells ( 2 ) are at least indirectly attached are designed and arranged as electrical conductors.