DE3130226A1 - Solar-energy installation with photo-electric cells - Google Patents

Abstract

Solar-energy installation with photo-electric cells which can be directly exposed to the rays of the sun, in which installation either the photo-electric cells directly form a parabolic effective surface, or a parabolically curved, selective filter covering the photo-electric cells is provided. The surface is curved in such a way that the rays of the sun impinging thereon and reflected thereby are concentrated into a focal point or a focal line. There is provided, in the focal point or the focal line, a secondary energy converter in the form of a thermal absorber or secondary solar cells for absorbing the reflected rays. The selected solar radiation impinging on the photo-electric cells is optimally utilised in this arrangement by virtue of the photo-electric cells in conjunction with the secondary energy converter.

Description

Solar energy system with photocells

The invention relates to a solar energy system with photocells, which can be exposed directly to the sun's rays.

Photocells are increasingly used to use the radiation energy for the Electricity generation used, in particular flat, directly lit by sunlight Cells are used that also use diffuse light.

Direct irradiation is understood to mean an arrangement in the photocells without the interposition of concentrators, such as reflectors or Lenses are exposed to the sun's rays.

Even in direct sunlight, the photocells can reach up to approx. 80 ° C. However, such high operating temperatures lead to a correspondingly low efficiency, which results in an electrical power loss up to carries 20% with it.

A solar energy system of the type mentioned above is known (DE-OS 28 47 433), in which the cells form the bottom of a warm-insulating box with less clear transparency Form face. Inside this box, a heat transfer medium flows at the same time cools the solar cells.

In this case, a cooling heat with a relatively low temperature level from 50 to 60 C. It is therefore hard to think of using this waste heat.

The invention is based on the object of providing a system of the initially mentioned to create the type mentioned, with which an optimal degree of efficiency can be achieved.

The object is achieved according to the invention in that the photocells are arranged side by side forming a parabolic surface such that the rays of the sun reflected by the cells focus on a focal point or a Concentrate focal line, and that in the focal point or the focal line a secondary Energy converter is provided.

In this way, the system also forms a beam-concentrating Reflector, which on the one hand converts the sun's rays absorbed in front of the photocells converts electrical energy and on the other hand the remaining rays to a secondary Energy converter reflected. This can affect the active photocell surface incident solar radiation is almost fully used and thus the efficiency compared the previously known systems are significantly improved.

The daily output of the system can according to a further development of the invention can be increased by the fact that the solar system tracks the path of the sun.

According to a further embodiment of the invention, the photocells are coated with selective filters, which are the wavelengths that cannot be used by the cell (UV + IR) reflects and transmits the other wavelengths.

This reduces the heat load and thus the reduction in performance of the Solar cells reduced. In addition, the selective filter can simultaneously control the deck or form a protective layer for the cells and thus replace any protective glasses.

In this case it is also advantageous if the secondary energy converter is a thermal absorber.

With the increased UV and IR reflective radiation, a high usable temperature level can be generated in the absorber.

According to a further embodiment of the invention, the secondary Energy converter also generates electrical energy by, for example further solar cells are attached in the focal point or in the focal line.

The above object is according to another embodiment the invention also achieved in that the photocells with a parabolically curved, selective filters are covered in such a way that the sun rays reflected by the filter concentrate on a focal point or a focal line, and that in the focal point or a secondary energy converter is provided for the focal line.

In this embodiment, the solar cells can be arranged on one level while the filter takes on the function of a reflector. In this manufacturing technology A simpler case is also the capacity of the solar cells due to the shielding the radiation that warms the cells is optimally used, with the radiation being reflected by the filter Radiation likewise only produces higher heat Temperature levels or additional electricity is used.

Embodiments according to the invention are shown schematically in the drawing shown.

In Fig. 1 is a solar energy system 10 with a cylinder parabolic Photocell carrier 11 shown. The solar radiation picked up by the photocells 12 is converted into electrical energy and carried on in the known manner.

The photocells 12 are covered with a protective layer or

a filter and optionally with an additional radiation-selective Filter 13 is provided, which reflects part of the incident solar rays 14. The reflected rays 15 concentrate along a focal line 16, in which is arranged as a tube thermal absorber 17. The one from the absorber 17 converted thermal energy is transferred to a liquid flowing in the absorber 17 or gaseous heat transfer.

In Fig. 2 an embodiment is shown in which the photocells 22 form a spherical active surface and with a spherically curved filter 23 are covered, which is transparent for the visible radiation spectrum and but reflects the UV and IR rays.

Due to the shape of the filter 23, the reflected ones are concentrated Rays 25 onto a focal point 26. In the focal point 26 there are further solar cells or a thermal absorber 27 is arranged. The entire system 20 is on one supporting structure 30 rotatable about a vertical axis 28 and a horizontal axis 29, 31 arranged.

In this way, the system 20 can be moved gradually or continuously are such that the incident rays 24 always have the optimal angle of incidence can maintain.

The systems can also be equipped with flat photocell carriers 21, as shown in Fig. 2 shown in dashed lines, and only be equipped with curved filters. In this case the cells 22 are not directly connected to the filter 23.

In Fig. 3, an embodiment with a flat carrier 3 is shown on to which the photocells 36 are applied in a Fresnel mirror arrangement. The ones from the Concentrate photocells due to the filter layer 37 reflected rays 38 on a focal point in which a thermal absorber 39 is arranged.

In systems of the type described above, the photocell uses the for the most favorable spectral range. The photocell thus achieves lower thermal Load higher electrical efficiency. The rest of the solar spectrum is based on the Secondary energy converter so highly concentrated that high useful temperatures with good Efficiency levels can be achieved or special photocells can be used.

The efficiency of the primary photocells and adds up of the secondary energy converter to an optimal overall efficiency.

Claims (7)

Claims solar energy system with photocells that the sun's rays can be exposed directly, characterized in that the photocells (12) next to one another, a spherical or parabolic surface are arranged forming such that the sun rays (15) reflected by the cells focus on a focal point or concentrate a focal line (16), and that in the focal point or in the focal line a secondary energy converter (17) is provided. 2. Plant according to claim 1, characterized in that the photocells (12) are coated with selective filters (13). 3. Solar energy system with photocells that direct the sun's rays can be suspended, characterized in that the photocells (22) with a spherical or parabolically curved, selective filter (23) are covered in such a way that the Sun rays reflected by the filter focus on a focal point (26) or a focal line concentrate, and that in the focal point or a secondary energy converter (27) is provided in the focal line. 4. Plant according to one of claims 1 to 3, characterized in that that the energy converter is a thermal absorber (17). 5. Plant according to one of claims 1 to 3, characterized in that that the secondary energy converter (27) converts the solar rays into electrical energy. 6. Plant according to one of the preceding claims, characterized in that that the photocells (12 or 22) together with the secondary energy converter (17 or 27) the path of the sun can be tracked. 7. Plant according to one of the preceding claims, characterized in that that the spherical or parabolic active surface by a Fresnel mirror arrangement the photocells 35 is reached.