EP1759423A2 - Method for converting the energy of solar radiation into an electrical current and heat by means of colour-selective interference filter mirrors, and a device pertaining to a concentrator/solar collector comprising colour-selective mirrors for implementing said method - Google Patents

Abstract

The invention relates to a method and a concentrator/solar collector for splitting solar radiation into various spectral colours by means of colour-selective mirrors, and for concentrating the same onto a plurality of semiconductor-photovoltaic cells optimised for various light colours. The inventive device is used to convert the energy of the solar radiation into an electrical current and heat with a high efficiency.

Description

Process for converting energy from solar radiation into electrical current and heat with color-selective interference filter mirrors and a device of a concentrator solar collector with color-selective mirrors for using the process

The invention relates to a method and a device of a concentrator solar collector in order to split solar radiation into different spectral colors with the aid of color selective mirrors and to concentrate on several semiconductor photovoltaic cells optimized for different light colors. It is used for the energy conversion of solar radiation into electrical power and heat with high efficiency. There are already various solar radiation collectors and energy converters. Thermal solar collectors, which convert the incident sun rays into thermal energy in order to heat a carrier medium (water, oil, gas, etc.), are often used for room air conditioning and in combination with thermodynamic cycle processes such as heat pumps, Stirling engines and Rankine cycle processes. This indirect conversion of the high-energy solar radiation via the detour of high-energy thermal energy in turn to high-energy electrical energy is lossy and in principle limited by the Carnot efficiency. In order to reach high temperatures, concentrator technologies such as concave mirrors or Fresnel mirror fields are required, which can only use direct radiation, but not diffuse light when it is cloudy. Thermal solar power plants for electricity generation are therefore usually only economically viable in particularly sunny areas. Semiconductor "photocells" are used for the direct conversion of light into electrical current. Basically, the individual semiconductor materials or combinations are only suitable for certain spectral ranges of the incident solar radiation. A large proportion of the radiation energy can therefore not be used to generate electricity Heat and an increase in temperature increase the recombination losses in the semiconductors during the photovolaischen energy conversion. Flat collectors made of polycrystalline silicon in the Market so far found the most widespread. So far, they typically achieve an efficiency of 12 - 17% and can use direct and diffuse light. In addition to silicon, other semiconductor materials are known which have high quantum efficiency for certain light colors. These include in particular GaAs, CdTe, GalnP, InP, GalnN, CuS ₂ , CuInS ₂ , CuIn (GaSe) ₂ , Ge, CdSe, a-Si: H and various alloys with 4 and more alloy elements, in particular with proportions of elements from the 3rd and 5th main group. Many of these alloys are relatively expensive to manufacture compared to Si. So far, the production costs of solar power generated in this way cannot compete with those of other energy sources. Thin-film technologies promise here

Cost reduction potential, as well as microporous DSC and quantum dot structures, such as B. the Graetzelzelle. The loss mechanisms in the individual semiconductor materials known for solar cells can hardly be further optimized because they are predetermined by the material used for physical reasons. This leads to a theoretical maximum efficiency of, for example, about 27% with the highest purity silicon. Layer systems made of semiconductor materials with different band gaps for the use of larger spectral ranges as well as nanoporous layer systems may lead to an increase in area efficiency. There are further potential for cost optimization

Concentrator. Instead of relatively expensive large semiconductor areas, one tries with inexpensive optical components, such as lenses or concave mirrors, to bundle the light in order to then illuminate small but highly efficient semiconductor areas with highly concentrated light intensity. Although this can significantly reduce the semiconductor costs per area and per watt, concentrator technologies are not very suitable for using diffuse radiation, which is particularly disadvantageous in temperate climates with frequent cloud cover. It requires particularly high cell efficiency in order to achieve at least the same annual energy yield per area as conventional photovoltaic flat cell modules. To achieve this increased cell efficiency requires stack cell technology (layer systems with several different semiconductor layers) or the conversion photovoltaically with the given photocell semiconductor unusable wavelengths into usable wavelengths, e.g. B. with photon splitter or luminance layers. A disadvantage of such multiple-layer stacks is that a part of the radiation components, which should actually arrive in the lower layers, is already absorbed and thermalized or also reflected in cover layers. In addition, more manufacturing steps are required, which increase costs. Another well-known approach to reducing these losses is the spatial separation of solar radiation into its light colors. These defined wavelength ranges of light are then directed onto equally spatially separated solar cells made of semiconductors optimized for the respective light color. holographic Concentrators over diffraction gratings in turn showed new sources of loss and problems (absorption and scattering losses as well as UV light, aging and moisture resistance of the holograms) and have so far not been able to find widespread use in the market. Interference mirrors are more suitable for this. It has long been known that interference on thin layers can intensify or weaken reflections. Constructive interference comes e.g. B. in dielectric mirrors and optical color filters for use and also heat protection glasses to increase the reflection for a desired wavelength range. Destructive interference is used for anti-reflective layers, so that with uninfluenced absorption significantly higher transmittance levels, e.g. B. glass panes and photo-optical lenses (suppression of reflections). By stacking many highly transparent dielectric layers, by varying the layer thicknesses and refractive indices, one can also cover larger spectral bandwidths with constructive interference and achieve high reflectivities up to over 99%. For example, alternating o / 4 layers of silicon dioxide and tantalum pentoxide have proven themselves as interference mirrors. The previous production of these interference mirrors by magnetron sputtering in a high vacuum is the more expensive the more layers are required. So far, these costs have not resulted in any cost advantages over the production of stacked cells. Such transparent systems can also use other transparent materials with very different optical refractive index form. In recent times there have been interference mirror foils made of plastic and there have also been reports about manufacturing processes made of plastic-like organic or inorganic soft glasses, which can be produced as comparatively inexpensive foils in the lamination and drawing process with several hundred layers. Problems with such films are UV light and aging resistance, moisture resistance, electrostatic charging (tendency to contamination) and mechanical stability, which has so far seemed to be unsuitable for use under weather conditions in solar collectors and areas of application for such colored films are more to be found in the area of decorative packaging films left. Another problem when used in solar collectors is the surface contamination and durability of such interference mirror layers under weather conditions.

The invention has for its object to find suitable interference filter materials and arrangements for solar radiation, which can be produced inexpensively and whose tendency to contamination, discoloration or corrosion under the influence of changing temperatures, air humidity in the dew point area and exposure to dust is low.

The object is achieved as follows: It is characteristic of the device according to the invention that the light with movable interference mirror films in at least two spectral Wavelength ranges are separated, a wavelength range being reflected on each film and a part being transmitted.

The direct solar radiation is refractive beforehand, e.g. B. with Fresnel lenses, or reflective, e.g. B. bundled with concave mirrors or Fresnel concave mirrors (mirror field). One or more such interference mirror foils are arranged in front of the optical focal point, so that there is in each case an optical focal point for the reflected and also for the transmitted light fraction. In the area of these optical focal points, photocells made of semiconductor materials are arranged which have the best possible efficiency for converting light radiation into electric current for the respective wavelength range. The color-selective interference mirrors are realized with foils that are slowly moved from roll to roll through the light cone like a film in a cinema. This offers the advantage that inexpensive plastic film laminates can be used. Many optically transparent but inexpensive plastics show signs of aging, such as gradual yellowing, embrittlement with loss of strength or shrinkage, when exposed to strong light, especially with UV-containing solar radiation. This process can be intensified by exposure to moisture and dust and the optical properties of the surface can also be adversely affected. Due to the continuous renewal of the film section located in the light cone Functional impairments of the filter mirror due to light-induced degradation and contamination can be reliably avoided. This film transport process can take weeks, months or years, depending on the film material and light intensity. Depending on the length of the film rolls, very long operating times over several years can be achieved without the need to replace and replace the film rolls. For the light-carrying construction elements (Fresnel lenses,

Interference mirror films) of the device according to the invention are preferably used ^'materials, which, in addition to the visible spectrum and a high transmittance of NIR radiation microns to about. 2 Flour polymers and Flourid soft glasses let sunlight through in a wide frequency range. Transparency for UV radiation reduces the degradation of the films and improves the energy yield. Thin layer systems in the form of thermoplastic films with transparent basic plastics (PMMA, PC, styrenes) with parts made of tellurium or flour compounds can be used for a wide spectral range down to the NIR. Two plastic films with different optical refractive indices in the range of the softening temperature are laminated several times on top of each other until the layer thickness of the individual layers is a quarter of the wavelength to be reflected. The photo cells arranged in the optical focal points in front of and behind the interference mirror film or films are irradiated with a high illuminance, typically in the range of 50-2500 times the sun concentration. The cells require a design that is tailored to the expected photocurrent (concentrator cells). If the band gap of the semiconductor is well matched to the respective light color range, the quantum efficiency of the photovoltaic conversion is high and the heat development proportionately lower. However, the heat generated must be dissipated, e.g. B. via water cooling. The photocells are therefore arranged on a heat sink through which a cooling medium can flow. In addition to water and aqueous solutions, organic solvents, classic refrigerants (e.g. R134, propane, etc.), binary solutions (e.g. ammonia solution) or gases (such as helium) under higher operating pressure can also be used. In addition to the operation of heaters, z. B. Absorption chillers, ORC systems (Organic Rankine Cycle), Villumier heat pumps and MCE converters (Magneto-Caloric-Effect) operate.

A very thin layer system with thermionic function from z. B. Bi ₂ Te ₃ / Sb ₂ Te ₃ (thermodiode) between the solar cell and the heat sink can partially convert the resulting heat flow into electrical current if necessary. The electrical efficiency can thus be increased again. Instead of a solar cell, a light fraction can also be fed into an optical waveguide (LWL). For example, B. blue light in the sun for Use photochemical reactions in a closed reaction vessel, which can also be installed in unlit rooms.

An embodiment of the device according to the invention with refractive concentrators is shown in Figure 1.

In a frame 6, convex Fresnel lenses 1 are incorporated in the translucent upper boundary plate facing the light. They are aligned perpendicular to the position of the sun, whereby the outside of the upper boundary plate can preferably have an anti-reflective or easy-to-clean coating (dirt and water-repellent surface). Below this is a lower boundary plate 8, which is arranged parallel to the upper boundary plate with the Fresnel lenses 1 and forms a largely dustproof and watertight box with this and the side walls of the frame 6. The depth of the frame 6, ie the distance between the upper Fresnel lens 1 and the lower boundary plate 8, corresponds approximately to the focal length of the Fresnel lenses 1 used. On the lower boundary plate 8 there are germanium photocells for NIR radiation 5b exactly at the point , where the focal point of the Fresnel lenses 1 is. They are mounted on heat sinks 7, through which a liquid can flow. If the Fresnel lenses 1 are aligned perpendicular to the sun, a light cone is formed in each case and the radiation is directed onto the respective, in comparison to the Fresnel Lens small-area germanium photocell for NIR radiation 5b bundled. The semiconductor germanium has a small band gap and is particularly efficient in a photocell for NIR radiation up to 2 μm, but less suitable for visible light. Between the Fresnel lenses 1 and the lower boundary plate 8, a multi-meter long interference mirror foil 2 is arranged in the form of a tape, which is wound on a spindle 3. It is rewound from this unwinding spindle 3 in the course of the device's usage time onto a winding spindle 4, so that the interference mirror film 2 is slowly drawn through the respective light cone of the Fresnel lenses 1. The interference mirror foil 2 consists of several layers of two alternately stacked transparent plastics with different optical refractive index, z. B. PMMA and polystyrene. Alternatively, other plastics with better resistance to UV light and NIR transparency can be used. The layer thickness of these plastic layers must be in the range of 88 - 200 nm, which results in a high reflection for wavelengths in the VIS range (350 - 800 nm), while NIR radiation is transmitted. The distance of this interference mirror film 2 between the Fresnel lenses 1 and the lower boundary plate 8 is approximately the same, so that the focal point of the VIS light reflected by the interference mirror film 2 is located just before the center of the Fresnel lens 1 of the upper boundary plate. At this focal point in the center of the Fresnel lens 1 A silicon photocell for VIS radiation 5a is also arranged on a heat sink 7 through which liquid flows. The semiconductor silicon has a larger band gap than germanium and can be used in a photocell for VIS radiation 5a, but is not suitable for NIR radiation from 1.2 μm. Instead of silicon and germanium, other semiconductors can also be used, such as GaAs, CdTe, GalnP, InP, GalnN, etc. as mentioned at the beginning.

FIG. 2 shows an embodiment of the invention which not only directs two but four different wavelength ranges (light colors) to four different photocells. Compared to the embodiment in Figure 1, an even better electrical efficiency can be achieved. The cover plate made of glass is on the outside with a weather-resistant multilayer interference mirror layer system, e.g. B. from silicon dioxide and tantalum pentoxide, each with a layer thickness of 55-110 nm, which reflects UV and blue light and transmits green, yellow, red and near-infrared radiation components down to at least 2 μm wavelength. The glass plate is embossed in a bowl shape and on the inside it has the Fresnel lenses with front

Interference concave mirror for blue light 10 with its typical groove structures. The bowl-shaped curvatures with the interference mirror layer system each have the function of a concave mirror. The frame 6 with the Fresnel lenses with front interference concave mirror for blue light 10 becomes vertical facing the sun, a cone of light is formed by the bowl-shaped curvatures with the interference mirror layer system above these concave mirrors with the reflected UV and blue light. In the focal points of these concave mirrors, photocells 15a are arranged, which have a high quantum efficiency for blue and UV radiation, for. B. from InGaP or CdS. Under the Fresnel lenses with a front interference concave mirror for blue light 10, a light cone is formed from the non-reflected green, yellow, red and NIR light components, which are further fractionated with interference mirror foils 2 according to the invention. Two different interference mirror foils 2 in the form of tapes are arranged one above the other between the Fresnel lenses with a front interference concave mirror for blue light 10 and the lower boundary plate 8, each of which is wound from a spool 3 to a spool 4 through the light cone. A relative movement of the interference mirror foils 2 within the light cone can also take place by axially displacing the spindles 3, 4 with respect to the zone with the highest light concentration, since in the edge regions of the light cone, due to the lower radiation concentration and dwell time, less foil damage due to light-induced degradation can be expected is. If the film has been rewound from the unwinding spindle 3 to the winding spindle 4, the film can therefore be rewound onto the first spindle 3 by axially displacing the spindles 3 and 4 thus the usage time of the respective interference mirror foil 2 can be extended. While the first interference mirror foil for green and yellow VIS radiation 12a covers the wavelength range from approx. 440 - 650 nm (green and yellow) to a photocell optimized therefor for green and yellow VIS radiation 25b, e.g. B. from GaAs, the second interference mirror foil for red VIS radiation 12b, which is located some distance below, is designed for the reflection range from about 650 to 1100 nm. In its upper focal point, arranged between the two interference mirror foils 2, z. B. a double-sided photo cell for red VIS radiation 15c unfold its optimal efficiency. The housing for the liquid cooling with the heat sink 5c of the photocell 15c is preferably transparent to the radiation range 650-2000 nm, as is the cooling medium. The lowermost photocells for NIR radiation 5d on the lower boundary plate 8 are in turn optimized for the NIR radiation 1.1-2 .mu.m, and could for example consist of the semiconductor germanium or InGaAs. Several such frames 6 can be mounted on suitable frames or on masts, equipped with rotary drives, which align the frames 6 perpendicular to the current sun position, so that the direct light radiation through the Fresnel lenses with front-side interference mirror for blue light 10 always on the photocells is focused.

FIG. 3 shows a device according to the invention with a reflective concentrator, in which the Concentrating the solar radiation with Fresnel concave mirrors 11 takes place. These can be realized with individual mirrors that are movably arranged on roof, facade or open spaces for tracking the position of the sun. The direct solar radiation is directed onto a solar receiver in the form of a frame 6, which, with adequate weather protection, contains several photocells consisting of different semiconductors and one or more interference mirror foils 2 according to the invention, each of which extends from a spool 3 to a spool 4 through the one entering the solar receiver Cones of light of the Fresnel concave mirror 11 or by a cone of light already reflected by the first interference mirror film for blue VIS radiation or UV and blue VIS radiation 22a. In this embodiment, the interference mirror foils 2 are dimensioned such that the optimum reflection wavelengths of the individual interference mirror foils 22a, 22b, 2c for the respective photocells 15a, 25b, 15c, 5d 'occur at an illumination angle of approximately 45 °.

FIG. 4 shows a solar receiver for the Fresnel concave mirror arrangement shown in FIG. 3. Here, an interference mirror film for blue and green VIS radiation 32a arranged in the light entry area of the frame 6 reflects a defined spectral range of light, e.g. B. blue, green and yellow, on an outside of the frame 6 photo cell for blue and green VIS radiation 45a, z. B. from GaAs. The radiation components red and NIR transmitted by the first interference mirror foil for blue and green VIS radiation 32a are directed to a second interference mirror foil for yellow and red VIS radiation 32b, which z. B. reflected on a Si photo cell for yellow and red VIS radiation 35b and NIR transmitted, which falls on a germanium photo cell for NIR radiation 5c.

FIG. 5 also shows a solar receiver for the Fresnel concave mirror arrangement shown in FIG. 3. Here, the fact is exploited that the same interference mirror film for blue and green VIS radiation 32a, irradiated with an entry angle of approximately 0 °, reflects a different wavelength range than is the case with a flatter radiation angle, e.g. B. about 45 ° is the case. In the exemplary embodiment in FIG. 5, the interference mirror film for blue and green VIS radiation 32a will have a respective layer thickness of the alternating plastic layers in the range 100-132 nm and will reflect the blue and green light when irradiated vertically, while yellow, red and NIR are transmitted. This initially transmitted radiation component passes through the same film again, but now at a steeper angle, e.g. B. about 40 ° - 50 °, the yellow light is now reflected, while red and NIR are largely transmitted. In Figure 6 it is shown that one or more of the light components separated with interference mirror foils 2 instead of a photocell in an optical waveguide 9, z. B. liquid-filled hose, can be fed and transported over limited distances to another place. This application is shown on the basis of the embodiment of the device with refractive light concentrator already shown in FIG. The focal point of the Fresnel lens 1 lies in the area of the glass fiber entrance when the sun is precisely aligned. Any number of such optical fibers 9 is summarized and the radiation can be at the other end of these optical fibers 9 z. B. on a photochemical reactor, on a photocell for NIR radiation 55b or other surfaces or rooms to be illuminated. This can have advantages. For example, a photoreactor can be located in a separate room (heated or insulated) or a photocell can be located directly in a cooling water reservoir (e.g. swimming pool). Instead of e.g. B. quartz glass fiber optic cables, liquid-filled hoses can also be used as fiber-optic cables, whereby heat losses are reduced and the cooling of a photocell can be simplified

The device according to the invention differs from previously known solar collectors and from other light feed devices for optical waveguides in that the light with movable interference mirror foils 2 in at least two spectral wavelength ranges is separated, with each interference mirror foil 2 reflecting a wavelength range and transmitting a part. The direct solar radiation is refractive beforehand, e.g. B. with Fresnel lenses 1, or reflective, for. B. bundled with concave mirrors or Fresnel concave mirrors 11 (mirror field). One or more such interference mirror foils 2 are arranged in front of the optical focal point, so that there is in each case an optical focal point for the reflected and also for the transmitted light fraction. In the area of these optical focal points, photocells made of semiconductor materials are arranged which have the best possible efficiency for converting light radiation into electric current for the respective wavelength range. The color-selective interference mirrors are realized with interference mirror foils 2, which are slowly moved from roll to roll via the spindles 3 and 4 through the light cone.

The invention offers several advantages. The advantage of concentrator technology is that the light is concentrated on only small semiconductor areas with relatively inexpensive optical components (mirrors, Fresnel lenses), thus saving expensive semiconductor area.

The separation of the solar radiation into several wavelength ranges (light colors) offers the advantage that different semiconductor photocells, which are optimized for the respective wavelengths, can be operated with a higher photovoltaic conversion efficiency, which improves the overall electrical efficiency.

The slow coils with the spindles 3 and 4 of the interference mirror films 2 from roll to roll by the light cone has the advantage that not act permanently prejudicial to this surface reached dirt and damage due to moisture, baked dirt particles and light-induced degradation ^"as the claimed sheet sections are continuously renewed. These thin interference mirror foils 2 can be produced from very inexpensive and commercially available plastic raw materials in mass production by lamination, rolling or drawing processes. There is no need for costly CVD or epitaxial deposition processes in a high vacuum.

Movable Fresnel concave mirrors 11 integrated in roof and facade constructions, as shown in FIG. 3, also have the advantage that they are equipped with flat low-light solar surfaces, such as, for example, solar panels. B. the DSC technology (Dye Sensitized Cell) can be combined, the Fresnel concave mirror 11 being rotated in such a way that these DSC surfaces are optimally illuminated when cloudy. Both direct-directional and diffuse (scattered) light can be used in a wide spectral range, which means that the annual energy yield can be increased considerably. The noiseless and largely maintenance-free collector surfaces can also be optimally integrated into existing settlement areas, attached to buildings, street lamps and masts, since the collector surfaces do not have to be coherent and can consist of many small, also differently designed forms and "islands" that can be too high The efficiency should be significantly higher than with conventional photovoltaic systems if the interference mirror foils 2 and semiconductor surfaces are dimensioned appropriately, and if they are exactly aligned with the sun. However, due to significantly lower investment costs and problem-free location selection, greater efficiency should also be achieved in comparison to surface modules using diffuse light to be achieved.

Feeding into fiber optic cables offers the advantage that the concentrated light energy of large areas has one defined area

Wavelength range can be transported over a limited distance in a non-linear way and focused on the smallest areas. This light can be used to illuminate windowless interior or

Serve basements. Plants for catalytic water separation (hydrogen production), biological wastewater treatment or photocatalytic chemical reactions can also be operated. The more effective production of biomass through photosynthesis (e.g.

Algae production) is made possible by immersing the fibers in cloudy liquids so that one no more complex (not heat-insulated) glass tube coil constructions as they are currently in use. Red and infrared radiation can generally not be used for photosynthesis, so that they can be used proportionately to generate electricity with the device according to the invention. Photosynthesis and power generation are not possible with other feeding devices for optical fibers.

reference numeral

1 Fresnel lens (refractive light concentrator)

2 interference mirror foil

2c interference mirror foil for red VIS radiation up to NIR <llOOnm

3 unwinding spindle

4 winding spindles

5a silicon photocells for VIS radiation

5b germanium photocells for NIR radiation

5c photocell for NIR radiation z. B. from Ge

5d photocells for NIR radiation

6 frames

7 heat sink

7a heat sink, container filled with liquid

7c heat sink of the photocell 15c lower boundary plate optical fiber, z. B. Liquid-filled tube Fresnel lenses with front interference concave mirror for blue light Fresnel concave mirror (reflective light concentrator) a interference mirror film for green and yellow VIS radiation b interference mirror film for red VIS radiation to NIR <llOOnm a photocells for blue VIS radiation c photocells for red VIS radiation up to NIR <llOOnm a interference mirror film for blue VIS radiation or UV and blue VIS radiation b interference mirror film for green and yellow VIS radiation b photocells for green and yellow VIS radiation a Interference mirror foil for blue and green VIS radiation b Interference mirror foil for yellow and red VIS radiation up to NIR <11OOnm b Photo cell for yellow and red VIS radiation up to NIR <11OOnm, e.g. B. from Si a photocell for blue and green VIS radiation, for. B. from GaAs b photocell for yellow and red VIS radiation, for. B. from Si a photocells for VIS radiation b photocell for NIR radiation

Claims

claims

1.Procedure for the energy conversion of solar radiation into electrical power and heat with color-selective one or more interference filter mirrors, which split the solar radiation into different wavelength ranges and concentrate on several semiconductor photovoltaic cells optimized for different light colors, characterized in that the light is arranged with movably arranged interference mirror foils (2 ) is separated into at least two spectral wavelength ranges, a wavelength range being reflected on each film and a part being transmitted.

2. The method according to claim 1, characterized in that the direct solar radiation is refractive or reflective concentrated in two or more wavelength ranges before splitting and one or more interference mirror foils (2) movable in one or two planes in front of the area of the highest light concentration as optical focal point are arranged such that there is an optical focal point for the light fraction reflected by the interference mirror film (2) and also for the light fraction transmitted through the 5 interference mirror film (2), wherein. the geometric position of these focal points does not change or changes only insignificantly as a result of the one- or two-dimensional movement of the interference mirror foils (2).

3. The method according to claims 1 and 2, characterized in that the movement of the interference mirror foil (2) in addition to the rewinding 15 from spindle (3) to spindle (4) also by axial displacement of the spindles (3 and 4) with respect to the zone with the highest light concentration.

4. The method according to claims 1 and 3, characterized in that the rewinding of the interference mirror film (2) is carried out continuously or discontinuously.

5. A device of a concentrator solar collector with color-selective mirrors, characterized in that, in a given frame (6) of the solar collector, there are lenses, preferably Fresnel, above the sunlight.

30. Lenses (1) are arranged and a photo cell is present in the optical focal point of the lens and between the lens and the photo cell an interference mirror film (2) is movably arranged.

6. The device according to claim 5, characterized in that the color-selective interference mirror film (2) is each executed with a flexible film film ^* , each slowly with a section by rewinding from spindle (3) to spindle (4) by the concentrated solar radiation is mobile.

7. The device according to claim 5, characterized in that photocells made of such semiconductor materials are arranged in the region of one or more of these optical focal points, the band gap of which is matched to the respective wavelength range.

8. The device according to claim 5, characterized in that one end of an optical waveguide (9) or a transition piece to such an optical waveguide is arranged in the region of one or more of these optical focal points.

9. The device according to claim 7, characterized in that the photocells are arranged on heat sinks (7) through which a liquid flows.

10. The device according to claim 7, characterized in that the photocells are arranged on heat sinks (7) which are flowed through by a gas with an operating pressure> 1 bar.

11. The device according to claim 9 or 10, characterized in that between the • photocells and the heat sinks (7) a thin layer system made of semiconductors with a band gap of less than 0.7 eV is arranged.