WO2008145113A2 - Photovoltaic device comprising at least one optical element having a light conversion layer - Google Patents

Abstract

The invention relates to a photovoltaic device comprising at least one first optical element for bundling the incident solar radiation onto at least one small-area solar cell. The first optical element comprises a holographic structure that deflects the incident solar radiation that cannot be converted to power by the solar cell, to at least one light conversion layer and lets other solar radiation through. The light conversion layer shifts the solar radiation deflected thereto to shorter wavelengths. An optical structure is present on the light conversion layer and deflects the solar radiation that is shifted by the light conversion layer to shorter wavelengths and that can be converted by the solar cell to electrical energy to the solar cell and lets other solar radiation through.

Description

 PHOTOVOLTAIC DEVICE COMPRISING AT LEAST ONE OPTICAL LIGHT AT LEAST ONE LIGHT CONVERTER LAYER

ELEMENT

The invention relates to a photovoltaic device according to the preamble of the appended claim 1, as known from the document DE 19 705 046 A1.

In the area of the use of solar energy it has been known for about 50 years that solar energy can be converted into electricity by silicon. Monocrystalline or multicrystalline silicon is usually used in the solar cells customary today. However, these solar cells convert a limited spectrum of incident radiation into electricity.

Frequently, thin-film solar cells are used to convert incident solar radiation into electricity.

Very high efficiency with over 40% conversion of solar radiation has in recent years been associated with high performance PV cells of higher value semiconductor compounds (preferably of Ill-V semiconductor material) such as e.g. Gallium arsenide (GaAs) has been achieved.

Such cells based on semiconductor material can be constructed stepwise as tandem or triple cells and thereby use a wider light frequency spectrum.

However, the large-scale production of such cells is very expensive. As is known from the document DE 103 20 663 A1, the approach was chosen to concentrate the incident sunlight on a very small area of, for example, below a few hundred square millimeters. Only for this small area then a solar cell is necessary. The use of materials is then significantly reduced. Since only the connection of several photovoltaic devices allows economical use of these, such photovoltaic Vorrichtrungen are preferably combined to form a solar system.

In a photovoltaic device in which the incident solar radiation is in each case concentrated by means of an optical element on the very small area of at least one associated solar cell, it is also necessary that a dissipation of the resulting heat from the solar cell is necessary.

Usually, only a part of the incident radiation can be converted into electricity by the solar cells used. The convertible solar radiation has wave frequencies v whose photon energy hv exceeds the energy gap of the solar cells used

Semiconductor materials lies. This usable by the solar cell part of the radiation is rather shortwave.

The part of the incident solar radiation, which is not converted by the solar cells into electricity, is rather long-wave and makes itself felt as heat.

To protect the solar cells from external influences, these are such. B. in document DE 103 20 663 A1 installed in a closed housing. Here, the solar cells are applied inside a transparent housing made up of several glass panes on the inside of a lower glass pane. The incident solar radiation is concentrated by means of optical elements in each case to 100 to 1000 times on the small surface of an associated solar cell. As is known, the efficiency of solar cells decreases with an increase in their temperature. At such high concentrations of incident solar radiation, the operating temperature of the solar cells is due to the large amounts of heat, the arise during their operation or because of incident on the solar cells or in their environment incident heat radiation, greatly increased. The method of attachment of the solar cells leads to problems in the necessary heat dissipation to the outside, since despite existing heat sink around each solar cell, this remains trapped in the closed housing.

It is known to dissipate heat generated during operation of the solar cells or caused by the incident heat radiation to the environment directly by means of air cooling or via heat sinks.

The previously commonly used lens systems have a high weight, which leads to a difficult tracking and increased production costs because of the large amounts of material used.

From the document DE 10 2004 031 784 A1 an arc-shaped deflection device 10 is known, wherein two hologram layers with diffraction holograms are arranged one behind the other on a hologram carrier. The hologram layers each have the same high diffraction efficiency in a selected, relatively wide spectral range, such as between 400 and 800 nm. The hologram layers respectively deflect the incident solar radiation in the selected spectral range incident at an angle of incidence onto the same target area having a photovoltaic element and respectively let the incident solar radiation incident at a different angle of incidence pass straight through. Each hologram is assigned a certain angle of incidence. The deflecting device can focus the incident solar radiation in the selected spectral range without tracking in the sun on the photovoltaic element which is positioned in the target area at different positions of the sun. Here, a very complex construction of a precisely curved bender is necessary. The hologram layers must be superimposed very precisely on each other and then bent to a concentration of usable, incident solar radiation each to be able to achieve the associated photovoltaic element. Such bent deflecting devices are also very space-intensive.

From the document DE 19 705 046 A1 it is known to apply to the plastic cover of a solar cell in a pocket calculator, a light converter layer of polymethylmethacrylate and / or polycarbonate. Part of the incident solar radiation is shifted into the red after transmission through this layer in its spectral range. In this case, part of the incident solar radiation, which is not convertible by the solar cell into electrical energy, partly converted into radiation with longer wavelengths, which is convertible by the Solarelle for the most part into electrical energy. Also, a portion of the incident solar radiation, which is convertible from the solar cell into electrical energy, is converted into radiation having longer wavelengths, which is convertible by the solar cell for the most part into electrical energy.

The portion of the incident solar radiation that is shifted from the light converter layer into the red, however, does not suffer negligible losses of efficiency, which are noticeable as heat, which is caused by the vibration relaxation caused by the

Lichtumwandlerschicht converted solar radiation occur. This heat then heats the solar cell and leads to a reduction in its efficiency. In addition, the converted radiation is emitted isotropically. This means that only part of the solar radiation converted by the light converter layer reaches the solar cell.

In addition, a portion of the incident solar radiation, which is not convertible by the solar cell into electrical energy, is not converted by the light converter layer, impinges on the solar cell and is converted by it into heat. Also, part of the converted solar radiation from the solar cell is not into electrical energy is convertible, reaches the solar cell and is converted by this into heat.

The invention has for its object to build a photovoltaic device according to the preamble of the appended claim 1, so that the above problems are solved. In particular, it is necessary to increase the efficiency of such a photovoltaic device according to the invention and to avoid overheating of the solar cells used therein.

To solve the problem, the invention proposes a photovoltaic device with the features mentioned in claim 1. Advantageous embodiments can be found in the dependent claims.

The photovoltaic device according to the invention for the direct conversion of solar energy into electrical energy has at least one optical element for bundling the vertically incident solar radiation on at least one associated therewith, this or a light entry region of this small area solar cell. In this case, preferably between the solar cell and the first optical element, at least one Lichtumwandlereinrichtung, in particular one

Conversion layer exists, which shifts the solar radiation in the partial spectrum which can not be converted into electrical current by the solar cell into shorter wavelengths. The light converter layer is preferably arranged on the side of the first optical element remote from the sun, spaced therefrom and more preferably has a surface whose vertical projection in the plane with the first optical element forms at least part of its edge surface and its projection in the plane does not overlap the solar cell surface with the solar cell. As a result, usable solar radiation can be radiated directly onto the solar cell without being obstructed by the light converter layer.

Preferably, light converter layers can be used which Convert infrared light into visible or ultraviolet light. In this case, for example, a two-quantum absorption process in a suitable fluorescent dye can be used.

According to the invention, a wavelength-dependent deflection device is provided in order to direct useful radiation to the solar cell and longer-wavelength first to the light conversion device.

A first hologram structure is preferably present on the side of the first optical element facing or facing away from the sun. The first hologram structure deflects the incident solar radiation, which can not be converted into electrical current by the solar cell assigned to it, onto the light converter layer and allows other solar radiation to pass through.

A second hologram structure is present on the side of the light converter layer facing away from the sun, which deflects the solar radiation, which is deflected by the light converter layer to shorter wavelengths, which is convertible from the solar cell into electrical energy onto the solar cell and others Lets through radiation.

By attaching the first hologram structure, the part of the incident on the light entrance surface of the first optical element solar radiation, which is not convertible by the solar cell into electricity, deflected to a remote on the side facing away from the sun of the first optical element Lichtumwandlerschicht and other radiation transmitted , The other vertically incident radiation that can be converted by the solar cell into electrical current, that is to say usable, then comes bundled from the first optical element, is then transmitted by the first hologram structure and finally reaches the solar cell or is passed through by the first hologram structure first optical element and is characterized by this the solar cell bundled. The solar cell can therefore use all the incident radiation, which can be converted into electricity.

By attaching the light converter layer, the part of the incident on the light entrance surface of the first optical element solar radiation, which is not convertible from the solar cell into electricity and which is deflected by the first hologram layer on the Lichtumwandlerschicht, to shorter wavelengths, ie for the most part Wavelengths that are convertible from the solar cell into electricity are shifted. About half of the shifted and isotropically radiated radiation then reaches the second hologram structure and is split by this in two parts. The convertible from the solar cell into electrical energy part is deflected by this on the solar cell and the other part is transmitted by this. The other half of the shifted and isotropically radiated radiation impinges upon, is reflected by, an optical device located on the sun-facing side of the light converter layer, then strikes the second hologram structure and is split therefrom like the other half of the isotropically radiated radiation and redirected or let through.

The optical device can be implemented particularly simply and cost-effectively by a semitransparent mirror which transmits the solar radiation deflected by the first hologram structure and reflects the radiation displaced by and incident on the light-transducer layer, or by a third hologram structure which transposes the light beam through the light-conversion layer Radiation incident on them, which is convertible from the solar cell into electrical energy, reflects and transmits other radiation. Consequently, the solar cell converts both its usable and other incident solar radiation into electricity.

The efficiency of such a solar cell is thereby significantly increased. Come in addition nor that on the solar cell no long-wave radiation is bundled, which is not converted by the solar cell into electricity, but into heat. Thus, in addition, the efficiency of the solar cell by avoiding overheating this is significantly increased.

Preferably, the photovoltaic device has at least one first optical element with a target area to which a plurality of solar cells are assigned. Thus, smaller-area solar cells can be used.

Also, at least one of the solar cell used in the photovoltaic device according to the invention may be associated with a plurality of first optical elements. Thus, a higher efficient efficiency of the solar cells used can be achieved by a stronger concentration of the incident solar radiation by means of several first optical elements.

In particular, the vertical projection surface of the light converter layer in the plane with the first optical element forms the entire edge surface of the optical element. In that case, the solar radiation deflected by the first hologram structure can then be distributed uniformly over the larger area of the light converter layer, thereby avoiding overheating of the latter.

The surface of the light converter layer preferably does not overlap the solar radiation bundled by the first optical element and usable by the solar cell. Thus, the solar radiation that can be used by the solar cell can be completely redirected to the solar cell. Efficiency losses of the radiation which can be used by the solar cell and which could occur as a result of interactions with the light converter layer are thus avoided. This achieves a higher efficiency of the solar cell.

In a preferred embodiment of the invention, at least one first and / or at least one second hologram structure and / or at least one third hologram structure simple and particularly inexpensive each formed as a flat hologram layers, each having a plurality of hologram regions with different hologram properties. Thus, the first and / or the second and / or the third hologram structures can be realized very accurately, since their hologram regions can each be individually tuned to the radiation impinging on them.

In particular, a second optical element for further bundling of the solar radiation bundled by the first optical element is present between the first optical element and the at least one solar cell assigned to it. As a result, a higher concentration of solar radiation is achieved on the solar cells and thereby the purchasing or manufacturing costs of solar cells can be reduced, since only smaller solar cells are necessary. In addition, the required accuracy of tracking a solar system to the sun, which has such photovoltaic devices, since the acceptance angle of the incident solar radiation is thereby higher, i. also that rays which deviate somewhat from the straight line perpendicular to the first optical elements are respectively collected by the corresponding first optical element on the relatively large surface of the associated second optical element and then further from the second optical element to the small surface of the associated one Solar cell be bundled.

Preferably, the light converter layer is arranged in approximately the same plane with the second optical element. This structure of the photovoltaic device according to the invention is simple and inexpensive to implement, since it is possible to make the second optical element and the associated Lichtumwandlerschicht in particular the corresponding second hologram structure and preferably also the corresponding optical device as a unit. Preferably, here is the Lichtumwand lerschicht arranged in particular adjacent to the second optical element. Thus, the light conversion layer can cover the entire edge region of the vertical projection surface of the associated first optical element up to the corresponding second optical element. Thereby, the solar radiation in the spectral region not usable by the solar cell can be relatively uniformly distributed from the first hologram structure to the relatively large area of the associated light conversion layer and, after being shifted to shorter wavelengths by the light conversion layer, uniformly distributed to the second hologram structure Distributed surface of the associated solar cell. Thus, the area of the associated solar cell is used evenly and a local overload of the solar cell is avoided.

Also, the light conversion device, in particular the

Light converter layer, be arranged between the first and the second optical element. Thus, in particular, the solar radiation displaced by the light converter layer, which is convertible from the solar cell into electrical energy, can be deflected by means of the optical device and the second hologram structure to the second optical element and be further focused by this on the associated solar cell. This achieves a very high concentration of the incident solar radiation on the solar cells. So solar cells can be used with a very small area. The reduction of the necessary area of the solar cells leads to a reduction in the purchase or production costs of such solar cells. In particular, the vertical projection surface of the light converter layer in the plane with the second optical element does not overlap the surface of the second optical element. Thus, the entire surface of the second optical element can be used for further bundling the light bundled by the first element and that deflected by the second hologram structure onto the latter. In a particular embodiment of the invention, the light converter layer in its interior and / or on its side facing away from the sun on a grid of conductive material, which is particularly dimensioned so that no diffraction of the incident thereon solar radiation occurs.

By using such a grating, the heat in the light converter layer due to the solar radiation with longer wavelengths impinging on it and thus also due to the heat radiation impinging on it is dissipated into the outside environment, thereby avoiding overheating of the light converter layer.

In particular, the grid of at least one light converter layer ends in a wall of conductive material which adjoins the corresponding first optical element and is arranged perpendicular thereto. This wall serves to further dissipate the heat generated in the light converter layer into the outside environment. The wall extends up to the plane of the light converter layer or past this plane, in particular up to the plane with the solar cell. The larger the wall area, the faster the heat is transported to the outside environment. In addition, such a wall can serve as a holding device for the second optical element and / or the corresponding light converter layer and / or the associated and / or the associated optical device and / or the associated second hologram structure.

Preferably, several, in particular, all first optical elements are attached to a common transparent light entry body. So you can handle the first optical elements easier and with less effort and thus more cost-effectively installed in the photovoltaic device according to the invention.

In particular, several or all Lichtumwandlerschichten are at one Intermediate plate attached.

Thus, one can install the light converter layers with little effort and thereby cost in the photovoltaic device according to the invention.

Preferably, an optical device or a second hologram layer is mounted on a zone of the plate that covers the vertical projection surface of the associated light converter layer in the plane with the second hologram layer. Thus, the light converter layers and / or the respective associated optical devices and / or the respectively associated second hologram structures can be manufactured simply as one unit. When such a unit is constructed, there can be a very accurate relative positioning of the light converter layers to the associated optical devices and / or to the associated second hologram structures, since the area to be covered by the optical devices or by the second hologram structures can be pre-marked. Such units may then be positioned very accurately relative to the corresponding first optical elements, relative to the second optical elements and to the solar cells. This leads to a use of the entire existing solar cell surface and thus to a high efficiency of such a photovoltaic device according to the invention.

Preferably, a plurality of solar cells, in particular all solar cells, are attached to a second common carrier body. Thus, the solar cells used can be handled more easily and installed with less effort and thus more cost-effective in the photovoltaic device according to the invention.

In particular, at least one first optical element and / or at least one second optical element is a Fresnel lens. Thus, by the use of a conventional and thus inexpensive first and second optical Elements the desired bundling of incident solar radiation can be achieved on the solar cell.

Also, at least a first and / or at least a second optical element may have a fourth hologram structure that the incident

Solar radiation, which is convertible from the solar cell into electricity, bundles on the appropriate target area and transmits other solar radiation. In particular, the fourth hologram structure has a plurality of planar superposed hologram layers, each having a plurality of hologram regions with different hologram textures, each deflecting a portion of the incident, from the solar cell into electrical energy convertible solar radiation to the solar cell and transmit other solar radiation. Thus, the fourth hologram structure can be realized very accurately, since the planar hologram layers have hologram regions which can be individually tuned to the respective incident radiation on them.

In a particular embodiment of the invention, at least one light converter layer assigned to a first optical element has a fifth hologram structure, which is present on the side of the light converter layer facing the sun and on the side of the first optical element facing away from the sun, and the solar radiation deflected by the first hologram structure in a parallel, to the light converter layer, in particular on this uniformly distributed beam converts. Thus, the light converter layer can be optimally utilized.

In particular, the fifth hologram structure may be formed very precisely but simply and inexpensively as a superposition of a plurality of planar hologram layers, each having a plurality of hologram regions having different hologram textures, each reflecting the solar radiation deflected therefrom by the first hologram structure a parallel, in particular on this uniformly distributed to the light converter layer distributed beam portion and transmit other solar radiation.

Preferably, several of the photovoltaic devices according to the invention are used in a system which always tracks the sun.

Embodiments of the invention will be explained in more detail with reference to the accompanying drawings. Show:

1 shows a sectional view through an embodiment of a photovoltaic device according to the invention with at least one first optical element in the form of a Fresnel lens and a wall of conductive material; 2 shows a sectional view through a further embodiment of a photovoltaic device according to the invention with at least one first optical element in the form of a Fresnel lens, an intermediate plate and a secondary lens attached thereto.

In the following description of the preferred embodiments, the same reference numerals will be used for corresponding parts.

FIG. 1 shows a photovoltaic device 10 with at least one first optical element 20. The first optical element 20 is a Fresnel lens, which is mounted on the side facing away from the sun of a transparent light entry body 21. The first optical element 20 bundles the vertically incident solar radiation 30 onto an associated solar cell 40. The first optical element 20 has on its side facing away from the sun a first planar hologram structure 50 with a plurality of hologram regions 51, 52 with different hologram textures, which differs from the first optical Element 20 bundled radiation 30 in a non-usable by the solar cell 40 spectrum 60 on two on its side facing away from the sun and their spaced and encompassed by the Lichtumwandlereinrichtung 70 Lichtumwandlerschichten 70 deflects and the other of the first optical element 20 bundled radiation 80 in the of of the

Solar cell lets usable spectrum through. The light converter layers 70 shift the radiation 60 incident on them to the shorter wavelengths, that is, for the most part, into radiation 80 in a spectrum that can be used by the solar cell 40.

The light converter layers 70 each comprise a grid 85 of conductive material which serves to dissipate the heat generated by the solar radiation 60 impinging on the light converter layers 70 and thereby present in the light converter layers 70 into the external environment. The grids 85 each terminate in a wall 100 of the material which is capable of carrying the solar cell 40 and has a carrier body 90 which extends on the solar cell 40 and is adjacent to the first optical element 20 Light converter shattering 70 impinging solar radiation 60 resulting and thereby in the

Lichtumwandlerschichten 70 existing heat is used in the outdoor environment.

The solar radiation 60, which is shifted from the light converter layers 70 to the shorter wavelengths, is detected by the

Lichtumwandlerschichten 70 isotropically emitted. Approximately half of the isotropically emitted radiation is reflected by the optical device 105 present on the sides of the light converter layers 70 facing the sun and by the planar, second optical elements present on the side of the light converter layers 70 facing away from the sun

Hologram structure 110 with a plurality of hologram regions 111, 112 with different hologram textures split into two parts. The Another half of the radiation shifted to shorter wavelengths by the light conversion layers 70 is incident on the second hologram structure 110. The part of the radiation impinging on the hologram structure 110, which is convertible into electrical energy by the solar cell 40, is deflected by the second hologram structure 110 onto the solar cell 40 and other radiation is transmitted.

To simplify the illustration, only radiation that has been emitted by the light converter layers 70 in a single direction has been indicated in FIG.

FIG. 2 shows a photovoltaic device 10 with at least one first 20 and at least one second 120 optical element. The solar radiation 80 that can be used by the solar cell 40 is bundled by the first optical element 20 onto the surface of the second optical element 120 and then further focused by the latter onto the solar cell 40. The second optical element 120 is disposed on the sun-facing side of an intermediate plate 130. On the side of the intermediate plate 130 facing away from the sun, the light converter layers 70 encompassed by the light converter device 70 are mounted with the second planar hologram structures 110 mounted on their side facing away from the sun. The radiation 60, which is not usable by the solar cell 40, is also deflected from the first planar hologram structure 50 onto the light converter layers 70 and is shifted from this to shorter wavelengths. Here too, the light converter layers 70 each have a grid 85 of conductive material.

The solar radiation 80, from which the light conversion layers 70 are shifted to shorter wavelengths and convertible into electrical energy by the solar cell 40, here becomes the same as that of the sun, in the same manner as indicated in the description of FIG remote side of the support body 90 arranged solar cell 40th diverted. Other radiation does not apply to the solar cell 40 here either.

To simplify the illustration, only radiation that was emitted by the light converter layers 70 in a single direction was also indicated in FIG.

Further embodiments result from any combination of the individual features of the various embodiments.

LIST OF REFERENCE NUMBERS

10 photovoltaic device

20 first optical element 21 light entrance body

30 vertically incident solar radiation

40 solar cell

50 first level hologram structure

51, 52 different hologram regions of the first planar hologram structure

60 Part of the incident solar radiation in a spectrum that can not be converted into electricity by the solar cell

70 light converter device

80 Part of the incident solar radiation in a convertible from the solar cell into electricity spectral range

85 grids

90 carrier body

100 wall

105 optical device 110 second hologram structure

111, 112 hologram regions of the second planar hologram structure

120 second optical element

130 intermediate plate

Claims

Photovoltaic device (10) for the direct conversion of solar energy into electrical energy with at least one solar cell (40) and at least one Lichtumwandlereinrichtung (70) for shifting at least a partial spectrum of solar radiation occurring on the solar cell to another wavelength range, characterized in that the light converter device (70) is designed to shift irradiated solar radiation from a longer wavelength which can not be converted into electrical energy by the solar cell (40) to a shorter wavelength which is convertible into electrical energy by the solar cell (40), in that a first optical element (20) for bundling by a light entry region incident solar radiation on the at least one, this optical element associated and with respect to the Light entry region smaller area solar cell (40) is provided, and that a wavelength-dependent deflection is provided, the incident solar radiation with not usable by the solar cell longer wavelength (60) away from the solar cell (40) and towards the Lichtumwandlereinrichtung (70) deflects and corresponding to at shorter wavelengths, radiation (80) which is convertible from the solar cell (40) into electrical energy passes from the light converter means (70) to the solar cell (40). 2. A photovoltaic device according to claim 1, characterized in that the Lichtumwandlereinrichtung (70) at least one Lichtumwandlerschicht (70) for moving solar radiation (60) in one of the solar cell (40) can not be converted into electrical current spectrum towards shorter wavelengths in that the light converter device is located in a region between the first optical element (20) and the solar cell but outside the beam path the solar radiation (80) from the first optical element (20) is arranged to the solar cell and that the deflecting means a first hologram structure (50) which is provided on the first optical element (20) and the solar radiation (60) in the of the Solar cell (40) deflects non-convertible into electric current spectrum from the beam path between the first optical element (20) and the solar cell (40) away, but by the solar cell (40) into electricity convertible radiation and transmits, and has an optical structure, the the radiation (80) deflected by the first hologram structure (50) and shifted by the light converter layer (70) to shorter wavelengths, which is convertible into electrical energy by the solar cell (40), deflects to the solar cell (40) and transmits other radiation. 3. Photovoltaic device according to claim 2, characterized in that, the at least one first optical element (20) for bundling the vertically incident solar radiation (30) on the at least one, this first element (20) and compared to the first element, kleinflächigere and a solar cell (40) arranged at a distance therefrom is formed such that the light converter layer (70) is present between the solar cell (40) and the first optical element (20) and that the light converter layer (70) is located on the side of the first optical path which faces away from the sun Element (20) is arranged at a distance therefrom and has a surface whose vertical projection in the plane with the first optical element (20) forms at least part of its edge surface and whose projection in the plane with the solar cell (40) the surface of the solar cell (40) does not overlap. 4. Photovoltaic device according to claim 3, characterized in that the optical structure has an optical device (105) attached to the side of the light converter layer (70) facing the sun, which irradiates the solar radiation (60) deflected by the first hologram structure (50) onto the light converter layer (70) and reflects the solar radiation shifted from the light converter layer to shorter wavelengths, and a second hologram structure (FIG. 2) disposed on the side of the light converter layer (70) facing away from the sun (FIG. 110), which deflects the radiation reflected by the optical device (105) and solar radiation (80) shifted from the light converter layer (70) to shorter wavelengths, which can be converted by the solar cell into electrical energy, and others Radiation lets through. 5. Photovoltaic device according to claim 4, characterized in that the optical device (105) comprises a semitransparent mirror or a third hologram structure, which is the of the light converter layer (70) shifted to shorter wavelength radiation, which is convertible from the solar cell into electrical energy , reflects and allows other radiation through. 6. Photovoltaic device according to one of claims 3 to 5, characterized in that the vertical projection surface of the light converter layer (70) in the plane with the first optical element (20) forms the entire edge surface of the optical element (20). 7. Photovoltaic device according to one of the preceding claims, characterized in that at least one first optical element (20) is present, the plurality of solar cells (40) are assigned and / or at least one Solar cell (40) is associated with which a plurality of the first optical elements (20). 8. Photovoltaic device according to one of the preceding claims, characterized in that the Lichtumwandlereinrichtung (70) of the first optical element (20) bundled solar radiation in the from the solar cell (40) into current transformable spectrum (80) does not overlap. 9. Photovoltaic device according to one of the preceding claims, characterized in that between the first optical element (20) and the at least one associated solar cell (40), a second optical element (120) for further bundling of the first optical element (20 ) bundled solar radiation (80) is present. 10. Photovoltaic device according to claim 7, characterized in that at least the Lichtumwandlereinrichtung (70) is arranged approximately in a plane with the second optical element (120). 11. A photovoltaic device according to claim 10, characterized in that a light converter layer (70) of the light converter means is disposed adjacent to the second optical element (120). 12. A photovoltaic device according to claim 9, characterized in that the at least one of the first element (20) associated Lichtumwandlerschicht (70) between the first optical element (20) and the second optical element (120) is arranged. 13. Photovoltaic device according to claim 12, characterized in that in that the deflection device has a second hologram structure (110) which is deflected by the solar cell (40) into the light converter layer (70) from the first hologram structure (50) and shifted by the light converter layer (70) to shorter wavelengths electrical energy is converted to the second optical element (120) deflects. 14. Photovoltaic device according to one of claims 9 to 13, characterized in that the second optical element (120) is a converging lens, in particular a Fresnel lens. 15. Photovoltaic device according to one of the preceding claims, characterized in that the Lichtumwandlereinrichtung (70) in its interior and / or on its side facing away from the sun, a grid (85) made of thermally conductive material for dissipating in her by on it (70 ) has incident solar radiation (60) resulting heat in the external environment, which in particular is dimensioned so that no diffraction of the incident thereon solar radiation (60) occurs. 16. Photovoltaic device according to one of the preceding claims, characterized in that at least one heat dissipation device, in particular a grating (85), the Lichtumwandlereinrichtung (70) on one of the first optical element (20) adjacent and perpendicular thereto arranged wall (100). of thermally conductive material suitable for further dissipating the heat generated in the light converter means (70) to the outside environment, the wall (100) extending from the first optical element (20) to a plane including the light converter means (70) and in particular also extends to a solar cell (40) having level. 17. Photovoltaic device according to one of the preceding claims, characterized in that a plurality, in particular all, first optical elements (20) are mounted on a common transparent light entry body (21). 18. Photovoltaic device according to one of the preceding claims, characterized in that a plurality of Lichtumwandlerschichten (70) of the Lichtumwandlereinrichtung are attached to a common intermediate plate (130). 19. A photovoltaic device according to claim 18, characterized in that at least one second hologram structure (110) is mounted on a zone of the intermediate plate (130), the vertical projection surface of the associated light converter layer (70) in the plane with the second hologram layer (110). covered. 20. Photovoltaic device according to one of the preceding claims, characterized in that a plurality of solar cells, (40) in particular all the solar cells (40) are attached to a second common carrier body (90). 21. Photovoltaic device according to one of the preceding claims, characterized in that at least one first optical element (20) is a Fresnel lens. 22. Photovoltaic device according to one of the preceding claims, characterized in that the first optical element (20) has a fourth hologram structure, the incident solar radiation (80), which is convertible from the solar cell (40) into electrical current, on the solar cell (40) bundles and other radiation passes through. 23. Photovoltaic device according to one of claims 9 to 13 and 15 to 22, characterized in that at least one second optical element (120) has a fourth hologram structure, the incident solar radiation (80) from the solar cell (40) in electric current is convertible, on the solar cell (40) bundles and other radiation passes. 24. Photovoltaic device according to one of the preceding claims, characterized in that at least one solar cell (40) is formed from semiconductor compounds, in particular as a multilayer solar cell (40) is formed. 25. Photovoltaic device according to claim 24, characterized in that the at least one solar cell (40) has an area which is smaller than 100 square millimeters. 26. Photovoltaic device according to claim 2 or one of claims 3 to 25, as far as dependent on claim 2, characterized in that at least one first optical element (20) associated Lichtumwandlerschicht (70) has a fifth hologram structure, which on the sun facing side of the light converter layer (70) and on the side facing away from the sun of the first optical element (20) and deflected by the first hologram structure (50) solar radiation (60) in a parallel, in particular uniformly distributed to the light converter layer (70) Beam (60) converts. 27. Solar system with several in particular with several isolated Photovoltaic devices (10) according to one of the preceding claims.