EP2162684A2 - Photovoltaic device with holographic structure for deflecting incident solar radiation, and method for producing it - Google Patents

Abstract

The invention relates to a photovoltaic device (10) for directly converting solar energy into electrical energy, comprising a light entrance body (1) having a multiplicity of holographic elements (3) which each have a hologram structure (30) with a plurality of superimposed hologram layers (32, 34) having different spectral sensitivities, which concentrate the short-wave solar radiation that is incident at a specific angle in each case onto the same region of an opposite solar cell (5) having an area smaller than the light entrance area of a corresponding holographic element (3), wherein each holographic element (3) has at least one topmost hologram layer (32) which transmits the short-wave incident radiation and deflects the incident long-wave solar radiation at an obtuse angle or directs it away from the opposite solar cell (5) in a region present between the opposite solar cell (5) and an adjacent solar cell (5) on that side of the solar cells (5) which is remote from the light.

Description

 PHOTOVOLTAIC DEVICE WITH HOLOGRAPHIC STRUCTURE

FOR DISCONNECTING IMMEDIATE SUNBURNING, AS WELL AS

MANUFACTURING HEREfor

The invention relates to a photovoltaic device according to the preamble of the appended claim 1, as known from DE 10 2004 031 784 A1. In particular, the invention relates to a PV concentrator module for direct conversion of light into electrical energy, in which the incident solar radiation is deflected by means of a hologram structure, wherein a portion of the incident solar radiation is concentrated on a solar cell. Finally, the invention relates to a manufacturing method for such a device.

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, the performance of these solar cells is relatively low because they convert only a limited spectrum of the incident radiation into electrical current.

A higher efficiency with e.g. Over 30% conversion of solar radiation has in recent years been associated with high power PV cells from higher value semiconductor interconnects (e.g., Ill-V semiconductor material), e.g. GalliumArsenide (GaAs) has been achieved. 0 Such semiconductor-based cells can be built up step by step as tandem or triple or multi-layer cells, thereby exploiting a wider light-frequency spectrum.

However, the large-scale production of such cells is very expensive. It was therefore chosen the approach to focus the incident sunlight on a very small area of such solar cells, for example, less than 1 mm ² . Only for this small area then a micro solar cell is necessary. Of the Material use can then be less than 1% compared to the areal use of such cells. The concentration makes it possible to use the high luminous efficacy of high-performance PV cells of, for example, about 36%. Since only the connection of several solar units enables economical use of such a PV system, these are preferably combined to form a PV concentrator module.

Micro solar cells made of semiconductor material with a size of less than a few hundred square millimeters are known from DE 103 20 663 A1. According to DE 103 20 663 A1, the micro-solar cells are applied inside a transparent housing constructed of a plurality of glass panes on the inside of a lower glass pane. Since the efficiency of the micro-solar cell decreases with increasing temperature, the micro-solar cells are each surrounded by a heat sink. The mounting method of all micro-solar cells in a housing leads, despite existing heat sinks around the micro-solar cells to problems in the necessary heat dissipation to the outside and to contamination of the module insides including the sensitive solar cells.

Usually, the incident sunlight is focused in PV concentrator modules by means of converging lenses on the existing solar cells. Due to aberrations such as aberrations. Color errors, when inserting converging lenses, do not focus the incident light on one point, but in the best case on a line. Consequently, only a portion of the incident light in a particular spectral range can be focused on a given solar cell.

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 part of the radiation that can be used by the solar cells is rather short-waved and in the following will become short-wave radiation called.

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. This part of the incident radiation is called long-wave radiation in the following.

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. Furthermore, it is known that the efficiency of solar cells decreases with an increase in temperature. A disadvantage that exists in the operation of the solar cells, is that the working temperature of the solar cells because of the large amounts of heat that during the operation of a PV concentrator module or because of the solar cells or in the

Surrounding impinging incident longwave radiation, is greatly increased. 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.

DE 10 2004 031 784 A1 discloses a holographic, preferably arc-shaped, deflecting device, wherein hologram structures, which preferably have diffraction gratings, have different spectral diffraction efficiencies and divert the usable incident solar radiation for different positions of the sun onto a light receiving element. The deflection device has a plurality of hologram layers, each hologram deflecting incident radiation in a given spectral range and at a certain angle of incidence equally to the light-receiving element and transmitting light in another spectral range or angle of incidence. Several

Hologram layers are superimposed and chosen so that a constant diffraction efficiency over the entire spectral range of the incident solar radiation results. The deflection device is suitable for converting or concentrating diffuse incident light into parallel light. The light receiving element may be a solar cell or a solar absorber.

From XuXiang, ZhouBin, Liu Chunze, XuChao, WuGuangming, NiXingyuan, ShenJun, Key Laboratory of Waves and Microstructure Materials, Pohl Institute of Solid State, from the article "Fabrication of relief gratings on high photosensitivity SiO ₂ / ZrO ₂ gel film by UV exposure" Physics, Tongji University, Shanghai, China. In 200092, a ZrO ₂ -GeI film is known, which is chemically modified with benzoyl acetone and prepared in a sol-gel process.

In the sol-gel process very thin coatings can be realized. In sol-gel processes, there are a variety of hydrolysis and

Polymerization reactions that result in the formation of a colloidal solution. Particles having a small diameter of a few hundred nanometers and previously dissolved in a liquid then condense to a gel.

Photosensitive gel films are each coated on a silicon dioxide substrate and then exposed to UV light through a mask and then leached in alcohol. Finally, gratings with a period of 2 μm and a depth of 80 nm are obtained. The absorbency of such GeI films is shifted to the shorter wavelengths below 300 nm. The optical and morphological properties of the grating are examined with FTIR, AFM, SEM, etc. Such diffraction gratings have been found to be acceptable in the manufacture of micro-optic elements such as optical communications holograms and optoelectronics.

The invention has for its object to provide a photovoltaic device according to the preamble of the appended claim 1, which has the advantages of PV concentrator technology uses such a way that a high efficiency of the solar cells over a longer time is obtained. In particular, it is necessary to build a PV concentrator module so that this can be produced in series with little effort and a high efficiency of the solar cell is obtained over a longer time.

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. An advantageous manufacturing method for this is the subject of the independent claim.

With the photovoltaic device according to the invention, a high efficiency of the solar cells over a long time by avoiding color aberrations and stabilization of the working temperature of the solar cell in a range in which the solar cells can work efficiently obtained.

In a preferred embodiment, by means of at least one holographic element having a holographic structure, focusing the usable light incident at a certain angle onto a smaller-area solar cell opposite the holographic element, which is preferably a micro-solar cell made of semiconductor material, which has a multilayer structure can. Several solar cells can each be applied under or on a transparent light emission body or carrier.

Preferably, a light entrance body has a plurality of holographic elements, each comprising at least one planar hologram layer having a maximum diffraction efficiency in a short-wavelength region of the incident solar radiation and a plurality of hologram structure regions of different holographic nature. As a result, the radiation incident at a certain angle can be deflected differently in a given spectral range and at the same point be focused. Other hologram layers can be similarly constructed and superimposed on one another for further spectral ranges.

As a result, the short-wave solar radiation incident at a certain angle can be focused on the same point in its entire usable spectral range by means of a planar hologram structure, which can thus be easily realized. Thus, a possible spectral decomposition of the incident usable solar radiation in a direction perpendicular to a solar cell direction can be canceled.

As a result, the area of the solar cells used can be reduced and their efficiency can be increased. The reduction in the necessary area of the solar cells brings about a reduction in the cost of the solar cells, which are very high, particularly in the case of multilayer solar cells made of semiconductor material.

Due to this very accurate focusing, the active area on a solar cell where focused light impinges becomes very small, and therefore, when tracking to the sun of a photovoltaic device that has such a strong focus, greater tolerance to the sun can be provided. As a result, the power generation cost of such photovoltaic devices also decreases.

Preferably, the at least one holographic element on a side facing the sun on second hologram structure, in particular in the form of one or more uppermost holographic layers, which deflects the long-wave incident radiation at an obtuse angle (> 90 °), in particular reflected, and the usable short-wave Light through. Thus, an increase in the working temperature of the solar cell (s) can be avoided and be achieved by the fact that the solar cell (s) longer working efficiently (working).

Preferably, a plurality of solar cells are on the back of a carrier body applied in the form of a transparent light exit body. So you just get to the solar cells for contacting and heat dissipation zoom. One could thus provide such a planar heat conductor, absorber body for solar thermal purposes or without problems three-dimensional heat dissipation devices, as in electronic

High performance devices are known, for example, rib structures.

In particular, the at least one holographic element on the side facing the sun, the second hologram structure having at least one preferably arranged at the top hologram, durchlast the short-wave radiation and long-wave radiation from the surface of the solar cell and deflects long-wave target areas of a heat conductor plate or an absorber body , These long-wave target areas are each below the space between two adjacent solar cells and the area of none of the solar cells overlap.

One could thus avoid an increase in the solar cell temperature during operation and the incident long-wave radiation and heat generated during operation of the solar cells by means of a heat transfer medium by an existing three-dimensional

Heat dissipation device flows, use thermally. When a heat plate is connected to the sun-facing side of the carrier, the incident heat radiation and heat generated during operation of the solar cells can be efficiently transported to the outside environment. In this case, the heat conductor plate serves as a heat sink for the solar cells.

Preferably, the absorber body may have a selective absorber, which also converts short-wave solar radiation into heat radiation. In this case, it is advantageous for the hologram structures of one, several or all of the holographic elements to each have further regions-referred to below as passages-which respectively transmit the short-wave and long-wave incident radiation. To the operation of the solar cells not to be affected, it is preferable that the passbands adjoin the hologram regions respectively focusing the short-wavelength radiation on the opposite solar cell and positioned above the space between two adjacent solar cells so as not to overlap the surface of the solar cells. Thus, a larger proportion of the incident radiation can be converted into heat by the absorber body without heat radiation being radiated back from the selective absorber or absorber body to the solar cells or into their immediate surroundings.

In a preferred embodiment, diffraction gratings are used as hologram layers. The hologram structure is so easy to implement.

In a further embodiment, grating structures are used which are produced in a gel film produced in the sol-gel process. So it is possible to redirect incoming solar radiation very accurately.

Advantages of the invention or its preferred embodiments are:

By the presence of a second hologram structure, for example with at least one topmost hologram layer on the side of each holographic element facing the sun, which second hologram structure reads through the shortwave radiation and redirects or redirects the longwave radiation at an obtuse angle, the working temperature can be set to control the solar cells more easily. The efficiency of solar cells decreases with each increase in temperature. The less heat radiation strikes the solar cells, the lower the likelihood that the solar cells will be heated, and consequently, these can then be used more efficiently for longer. By forming the holographic elements from a plurality of planar superimposed hologram layers with a maximum diffraction efficiency in the usable range of incident radiation and several areas with different holographic properties, the short-wave incident radiation at a certain angle can be deflected differently and in a given spectral range Point - in particular a point-shaped short-wave target area on each solar cell - focus. Thus, a possible spectral decomposition, which occurs in the case of the PV concentrator modules commonly used Fresnel lenses, can be avoided. As a result, the active area of the solar cells is reduced, which, given the solar cell area, results in greater photoraduction tracking tolerance of photovoltaic devices employing such holographic elements. This will be a

Cost reduction of power generation costs for such photovoltaic devices achieved.

• Plane holographic structures are also technically simpler and can be realized with less material input than curved structures.

Such flat holographic elements are light and space-saving and allow their reduced weight easier tracking to the sun.

• By attaching the solar cells facing away from the sun

Side of a support body load the heat generated during operation of the solar cells or the incident long-wave radiation easier to handle, for. B. by means of a heat conductor plate, which is connected to the side facing away from the sun of the carrier and can be used as a heat sink for the solar cells. With the heat conductor plate, which can also be supplemented or replaced by an absorber body for solar thermal purposes, a heat dissipation device be connected to exploit the incident long-wave radiation and heat generated during operation of the solar cell. The resulting heat is then fed by means of a heat transfer medium for thermal utilization.

Looking at a long-wave radiation sensitive second hologram structure, for example, with at least one Hogrammschicht top on the sun-facing side of each holographic element before, each of the short-wave radiation through and additionally or alternatively to a return line or

Reflection of long-wave radiation, long-wave radiation on long-wave target areas of the heat conductor plate or the absorber body deflects, which are each positioned below the space between two adjacent solar cells with lateral distance to such adjacent solar cells, can be more of the incident heat radiation for solar thermal use exploited. By positioning the above-mentioned long-wave target areas incident heat radiation is deflected away from the immediate vicinity of the solar cell and thus an increase in the working temperature of the solar cell is avoided.

By forming at least one of the hologram structures or hologram layers by means of a photosensitive gel film in a sol-gel process, diffraction gratings having different lattice structures in the same can be precisely and inexpensively obtained

Create hologram layer.

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

Fig. 1 is a perspective view of a photovoltaic device in

Form of a PV concentrator module with a variety of individual photovoltaic devices (also called concentrator unit), which each serve for the direct conversion of solar radiation concentrated on a small-area solar cell into electrical energy, as well as a schematic detail view of the general structure of a first embodiment of the

Photovoltaic devices;

Fig. 2 is a sectional view through a photovoltaic device of FIG

1 according to a first embodiment (with top hologram layer deflecting long wavelength radiation at an obtuse angle);

Fig. 3 is a sectional view through a photovoltaic device of FIG

1 according to a second embodiment (with topmost hologram layer deflecting long-wavelength radiation at an obtuse angle and with heat conductor plate);

Fig. 4 is a sectional view through a photovoltaic device of FIG

1 according to a third embodiment (with top hologram layer having different regions which either redirect or transmit long wavelength radiation at an obtuse angle, heat conductor plate and heat dissipation device);

Fig. 5 is a sectional view through a photovoltaic device of FIG

1 according to a fourth embodiment (with topmost hologram layer having different regions deflecting or transmitting long wavelength radiation either at an obtuse angle, other hologram layers having regions transmitting longwave and shortwave radiation, absorber body and heat dissipation device); Fig. 6 is a sectional view through a photovoltaic device of FIG

1 according to a fifth embodiment (topmost hologram layer having various regions which either redirect or transmit longwave radiation, heat conduction plate and heat dissipation device);

Fig. 7 is a sectional view through a photovoltaic device of FIG

1 according to a sixth embodiment (topmost hologram layer having different regions that either redirect or transmit longwave radiation, other hologram layers having regions that transmit longwave and shortwave radiation, absorber body and heat dissipation device);

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

1 shows a photovoltaic device 10 in the form of a PV concentrator module with a plurality of individual photovoltaic devices 11 in the form of concentrator units, each with at least one solar cell 5 in the form of a microsolar cell. The solar cells 5 of the photovoltaic devices 11 are held by a light-emitting body in the form of a transparent carrier 50, which is arranged at a certain distance from a light inlet body 1.

In a first embodiment of the photovoltaic device 10 shown in FIG. 2, holographic elements 3, each having a first hologram structure 30 and a second hologram structure, are used here on the light entry body 1. The first hologram structure is formed of a plurality of planar hologram layers 34, 36. To form the second hologram structure, there is at least one upper hologram layer 32 which receives incident longwave radiation 25 (radiation with a Photon energy below the energy gap of the photovoltaically active materials used in the micro solar cell 5) deflects at an obtuse angle and the remaining, in particular short-wave radiation 20 passes.

The hologram layers 34, 36 of the first hologram structure 30 focus incident shortwave radiation 20 (radiation convertible into current in the microsolar cell) to the opposing solar cell 5. By the presence of hologram structure regions 40, 42 of different hologram nature in the same planar hologram layer 34, 36 , which deflect the vertically incident shortwave radiation differently in a given spectral range and transmit radiation in a different spectral range, a strong focusing of radiation in a given spectral range can be achieved. If a plurality of such hologram layers 34, 36 overlap, incident shortwave radiation 20 of different spectral regions can be focused on the same point.

The efficiency of the solar cells can be increased because with such a first hologram structure 30, the color error usually occurring in lens systems is avoided.

Overheating of the solar cell 5 is avoided by the second hologram structure having the upper hologram layers 32, which in the first embodiment redirects or redirects the incident long-wavelength light 25 as shown in Figs. 1 and 2 at an obtuse angle between incident and deflected beams. The solar cells 5 can be mounted under the transparent support 50, which also serves as a common carrier and on its side facing away from the sun conductors (not shown) for contacting the solar cell 5 has.

In addition, a (eg, adhesive) transparent insulating layer 60 may be applied. This mounting method of the solar cells 5 is special advantageous because the solar cells between the side facing away from the sun of the support body 50 and the insulating layer 60 are better protected against environmental influences.

In a second embodiment shown in FIG. 3, in addition to the (adhesive) insulating layer 60, a heat conductor layer 70 is mounted on this and on the underside of the solar cells 5. The thermal conductivity of the heat conductor layer 70 can be changed directly by the use of particularly conductive material and / or different thickness of the material directly or even later by the additional application of conductive material layers. Due to the presence of the heat conductor plate 70, the heat generated during operation of the solar cells 5 can be better transported from the solar cells to the environment.

In contrast to the second embodiment, a third embodiment shown in FIG. 4 has holographic elements 3, each with a second hologram structure in the form of at least one top hologram layer 32 positioned on the side facing the sun, with juxtaposed different hologram structure regions 301, 302 with different hologram properties , The long-wave incident radiation is deflected back or deflected at an obtuse angle by a first hologram structure region 301 of the second hologram structure positioned above a solar cell 5 in each case. A second hologram structure region 302 adjacent to this first hologram structure region 301, which is positioned above the interspace of two adjacent solar cells 5, transmits the long-wave radiation 25. In addition, under the heat conductor layer 70 there is a heat dissipation device having a piping system 80 for a heat transfer medium.

By this arrangement, long-wavelength radiation from the first hologram structure regions 301 located above the solar cell 5 can be obtained. be redirected back to the outside environment. However, long-wavelength radiation is transmitted by the adjacent second hologram structure regions 302 and impinges on the heat conductor plate 70. Through the heat conductor plate 70 then incident heat radiation and heat generated during operation of the solar cells can be dissipated to the standing in contact with the heat conductor plate 70 heat dissipation device and heat a heat transfer medium flowing through the piping 80. The heated heat transfer medium can then be used for thermal utilization. Also, both incident long-wave radiation 25, which makes itself felt as heat radiation, as well as during operation of the solar cell 5 resulting heat from the environment of the solar cell 5 transported away to avoid an increase in the operating temperature of the solar cell 5.

In contrast to the third embodiment, a fourth embodiment shown in FIG. 5 has an absorber body 75 instead of the heat conductor layer 70 for solar thermal purposes. In addition, the superimposed hologram layers 34, 36 for deflecting shortwave radiation 20 may have passbands 46 each positioned above the space between two adjacent solar cells 5 so as not to overlap the surface of the solar cells 5 and transmitting the shortwave incident radiation. Thus, incident short-wave radiation 20 is absorbed by the absorber body 75. The absorber body 75 has a glass plate (if possible from solar glass) on a side of an absorber facing the sun. The incident through the glass plate solar radiation impinges on the absorber. This short-wave, high-energy radiation is converted into thermal radiation. The released heat must not be lost, which is why the absorber body should be thermally insulated on all sides. Heat that is not directly absorbed by the absorber or emitted by it as an emission is reflected back through the glass. It is thus trapped in the absorber body 75. The absorber should absorb direct and diffused radiation as well as possible and into heat convert (absorption). At the same time, it should emit as little heat as possible in the form of radiation (emission). He should behave selectively.

The heated absorber transfers the heat to the flowing in the fixedly connected to the absorber body 75 piping 80

Heat transfer fluid. This transports the collected heat energy to a consumer or a heat storage.

In contrast to the third embodiment, a fifth embodiment shown in FIG. 6 has a second hologram structure in the form of an upper hologram layer 32, which has different hologram structure regions 311, 302 with different hologram properties. The long-wave incident radiation 25 is irradiated by a third hologram structure region 311 of the uppermost hologram layer 32 positioned above a solar cell 5 on long-wave target regions 702 of FIG

Redirected heat conductor plate, which are not directly under the solar cell 5 and the solar cell areas 711 of the heat plate 70, which are each located directly below a solar cell 5, adjacent.

The long-wavelength incident radiation 25 is transmitted by a second hologram structure region 302 of the topmost hologram layer 32 adjoining the region 311, which is located over the interspace of two adjacent solar cells 5, and impinges on the long-wave target regions 702 of the heat conductor layer 70. Here, a heat dissipation device (not shown) having a piping system 80 may abut the heat conduction plate 70.

In contrast to the fifth embodiment, instead of the heat conductor layer 70 from FIG. 4, a sixth embodiment shown in FIG. 7 has an absorber body 75 for solar thermal purposes, which has a selective absorber. In addition, the superimposed hologram layers 34, 36 for deflecting short-wave radiation 20 Have transmission regions 46 which are positioned over the space between adjacent solar cells 5, the solar cells 5 do not overlap and let through short-wave incident radiation 20. Thus, incident short-wave radiation 20 can be converted by the absorber body 75 into thermal radiation and fed to a thermal utilization.

LIST OF REFERENCE NUMBERS

I light entrance body

3 holographic element 5 solar cell

10 photovoltaic device

I 1 photovoltaic device

20 incident shortwave solar radiation 25 incident longwave solar radiation 30 first hologram structure (holographic structure)

32 top hologram layer for redirecting long-wave radiation (second hologram structure)

34 Hologram layer for deflecting short-wave radiation in a first spectral range 36 Hologram layer for deflecting short-wave radiation in a further spectral range 40 First hologram structure region of the first hologram structure for

Deflecting shortwave radiation at a first deflection angle 42 second hologram structure region of the first hologram structure for deflecting shortwave radiation under another

Deflection angle 46 passage area in the first hologram structure serving for deflecting short-wave radiation, which passage area transmits the short-wave radiation 50 transparent carrier (light exit body) 60 insulating layer 70 heat conductor plate 75 absorber body 80 piping system 301 First hologram structure area of the top hologram layer (s) for Redirecting longwave radiation at an obtuse angle, which is positioned immediately above a solar cell. 302 Second hologram structure area of the uppermost one Hologram layer (s), each of which is not directly above a solar cell and transmits long-wave radiation Immediately above a solar cell positioned area of the top

Hologram layer (s) for redirecting long-wave radiation into a region which is in each case immediately below the space between two adjacent solar cells. Area of the heat conductor plate or the absorber body immediately under the solar cell (long-wave target area) Area of the heat conductor plate or of the absorber body under the space between adjacent solar cells (solar cell area)

Claims

Photovoltaic device (10) for direct conversion of solar energy into electrical energy with at least one solar cell (5) and at least one of the solar cell (5) associated holographic element (3) having a first hologram structure (3), which incident shortwave Solar radiation, which consists of radiation from at least one by the solar cell (5) convertible into current spectral range, focuses on a shortwave target area on a relative to the light entrance surface of the holographic element (3) smaller area solar cell (5), characterized in that the holographic element (3) comprises a second hologram structure (32) which transmits short-wave radiation (20) consisting of radiation in a spectral range usable by the solar cell (5), but long-wavelength radiation consisting of radiation from one of the solar cell (5). unusable spectral range, from the solar cell (5) deflects away. 2. Photovoltaic device according to claim 1, characterized in that it comprises a plurality of solar cells (5), wherein each solar cell (5) at least one of the holographic elements (3), the light entrance surface substantially larger than that as the surface of the solar cell ( 5) is assigned to bundle short-wave solar radiation (20) from the usable spectral range to the solar cell surface. 3. Photovoltaic device according to claim 2, characterized in that the plurality of holographic elements (3) are formed on a common light entry body (1). 4. Photovoltaic device according to one of the preceding claims, characterized in that the first hologram structure (30) for bundling usable short-wave radiation has a plurality of superimposed hologram layers (32, 34) with different spectral sensitivities which focus the short-wavelength solar radiation incident at a certain angle onto the same shortwave target area of the associated solar cell. 5. Photovoltaic device according to one of the preceding claims, characterized in that the second hologram structure is formed by at least one uppermost hologram layer (32). 6. Photovoltaic device according to one of the preceding claims, characterized in that the second hologram structure deflects incident long-wave radiation under a, preferably blunt, angle, in particular reflected. 7. Photovoltaic device according to one of the preceding claims, characterized in that the second hologram structure incident long-wave radiation from a first solar cell (5) away in between the first solar cell (5) and an adjacent second solar cell (5) existing long-wave target area deflects. 8. Photovoltaic device according to one of the preceding claims, characterized in that the first hologram structure (30) is planar. 9. Photovoltaic device according to claim 8, characterized in that the planar first hologram structure has a plurality of hologram structure regions formed side by side in the planar hologram structure (40, 42) of different holographic nature for deflecting the incident in the respective region of short-wave radiation at correspondingly different angles to a common point-shaped short-wave target area on the solar cell surface. I The photovoltaic device according to claim 9 and claim 4, characterized in that said first hologram structure (30) is planar with a plurality of superimposed hologram layers (34, 36) and each hologram layer (34, 36) covers said plurality of hologram structure regions (40, 40). 42) having different holographic properties which divert the incident shortwave light differently from a given spectral range per hologram layer (34, 36), the different hologram structure regions (40, 42) of different hologram layers determining the incident shortwave radiation independently of the respective sensitive spectral range Focus on the same punctual shortwave target area on the associated solar cell (5). 11. Photovoltaic device according to claim 2 or according to one of the preceding claims, as far as dependent on claim 2, characterized in that the solar cells (5) are mounted on a common transparent support (50) in particular on its side facing away from the sun. 12. Photovoltaic device according to claim 11, characterized in that an insulating layer (60) of transparent material is applied between the solar cells (5) and the side of the carrier (50) facing away from the sun. 13. Photovoltaic device according to claim 11 or 12 and according to claim 7, characterized in that the second hologram structure (32) incident long-wave solar radiation from the first solar cell (5) in one between the first solar cell (5) and an adjacent second solar cell (5) immediately under the support (50), in particular immediately below the insulating layer (60), deflects existing longwave target area. 14. Photovoltaic device according to one of claims 11 to 13, characterized in that a heat conductor plate (70) with the side facing away from the sun of the carrier body (50) is connected. 15. Photovoltaic device according to one of claims 11 to 14, characterized in that an absorber body (75) for solar thermal purposes with the side facing away from the sun of the carrier body (50) is connected. 16. Photovoltaic device according to claim 15, characterized in that the absorber body (75) has a selective absorber, which converts short-wave solar radiation into heat radiation. 17. Photovoltaic device according to one of claims 14 to 16, characterized in that the second hologram structure (32) deflecting incident long-wave radiation respectively on long-wave target areas (712) of the heat conductor plate (70) or the absorber body (75), each under a space between two adjacent solar cells (5) are positioned and not with each immediately below the solar cell (5) located solar cell areas (701) of the heat conductor plate (70) or the absorber body (75) overlap. 18. Photovoltaic device according to one of claims 14 to 17, characterized in that a piping system (80) on the side facing away from the sun of the heat conductor plate (70) or the absorber body (75) is mounted and for deriving in the photovoltaic device (10 ) by solar radiation or during operation of the solar cell (5) resulting heat by means of a heat transfer medium and for supplying the thus heated heat transfer medium to a thermal utilization. 19. Photovoltaic device according to one of the preceding claims, characterized in that the at least one holographic element (3) and / or the at least one holographic element (3) having Lichteintrittskörper (1) adjacent to the short-wave radiation focussing first hologram structures (30 ) in at least one intermediate region, which is not arranged directly above a solar cell (5), at least one passage region (46), which allows both the short-wave and the long-wave incident radiation through to a solar cell-free target area (702). 20. Photovoltaic device according to one of the preceding claims, characterized in that at least one solar cell (5) is a microsolar cell, in particular with an areal extent of equal to or less than about 100 mm ² . 21. Photovoltaic device according to one of the preceding claims, characterized in that the at least one solar cell (5) is a multilayer cell of semiconductor compounds, in particular tandem or triple cells of IM-V semiconductor compounds. 22. Photovoltaic device according to one of the preceding claims, characterized in that the first and second hologram structures (30, 32) Hologram layers (32, 34, 36) having diffraction gratings. 23. A photovoltaic device according to claim 22, characterized in that at least one of the hologram layers (32, 34 _r 36) each comprises at least one photosensitive gel film having at least one diffraction grating having a given period and depth. 24. A method for producing a photovoltaic device according to any one of claims 1 to 23, characterized by any order of the following steps: a1) providing a light entry body (1) having a plurality of holographic elements (3), each having a first Hologram structure (30) having a plurality of superimposed hologram layers (34, 36) having different spectral sensitivities, each focusing the incident at a certain angle short-wave solar radiation on the same short-wave target area, each having a smaller area than a corresponding holographic element (3) and (3) on the side facing away from the sun, b) providing a transparent carrier (50) with a multiplicity of solar cells (5) in each case in the short-wave target area with a smaller area than a solar cell (5), onto which the incident short-wave radiation from the c) attaching at least one top hologram layer (32) on the sun facing side of the first hologram structure (30) of each holographic element (3), the top hologram layer (32) being formed that will be the incident transmits short-wave radiation and redirects the incoming long-wave solar radiation at an obtuse angle in particular reflective or from the place to in which the associated solar cell (5) is to be arranged, deflects in a solar cell-free, long-wave target area, which between adjacent solar cells (5) on a side facing away from the light of the solar cells (5), the surface of the solar cell is not overlapping to arrange. 25. The method according to claim 24, characterized by the step to be carried out before step a1): a) producing one holographic element (3) from a plurality of planar superposed hologram layers (34, 36) each having a plurality of hologram structure regions (42, 46) different holographic nature, which deflect the incident shortwave light differently in a given spectral range and focus independent of the spectral range on the same punctual short-wave target area, which is to be arranged on a solar cell to be assigned (5). 26. The method according to any one of claims 24 or 25, characterized in that step b) comprises: Applying the solar cells (5) on the side facing away from the sun of the transparent support (50). 27. Method according to claim 26, characterized by the step to be carried out after step b): b1) applying a transparent material to the side of the carrier (50) facing away from the sun for the protective covering of the solar cells (5). 28. The method according to claim 26 or 27, characterized in that step c) comprises: forming the topmost hologram layer (32) such that the long-wave target area immediately under the support (50), in particular immediately below the insulating layer (60) existing area lie comes. 29. The method according to any one of claims 24 to 28, characterized by the step to be performed before or after step c) d) applying a heat conductor plate (70) on the side facing away from the sun of the carrier (50). 30. The method according to any one of claims 24 to 29, characterized by the step to be carried out before or after step c) e1) attaching an absorber body (75) for solar thermal purposes on the side facing away from the sun of the carrier (50). 31. The method according to claim 30, characterized by the step e) to be carried out before the step e) producing or selecting an absorber body (75) with a selective absorber, which converts the short-wave radiation into heat radiation. 32. The method according to any one of claims 29 to 31, characterized by the step to be carried out after step d) or e): f) attaching a piping system (80) on the side facing away from the sun, the heat conductor plate (70) or the absorber body (75) which is used for deriving in the photovoltaic device (10) by incident solar radiation or during operation of the solar cell (5) resulting heat by means of a heat transfer medium and for supplying the thus heated heat transfer medium for thermal utilization. 33. The method according to any one of claims 29 to 32, characterized in that step a) or a1) comprises: producing the hologram layers (34, 36) of each holographic element (3) such that at the light entrance body (1) adjacent to the short-wave Radiation focusing first hologram structure additional Passage regions (46) are formed which transmit the short-wave and the long-wave incident radiation. 34. The method according to any one of claims 24 to 33, characterized in that step a) or a1) comprises: Producing diffraction gratings for forming the hologram layers (34, 36) of each holographic element (3) having a suitable holographic texture. 35. The method according to any one of claims 24 to 34, characterized in that step c) comprises: Producing diffraction gratings for forming the at least one uppermost hologram layer (32) of each holographic element (3) having a suitable holographic texture. 36. The method according to claim 34 or 35, characterized in that the diffraction gratings of at least one of the hologram layers (32, 24, 26) of each holographic element (3) are produced by the following steps: g) producing at least one photosensitive gel film in the sol GeI method and coating a substrate with the at least one gel film, h) applying a mask with a grid or a series of gratings with a given period and depth each on the at least one gel film, i) exposing the one gel Through the mask with light and generating, in particular, by leaching one or more grids negative in relation to the grating or the plurality of grids of the mask in the one gel film.