EP2066986A2

EP2066986A2 - Solar multistage concentrator, and greenhouse

Info

Publication number: EP2066986A2
Application number: EP07817530A
Authority: EP
Inventors: Jürgen KLEINWÄCHTER
Original assignee: Sunvention International GmbH
Current assignee: Sunvention International GmbH
Priority date: 2006-09-19
Filing date: 2007-09-17
Publication date: 2009-06-10
Also published as: US20090314347A1; DE102006044603A1; WO2008034418A3; WO2008034418A2; DE112007002830A5

Abstract

Disclosed is a solar multistage concentrator in which at least one imaging lens system is mounted in front of a non-imaging lens system in such a way that both systems are an integral part of a specifically formed, light-transparent dielectric.

Description

Solar multi-stage enkonzentrator and greenhouse

[01] The invention relates to a solar multistage enkonzentrator and a greenhouse.

[02] Refractive optics in solar technology are used either as optically imaging lenses (solid lenses or Fresnel lenses) or as optically non-imaging devices, usually referred to in the literature as CPC (Compound Parabolic Concentrator) arrangements.

The imaging lenses (linear or punctiform) image the sun into focal lines or points which, if the contour of the lenses is not exactly parabolic, involve aberrations. Lenses operate on the principle of refraction of the light rays from the optically thin to the optically denser medium and vice versa. With point-type concentrating lenses sunlight can be compacted in practice up to concentration factors of> 10,000 (theoretically up to approx. 44,000), with linear lenses in practice up to> 100 (theoretically up to approx. 200).

On the other hand, non-imaging optics concentrate sunlight in wedge-like structures (linear or rotationally symmetric), where the sunlight passing through the aperture surface is reflected at the wedge flanks by total reflection between the outside air and the optical material of the wedge toward the narrower end of the wedge it concentrates, but no longer depicts, exits.

Often, the flanks of such linear or rotationally symmetric "wedges" are parabolically shaped, because this makes the arrangement shorter than straight walls, hence the name CPC = Compound Parabolic Concentrator. In principle, very long wedges with only slightly inclined flanks with respect to the optical axis can concentrate the sunlight up to the theoretical limit, since the total reflection works with 100% efficiency.

[07] However, this is in practice too large lengths, the associated high cost of materials and the unavoidable occurring in real materials light absorption losses in such long structures.

Therefore, in practice, non-imaging CPC optics are used either when sunlight is to be condensed up to a factor of about 4 without tracking and / or special energy density ratios are to be generated in their exit aperture. Or as a second stage of a concentration level or lens with non-ideal imaging. The CPC serves here for the post concentration of the light ("Second stage concentrator") or for the homogenization of the radiation flow.

[09] The invention is based on the object to improve the previous solar technology.

This object is achieved by a solar multistage concentrator according to claim 1. Likewise this object solves a greenhouse according to claim 22. Advantageous embodiments of the solar multistage concentrator can be found in particular in the dependent patent claims.

[11] In all prior optical concentrator arrangements, the primary concentrator (high concentration mirror or lens) is spatially separated from the downstream non-imaging stage, i. h., there is air between them. This results in the case of the lens system three, the optical efficiency of the arrangement reducing partial reflection losses, in the system with the collecting mirror two.

[12] For the lens, these are: partial reflection in the entrance aperture partial reflection in the exit aperture partial reflection in the entrance aperture of the non-imaging stage at the mirror the partial reflection in its entrance aperture and at the secondary optics.

[13] The lens system results in optical losses> 12%, in the mirror system> 8%.

The basic idea of the multi-stage concentrator according to the invention is therefore to connect at least one optically imaging lens integrally with the downstream non-imaging optics so that only a partial reflection at the entrance aperture of the system occurs, the radiation flux until impinging on the lossless coupled Solar converter in the highly transparent dielectric runs and this is on the downstream stage (s) (s) designed so that it is optimally adapted in relation to the specific requirements of the solar converter in its geometric shape, its optical concentration and the energy density distribution.

Further advantages of the solar multi-stage concentrator according to the invention over the prior art are shown with the variants described below with reference to the drawing.

[1] FIG. 1 shows a multistage concentrator with three stages, which has the task of achieving the sunlight falling perpendicular to its entrance aperture on a square exit cross-section of 4 mm ² and a homogeneous energy density distribution of 600 suns over the entire exit area. The first concentrate precursor (1), which is designed as a spherical cap, concentrates the sunlight into the depth of the transparent dieelectrically (2). In the inlet cross section to the second stage (3), which is designed as secondary concentrator, the radiant flux is still highly inhomogeneous - according to the Kaustik of the ball concentrator - distributed. The maximum concentration in this section plane is approx. C = 260.

[17] The secondary concentrator (3) compresses the beam flux impinging on its upper edge on a square area of 8 x 8 mm ² to the desired square cross-section of 2 x 2 mm ² . At the same time, the concentration in the still inhomogeneous radiation field in the middle rises above c = 800, in the peripheral areas to approx. C = 500. In the downstream homogenizer cuboid (4), a quasi-perfect homogeneous distribution of approximately c = 600 is achieved in the outlet cross-section.

[18] In the chosen example, the multi-stage concentrator according to an embodiment of the invention consists of a highly transparent fluoropolymer body of refractive index 1.3, which is filled with a fluorine liquid of refractive index 1.3 which is also highly transparent over the entire solar single-beam spectrum. While in step 1 of the arrangement the quasi-parallel sunlight is refracted and concentrated directly into the depth of the liquid, in stages 2 and 3 it is concentrated and homogenized by the total reflection at the outer boundary surfaces to the air.

[19] Although the relatively low refractive index of the dielectrics used leads to an elongated structure, this is negligible due to the small absolute dimensions of the structure. However, the low refractive index in the region of the input calotte (1) is advantageous since it is thus partially reflected.

[20] If one considers the optics taking into account the optical material parameters, the solar spectrum, the Fresnel losses, the dispersion and the opening angle of the sun from the earth ("sun size") is obtained with perfect sun alignment (normal vector of the aperture shows on sun) an optical efficiency of 97.3%. [21] If an angle deviation of + 0.5 ° is allowed (modern sun tracking systems fall short of this deviation), the homogeneity in the exit plane is maintained, the efficiency drops to 95.8% due to a few, exceeding the total reflection angle , Ray paths.

[22] If a high-power solar cell of square cross-section is typically coupled losslessly to the exit aperture of the described multistage condenser, this can be achieved in the current state of the art (so-called triple-junction solar cells reach about 40% electrical efficiency at 600 light concentration and homogeneous light distribution). in a few years one expects 50%) Total efficiency sun / current of 0.97 x 0.4 = 0.388 reach.

[23] The best known arrangements with air-separated optical elements reach about 30%. The superiority of the multistage concentrator according to the invention is expressed here, as described, by avoiding reflection losses and the synergy of the various stages in terms of concentration and homogeneity.

An important prerequisite for achieving the above efficiencies and for the life of the photovoltaic converter is sufficient cooling of the solar cells. This is particularly effective and controllable by means of active liquid cooling.

[25] This is shown schematically in FIG. In this case, (4) the homogenizer wedge, (5) the solar cell coupled to the outlet cross-section of (4) via an optical immersion, (6) a transparent, rigid plate on whose periphery a highly transparent fluoropolymer membrane (7) is attached in such a way that in the space can circulate a transparent dielelektrische liquid that cools the cell. This transparent cooling arrangement is provided by the struts (8) with the multistage optics. connected and lets the diffused light component (9), which penetrates from the flanks of the optics, penetrate into the cubic capacity below the optical arrangement.

[26] The liquid-core multi-stage optics described in the example can also be replaced by a solid optical dielectric (PMMA, glass, silicone rubber, etc.). In this case, the higher refractive index differences medium-air and thus more compact optical geometries can be realized, but in this case, the solar cell according to Figure 2 is cooled only on the back, while in the former case the only separated by a thin end of the dielectric liquid of the optical front of the Solar cell can give off heat to these.

Basically, the solar cell according to a version of the invention, despite an optics made of solid dielectric material can be cooled on both sides transparent. FIG. 3 schematically shows how the final stage of the optical system (4), which consists for example of PMMA, ends in a transparent plate of the same material (FIG. 4a). This plate together with (4b) forms a transparent double-walled plate, which is flowed through by the cooling fluid (preferably highly transparent, radiation-resistant, inert, electrically insulating fluorine fluid). The solar cell protrudes on a metallic strut into the region of the plate in which the diverging rays emerging from (4) reach the size of the solar cell. The cell is now cooled particularly effectively, as it is flowed around dynamically from both sides, and the metallic strut causes an additional surface enlargement. This strut provides the electrical backside contact on the lower plate, which is provided with a conductor pattern. The front side contact is made by a separate cable.

The active liquid cooling of the solar cells in the manner described is not only particularly effective, but allows to convert the non-electrical converted part of the radiation (about 60%) in usable liquid heat (electricity-heat coupling). In the case of triple-junction cells, the cooling can rise to 80 ^° C. without damaging the cells or generating large efficiency losses. Since solar energy is particularly useful decentralized use, and small consumers in the commercial, agricultural and residential sectors, in particular electricity and heat need, contributes to the described system with high efficiency heat significantly to the economic success of the entire system.

[30] Figure 4 shows schematically a typical possibility for constructing a plate-shaped cluster of n-multistage concentrators. These are located on a support frame (10), which realizes via the gimbal bearing (12) both the Sonnenazimut- and the elevation tracking. The micromotors and control logics required for this purpose (sensor-based and / or via digital memory logics) are not further explained here since they correspond to the state of the art.

[31] The gimbal bearing is preferably mounted on a carrier (10), the meaning of which is apparent from FIG. In FIG. 4, the rays denoted by (6) represent the diffused light which, after it has penetrated into the optics via the entrance apertures and is not focused into the focus like the parallel sunlight, but over the flanks of the arrangement into the underlying ones Space is flowing.

[32] As the downstream solar cells are very small, the cooling systems are largely transparent and the suspension structures of the optic clusters are filigree and thus produce only minimal shadow, this diffuse daylight current can be regarded as the third element in the "added value" of the overall system (electricity Heat-light coupling).

[33] This fact is clarified in FIG. 5.

[34] Here the described optics clusters are installed below the transparent shell of a greenhouse (13). The carrier (11) allows a low-shadow attachment, which adapts to any structures. The under the shell protected from wind and weather arrangement is subject to any wind and weather forces and can thus be manufactured cost-optimized with minimal material costs.

[36] The generated electricity as well as the heat are led out of the greenhouse, so that only the diffused light for the generation of photosynthesis gets inside. Since photosynthesis requires a maximum of 200 W / m ² and this in the partial shade created by the multi-stage concentrators, the system can make a greenhouse from a combined solar power plant, with the thermal energy obtained in the hot summer months at long-term storage for win- terliche heating of the crops can be used.

The flexible design of multi-stage concentrators in terms of concentration, light distribution and separation (direct / diffuse) makes them particularly suitable for integration into multifunctional structures (greenhouses, architectural shells, etc.), with virtually the total luminous flux falling on the aperture in the form of a Cascade of different types of use leads to a total efficiency> 80%.

Claims

claims:

1. Solar multi-stage concentrator, characterized in that at least one imaging optics of a non-imaging optics is connected upstream in such a way that both systems are an integral part of a specifically shaped, light-transparent dieelektrikums.

2. Solar multi-stage concentrator according to claim 1, characterized in that the imaging optics consists of a spherical cap, which merges into a wedge-shaped, non-imaging optics.

3. Solar multi-stage concentrator according to claim 1 or 2, characterized marked, that the primary imaging optics incident directly on the aperture surface direct sunlight in the transparent Dieelektrikum, without total reflection on the flanks to the air, directly into the depth of the arrangement and here concentrated.

4. Solar multi-stage concentrator according to one of the preceding claims, characterized in that in the region in which forms the focal zone of the first optics, the subsequent contour of the second stage takes the form of a non-imaging optics, the pre-concentrated light by total reflection at their Flanks leading to the air further into the depth.

5. Solar multi-stage concentrator according to one of the preceding claims, characterized in that the non-imaging optics is designed so that it concentrates the sunlight concentrated by the first stage with spherical aberration and pre-homogenizes with respect to the spherical and the chromatic aberration.

6. Solar multi-stage concentrator according to one of the preceding claims, characterized in that in a third, integrally adjoining the second stage optical arrangement, the concentrated light is posthumogenized by total reflection at the interfaces dielectric - air with respect to its energy density and chromatic distribution and the shape of the Exit surface of this third stage of the selected solar receiver is adjusted.

7. Solar multi-stage concentrator according to one of the preceding claims, characterized in that the solar receiver consists of a photovoltaic concentration cell, which is attached directly by means of an optical immersion medium and low loss on the exit aperture of the last stage of the arrangement.

8. Solar multi-stage concentrator according to one of the preceding claims, characterized in that the back of the solar cell is cooled by a liquid flowing through a thin transparent polymer tube which is mechanically pressed against the solar cell.

9. Solar multi-stage concentrator according to one of the preceding claims, characterized in that the concentrated sunlight diverges selectively after its exit from the Endapertur in an optically coupled transparent double plate.

10. Solar multi-stage concentrator according to one of the preceding claims, characterized in that the double plate is traversed by a transparent optical cooling liquid and that in this liquid at a suitable distance from the diverging beam is a concentrator solar cell.

11. Solar multistage enkonzentrator according to one of the preceding claims, characterized in that the solar cell ends on a good heat-conducting metallic attachment on the opposite side of the plate, which is constructed as an electronic pressure circuit and the circuit of the cell into this circuit.

12. Solar multi-stage concentrator according to one of the preceding claims, characterized in that the first stage consists of an arbitrary deviating from the spherical shape imaging optics and the subsequent (n) stage (s) are formed as non-imaging concentrators or homogenizers so, that the solar receiver used on its optically coupled directly into the final stage entrance aperture receives the concentrated sunlight in the desired energy density distribution.

13. Solar multi-stage concentrator according to one of the preceding claims, characterized in that the sunlight is concentrated either one-dimensionally in focal lines or two-dimensional in foci, in the first case a uniaxial, in the second case, a biaxial sun tracking is necessary.

14. Solar multi-stage concentrator according to one of the preceding claims, characterized in that up to a certain range angular deviations in the sun tracking are compensated in that the non-imaging stages reflect the resulting oblique beam paths back into the array.

15. Solar multi-stage concentrator according to one of the preceding claims, characterized in that the diffused portion of the sunlight radiates through the lateral flanks of the arrangement in the underlying half-space.

16. Solar multi-stage concentrator according to one of the preceding claims, characterized in that several concentrators are combined to flat plates.

17. Solar multi-stage concentrator according to one of the preceding claims, characterized in that the one- or two-dimensional imaging plates behind transparent sheaths (windows, facades, roofs, greenhouses) convert the direct solar radiation into useful energy (electricity, chemical energy, heat) while the diffused sunlight is used to illuminate the rooms behind or behind.

18. Solar multi-stage concentrator according to one of the preceding claims, characterized in that the optics consist of highly transparent, coated at their input and exit apertures optical materials as high refractive index and the Totalrefelektionen at the interface optical material - air arise.

19. Solar multi-stage concentrator according to one of the preceding claims, characterized in that the optics consist of transparent hollow bodies which are filled with likewise highly transparent optical fluids.

20. Solar multi-stage concentrator according to one of the preceding claims, characterized in that the transparent walls of fluoropolymers with low refractive index and the liquid, for. As a silicone oil, a high

Has refractive index, so that the total reflection takes place at the interface oil - fluoropolymer.

21. Solar multi-stage concentrator according to one of the preceding claims, characterized in that the walls are made of fluoropolymer and the liquid - typically a fluorine liquid or water - also a low Has refractive index, so that the total reflection at the interface envelope - air is formed.

22. Greenhouse with a solar multi-stage concentrator according to one of the preceding claims, in particular with a plurality of such solar multi-stage concentrators.