EP2243171A1

EP2243171A1 - Production and applications of multifunctional optical modules for photovoltaic current generation and for lighting purposes

Info

Publication number: EP2243171A1
Application number: EP09705798A
Authority: EP
Inventors: Tonino Greco; Andreas BÜCHTEMANN; Rudi Danz; Burkhard Elling
Original assignee: Fraunhofer Gesellschaft zur Forderung der Angewandten Forschung eV
Current assignee: Fraunhofer Gesellschaft zur Forderung der Angewandten Forschung eV
Priority date: 2008-01-31
Filing date: 2009-01-15
Publication date: 2010-10-27
Also published as: WO2009095310A1; DE102008006955B4; DE102008006955A1

Abstract

The invention relates to an optical module comprising a substrate and a polymer layer applied to the substrate, wherein the substrate and polymer layer are transparent in the spectral range of between 250 and 700 nm; fluorescent additives (A) absorbent at least in the spectral range of between 250 and 400 nm (UV range), fluorescent additives (B) absorbent at least in the spectral range of between 400 and 700 nm (visible range), and additives (C) absorbent at least in the spectral range of between 700 and 2000 nm (NIR range), are distributed in the polymer layer; and the average diameter of all additives does not exceed 200 nm.

Description

Production and application of multifunctional optical modules for photovoltaic power generation and lighting purposes

The present invention relates to a novel optical module, its production and use.

Photovoltaic power generation uses fluorescence collectors consisting of optically transparent polymer plates doped with fluorescent dyes. When solar radiation strikes the large surfaces of the doped polymer plates, the fluorescent dyes present in the polymer plates are excited electronically and emit fluorescence radiation which is conducted to the narrow edges of the doped polymer plates due to total reflection and exits there in concentrated form (W. Stahl and A. Zastrow, "Fluorescence collectors", Physik in der Zeit, 16 (1985), 6, 167-179; U. Rau, F. Einsele, GC Glaeser, "Efficiency Limits of Photovoltaic Fluorescent Collectors", Applied Physical Letter, 87 (2005), 171101 -171101-3.).

A consisting of a doped polymer plate fluorescence collector, which can also be designed as a half or full circle, is used for photovoltaic power generation or as a light detector by looking at the edges of the collector Applying solar cells on which the fluorescent radiation impinges and is converted into electrical current (US 4,193,819, DE 3832803 Al).

With the fluorescence collectors, it is important that as far as possible the entire radiation is absorbed, emitted with high efficiency and only a small proportion of radiation is transmitted through the collector. The fluorescent materials contained in the fluorescence collectors must have a high photostability and quantum efficiency, as well as be molecularly dissolved in the collector materials or distributed nanoscale, so that a strong fluorescence can occur without optical control effects. The fluorescence collectors used for photovoltaic power generation generally have the disadvantage that about only one third of the solar radiation is used technically, most of the radiation is not absorbed and is therefore lost in the application.

The patent EP 1659347 A2 describes fluorescence collectors as solar

Energy converters designed as roof tiles and window panes or designed as facades for buildings. In this document, dyes and quantum dots are called as fluorescent particles without further description. Thus, the indicated use of the patent can not be realized and fulfilled. Most dyes do not fluoresce and therefore can not be used for the article of the invention. Of the fluorescent dyes, most have too little photostability and quantum efficiency for use in fluorescence collectors. Quantum dots can not be brought into nanoscale without disadvantageous scattering effects without the use of special manufacturing technologies in polycarbonates, polyacrylates or polystyrene.

Another disadvantage of EP 1659347 A2 is that in this device the UV radiation from the sunlight is absorbed to protect the polymer substrates and thus a substantial proportion of the energy of the solar radiation is not utilized. Instead of fluorescent plates for photovoltaic power generation or energy conversion and fluorescent multilayers, which contain different fluorescent dyes with respect to the absorption and emission behavior proposed (EP 1659347A2).

In a further variant, fluorescent polymer layers are applied to optically transparent undoped substrates. After excitation of the fluorescent layer with a radiation source, the generated fluorescent light couples into the substrate and arrives at its edges on which detectors are arranged for radiation detection (US 4,262,206). Although the fluorescence converter described in US 4,262,206 can be used for the detection of diffuse and weak radiation, but is not suitable for efficient energy use of solar radiation, since the device can not use most of the solar radiation.

In vegetable growing, polymeric films doped with a red or blue fluorescent dye and positively influenced by the emission of red and blue fluorescent radiation, respectively, for growth of tomatoes and other vegetables, e.g. the maturity of the fruits is shortened and their taste is improved (F. Kaufmann, B. Baranow, R. Bochow, "Luminescence Foils for Harvesting Prematurity in Lettuce", Gemüse 27 (1991), 96-98, B. von Eisner, "Farbfolien für den Gartenbau ", Deutscher Gartenbau 25 (1991), 1544-1551; Y. et al. Zarka," New PVC-fluorescent film for cladding greenhouses the results of three years trials ", Plasticulture" n "85 (1990/1) 6 - 16, TAO

Dougher, B. Bugbee, "Differences In The Response Of Wheat, Soybean And Lettuce To Reduced Blue Radiation", Photochemistry and Photobiology 73 (2001), 199-207). The fluorescent garden foils used hitherto have the disadvantage that they have one more or less large spectral component of solar radiation absorb and convert to fluorescent radiation, the largest absorbed radiation fraction due to total reflection but remains in the film and is not available for the growth of the plants. On the other hand, the fluorescent garden foils used make infrared radiation which leads to undesirable heating in the greenhouses to a high degree.

For autonomous energy generation thin-film solar cells and electrochromic layers are applied to glass substrates and electrically connected to each other to control the electrochromic layers. Upon incidence of light, a photovoltaic current is generated, which switches the electrochromic layers and leads to a transmission decrease (US 5,377,037). The claimed solution has the disadvantage that, for its function, the thin-film solar cell must have an optical absorption in the spectral range of the solar cell of at least 40%, which leads to an undesired reduction in the overall transmission of the system. The spectral transmission of the entire system is determined by the thin-film solar cell and can no longer be affected. The indicated control system is therefore limited practicable.

It is therefore an object of the present invention to provide a multifunctional optical module, which makes it possible to efficiently convert solar radiation into electrical energy and to avoid unwanted overheating of interiors.

The finding of the present invention is that the optical module converts the solar energy, such as UV light and visible light, into fluorescence radiation and at least partially absorbs heat radiation. Accordingly, the present invention provides an optical module comprising a substrate and a polymer layer deposited on the substrate, wherein substrate and polymer layer are transparent in the spectral range of 250 to 700 nm and in the polymer layer

a) fluorescent additives (A) which absorb at least in the spectral range from 250 to 400 nm (UV range),

b) fluorescent additives (B) which absorb at least in the spectral range from 400 to 700 nm (visible range), and

c) additives (C) which absorb at least in the spectral range from 700 to 2000 nm (NIR range),

are distributed and all additives do not exceed an average diameter of 200 nm, preferably of 100 nm, more preferably of 20 nm.

In this case, the substrate and polymer layer are preferably chosen such that they have approximately the same refractive index, so that the polymer layer and the substrate form an optical unit and for the total reflection of the light, the adjacent air layers are determining.

Furthermore, the optical module preferably comprises at least one solar cell in order to convert the generated fluorescence radiation into electrical current. It has been found to be particularly advantageous that the solar cell or cells are arranged on the narrow edges of the substrate, whereby the fluorescence radiation generated in the polymer layer by solar radiation optically coupled into the substrate and is passed as a result of total reflection to its edges and there on the solar cells impinges, which convert the energy into electric current. A particular embodiment is shown in FIG.

Surprisingly, it has been found that such an optical module can convert solar energy into fluorescence energy in a particularly efficient manner. In addition, solar radiation, which mainly generates heat energy, such as near infrared, is captured by the optical module, so that overheating under the optical module, such as indoors, can be prevented. As a result, the optical modules according to the invention can be used in particular in greenhouses, buildings or means of transport.

Preferably, the optical module should contain additives in the amount and type that the optical module a) radiation in the spectral range of 250 to 400 nm at least 90%, preferably at least 95%, in particular at least 99.5% and / or b) radiation in the spectral range from 400 to 700 nm from 30 to 80%, preferably from 35 to 75% and in particular from 40 to 70% and / or c) radiation in the spectral range from 700 to 2000 nm to at least 40%, preferably to at least 50%, absorbed.

The additives (A) to (C) may be organic fluorescent dyes, quantum dots, nanophosphors and / or inorganic metal oxides.

Suitable organic fluorescent dyes in the present invention are, in particular, the fluorescent dyes selected from the group consisting of xanthenes, rhodamines, cyanines, coumarins, oxazines, perylenes, naphthylimides, naphthyldiimides, stilbenes, styryls, pyrromethenes and mixtures thereof. Preferably, organic Fluorescent dyes up to 6.0 wt .-%, more preferably from 0.1 to 5.5 wt .-%, most preferably from 0.1 to 5.0 wt .-%, in the polymer layer.

Quantenpunkte in the present invention are understood in general inorganic nanoparticles that have fluorescence properties and are nanoscale.

Under nanoscale is to be understood according to the present invention that the largest dimension of the discrete additives of the polymer layer is less than 200 ran, preferably 20 nm. In this case, this size definition refers to all possible particle morphologies, such as primary particles and any aggregates or agglomerates. However, it is preferred that the present additives are primary particles and do not form aggregates and / or agglomerates.

In particular, quantum dots according to the present invention are understood as meaning fluorescent inorganic nanoparticles which are semiconductive materials and consist of II-VI or III-V semiconductors and preferably have a core-shell structure. In this case, such semiconducting materials preferably have an inorganic core of the size of preferably less than 10 nm. In addition, such preferred semiconductor nanoparticles are capped, ie surrounded by an organic shell. For the hydrophobization of the quantum dots, these are preferably capped with long-chain alkylamines, alkenylamines, aromatic amines, thiols, carboxylic acids, carboxylic acid esters, phosphoric esters, phosphonic acid esters, phosphenes and / or phosphine oxides. For hydrophilization, these are preferably capped with mercaptocaboxylic acids, aminocarboxylic acids, thioalcohols, aminoalcohols, aminoalkylsiloxanes, thioalkylsiloxanes, hydroxycarboxylic acids and / or carboxylic acid esters. Preferred quantum dots in the present invention are semiconducting materials selected from the group consisting of InAs, InP, GaAs, GaP, GaN, InGaAs, GalnP / InP, CdO, CdSe, CdS ₅ CdTe ZnO, ZnS, ZnSe, ZnTe, PbS, PbSe, PbTe, HgS, HgSe and HgTe. The quantum dots can also be provided with a doping element, wherein in the following notation to the right of

Colon one or more dopants and to the left of the colon, the host material are listed. Examples of these are ZnO: M, ZnS: M, ZnSe: M, CdS: M, CdSe: M with M = Ag, Cu, Al, Mn, Ln and in combination with Ln = lanthanides (Ex. ZnS: Mn, Eu) , Preferably, the quantum dots are up to 15 wt .-%, still more preferably from 0.5 to 12.05 wt .-% _s most preferably about 10.0 wt .-% to LO, in the polymer layer.

In the present application, nanophosphors are again understood as meaning inorganic nanoparticles which consist of non-conductive or semi-conductive materials and are doped with rare-earth ions. Preferably, therefore, it is semiconducting materials. In principle, the following compounds can be selected as the material for the doped nanophosphors, with one or more doping elements listed to the right of the colon in the following notation, and the host material to the left of the colon. The host material may include compounds from the group of phosphates, silicates, germanates, oxides,

Sulfides, oxysulfides, selenides, sulfoselenides, vanadates, niobates, arsenates, tantalates, tungstates, molybdates, halates, nitrides, borates, aluminates, gallates, and halides. Particular preference is given to nanophosphors which are prepared on the basis of lanthanum phosphate and / or yitrium-vanadium oxide. Examples are LiLEu; Al ₂ O ₃ : Eu; BaFCl: Sm; BaFBnEu; BaY ₂ F ₈ : Ln (Ln-Pr, Tm, Er, Ce), BaMgAl ₁₆ O ₂₇ = Eu; BaMgAl ₁₄ O ₂₃ : Eu; BaMgAl ₁₀ O _{) 7} : Eu;

BaMgAl ₂ O ₄ = Eu ₁ Ce (Mg ₁ Ba) Al ₁₁ Oi ₉ ; MgAl ₁ | O ₁₉ : Ce; (Mg, Ca) S: Eu; MgW0 ₄ : Sm; CaS: Ln (Ln = lanthanide); CaW0 ₄ ; Sm; CaSO ₄ : Ln (Ln = lanthanide); SrS: Ln (Ln = lanthanide), Sr ₂ P ₂ O ₇ ^ u; SrGa ₂ S ₄ : Ln (Ln = lanthanide); YF ₃ : Ln (Ln = lanthanides); Y ₂ O: Ln (Ln = lanthanides); Y (P, V) O ₄ : Eu; YOCl: Yb, Er; LuVO ₄ : Eu; GdVO ₄ : Eu; Gd ₂ O ₂ SjTb; GdMgB ₅ O ₁₀ : Ce ₅ Tb; LaOBr: Tb; La ₂ O ₂ S: Tb; LaF ₃ : Nd, Ce; BaYb ₂ F ₈ : Eu; NaYF ₄ : Yb ₅ He; NaGd F ₄ : Yb ₁ He; NaLaF ₄ : Yb ₅ He; LaF ₃ : Yb ₁ He ₅ Tm; BaYF ₅ : Yb, He; Ga ₂ O ₃ : Dy; GaN: A (A = Pr, Tm ₅ Er, Ce); Gd ₃ Ga ₅ Oi ₂ = Tb; LiLuF ₄ : A (A-Pr ₅ Tm ₅ Er, Ce);

CaSiO ₃ : Ln; CaS: Ln; CaO: Ln; ZnS: Ln; MgF ₂ : Ln with Ln = lanthanide YVO ₄ : Ln; LnPO ₄ : Ce, Tb; Y ₂ O ₃ : Ln; Y ₂ O ₂ S: Ln; Y ₂ Si0 ₅ : Ln with Ln = lanthanides.

Preferably, the nanophosphors have an inorganic core surrounded by an organic shell. In addition, it is preferred that nanophosphors have an inorganic core of preferably less than 10 nm. It is further preferred that the nano-phosphors up to 15 wt.%, Even more preferably from 0.5 to 12.0 wt .-% ₅ most preferably contain about 1.0 to 10.0 wt .-%, in the polymer layer.

It has been found that the present invention achieves particularly good results when the fluorescent additives (A) are selected from the group consisting of organic fluorescent dyes, quantum dots, nanophosphors or mixtures thereof. It is particularly preferred if the fluorescent additives are fluorescent dyes and / or quantum dots.

If the additives (A) are at least partially organic fluorescent dyes, these are preferably selected from the group consisting of xanthenes, coumarins, oxazines, rhodamines, perylenes, naphthylimides, naphthyldiimides, stilbenes, styryls, pyrromethenes and mixtures thereof. Especially preferred for fluorescent additives (A) are organic fluorescent dyes selected from the group consisting of naphthylimides and naphthyldiimides, styryls, and stilbenes. If the fluorescent additives (A) are also quantum dots, these are selected from the group consisting of InAs, InP, GaAs, GaP, GaN, InGaAs, GalnP / InP, CdO, CdSe, CdS, CdTe, ZnS, ZnSe, ZnO, ZnTe, PbS, PbSe, PbTe, HgS, HgSe, HgTe.

Particularly suitable are ZnO, ZnS, ZnSe and the doped forms thereof with ZnO: M, ZnS: M, ZnSe: M and M = Ag, Cu, Al, Mn, Ln and in combinatin with Ln = lanthanides.

It is also conceivable that the additives (A) are at least partially nanophosphors. It is preferred that these are semiconducting materials based on lanthanum phosphate and / or yttrium-vanadium oxide, for example YVO ₄ : Eu, LaPO ₄ : Ce, Tb

The fluorescent additives (B) are preferably organic fluorescent dyes and / or quantum dots.

In the event that at least partially the fluorescent additives (B) are organic fluorescent dyes, they are preferably selected from the group consisting of rhodamines, xanthenes, oxazines, perylenes, naphthylimides and

Naphthyldiimiden, stilbenes, coumarins, styryls, pyrromethenes and mixtures thereof selected.

Particularly suitable here are the rhodamines, perylenes, oxazines, xanthenes, coumarins and pyrromethenes.

In the event that the fluorescent additives (B) are at least partially quantum dots, it is preferred that the quantum dots are semiconducting materials selected from the group consisting of InAs, InP, GaAs, GaP, GaN, InGaAs, GalnP / InP, CdO, CdSe, CdS, CdTe, ZnO, ZnS, ZnSe, ZnTe, HgS, HgSe, HgTe, PbS, PbSe, PbTe. Particularly suitable are core-shell quantum dots consisting of CdS, CdSe, ZnS, ZnSe.

Furthermore, the optical module may comprise additives (C), wherein it is preferred that these additives (C) at least partially represent metal oxides. These nanoparticle metal oxides are neither quantum dots nor nanophosphors. Preferred metal oxides are antimony and / or tin (IV) oxides, such as indium-tin oxide and antimony-doped tin oxides, such as SbO ₂ , SnO ₂ , In ₂ O ₃ / SnO ₂ and SnO ₂ : Sb. Preferably, in the polymer layer up to 35 wt .-%, more preferably 5.0 to 30.0 wt .-%, of metal oxides present.

In the case that the additives (C) are also to have fluorescent properties, it is preferable that at least partly the additives (C) include organic fluorescent dyes such as fluorine dyes. Cyanines are.

As polymers in which the additives (A) to (C) are distributed, all transparent polymer types can be used. However, preference is given to polyacrylates, polyurethanes, polystyrenes, silicone polymers, polyvinyl alcohols and acetates, polyvinyl butyrates and also cellulose derivatives, cycloolefin copolymers, acrylonitrile copolymers and polylactides. Particularly preferred are polyacrylates, cellulose esters and cellulose ethers.

The thickness ratio of substrate to polymer layer should be at least 1:10, preferably 1:15.

The solar cell (s) are preferably selected from the group consisting of monocrystalline silicon, polycrystalline silicon, amorphous silicon, gallium arsenide, indium phosphide compounds, cadmium telluride, cadmium Sulfide, copper indium gallium diselenide, copper indium sulfide or mixed compounds of these elements. These solar cells can also comprise semiconducting polymers and dye layers which convert the proportion of the radiation which is conducted to the narrow edges of the coated glass and plastic substrates due to the fluorescence effect in the multiply-doped polymer coating and the total reflection into electrical current. The solar cells are selected so that the maxima of their spectral sensitivity largely coincide with the spectral maxima of the fluorescence radiation.

As mentioned above, it is preferred that the additives do not exceed an average diameter of 200 nm, preferably not 100 nm, more preferably 20 nm. This means that the additives are distributed in the polymer layer, in particular distributed homogeneously and thereby the polymer layer has nanoscale additives which do not hinder their properties. In order to achieve such a fine distribution, it is preferable to dissolve or disperse the additives in the monomers of the polymer layer or in the polymer solutions.

Accordingly, the optical module as described above is preferably prepared by a) preparing a solution (D) by dissolving the organic fluorescent dyes serving as additives (A) to (C) in the monomers of the polymer layer, and b) preparing a Dispersion (E) by dispersing the inorganic substances such as quantum dots, Nanophopshore and metal oxides, which serve as additives (A) to (C), in the monomer (s) of the polymer layer, c) mixing the solution (D) and the dispersion (E ) to a mixture (F), d) addition of a UV initiator to the mixture (F), e) preparation of a prepolymer by irradiation of the mixture (F) with UV light, preferably at 360 nm, f) application of the prepolymer to a support, g) through-polymerization of the prepolymer, preferably by thermal polymerization, for example at 60 ° C.

Alternatively, the optical modules can be prepared as follows: a) preparing a solution (D) by dissolving the organic fluorescent dyes serving as additives (A) to (C) in the monomer (s) of the polymer layer, and b) adding a C) preparing a prepolymer by irradiating the solution (D) with UV light, d) preparing a dispersion (E) by dispersing the inorganic substances, such as quantum dots, nanophosphors and metal oxides, which are used as additives (A) to (C) serve, e) mixing the solution (D) and the dispersion (E) to a mixture (F), f) applying the mixture (F) to a carrier, g) through-polymerization of the prepolymer. Preferably by thermal polymerization, e.g. at 60 ° C. Preferably, the monomers are distilled.

After making the polymer layer on the substrate, solar cells are preferably attached to the narrow edges of the substrate.

Here u.a. The technology has been found to be beneficial, starting from two, preferably three different monomers, such as monomeric acrylates, both for the organic fluorescent dyes and for the inorganic materials used, such as quantum dots, nanophosphors and

Metal oxides are suitable as solvent or dispersion carrier. The monomers are composed in particular of methyl methacrylate (MMA), hydroxyethyl methacrylate (HEMA) and lauryl methacrylate (LMA). Preferred ranges for a mixture with three monomers are 40 to 60 wt .-% Methyl methacrylate, 20 to 40% by weight of hydroxyethyl methacrylate and 10 to 30% by weight of lauryl methacrylate. The organic fluorescence molecules are preferably predissolved in methyl methacrylate, hydroxyethyl methacrylate, dimethylformamide, methyl ethyl ketone or acetone. The inorganic substances, such as quantum dots, nanophosphors and metal oxides, are preferably dispersed in a monomer mixture of methyl methacrylate, hydroxyl ethyl methacrylate and lauryl methacrylate, wherein the dispersion is preferably carried out by ultrasound. Subsequently, the dissolved organic fluorescence molecules and the dispersed inorganic nanoparticles are added to the monomer solution. By adding a UV initiator, such as Irgacure 1700 (0.4% by weight) and / or a thermal initiator, such as 2,2'-azoisobutyronitrile (0.04 wt%), this mixture with UV radiation, for example in a Wavelength of 360 nm, or thermally polymerized at 60 ⁰ C.

Instead of lauryl methacrylate, lauryl acrylate and styrene can also be used for the multicomponent monomer system.

In the case that the optical module comprises quantum dots as additives, the monomers, in particular methyl methacrylate and hydroxyethyl methacrylate, are distilled under vacuum to separate impurities. Subsequently, the monomers are preferably prepolymerized under nitrogen atmosphere at preferably 95 ° C with continuous vigorous stirring. When the batch has reached sufficient viscosity, the reaction is interrupted. This can be done, for example, by rapid cooling in an ice bath. The quantum dots are dispersed in an apolar monomer, such as styrene, by means of ultrasound. The amount of apolar monomer is preferably about 10 wt .-% based on the proportion of the remaining monomers, in particular based on methyl methacrylate and hydroxyethyl methacrylate. The dispersion obtained is the prepolymerized monomers, such as methyl methacrylate and hydroxyethyl methacrylate, under vigorous Stirring and nitrogen atmosphere added. In order to achieve a particularly good homogeneous distribution of the quantum dots, the solution is stirred for 5 to 10 minutes, (for example with a Teflon) and treated with an ultrasonic probe. Preferably, the mixture is exposed for about 30 seconds to the ultrasound probe. Furthermore, it is preferred that the solution is then degassed at about 200 mbar and polymerized by thermal polymerization, preferably at about 60 ⁰ C on the substrate.

The use of the technology according to the invention has the advantage that optically transparent and with a high quantum efficiency fluorescent, multi-doped polymer layers can be produced, which have no scattering effects, but high photostability and suitable for use in multifunctional modules for power generation and / or lighting purposes are. In particular, by using the disclosed preparation technologies, it is possible to produce fluorescent polymer layers which meet the requirements for use in the multifunctional modules according to the invention.

The coating of the glass and plastic substrates is preferably carried out by the multiply-doped monomer systems by conventional technologies, such as spraying, spraying and casting techniques, spin-coating, et al., Are applied after a prepolymerization on the substrates, solvent expelled at elevated temperature and the polymerization or crosslinking is carried out. To adjust the viscosity necessary for the coating process and to stabilize the solution or dispersion, the monomers are preferably added to a 1-10% polymer fraction based on polyacrylates, polycarbonates, etc., based on the monomer system. Subsequently, at least one solar cell is preferably arranged on the narrow edges of the optical module by adhering it to a UV-curable special optical adhesive. To produce the multifunctional optical modules for horticulture, for example, in ethanol-soluble polyacrylates (10% wt .-%) and the monomers MMA (40% wt .-%), HEMA (30% wt .-%) and LMA (20 % Wt .-%). A 10% strength by weight polyacrylate solution in ethanol is initially prepared in ethanol, starting from the monomers as solvent. Nanophosphors based on lanthanum phosphate and yttrium vanadium oxide and naphthalimides, which strongly absorb UV light and emit light in the blue, red, yellow and green spectral regions, are used as additives. Antimony and indium-tin oxide nanoparticles serve to absorb the undesired NIR radiation for horticulture. For light amplification in the red spectral range, the polymer coating is supplemented with a red perylene fluorescent dye Lumogen F RED 300, which absorbs UV light and radiation in the wavelength range from 440 to 550 nm and emits red light above 600 nm. The multiply-doped polymer coating is preferably designed such that the proportions by weight of the UV-absorbing additives and of the fluorescent red perylene dye-based on the weight fractions of the polyacrylates or of the MMA, LMA and HEMA monomers-0.1 to 10% by weight. % and the NIR-absorbing antimony indium-tin oxide nanoparticles 10 to 30 wt .-% amount. The additives are gradually added in suitable solvents, such as, for example, alcohol, methyl ethyl ketone, dimethylformamide, methylene chloride, the corresponding polyacrylate solutions and MMA or HEMA and LMA monomers and treated with ultrasound for the nanoscale distribution of the nanoparticles. Subsequently, the doped solutions are applied by air-brushing or casting techniques on the glass or plastic substrates of thickness, for example, 5 mm, polymerized the monomers and expelled the solvent. In this way, multifunctional fluorescent and absorbent polymer coatings of the thickness of 10 to 100 .mu.m are formed which absorb at least 50% of the radiation in the UV and at least 50% of the radiation in the visible and NIR range and at the same time form strong blue, produce yellow, red and green fluorescent light and have high photostability.

For the photovoltaic power generation of the multiply-doped polymer coatings produced in this way on optically transparent substrates alternately solar cells made of amorphous and monocrystalline silicon are applied on the edges. The amorphous solar cells have a higher spectral current sensitivity for the guided to the substrate edges blue fluorescence radiation, while the crystalline solar cells are more sensitive to red light. With the completion of the multifunctional modules, a large-area optical component is available, which partially transmits blue and red radiation, which positively influences the growth of plants, fruits, etc., through targeted stimulation of photosynthesis and at the same time provides electricity for small consumers. The radiation used in the commonly used fluorescent gardening films as a result of total reflection in the film and thus destroyed radiation is used in the invention for power generation. By selective electrical shading of the solar cells (one behind the other or in parallel), electrical currents or voltages adapted to the respective electrical consumer can be offered. It is advantageous in this case to arrange the solar cells arranged on the substrate edges with suitable accumulators, e.g. be combined with lithium ion or metal hydride batteries, so that the photovoltaic energy is available even in periods of low radiation. The energy produced according to the invention can be used in horticulture, e.g. for the autonomous supply of sensor systems / emergency lighting or also for low-voltage heating to prevent water vapor impact

Greenhouse glazing, find application. In the greenhouse technology, the multifunctional modules according to the invention have the additional advantage that they protect the plants from damaging UV light due to the strong UV and infrared absorption of the coatings located on the modules avoid unnecessary heating in the greenhouses. The spectral light conversion from UV into the visible spectral range, which is brought about by the fluorescence effect, has the further advantage that unwanted UV radiation is converted into radiation that can be used for plant growth and for power generation.

In the glazing of buildings and / or transport, such as trains, the invention is applied by the polymer coatings by targeted adjustment of the concentration of the additives in the visible spectral range to a transparency of about 60 to 70%, in the UV on total absorption and in the NIR range can be adjusted to about 50% absorption. In this way, about 50 to 60% of the direct and diffuse radiation for illumination purposes and about 40 to 50% are converted by the physical principle of fluorescence into longer-wave light and directed to the solar cells located on the substrate edges, where electrical energy is generated there , By doping the polymer layers with several different additives such as fluorescent dyes, nanophosphors and indium and antimony tin oxide nanoparticles in different concentrations based on the polymer content (eg 1.0 wt .-%) naphthalimide, 0.5 wt .-% Pyrromethen 580 and 0.2 wt. % Perylene (Lumogen F RED 300), 5.0% by weight of nanophosphors, 20% by weight of antimony and indium-tin oxide) to produce a polymer coating which is semitransparent and strongly fluoresces. For large-area applications (module size greater than Im ² ) are preferred as matrix materials due to their good light pipe properties and compatibility with the nanoparticles and fluorescent molecules Cellosederivate, such as cellulose triacetate. In the doping of 3 wt .-% strength cellulose triacetate solution in dichloromethane / acetoacetic acid ester (in a ratio of 95: 5) is assumed, wherein the composite mixture is treated for 15 minutes with an ultrasonic sonotrode. The solvent mixture is required to obtain even layers. Subsequently, the multiple doped polymer coating applied to a glass substrate and dried. On the edges of the substrate previously silicon solar cells have been glued with an optical adhesive. The result is a tinted glass that has a sufficiently high transparency for visible light for lighting purposes and at the same time produces photovoltaic electricity. In conjunction with arranged on or in the window frame accumulators and suitable electrical connections is an autonomous, without electrical leads emanating current or voltage source available, for example, for charging cell phones, for the operation of notebooks or for the operation of other small electrical appliances (eg electric toothbrushes , etc.) is suitable. The required currents or voltages for the small devices can be set defined via a predetermined electrical interconnection of the solar cells.

In a favorable embodiment of the invention, the optical modules according to the invention are optically connected upstream of an electrochromic cell and electrically connected to one another. Thus, it is possible to provide a self-controlling optical light filter system for lighting and display purposes. It is important to dope the fluorescent coatings of the optical modules so that they transmit 70 to 80% of the radiation in the visible spectral range. This ensures that the light filter system consisting of the optical module and the electrochromic cell allows enough light to pass through when not switched on.

With small radiation intensity, the light transmitted through the optical module according to the invention is also transmitted by the electrochromic cell and serves, for example, to illuminate a room. Increases the radiation intensity, for example, the solar radiation increases sharply, then occurs at the solar cells of the optical modules according to the invention, depending on the electrical wiring, an increase in the photovoltaic currents or voltages generated, which causes a decrease in light transmission at the electrochromic cell. Does that go? Radiation intensity back, take power and voltage on the solar cell again, and the electrochromic cell is again transparent to light. This makes it possible to realize a self-regulating Lichtfiltersy system for intelligent glazing for vehicles, buildings and displays without external power supply. These light filter systems can be made by specifically selecting the fluorescent coatings on the optical modules to be spectrally responsive to their applications. Take, for example, the UV and the blue portion of the incident radiation to strongly, then there is a fluorescence enhancement, which causes the current and voltage increase at the solar cells driving the electrochromic cell.

In the following, the invention will be described in greater detail by way of examples.

B E I S P I E L E

example 1

For the production of an optical module with power supply functions and for lighting purposes, inorganic window glass is assumed. The doped polymer coating is applied to the glass substrate having the dimensions of 60 cm × 40 cm and the thickness of 4 mm. For doping, first the fluorescent and absorbing materials are naphthaldiimide Lumogen F VIOLET 570 (1.0% by weight), perylene yellow (Lumogen F YELLOW 083) (0.5% by weight), perylene red Lumogen F RED 300 (0.1% by weight). -%), CdSe / ZnS core-shell nanoparticles capped with hexadecylamine (2.0 wt .-%), and indium-tin oxide nanoparticles capped with octadecylamine ((90% In ₂ O ₃ , 10% SnO ₂ ) 10 wt. %) and with the photoinitiator Irgacure 1700 (0.04 wt .-%) and thermal initiator azobisisobutyronitrile (AIBN) (0.4 wt .-%) dissolved in the freshly distilled monomers MMA, HEMA, LMA and methylene chloride via ultrasound. The concentrations of the additives are based on the proportion by weight of the monomers MMA, HEMA and LMA, which are used with a mass ratio of 5: 3: 2. After subsequent degassing and expulsion of the methylene chloride at 200 mbar for 1 hour at room temperature, the reaction solution is polymerized with vigorous stirring with a KPG stirrer at 60 ⁰ C for 15 min until a slightly viscous prepolymer has formed. This is filled in the subsequent coating step in an air brush gun and sprayed with nitrogen on the heated to 50 ° C glass substrate. The coating on the glass plate is subsequently UV-A radiation (360 nm) polymerized through for 3 hours, and cured in an annealing for 8 hours at 6O ⁰ C. This produces highly fluorescent, brownish-tinted coatings that absorb UV light completely, visible light at 40%, and NIR radiation at 50%. The resulting in the coatings fluorescent light coupled into the optically transparent substrates and is there routed to their edges, on which solar cells made of polycrystalline silicon are glued with an optically transparent adhesive. The solar cells have a width of 4 mm and a length of 50 mm and deliver individually depending on the intensity of the solar radiation currents in the range of 40 to 60 mA at voltages of 400 to 600 mV. A total of 40 solar cells are arranged on the edges, which are connected depending on current and voltage requirements, partly in parallel, partly in series. In this way, a power or low-voltage generator is available, with the cell phones, notebooks, electric toothbrushes, hair trimmers, etc., can be supplied with electricity. Conveniently, the power generating substrate is combined with suitable accumulators. In addition to providing power, the coated substrate transmits sufficient visible light for illumination purposes and strongly absorbs infrared light in the NIR region, thereby preventing undesirable heating in spaces surrounded by the multifunctionally coated substrates. The modules produced in this way are integrated and applied in windows and doors as well as facades of buildings, in means of transport (train, bus, automobiles, etc.).

Example 2

When using fluorescent nanophosphors, quantum dots and absorbent indium or antimony tin oxide nanoparticles for multifunctional coatings, nano-dispersions based on silicon and titanium dioxides as a coating matrix are suitable for coating. The nanophosphors YVO ₄ : Eu; LaPO ₄ : Ce, Tb; capped with trioctylphosphine oxide, core-shell quantum dots (CdSe / ZnS capped with oleylamine) and indium or antimony tin oxide nanoparticles (SnO ₂ : Sb, In ₂ O ₃ / SnO ₂ capped with tris (2-ethylhexyl) Phosphane is dispersed in ethanol with ultrasound for 30 min and processed together with the finished alcoholic silicon and titanium dioxide sols to dispersions and sol-gel process with subsequent thermal curing produced between 100 and 250 ° C multifunctional coatings on the glass substrates. In this way, multifunctional systems with both power-generating and lighting functions are created.

Example 3

In the electrical supply of hearing glasses, fluorescent coatings are applied to spectacle lenses (thickness 2 to 3 mm), which preferably absorb UV and short-wave visible light and fluoresce strongly. Suitable fluorescers for this purpose include naphthaldiimides and pyrromethenes, with concentrations between 0.1 and 1% by weight, based on the polymer matrix. Naphthaldiimides are used to obtain transparent spectacle lenses tinted orange with pyrromethene. The polymer matrix used is cellulose triacetate. In this process, the desired amount of dye is dissolved in dichloromethane and mixed with a cellulose triacetate solution (2.5% by weight in 90% by weight of dichloromethane and 10% by weight of methanol). After applying the dye-polymer solution by air brush method and drying at room temperature for 24 hours and then annealing at 50 ° C for 2 hours to obtain coated, at the edges strongly fluorescent spectacle lenses. Depending on the duration of spraying, the layer thickness is between 10 and 100 μm. This results in slightly tinted lenses that allow enough light with up to 70% transmission. Gallium arsenide and indium phosphide solar cell chips are bonded to the edges of the lenses with 40% efficiency and 2 x 2 mm ² dimensions using an optical adhesive. The power generated by the solar cells of about 1 to 5 mW is fed to suitable miniature accumulators and thus serves the electrical supply of the electrical components of the hearing glasses or for heating purposes to avoid water vapor fitting to the lenses.

Claims

An optical module comprising a substrate and a polymer layer applied to the substrate, wherein the substrate and the polymer layer are transparent in the spectral range from 250 to 700 nm and in the polymer layer

(A) fluorescent additives (A), which absorb at least in the spectral range of 250 to 400 nm (UV range)

(b) fluorescent additives (B) absorbing at least in the spectral range of 400 to 700 nm (visible region), and

(C) additives (C), which absorb at least in the spectral range from 700 to 2000 nm (NIR range), are distributed, and all additives do not exceed an average diameter of 200 nm.

2. An optical module according to claim 1, wherein the optical module

(a) radiation in the spectral range of 250 to 400 nm at least 90% and / or

(b) radiation in the spectral range of 400 to 700 nm at least 30 to 80% and / or

(C) absorbed radiation in the spectral range of 700 to 2000 nm to at least 40%.

3. An optical module according to any one of the preceding claims 1 to 2, wherein the fluorescent additives (A) are selected from the group consisting of organic fluorescent dyes, quantum dots, nanophosphors and their mixtures.

4. An optical module according to any one of the preceding claims 1 to 3, wherein the fluorescent additives (B) are organic fluorescent dyes and / or quantum dots.

5. Optical module according to one of the preceding claims 1 to 4, wherein the additives (C) are organic fluorescent dyes and / or metal oxides.

6. Optical module according to one of the preceding claims 1 to 5, wherein the organic fluorescent dyes are selected from the group consisting of xanthenes, cyanines, coumarins, oxazines, rhodamines, perylenes, naphthalimides, Naphthaldiimiden, stilbenes,

Styryls, pyrromethenes and mixtures thereof.

7. An optical module according to any of the preceding claims 1 to 6, wherein the quantum dots are semiconducting materials selected from the group consisting of InAs, InP, GaAs, GaP, GaN, InGaAs,

GalnP / InP, CdO, CdSe, CdS ₅ CdTe ZnS, ZnO, ZnS, ZnSe, ZnTe, HgS, HgSe, HgTe, PbS, PbSe, PbTe.

8. An optical module according to any one of claims 1 to 7, wherein the nanophosphors comprise semiconductive or non-conductive materials

Base of at least one compound selected from the group consisting of phosphates, silicates, germanates, oxides, sulfides, oxysulfides, selenides, sulfoselenides, vanadates, niobates, arsenates, Tantalates, tungstates, molybdates, halogenates, nitrides, borates, aluminates, gallates, and halides,

9. Optical module according to one of the preceding claims 1 to 8, wherein the quantum dots and / or the nanophosphors are capped by means of organic layers.

10. Optical module according to one of the preceding claims 1 to 9, wherein fluorescent additives (A) at least partially organic fluorescent dyes are selected from the group consisting of

Xanthenes, oxazines, rhodamines, perylenes, naphthalimides, naphthaldiimides, stilbenes, coumarins, styryls, pyrromethenes and mixtures thereof.

The optical module according to any of the preceding claims 1 to 10, wherein the fluorescent additives (B) are at least partially organic fluorescent dyes selected from the group consisting of xanthenes, oxazines, rhodamines, perylenes, naphthalimides, naphthaldiimides, stilbenes, coumarins, styryls, pyrromethenes and their mixtures.

12. An optical module according to any one of the preceding claims 1 to 11, wherein the additives (C) are at least partially cyanines.

The optical module according to any one of the preceding claims 1 to 12, wherein the fluorescent additives (A) are at least partially based on semiconducting materials selected from the group consisting of InAs, InP, GaAs, GaP, GaN, InGaAs, GaInP / InP. CdO, CdSe, CdS ₅ CdTe, ZnO, ZnS, ZnSe, ZnTe, PbS, PbSe, PbTe, HgS, HgSe, HgTe, ZnO: Ag, ZnO: Cu, ZnO: Al, ZnOMn, ZnO: Cu, ZnS: Ag, ZnS: Cu, ZnS: Al, ZnS: Mn, ZnS: Cu, ZnSe: Ag; ZnSe: Cu, ZnSe: Al, ZnSe: Mn, ZnSe: Cu, CdS: Ag, Cds: Cu, CdS: Al, Cds: Mn, CdS: Cu, CdSe: Ag, CdSe: Cu, CdSe: Al, CdSe: Mn and CdSe: Cu.

14. An optical module according to any one of the preceding claims 1 to 13, wherein the fluorescent additives (B) are at least partially based on semiconducting material quantum dots selected from the group consisting of InAs, InP, GaAs, GaP, GaN, InGaAs, GalnP / InP, CdO, CdSe, CdS ₅ CdTe ZnO, ZnS, ZnSe, ZnTe, PbS, PbSe,

PbTe, HgS, HgSe and HgTe.

15. Optical module according to one of the preceding claims 1 to 14, wherein the fluorescent additives (A) are at least partially nanophosphors, wherein the nanosphosphors semiconducting or non-conductive materials based on at least one compound selected from the group consisting of phosphates, silicates, germanates, Oxides, sulfides, oxysulfides, selenides, sulfoselenides, vanadates, niobates, arsenates, tantalates, tungstates, molybdates, halogenates, nitrides, borates, aluminates, gallates, and halides.

16. An optical module according to any one of the preceding claims 1 to 15, wherein the additives (C) are at least partially metal oxides, wherein the metal oxides are antimony and / or tin oxides.

17. An optical module according to any one of the preceding claims 1 to 16, wherein the polymer is selected from the group consisting of polyacrylates, polyurethanes, polystyrenes, silicone polymers, polyvinyl alcohols, polyvinyl acetates, polyvinyl butyrates, Cellulo sederivaten, cycloolefin copolymers, acrylonitrile copolymers and polylactides.

18. An optical module according to any one of the preceding claims 1 to 17, wherein the polymer is selected from the group consisting

Polyacrylates, cellulose esters and cellulose ethers.

19. An optical module according to any one of the preceding claims 1 to 18, wherein the thickness ratio of substrate: polymer layer is at least 1:10.

20. An optical module according to any one of the preceding claims 1 to 19, wherein the module additionally comprises at least one solar cell, which converts the fluorescence radiation of the additives into electrical current.

21. A method for producing an optical module according to any one of claims 1 to 20 comprising the steps

(a) preparing a solution (D) by dissolving the organic substances serving as additives (A) to (C) in the monomer (s) of the polymer layer and

(b) preparing a dispersion (E) by dispersing the inorganic substances serving as additives (A) to (C) in the monomer (s) of the polymer layer

(c) mixing the solution (D) and the dispersion (E) into a mixture (F)

(d) adding a UV initiator to the mixture (F)

(e) preparing a prepolymer by irradiating the mixture (F) with UV light

(f) applying the prepolymer to a support (g) Transpolymerization of the prepolymer.

22. A process for producing an optical module according to any one of claims 1 to 20, comprising the steps of (a) preparing a solution (D) by dissolving the organic substances which serve as additives (A) to (C) in which Monomer (s) of the polymer layer and

(b) adding a UV initiator to the solution (D)

(c) preparing a prepolymer by irradiating the solution (D) with UV light

(d) preparing a dispersion (E) by dispersing the inorganic substances serving as additives (A) to (C)

(e) mixing the solution (D) and the dispersion (E) into a mixture

(F) (f) applying the mixture (F) to a support

(g) Transpolymerization of the prepolymer.

23. A process for producing an optical module according to any one of claims 1 to 20, comprising the steps of (a) preparing a solution (D) by dissolving the organic substances which serve as additives (A) to (C) in which Polymer solution (s) (b) preparing a dispersion (E) by dispersing the inorganic substances serving as additives (A) to (C) in the polymer solution (s) (c) mixing the solution (D) and the dispersion (E) to a mixture

(F)

(d) applying the polymer additive solution / dispersion to a support

(e) expulsion of the solvents and drying of the polymer layer.

A process according to any one of claims 21 to 23, wherein the monomer (s) are distilled.

25. The method according to any one of claims 21 to 24 comprising the additional step of the solar cell (s) are attached.

26. Use of a module according to one of claims 1 to 20 for generating the electric current.

27. Use according to claim 26, wherein the module is additionally used for protection against UV and infrared radiation.