FR3076949A1 - OPTICAL AND PHOTONIC DEVICE OF AN AGRIVOLTAIC MODULE - Google Patents

Abstract

Optical and photonic device of an agrivoltaic module characterized in that it comprises: Rows of solar cells (1) having a front surface (1f) and a rear surface (1r) and interconnected to form a matrix (2) having a area (2s) including the free spaces between rows of solar cells, encapsulated between an incoming (4) and outgoing (7) diopter whose distance (e) separating two rows of solar cells (1) is equal to or smaller than the most along a solar cell (1) A light transmission area (LS) consisting of the intervals (e) between rows of solar cells (1) defined according to the surface ratio with the area (2s) such that (LS) is greater than or equal to 0.42 of the area (2s) An optical and photonic device (8) bonded to the surface (7 '') and an area equal to the area (2s) composed of an optical filter ( 8fd) and a photonic concentrator (8ce) and a plasmonic filter (8fp), the device (8) is posit ionized exactly in parallel superposition at any point of the area (6S) to reflect a selection of light rays towards the rear face (1r) of the solar cells and to transmit a selection of spectral bands corresponding precisely and exclusively to the different absorption peaks photo receptors of heliotropic plants covering the three mechanisms of plant development, namely photo morphogenesis, photo synthesis and photo periodism. The device (8) is positioned so as not to be superimposed on the connection boxes (6+) and (6-) as shown in FIG.

Description

Optical and photonic device of an agrivoltaic module

Introduction to art:

The manufacture of a crystalline photovoltaic module requires the following process: cleaning the glass or positioning a material with high transparency positioning an EVA encapsulating film "Ethylene Vinyl Acetate" which is mainly ethylene vinyl acetate on the glass or material highly transparent soldering of a copper tape having a protective layer based on an alloy based on silver, lead and tin: the temperature of the solder does not exceed 250 ° C and does not last more than 3 seconds per solar cell having zones in the form of a current collector line of metallization of the emitter over a width of 1.5 to 3 millimeters interconnection of the negative polarity 'front face of a cell of a substrate of P type with positive polarity 'rear face of a cell of a P type substrate' for example arrangement in row of welded cells interconnection of rows for mounting in s rie of solar cells requiring welding of each line of current collector positioning of an encapsulating film on the matrix of cells positioning of a rear electrical protection film or a glass or other insulating material lamination for encapsulation purposes solar cells

This technique is used unilaterally but has drawbacks:

the EVA encapsulating material has a viscosity of great variability as a function of temperature, which induces mechanical pressure on the entire device of the interconnected solar cells, the EVA encapsulating material containing 1% of water liberates acetic acid and hydrogen peroxide permanently which are trapped in the photovoltaic module causing corrosion, chemical reactions with the surfaces of solar cells, chemical reactions with the inner surface of the glass and creates corrosion of the glass by the formation of halides which are electron traps but also with the polymer used in electrical protection of the module, the EVA material having a refractive index of real part varying between 1.49 and 1.47 on the band of solar radiation, which corresponds to a close spectral response. white glass used, namely that the glass has a special treatment, the EVA material being crosslinked on the glass surface, it is very difficult to separate by some techniques that it is the EVA film of the glass and the recycling of the glass comprising the EVA makes the materials constituting the glass too polluted and therefore make the recycling of the module non-functional the encapsulation of 60 solar cells on monocrystalline silicon of wafer in pseudo square format of 156mm side obtained by the Czochralski growth method, “CZ” homojunction cell and homogeneous emitter of 18.6% of yield involves the following losses:

from a ribbon interconnecting the cells 2mm wide by 0.2mm thick in series and interconnecting the rows of heat-sealed cells by a 5 by 0.3mm ribbon, the electrical losses are 2.5% the optical losses are 1% for a glass with a porous silica layer with a refractive index varying between 1.23 and 1.33 for a glass of transmittance on the solar spectrum of 93% the crystalline module of these 60 solar cells of 18.6% will have a yield of 15.85% or 2.75% and its behavior in temperature will be very affected by the encapsulation of the solar cell of 18.6% on silicon CZ orientation "1-0-0 »With homogeneous emitter will have a coefficient of variation of its power compared to the temperature of a negative factor of 0.45% / ° Kelvin and the crystalline module using EVA among others will have a coefficient of variation of its power of a negative factor of 0.51% / ° K the combination of 93% glass materials transmittance with EVA and cells with homogeneous emitter is compatible but the technological evolution of homojunction cells towards selective emitters and back passivations, the spectral response of the cells evolve greatly making the combination of the materials of a module improper and not efficient the silicon crystalline module is also characterized by the optical behavior of silicon, namely a high absorption coefficient in ultraviolet "UV" and almost transparency to infrared "IR" and the behavior as a function of the temperature of a crystalline module is intimately linked to the ability to capture the spectral solar band, the wavelengths of 250 to 1300nm representing 80% of the spectrum

The present invention describes an integrated optical and photonic device making it possible to filter the light spectrum by three components to provide the photon at the junction of the solar cell with absorbed wavelengths and transmit the useful wavelengths to applications under the panel. photovoltaic and reflect the wavelengths that are not useful for photovoltaic production.

Description of the optical and photonic device of an asrivoltaïaue module

Optical and photonic device of an agrivoltaic module characterized according to Figures 1 and 2 in that it comprises:

Arrays of solar cells (1) having a front surface (lf) and a rear surface (lr) and interconnected to form a matrix (2) having an area (2s) including the free spaces between rows of solar cells, encapsulated between a incoming (4) and outgoing (7) diopter whose distance (e) separating two rows of solar cells (1) is equal to or less than the longest segment of a solar cell (1)

A light transmission area (LS) consisting of the intervals (e) between rows of solar cells (1) defined according to the surface ratio with the area (2s) such that (LS) is greater than or equal to 0.42 of the area (2s) ....

An optical and photonic device (8) bonded to the surface (7 ”) and an area equal to the area (2s) composed of an optical filter (8fd) and a photonic concentrator (8ce) and a plasmon filter (8fp), the device (8) is positioned exactly in parallel superposition at any point in the area (6S) to reflect a selection of light rays towards the rear face (lr) of the solar cells and to transmit a selection spectral bands corresponding precisely and exclusively to the different absorption peaks of the photo-receptors of heliotropic plants covering the three mechanisms of plant development, namely photo morphogenesis, photo synthesis and photo periodism.

The device (8) is positioned so as not to be superimposed on the connection boxes (6+) and (6-) as shown in figure n ° l

The optical and photonic device of an agrivoltaic module according to FIG. 2 characterized in that the free space for the passage of light entering through the agrivoltaic module is of a width (e) between two rows of solar cells (1 ) and the length of the row of solar cells (1) to form the area (LS).

This optical and photonic device of an agrivoltaic module according to FIGS. 1 and 2 characterized in that the upper face of the matrix (2) of solar cells is encapsulated with the surface (4 ′) of the incoming diopter (4) by a material encapsulant (5) chosen from silicones, acrylics, thermoplastics and the surface (4 ”) has a refractive index 10% lower than the refractive index of the incoming diopter (4).

This optical and photonic device of an agrivoltaic module according to FIGS. 1 and 2 characterized in that the surface of the optical and photonic device (8) has a surface equal to the area (2s) and constitutes two parallel planes.

The optical and photonic device (8) is designed so that the reflection of light rays corresponds to 80% of the spectral response of the rear face of a bifacial solar cell whose figure n ° 3 gives the behavior by Internal Quantum Efficiency (IQE) and External (EQE): the dichroism filter must therefore have the property of reflecting spectral bands between 400 and 11OOnm.

The spectral response (SR) of this bifacial solar cell has an extremum at lOOOnm, therefore any corpuscular wave having a photon of wavelength of lOOOnm and having to cross the area (LS) must at least be reflected by the plasmonic filter 8fp so that the rear face of the rear face solar cell (lr) has maximum absorption in its NP junction.

The optical and photonic device of an agrivoltaic module according to FIG. 4 characterized in that the optical and photonic device (8) comprises:

an optical filter (8fd) which can either be a dichroism filter such as a Bragg mirror, a multirefringent filter, a variable multirefringence filter a photonic concentrator (8c) which is a complex of laminated materials doped with nano dots or fluorescent pigments or the combination of nano dots and fluorescent pigments.

-3a plasmonic filter (8fp) which is a polymer complex doped by nano-objects of a defined metal and of predefined shape and according to a precise density and an arrangement of monolayer precisely.

The optical filter (8fd) is a filter with preferential dichroism and with variable multirefringence very preferentially and according to FIG. 8 comprises:

a combination of layers (8a) and (8b) forming a nano-laminate, each of which (8a) and (8b) varies in thickness between 2Angstrôm and 500Angstrom each layer (8a) is the first and last layer of the nano-laminate with a real part refractive index of between 1.45 and 1.55 on the spectral band from 300 to 1600nm the layer (8b) is the combination of (8a) whose real part refractive index varies between 1.6 and 2 on the spectral band from 300 to 1600nm.

According to figure n ° 4 the filter (8fd) reflects a main spectral band between 600 and 1300nm which corresponds to 80% of the spectral response of the rear face of bifacial solar cell (lr): figure n ° 4 does not show behavior in reflection and transmission for a fixed angle of 8 °, whose reflected spectral band will vary towards lOOnm or from 500 to 11OOnm for an angle of 80 °.

The transmission of the filter (8fd) ensures transmission of the incident corpuscular wave on the photonic concentrator (8ce), i.e. for an angle of 8 ° the spectral transmission of 400-600nm.

The photonic concentrator (8ce) is a complex of photonic media and comprises at least one photonic medium from:

a polymer chosen from silicone and epoxy resins, polyethylenes, acrylics, polyamides, polycarbonates and doped with a pigment from perylene and preferably from N, N-Bis (2,6diisopropylphenyl) -1,7, 12-tetraphenoxyperylene-3,4: 9,10-tetracarbonate (C72 H58 N2 08) a polymer chosen from silicone and epoxy resins, polyethylenes, acrylics, polyamides, polyacrylamides, polycarbonates and doped with a phycobilisome protein a polymer chosen from silicone and epoxy polyethylene resins, acrylics, polyamides, polyacrylamides, polycarbonates and doped with a family of nanodots described in another patent application by the same author, namely a nano nucleus crystal (N) consisting of an alloy based on Ct-An where Ct is an anionic combination chosen from Cadnium, Zinc, Mercury, Coppemicium or their alloys by combination of Cd, Zn, Hg, Cn and where An is a combi cationic reason chosen from Tellurium, Selenium, Sulfur or their alloys by combination of Te, Se, S and an envelope (E) around the nucleus (N) by alloys of (CtAn) Ct _x Bd _z with gradient concentration of which Bd is an atom chosen by S, Se, Cu, In, Ga or the combination of an alloy of S, Se, Cu, In, Ga.

The fluorescent pigment can be chosen from R305 and A699, the maximum absorption of which is 580nm for an emission centered on 670nm for R305 and 720nm for A699 or the combination of these two fluorescent pigments.

The photonic concentrator (8ce) can include the combination of photonic media from:

a polymer chosen from silicone and epoxy resins, polyethylenes, acrylics, polyamides, polycarbonates and doped with a pigment from perylene and preferably from N, N-Bis (2,6diisopropylphenyl) -1,7, 12-tetraphenoxyperylene-3,4: 9,10-tetracarbonate (C72 H58 N2 08) a polymer chosen from silicone and epoxy resins, polyethylenes, acrylics, polyamides, polyacrylamides, polycarbonates and doped with a phycobilisome protein a polymer chosen from silicone and epoxy resins, polyethylenes, acrylics, polyamides, polyacrylamides, polycarbonates and doped with a family of nanodots described in another patent application by the same author, namely a nucleus of the nanocrystal (N) consisting of an alloy based on Ct-An where Ct is an anionic combination chosen from Cadnium, Zinc, Mercury, Coppemicium or their alloys by combination of Cd, Zn, Hg, Cn and where An is a com cationic pairing chosen from Tellurium, Selenium, Sulfur or their alloys by combination of Te, Se, S and an envelope (E) around the nucleus (N) by alloys of (CtAn) Ct _x Bd _z with gradient of concentration of which Bd is an atom chosen by S, Se, Cu, In, Ga or the combination of an alloy of S, Se, Cu, In, Ga.

The fluorescent pigment can be chosen from R305 and A699, the maximum absorption of which is 580nm for an emission centered on 670nm for R305 and 720nm for A699 or the combination of these two fluorescent pigments.

The photonic concentrator (8ce) is a complex of laminated materials doped with nanodots or fluorescent pigments or the combination of nanodots and fluorescent pigments. The nano dots family is

-4 defined by another invention of the same inventor describing a Ct-An nanocrystal where Ct is an anionic combination chosen from Cadnium, Zinc, Mercury, Coppernicium or their alloys by combination of Cd, Zn, Hg, Cn and where An is a cationic combination chosen from Tellurium, Selenium, Sulfur or their alloys by combination of Te, Se, S.

The nanocrystal complex has an envelope at the nucleus (N) by alloys of (Ct-An) Ct _x Bd _z with concentration gradient of which Bd is an atom chosen by S, Se, Cu, In, Ga or the combination of an alloy of S, Se, Cu, In, Ga and which are formed by the ALE technique (Atomic Layer Epitaxy) or by ALD (Atomic Layer Deposition) or the combination of the two deposits on the nano powder made up of the nano crystal Ct Year. The formation of the outer layer (E) of an alloy with a concentration gradient of nano dot for example (Cd _x Se _x -Tei _x ) Cd _x Zn _y S ₂ creates a crystal mesh distortion: this mesh distortion increases the plasmonic relaxation by the constrained semiconductor crystal and plasmonic relaxation makes it possible to perfectly control the degeneration according to orbital levels that an unconstrained crystal does not allow.

The photonic concentrator (8ce) is an ultra Raman device thus made up of different layers with variable density of the nano dot depending on the layer and the density of pigments to form the photonic complex whose operating efficiency is ensured by the transmitted incident spectral band. by the optical filter (8fd) to limit the photonic interference and that the photonic emission a photoluminescence as high as possible.

The combination of the filter (8fd) and the photonic concentrator (8ce) ensures the reduction of the absorption by the nano dots since the incident spectrum on the nano dots is pre-selected and corresponds to the maximum photoluminescence.

According to Figure 8, the plasmonic optical filter (8fp) includes:

a polymer chosen from polyethylenes, acrylics, polyamides, polycarbonates, resins chosen from epoxy, silicone, a density of nanomirrors (8 g) of less than 70% but preferably of density between 20 and 50%, of which nano mirrors are nano metal powders of a particular geometric shape and preferably polygonal and arranged in layers to form a monolayer.

The nanomirror has a polygonal shape with a geometry preferably defined by the ratio between the longest section of the polygon and the thickness of the polygon which must be greater than 8 and very preferably greater than 12 and less than 16.

Nano mirror is a metal chosen from aluminum, chromium, nickel, silver, gold.

As shown in figure n ° 6 this optical filter (8fp) with plasmonic functioning works according to the principle of local plasmonic resonance, namely that the frequency of the plasmons generated in the metallic nanomirror by the flow of fermions under the action of the field electric of the corpuscular wave of a given quanta which is absorbed and diffused on both sides of the resonance frequency. Given the function of the filter (8fp) that the present invention wants to calibrate its resonance on the light conversion peak of the rear face (lr) of a symmetrical bifacial bifacial solar cell on N-type monocrystalline silicon, ie at 100 nm, the aspect ratio of the nano mirror will be 14 for a silver material in the case of the constitution of this filter at the highest Fermi speed possible.

The absorption in this filter (8fp) is strictly necessary, this is why the density of nanomirror is optimized to ensure an average transmittance of 50% on the incident spectrum, namely from 300 to 2800nm for maximum reflection at the conversion peak light of the bifacial solar cell (lr).

Advantageously, this filter is variable by adjusting the aspect ratio of the nano mirrors (8 g) so that the local plasmon resonance is always in phase with the spectral behavior of the solar cell.

Figure 7 shows the spectral behavior of the filter (8fp) which does not interfere with the ultra Raman emission coming from the concentrator (8ce) when an incident light wave with an angle less than 60 ° diffracted is transmitted through the diopter (4) in the space between the solar cells of the area (LS) then of the diopter (7) before being polarized by the filter (8fd) in order to separate the light into spectral bands so that a band of 580 -1300nm is reflected towards the matrix (2) and in particular towards the bifacial solar cells (lr) and that another spectral band of 350-600nm is transmitted to the concentrator (8ce) which by absorption in each nano crystal and its crystal envelope of nano dot will excite the electrons of the nano dot nano crystal which works by successive photonic cascades and that this nano dot can emit a stable fluorescence and of which each nano dot

-5 having a precise and different envelope so that each nano dot precisely emits the following wavelengths by peaks of fluorescence radiation at a relative photoluminescence greater than 80 for each of the following wavelengths 375nm, 405nm, 426nm, 430nm, 450nm, 460nm, 640nm, 666nm, 670nm, 720nm, 725nm then photons of the spectral band transmitted by (8fd) not having been absorbed by (8ce) on the one hand and on the other hand the weak fluorescence residues and backscattered constitute a new spectral band of 780-1200nm which will be reflected towards the solar cells (lr) by the filter (8fp) according to the principle of local plasmon resonance namely that the frequency of the plasmons generated in the nano metallic mirror by the flow of fermions under the action of the electric field of the corpuscular wave of a given quanta which is absorbed and diffused on both sides of the corresponding resonance frequency at the extremum of the spectral response (SR) of a bifacial solar cell having its extremum at lOOOnm, therefore any corpuscular wave having a photon of wavelength of lOOOnm and having crossed the area (LS) must at least be reflected at the last diffraction reflection by the plasmon filter (8fp) so that the rear face of the rear face solar cell (lr) has maximum photon absorption in its NP junction while the other spectral band of 370-730nm is transmitted in the greenhouse whose agrivoltaic module of the present invention is applied on the roof of photovoltaic energy production and chromatic culture in this greenhouse.

As shown by the spectrum in transmission in FIG. 7 of the optical and photonic device of an agrivoltaic module according to claim 1, characterized in that the device (8) transmits a spectrum of light, so that the ray transmitted to through the surface plane (6s) be filtered by the variable multirefringent filter (8fd) to separate the light into two components, one reflected towards the bifacial solar cells (lr) according to a spectral band of 580-1300nm and the other form a spectral band transmitted from 350-600nm to the photonic concentrator (8ce) comprising a maximum wavelength absorbed by the nanocrystals at 600nm in (8ce) in order to ensure the electronic excitation of the nanocrystals and an orbital degeneration so that the successive emissions produce a photonic cascade which corresponds to each absorption peak of the photoreceptors of heliotropic plants and is transmitted at different angles under the d ispositive (8) therefore under the agrivoltaic module and that the spectrum transmitted by the dispostive (8) has transmission peaks centered on each absorption peak of phototropin, cryptochromes, phytochromes Pr and Prf, chlorophylls a and b and of higher intensity at each of the absorption peaks of the photoreceptors of heliotropic plants.

Chromophores are key molecules in the plant development mechanism and are the essential constituents of photo-synthesis and photo-morphogenesis: molecules are alternations of sequences with double or single chemical bond forming auxochromes (basic, acids, halogens ) which have a group of ionizable atoms and therefore create an electronic degeneration of transition of orbital and therefore of energy level to result in different spectral absorptions and variable by the diversity of auxochromes constituting the chromophores, which chromophores are the organic complex of genesis of photosensitivity and therefore of photo-response of the plant through two different mechanisms that are photo morphogenesis and photosynthesis.

Photo-morphogenesis is the structuring of the chromatic response of any plant which is specific to each plant species by its three types of photoreceptor which interact with each other and whose induced mechanisms are catalyzed by temperature, pressure, gravity among others:

Phytochromes sensitive to wavelengths between 650 and 730nm Phototropins, sensitive to wavelengths between 420 and 490nm Cryptochromes, sensitive to wavelengths for two spectral ranges of 320-380nm and 400480nm

Phytochromes are chromoproteins existing in two forms, the inactive form Pr (For red) at the peak of light absorption at 660nm triggering the active form Prf (For far-red) at 720nm or reversibly allows to regulate certain phases of the development of vegetable like floral induction whose peak of absorption of light is at 650-660nm coincides with (Pr), the germination inducing a sensitivity to the shade, the photo-periodism of certain plants.

Phototropins are photoreceptors which ensure the sensitivity of the plant to the direction of its growth as a function of the incident light (Phototropism) and a major action of photomorphogenesis by the dosage of the photonic signal in bio-chemical actions and in particular by movements of chloroplasts either in protection from incident light or in exposure to incident light to increase receptivity to light and to the opening of stomata.

-6 Cryptochromes are photoreceptors regulating morphology by the growth of stems, leaves, flowering, the synthesis of anthocyanin among flavonoids, the induced mechanism of the plant circadian cycle.

Photo-morphogenesis and photosynthesis are the result of the absorption of light from the chromophores and in particular by the process within the chloroplast of photosystems I of the isomer of chlorophyll A and photosystem II of the isomer of chlorophyll B among others including the intensity by wavelength characterizing the spectral absorption of the two types of chlorophyll isomer ensures their conversion into a reducing agent P700 (enzymes) of CO2 and oxidation P680 of H2O whose double oxidation - reduction reactions allows the formation of carbohydrate binders at the absorption peak at 520nm (green color): this chromatic characteristic makes it possible to ensure the vegetative cycle and if the photo-chemical signal is altered either in intensity or in wavelength, the morphogenesis of the plant will be affected either by stunted growth, lengthened dormancy cycles, weak blooms that do not provide fruit set and therefore a poor crop yield degraded

An example of implementation of the present invention consists in:

encapsulation of a matrix of 4 strings of 12 crystalline solar cells on bifacial silicon of 156.75x156.75mm and conversion efficiency of 22.8% or a power of 5.51W and spaced apart by a space of 108mm, between two 1662 x 992 x 2mm thermal-tempered solar glasses with a thermoplastic resin to form a non-agrivoltaic bifacial photovoltaic module of 256W in Pmp power by a flash test under standard conditions the device (8) includes:

o a variable multirefringent filter in PMMA and PEN o a PMMA film doped with Ct-An nano dots o a polyacrylamide film doped with nano dots based on phycoerythrobilin - phycourbiline depositing an optically clear adhesive on the various films of device (8) and lamination of (8) on the face (7 ”) of the photovoltaic module to thus form an agrivoltaic module with a Pmp power of 400W in standard conditions of solar simulation with optical behavior of integral transmission of the spectra d of phototropin, chromophores of the photo morphogenesis Pr and Prf, cryptochromes and isomers of chlorophyll

Claims (10)

1 - Optical and photonic device of an agrivoltaic module characterized in that it comprises: Arrays of solar cells (1) having a front surface (lf) and a rear surface (lr) and interconnected to form a matrix (2) having an area (2s) including the free spaces between rows of solar cells, encapsulated between a incoming (4) and outgoing (7) diopter whose distance (e) separating two rows of solar cells (1) is equal to or less than the longest segment of a solar cell (1) A light transmission area (LS) consisting of the intervals (e) between rows of solar cells (1) defined according to the surface ratio with the area (2s) such that (LS) is greater than or equal to 0.42 of the area ^(2S) An optical and photonic device (8) bonded to the surface (7 ”) and an area equal to the area (2s) composed of an optical filter (8fd) and a photonic concentrator (8ce) and a plasmon filter (8fp), the device (8) is positioned exactly in parallel superposition at any point in the area (6S) to reflect a selection of light rays towards the rear face (lr) of the solar cells and to transmit a selection spectral bands corresponding precisely and exclusively to the different absorption peaks of the photo-receptors of heliotropic plants covering the three mechanisms of plant development, namely photo morphogenesis, photo synthesis and photo periodism. The device (8) is positioned so as not to be superimposed on the connection boxes (6+) and (6-) · 2 - Optical and photonic device of an agrivoltaic module according to the preceding claim characterized in that the free space for the passage of light entering through the agrivoltaic module is of a width (e) between two rows of solar cells (1) and the length of the row of solar cells (1) to form the area (LS) and that the surface of the optical and photonic device (8) has an area equal to the area (2s) and constitutes two parallel planes. 3 - Optical and photonic device of an agrivoltaic module according to claim No. l characterized in that the optical and photonic device (8) comprises: an optical filter (8fd) which can either be a dichroism filter such as a Bragg mirror, a multirefringent filter, a variable multirefringence filter a photonic concentrator (8ce) which is a complex of laminated materials doped with nano dots or fluorescent pigments or the combination of nano dots and fluorescent pigments. a plasmonic filter (8ip) which is a polymer complex doped by nano-objects of a defined metal and of predefined shape and according to a precise density and a precisely monolayer arrangement. 4 - Optical and photonic device of an agrivoltaic module according to the preceding claim characterized in that the optical filter (8fd) with dichroism comprises: a combination of layers (8a) and (8b) forming a nano-laminate, each of which (8a) and (8b) varies in thickness between 2Angstrôm and 500Angstrom each layer (8a) is the first and last layer of the nano-laminate with a real part refractive index of between 1.45 and 1.55 on the spectral band from 300 to 1600nm the layer (8b) is the combination of (8a) whose real part refractive index varies between 1.6 and 2 on the spectral band from 300 to 1600nm. 5 - Optical and photonic device of an agrivoltaic module according to claim 3 characterized in that the photonic concentrator (8ce) is a complex of laminated materials doped with nano dots or fluorescent pigments or the combination of nano dots and fluorescent pigments and comprises at least one photonic medium from: a polymer chosen from silicone and epoxy resins, polyethylenes, acrylics, polyamides, polycarbonates and doped with a pigment from perylene and preferably from N, N-Bis (2,6diisopropylphenyl) -1,7,7, 12-tetraphenoxyperylene-3,4: 9,10-tetracarbonate (C72 H58 N2 08) a polymer chosen from silicone and epoxy resins, polyethylenes, acrylics, polyamides, polyacrylamides, polycarbonates and doped with a phycobilisome protein -8a polymer chosen from silicone and epoxy polyethylene resins, acrylics, polyamides, polyacrylamides, polycarbonates and doped with a family of nanodots described in another patent application by the same author, namely a nucleus of the nanocrystal (N) consisting of an alloy based on Ct-An where Ct is an anionic combination chosen from Cadnium, Zinc, Mercury, Coppemicium or their alloys by combination of Cd, Zn, Hg, Cn and where An is a cationic combination chosen from Tellurium, Selenium, Sulfur or their alloys by combination of Te, Se, S and an envelope (E) around the nucleus (N) by alloys of (CtAn) Ct _x Bd _z with gradient of concentration of which Bd is an atom chosen by S, Se, Cu, In, Ga or the combination of an alloy of S, Se, Cu, In, Ga. The fluorescent pigment can be chosen from R305 and A699, the maximum absorption of which is 580nm for an emission centered on 670nm for R305 and 720nm for A699 or the combination of these two fluorescent pigments. 6 - Optical and photonic device of an agrivoltaic module according to the preceding claim characterized in that the photonic concentrator (8ce) can include the combination of photonic media from: a polymer chosen from silicone and epoxy resins, polyethylenes, acrylics, polyamides, polycarbonates and doped with a pigment from perylene and preferably from N, N-Bis (2,6diisopropylphenyl) -1,7, 12-tetraphenoxyperylene-3,4: 9,10-tetracarbonate (C72 H58 N2 08) a polymer chosen from silicone and epoxy resins, polyethylenes, acrylics, polyamides, polyacrylamides, polycarbonates and doped with a phycobilisome protein a polymer chosen from silicone and epoxy resins, polyethylenes, acrylics, polyamides, polyacrylamides, polycarbonates and doped with a family of nanodots described in another patent application by the same author, namely a nucleus of the nanocrystal (N) consisting of an alloy based on Ct-An where Ct is an anionic combination chosen from Cadnium, Zinc, Mercury, Coppemicium or their alloys by combination of Cd, Zn, Hg, Cn and where An is a comb cationic inaison chosen from Tellurium, Selenium, Sulfur or their alloys by combination of Te, Se, S and an envelope (E) around the nucleus (N) by alloys of (CtAn) Ct _x Bd _z with gradient of concentration of which Bd is an atom chosen by S, Se, Cu, In, Ga or the combination of an alloy of S, Se, Cu, In, Ga. the fluorescent pigment can be chosen from R305 and A699, the maximum absorption of which is 580nm for an emission centered on 670nm for R305 and 720nm for A699 or the combination of these two fluorescent pigments. 7 - Optical and photonic device of an agrivoltaic module according to claim No. 3 characterized in that the optical filter (8fp) plasmonic comprises: a polymer chosen from polyethylenes, acrylics, polyamides, polycarbonates, resins chosen from epoxy, silicone, a density of nanomirrors (8 g) of less than 70% but preferably of density between 30 and 50%, of which the nano mirrors are nano powders of transition metals of a particular geometric shape and preferably polygonal and arranged in layers to form a monolayer. 8 - Optical and photonic device of an agrivoltaic module according to the preceding claim characterized in that the nano mirror (8g) has a polygonal shape of a geometry preferentially defined by the ratio between the longest section of the polygon and the thickness of the polygon which must be greater than 8 and very preferably greater than 12 and less than 16 and that the nano mirror is a metal chosen from aluminum, chromium, nickel, silver, gold. 9 - Optical and photonic device of an agrivoltaic module according to claim No. l characterized in that the device (8) transmits a light spectrum, so that the ray transmitted through the plane of the surface (6s) is filtered by the variable multirefringent filter (8fd) to separate the light into two components, one reflected towards the bifacial solar cells (lr) according to a spectral band of 580-1300nm and the other forms a spectral band transmitted from 350-600nm to the photonic concentrator ( 8ce) comprising a maximum wavelength absorbed by the nanocrystals at 600 nm in (8ce) in order to ensure the electronic excitation of the nanocrystals and an orbital degeneration so that the successive emissions produce a photonic cascade which corresponds to each peak d absorption of photo receptors from heliotropic plants and is transmitted at different angles under the device (8) therefore under the agrivoltaic module and that l The spectrum transmitted by the device (8) has transmission peaks centered on each absorption peak of phototropin, cryptochromes, phytochromes Pr and Prf, chlorophylls a and b and of intensity greater than each of the peaks of absorption of photo receptors from heliotropic plants. 10 - Optical and photonic device of an agrivoltaic module according to claims 1 characterized in that an incident light wave of an angle less than 60 ° diffracted is transmitted through the diopter (4) in the space between the solar cells of the area (LS) then of the diopter (7) before being polarized by the filter (8fd) in order to separate the light into spectral bands so that a band of 580-1300nm is reflected towards the matrix (2) and in particular towards the bifacial solar cells (lr) and that another spectral band of 35O-6OOnm is transmitted to the concentrator (8ce) which by absorption in each nano crystal and its crystalline envelope of nano dot will excite the electrons of the nano crystal of nano dot which works by successive photonic cascades and that this nano dot can emit a stable fluorescence and of which each nano dot having a precise and different envelope so that each nano dot emits precisely the lengths d following wave by fluorescence radiation peaks at a relative photoluminescence greater than 80 for each of the following wavelengths 375nm, 405nm, 426nm, 430nm, 450nm, 460nm, 640nm, 666nm, 670nm, 720nm, 725nm then photons of the spectral band transmitted by (8fd) not having been absorbed by (8ce) on the one hand and on the other hand the weak and backscattered fluorescence residues constitute a new spectral band of 780-1200nm which will be reflected towards the solar cells (lr) by the filter (8fp) according to the principle of local plasmon resonance, namely that the frequency of the plasmons generated in the metallic nano mirror by the flow of fermions under the action of the electric field of the corpuscular wave d '' a given quanta which is absorbed and diffused on either side of the resonant frequency corresponding to the extremum of the spectral response (SR) of a bifacial solar cell having its extremum at lOOOnm, therefore any particle wave having a photon with a wavelength of lOOOnm and having crossed the area (LS) must at least be reflected as a last diffraction reflection by the plasmon filter (8fp) so that the rear face of the solar cell faces rear (lr) has a maximum photonic absorption in its NP junction while the other spectral band of 370-730nm is transmitted in the greenhouse whose agrivoltaic module of the present invention is applied on the roof of photovoltaic energy production and culture chromatic under this greenhouse.