FR3042341A1 - PHOTOVOLTAIC OPTICAL DEVICE WITH FRONT PLASMONIC FILTRATION AND VARIABLE REVERSE MULTIPLEFRINGENCE SIMPLE CONVAVE AND DOUBLE CONVEX LOCALLY - Google Patents

Abstract

Photovoltaic optical device with frontal plasmonic filtration and single concave and double convex rear variable multirefringence locally characterized in that it comprises: - rows of crystalline bifacial solar cells (1) having a front surface (1f) and a rear surface (1r) of photovoltaic conversion ratio of 80% minimum and interconnected to form a matrix (2) encapsulated between an incoming (4) and outgoing (7) diopter whose distance (e) separating two rows is equal to or smaller than the segment of a cell solar (1) - The surface taken in the plane of the matrix (2) forms an area (2s) - a plasmonic filter (3) stuck on the incoming diopter (4) and positioned in parallel with a row of solar cells ( 1) in the interval (e) separating the solar cells (1) and centered on the median axis between two rows of cells so 1/2 of (e) - A light transmission area (6S) consisting of the interval (e) by a ra Negative solar cells (1) - A variable multirefringent variable filter (8) with concave single mirror and double convex locally (8c) adhered to the lower surface (7 ") of the outgoing diopter (7) covering the lower surface (7") d a surface equal to the area (2s) and in which the single concave and double convex zone (8c) of the filter (8) is positioned exactly in parallel superposition at any point of the area (6S) to reflect the light rays towards the rear face (1r) of the solar cells and to the plasmonic filter (3) by divergence of the diffracted rays of the simple convex dichroic mirror (8c) and by convergence of the diffracted rays of the double concave dichroic mirror The median axis of the concave simple shape the optical filter (8) must be positioned exactly and coincident with the median axis between two rows of solar cells (1) and the median axis of the plasmonic filter (3).

Description

Photovoltaic optical device with frontal plasmonic filtration and multifrequency variable rear single concave and double convex locally

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The manufacture of crystalline photovoltaic modules requires the following process: cleaning of the glass or positioning of a material with high transparency positioning of an encapsulating film EVA "Ethylene Vinyl Acetate" which is mostly ethylene vinyl acetate on the glass or material high-transparency welding of a copper ribbon having a protective layer based on an alloy based on silver, lead and tin: the temperature of the weld does not exceed 250 ° C and does not last more than 3 seconds per solar cells having current collector-like areas of the emitter metallizations over a width of 1.5 to 3 millimeters interconnection of the negative polarity front face of a cell of a substrate of type P at the positive polarity 'rear face of a cell of a P type substrate' for example row layout of welded cells row interconnection for a mounting in s erie solar cells requiring solder of each line of current collector positioning a film encapsulating on the array of cells positioning a rear electric protection film or glass or other lamination insulating material for encapsulation purposes solar cells

This technique is used unilaterally but has drawbacks: the encapsulating material EVA has a viscosity of great variability as a function of the temperature which induces a mechanical pressure on the entire device of the interconnected solar cells the encapsulating material EVA containing 1% of water releases acetic acid and hydrogen peroxide permanently trapped in the photovoltaic module causing corrosions, chemical reactions with the surfaces of solar cells, chemical reactions with the inner surface of the glass and creates the corrosion of the glass by the formation of halides which are traps of electrons but also with the polymer used in electrical protection of the module the EVA material having a refractive index real part varying between 1.49 and 1.47 on the strip of solar radiation, which corresponds to a spectral response close to the white glass used, To know that the glass has a particular treatment the EVA material being crosslinked on the surface of the glass, 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 too polluted glass and therefore make the recycling of non-functional module the encapsulation of 60 solar cells on monocrystalline wafer silicon of square-shaped format of 156mm side obtained by Czochralski growth method, "CZ" homojunction cell and homogeneous transmitter of 18.6% yield results in the following losses: from a ribbon interconnecting in series cells 2mm wide by 0.2mm thick and interconnecting the rows of heat-sealed cells with a ribbon of 5 by 0, 3mm, the electrical losses are 2.5% the optical losses are 1% for a glass with a porous silica layer of refractive index varying between 1.23 and 1.33 for a glass of transmittance on the solar spectrum of 93% the crystalline modulus 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 encapsulation

the 18.6% solar cell on homogeneous emitter "1-0-0" CZ silicon will have a coefficient of variation of its power relative to the temperature of a negative factor of 0.45% / ° Kelvin and the crystalline modulus using EVA among others will have a coefficient of variation of its power of a negative factor of 0.51% / ° K the combination of glass materials with 93% transmittance with EVA and transmitter cells Homogeneous is compatible but the technological evolution of homojunction cells to selective emitters and back passivations, the spectral response of cells evolve greatly making the combination of materials of a module unsuitable and inefficient the crystalline silicon module is also characterized by the optical behavior of silicon, namely a high absorption coefficient in ultraviolet "UV" and near-infrared transparency "IR" and the behavior in function The temperature of a crystalline module is closely related to the ability to capture the spectral solar band whose wavelengths from 250 to 130 nm representing 80% of the spectrum

The present invention discloses an optical integrated device for filtering the light spectrum by three components to provide the solar cell junction with photons at absorbed wavelengths and to transmit wavelengths useful for applications under the photovoltaic panel and to reflect wavelengths that are not useful for photovoltaic production.

Description of the photovoltaic optical device with frontal plasmonic filtration and single concave and double convex rear variable multirefringence locally:

Photovoltaic optical device with frontal plasmonic filtration and concave single and double convex variable rearward displacement locally characterized according to FIGS. 1 and 2 in that it comprises:

Rows of crystalline bifadial solar cells (1) having a front surface (lf) and a rear surface (lr) of at least 80% photovoltaic conversion ratio and interconnected to form a matrix (2) encapsulated between an incoming diopter (4) and outgoing (7) whose distance (e) separating two rows is equal to or smaller than the segment of a solar cell (1)

The surface taken in the plane of the matrix (2) forms an area (2s) a plasmonic filter (3) stuck on the incoming diopter (4) and positioned in parallel with a row of solar cells (1) in the interval (e) separating the solar cells (1) and centered on the median axis between two rows of cells so% of (e)

A light transmission area (6S) consisting of the interval (e) by a row of solar cells (1)

A variable multirefringent filter (8) with concave single mirror and double convex locally (8c) adhered to the lower surface (7 ") of the outgoing diopter (7) covering the bottom surface (7") of a surface equal to the area (2s) and whose concave double convex double zone (8c) of the filter (8) is positioned exactly in parallel superposition at any point of the area (6S) to reflect the light rays towards the rear face (lr) of the cells to the plasmonic filter (3) by convergence of the diffracted radii of the concave single dichroic mirror (8c) and by divergence of the diffracted radii of the double convex dichroic mirror

This photovoltaic optical device with frontal plasmonic filtration and concave simple multirefringence rear single and double convex locally according to Figure No. 3 characterized in that the plasmonic filter (3) comprises:

A film of a polymer (3p) selected from poly (ethylene terephthalate) (PET), polyolefin (PO), a fluoropolymer (PVDF), polycarbonates, acrylates having a bifadal micro-replication of a pattern prismatic (3 ") and (3 '") of segment less than or equal to 25 micron at an angle less than or equal to 60 ° a nanolamine compound (3r) composed of multi-layer materials selected from silver, aluminum, Silicon, Gold, Chromium, Zinc, Copper, Nickel, Cobalt, Lithium, Platinum Carbon Nanotubes, Boron Nitride, Aluminum oxide A1203, Oxide Hafhium Hf02, zirconium oxide Zr02, ternary alloys hafnium aluminate HfxAlyOz, ternary alloys zirconate aluminate ZrxAlyOz, ternary alloys hafnium zirconate HfxZryOz, quaternary alloys hafnia zirconate aluminate HfxZryAlzOi, titanium oxide TiO2

The photovoltaic optical device with frontal plasmonic filtration and single concave rear variable multirefringence and double convex locally according to FIG. 2 characterized in that the plasmonic filter (3) has a length equal to the row of solar cells (1) and constitutes a bifacial reflective tape.

This photovoltaic optical device with frontal plasmonic filtration and concave single multirefringence rear single concave and double convex locally according to Figure No. 2 characterized in that the reflective band constituting the plasmonic filter (3) has a width less than one third the interval (e) E / 3 per unit of reflective tape.

The photovoltaic optical device with frontal plasmonic filtration and multilefringence variable rearward single concave and double convex locally according to Figure No. 5 characterized in that the free passage of light entering and exiting through 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 (6S).

This photovoltaic optical device with frontal plasmonic filtration and concave simple multirefringence rear single and double convex locally according to Figures 1 and 5 characterized in that the upper face of the matrix (2) of solar cells is encapsulated with the surface (4 ") of dioptre entering (4) by encapsulating material (5) selected from silicones, acrylics, thermoplastics.

The photovoltaic optical device with frontal plasmonic filtration and multilefringence variable rear single concave and double convex locally according to Figures 1 and 5 characterized in that the plasmonic filter (3) by its textured underside (3 '") is oriented towards the front face (lf) solar cells (1) and that its textured upper face (3 ") is encapsulated between the surface (4 ') of the incoming diopter (4) by an encapsulating material (6) selected from silicones, acrylics, thermoplastics.

This device is characterized in that the area (6S) is defined by the dimensions of the interval (e) and the length of the rows of cells.

This photovoltaic optical device with frontal plasmonic filtration and single concave rear variable multirefringence and double convex locally according to FIG. 5 characterized in that the surface (8s) of the variable multireftingent filter (8) has a surface equal to the area (2s ) of the matrix (2) of solar cells (1) and constitutes three parallel planes between the plasmonic filter (3) and the matrix of cells (2) and the variable multirefringent filter (8) so that the dichroism resulting from the filter (8) ) is positioned on the underside (1r) of the solar cells superimposed at any point in this area (2s).

The photovoltaic optical device with frontal plasmonic filtration and concave simple multirefringence rear single and double convex locally according to Figure No. 4 characterized in that the variable multi-refractive filter (8) comprises: an interface (8i) of bonding from materials selected from acrylics, silicones a combination of layers (8a) and (8b) forming a nano-laminate each of which (8a) and (8b) varies in thickness between 2 Angstrom and 500 Angstrom each layer (8a) is the first and the last layer of nano-laminate with refractive index real part between 1.45 and 1.55 on the spectral band of 300 to 1600 nm layer (8b) is the combination of (8a) whose refractive index actual part varies between 1,6 and 2 on the spectral band of 300 to 1600nm

This photovoltaic optical device with frontal plasmonic filtration and multilefringence variable rear single concave and double convex locally according to Figures 2 and 4 characterized in that the variable multirefringent filter (8) consists of a dichroism between λ / 10 and λ / 2 of the spectrum incident for a given wavelength λ whose interface (8i) can have a texturing of its surface in interface with (7 ").

The optical device (8) characterized in that the convex shape is acrjdate material whose surface has the variable multirefringent filter and whose diameter (F) of the convex shape is at most equal to the width of the filter (3) is e / 3 and whose depth (h ") must be less than (e / 3) to form a convex hyperbolic paraboloid dichroic mirror.

The optical device (8) characterized in that the concave shape is of acrylate material whose inner surface has the variable multirefringent filter and whose diameter (l ") of the concave shape is at most equal to the width of the filter (3) ie e / 3 and whose depth (h ") must be less than (e / 3) to form a concave hyperbolic paraboloid dichroic mirror. The median axis of the convex shape of the optical filter (8) must be positioned exactly and coincident with the median axis between two rows of solar cells (1) and the median axis of the plasmonic filter (3).

An example of the construction of such a photovoltaic device consists of: a matrix of bifacial solar cells with rear passivation of the emitter formed on Phosphorus-doped monocrystalline silicon whose dimensions of the pseudo-square substrate are 156.75 × 156.75 mm for a 205mm ingot radius: the solar cell has a conversion efficiency of 20.8% minimum for a maximum power of 5.06Watt, interconnected by a coated tape conductive glue of a silicone resin and copper and nanowires lead-free copper: the matrix (2) consists of 6 rows of 10 solar cells the array is organized to have 16mm of space (e) between rows of cells connected in series - incoming optic (4) is a solar glass 96% transmittance thermally hardened silicate print on 1.5mm solar spherre 1.5AM - the matrix (2) formed is encapsulated by its front side subjected to direct solar radiation by an encapsulant (5) of liquid silicone UV laminated by a liquid lamination - the outgoing diopter (7) is a printed solar glass with a thickness of 2 mm hardening quenching silicate. the plasmonic filter is a micro-replicated PET compound with a thickness of 100 micron, whose prism-forming grooves have a pitch of 20 micron and whose surface is a nano-laminate of aluminum, aluminum oxide A1203 and in surface layer a ternary alloy of HfxAlyOz which increases the reflectivity on the spectral band of 250-400nm which are reflected by the dichroism filter and have a width of 7mm - a variable multirefitingent filter composed of acrylic materials (8a) with index refractive index of 1.49 for a wavelength of 62 nm and of poly-ethylene material (8b) with refractive index of 1.76 for a wavelength of 620 nm at an acrylic interface (8i): this film has a network of 100 for a thickness of 350nm and is laminated on the outgoing dioptre (7) of the laminate before fixing the cables and the convex cavity has a width of 18mm for a depth of 4.5mm.

Such a dual rear plasmon filter photovoltaic device has power in the standard 360Watt insolation test for only 60 solar cells of 5.06W

This invention allows the realization of an increase in the power of a photovoltaic module fotre transparency by a low density of solar cell matrix by a plasmonic filtration which is not sensitive to photo aging by the combination of integrated materials: the geometry of the filter is adapted according to the spectral response of the solar cell and corresponds to the reflection of wavelengths between 600 and 900nm: this feature has an economic interest by the cost of silicon decreasing by 50% the number of cells solar panels for the surface of the diopter entering on the one hand and a use of the light spectrum coming out of the outgoing diopter for various applications including the chroma-culture of different types of plants among others and to control the spectrum transmitted through the photovoltaic optical device for wavelengths according to the inclination of the latter.

Claims (2)

1 - Photovoltaic optical device with frontal plasmonic filtration and single concave and double convex rear variable multirefringence locally characterized in that it comprises: Rows of crystalline bifadial solar cells (1) having a front surface (lf) and a rear surface ( lr) of minimum photovoltaic conversion ratio of 80% and interconnected to form a matrix (2) encapsulated between an incoming diopter (4) and outgoing (7) whose distance (e) separating two rows is equal to or smaller than the segment of a solar cell (1) The surface taken in the plane of the matrix (2) forms an area (2s) a plasmonic filter (3) stuck on the incoming diopter (4) and positioned in parallel with a row of solar cells ( 1) in the interval (e) separating the solar cells (1) and centered on the median axis between two rows of cells so% of (e) A light transmission area (6S) consisting of the int ervalle (e) by a row of solar cells (1) A variable multirefringent variable filter (8) with concave single mirror and double convex locally (8c) adhered to the lower surface (7 ") of the outgoing diopter (7) covering the lower surface (7 ") of an area equal to the area (2s) and whose single concave and double convex zone (8c) of the filter (8) is positioned exactly in parallel superposition at any point in the area (6S) for reflect the light rays towards the rear face (1r) of the solar cells and towards the plasmonic filter (3) by divergence of the diffracted radii of the simple convex dichroic mirror (8c) and by convergence of the diffracted rays of the double concave dichroic mirror. the simple concave shape of the optical filter (8) must be positioned exactly and coincident with the median axis between two rows of solar cells (1) and the median axis of the plasmonic filter (3). 2 - Photovoltaic optical device with frontal plasmonic filtration and multilefringence variable rear single concave and double convex locally according to the preceding claim characterized in that the plasmonic filter (3) comprises: A film of a polymer (3p) selected from poly (terephthalate ethylene) (PET), polyolefin (PO), fluoropolymer (PVDF), polycarbonates, acrylates with bifacial micro-replication of a prismatic pattern (3 ") and (3 '") of lower segment or equal to 25 micron at an angle less than or equal to 60 ° a nanolamine compound (3r) composed of multi-layer materials selected from among silver, aluminum, silicon, gold, chromium, zinc, copper , Nickel, Cobalt, Lithium, Platinum Carbon Nanotubes, Boron Nitride, Aluminum Oxide A1203, Hafhium Oxide Hf02, Zirconium Oxide Zr02, Ternary Hafnium Aluminate Alloys HfxAlyOz, the alliag ternary aluminate zirconate ZrxAlyOz, ternary alloys hafnium zirconate HfxZryOz, quaternary alloys hafnia zirconate aluminate HfeZryAlzOi, titanium oxide TiO2 3 - Photovoltaic optical device with frontal plasmonic filtration and bire variable multirefringence simple concave and double convex locally according to the preceding claim characterized in that the plasmonic filter (3) has a length equal to the row of solar cells (1) constituting a reflective band bi-facial and has a width less than one third the interval (e) is e / 3 per unit of reflective tape. 4 - Photovoltaic optical device with frontal plasmonic filtration and bire-shaped diffuse multirefringence simple concave and double convex locally according to claim 1, characterized in that the front face (1f) of the matrix (2) of solar cells is encapsulated with the surface ( 4 ') of the incoming diopter (4) by an encapsulating material (5) chosen from silicones, acrylics and thermoplastics. 5 - Photovoltaic optical device with frontal plasmonic filtration and bire variable multirefringence simple concave and double convex locally according to claim No. 1 characterized in that the plasmonic filter (3) by its textured lower face (3 '") is oriented towards the face front view (lf) of solar cells (1) and that its textured upper face (3 ") is encapsulated between the surface (4") of the incoming diopter (4) by an encapsulating material (6) chosen from silicones, acrylics, thermoplastics. 6 - Photovoltaic optical device with frontal plasmonic filtration and single concave and double convex rear variable multirefringence locally according to claim 1, characterized in that the surface (8s) of the variable multirefringent filter (8) has an area equal to the area ( 2s) of the matrix (2) of solar cells (1) and constitutes three parallel planes between the plasmonic filter (3) and the matrix of cells (2) and the variable multirefringent filter (8) so that the dichroism resulting from the filter ( 8) is positioned on the surface (7 ") superimposed at any point of this area (2s) and in parallel at any point of this area (2s) behind the outgoing diopter (7) and the plasmonic filter (3). 7 - Photovoltaic optical device with frontal plasmonic filtration and concave single multirefringence rearward simple concave and double convex locally according to claim No. 1 characterized in that the variable multi-refractive filter (8) comprises: an interface (8i) of bonding from selected materials among the acrylics, the silicones a combination of layers (8a) and (8b) forming a nano-laminate each of which (8a) and (8b) varies in thickness between 2 Angstrom and 500 Angstrom each layer (8a) is the first and the last layer of nano-laminate with refractive index real part between 1.45 and 1.55 on the spectral band of 300 to 1600 nm layer (8b) is the combination of (8a) whose refractive index actual part varies between 1.6 and 2 on the spectral band of 300 to 1600nm. 8 - Photovoltaic optical device with frontal plasmonic filtration and concave single multirefringence rearward rearward and double convex locally according to claim 1 and claim 7 above characterized in that the variable multirefringent filter (8) consists of a dichroism between λ / 10 and λ / 2 of the incident spectrum for a given wavelength λ and whose interface (8i) can have a texturing of its surface in interface with (7 "). 9 - Photovoltaic optical device with frontal plasmonic filtration and concave simple multirefringence rear single and double convex locally according to claim 1 and 8 characterized in that the concave shape is acrylate material whose surface has the variable multirefringent filter and whose the diameter (Γ) of the convex shape is at most equal to the width of the filter (3) is e / 3 and whose depth (h ') must be less than (e / 3) to form a concave hyperbolic paraboloid dichroic mirror . 10 - Photovoltaic optical device with frontal plasmonic filtration and bitter variable multirefringence simple concave and double convex locally according to claim 1 and 8 characterized in that the convex form is acrylate material whose inner surface has the variable multirefringent filter and whose diameter (1 ") of the concave shape is at most equal to the width of the filter (3) is e / 3 and whose depth (h") must be less than (e / 3) to form a paraboloid dichroic mirror hyperbolic convex.