Abstract: This invention provides an inorganic coating-protected unitary graphene material article for concentrated photovoltaic cell heat dissipation. The article comprises at least a layer of unitary graphene material having two primary surfaces and an electrically non-conducting layer of inorganic coating deposited on at least one of the primary surfaces, wherein the unitary graphene material is obtained from heat-treating a graphene oxide gel at a heat treatment temperature higher than 100° C. and contains chemically bonded graphene molecules or chemically merged graphene planes having an inter-graphene spacing no greater than 0.40 nm, preferably less than 0.337 nm, and most preferably less than 0.3346 nm.

Abstract: A laminate sheet including a layer containing a polyester resin as a main component (P1 layer), an adhesive resin layer (P2 layer), and a layer containing a polyolefin resin as a main component (P3 layer), wherein the laminate sheet has a total thickness of at least 30 ?m and up to 500 ?m, the P2 layer has a thickness of at least 0.1 ?m and up to 3 ?m, and a ratio of the thickness of the P1 layer (P1) to the thickness of the P3 layer (P3) (ratio P1/P3) is at least 0.2 and up to 5.

Abstract: Disclosed are polyolefin copolymer films comprising alkoxysilane groups and a catalyst for cross-linking the alkoxysilane groups; wherein the cross-linking catalyst is a Lewis or Bronsted acid or base compound that has a relatively high melting point and therefore initiates the cross-linking essentially only at the lamination temperature, preferably at or above at least 50° C. Also disclosed are films wherein (i) the layer or layers comprising the alkoxysilane groups, including surface layer(s), comprise the cross-linking catalyst; or (ii) layer or layers comprising alkoxysilane groups do not contain cross-linking catalyst and have a facial surface in adhering contact with a layer of a thermoplastic polyolefin copolymer comprising the cross-linking catalyst; or (iii) there is a combination of layers (i) and (ii). Also disclosed are laminated glass structures and processes for their preparation that employ such films. The disclosed laminate structures include safety glass and photovoltaic modules.

Abstract: Provided is a solar cell module wherein solar cells and a sealing material, which is sealing the solar cells, are not easily peeled from each other. A solar cell module is provided with solar cells, a wiring material, and a sealing material. Each of the solar cells has first and second main surfaces. The wiring material is electrically connected to each of the solar cells on the first main surface. The sealing material seals the solar cells. The sealing material has a first sealing section and a second sealing section. The first sealing section contains a non-bridging resin. The first sealing section is positioned on the first main surface side of the solar cells. The second sealing section contains a bridging resin and pigment. The second sealing section is positioned on the second main surface side of the solar cells.

Abstract: An encapsulating material for solar cell containing an ethylene/?-olefin copolymer satisfying the following a1) and a2), and a specific peroxyketal having a 1-hour half-life temperature in a range of 100 to 135 degrees centigrade; the peroxyketal being contained in an amount of 0.1 to less than 0.8 weight parts relative to 100 weight parts of the ethylene/?-olefin copolymer. a1) the shore A hardness is from 60 to 85 as measured in accordance with ASTM D2240. a2) MFR is from 2 to 50 g/10 minutes as measured under the conditions of a temperature of 190 degrees centigrade and a load of 2.

Abstract: A photovoltaic element including a resonator is arranged on a semiconductor structure (5) that is constituted by a region without electromagnetic damping (5a), whose upper plane forms the plane of incidence (3), and a region with electromagnetic damping (5b), both regions being bound by virtual boundaries (6) of variation in material properties. At least one 2D-3D resonator (4) is surrounded by a dielectric (10) and configured on the semiconductor structure (5), with a relative electrode (11) bordering on the region with electromagnetic damping (5b). The photovoltaic element having a resonator arranged on a semiconductor structure (5) uses the structure (5) and its characteristics to set suitable conditions for the impingement of an electromagnetic wave and its transformation to a stationary form of the electromagnetic field and not to secure the generation of an electric charge.

Abstract: An aspect of the invention provides a solar cell module, which comprises a solar cell with a light-receiving surface and a back surface, a first protection member disposed at a light-receiving surface side of the solar cell and made of a glass plate, a second protection member disposed at a back surface side of the solar cell, and a filler layer provided between the first protection member and the second protection member and sealing the solar cell. At least part of a portion of the filler layer situated at the back surface side of the solar cell contains an acidic additive.

Abstract: A light harvesting system employing a photoresponsive layer having a plurality of light input ports that are formed in a light input surface of the layer. Light received by the light input ports is admitted into the photoresponsive layer an incidence angle that is greater than a predetermined critical angle, such as the angle of the total internal reflection (TIR). The admitted light is retained in the photoresponsive layer and is propagated within the layer until it is substantially absorbed.

Abstract: A photoelectric conversion device is disclosed. In one embodiment, the device includes i) first and second substrates facing each other, wherein first and second electrodes are formed on the first and second substrates, respectively and ii) an electrolyte inlet formed to pass through the first substrate and configured to receive an electrolyte. The device may further include an inlet sealing member connected to an external surface of the first substrate and outwardly extending from a top portion of the electrolyte inlet, wherein the top portion is formed in the external surface of the first substrate, and wherein the inlet sealing member comprises an encapsulation space being in fluid communication with the electrolyte inlet.

Abstract: In at least one aspect of this disclosure, a photovoltaic module includes a frame, at least one photovoltaic cell disposed on the frame, a photovoltaic junction box electrically connected to the at least one photovoltaic cell and having a first photovoltaic junction box terminal and a second a photovoltaic junction box terminal, a first frame terminal electrically connected to the first photovoltaic junction box terminal via a first wire disposed within the frame, a second frame terminal electrically connected to the second photovoltaic junction box terminal via a second wire disposed within the frame, a third frame terminal, and a fourth frame terminal electrically connected to the third frame terminal via a third wire.

Abstract: In order to obtain a composite glass plate which shields infrared light and/or ultraviolet light, two glass substrates on which transparent conductive layers are formed respectively are disposed with the transparent conductive layers thereof facing each other. Infrared light is shielded and electric power is generated by using one glass substrate as a light incident side electrode, disposing a silicon dioxide particle layer thereon, and filling a colorless electrolyte between the two glass substrates. Further, ultraviolet light is also shielded by disposing a titanium dioxide layer on the other glass substrate. This composite glass plate is used as a window glass plate to shield only infrared light and/or ultraviolet light and transmit only visible light.

Abstract: Mounting systems for PV modules and assemblies of modules, including apparatus and methods of use. The disclosed systems generally involve mounting a flexible photovoltaic module in a slight arch, bending it with a large radius around one axis of the module.

Abstract: A light concentration module includes a primary light concentration plate, a light concentration component and an electricity generation module. The primary light concentration plate includes a primary light concentration surface and a light-emitting surface. The primary light concentration surface is used for collecting light. The light-emitting surface is used for emitting light collected by the primary light concentration surface. The light concentration component includes a first surface and a second surface. The first surface collects light from the light-emitting surface. The area of the first surface is larger than the area of the second surface. The second surface is used for emitting light collected by the first surface. The electricity generation module is used for converting energy from light into electricity.

Abstract: This invention relates to a polymer/inorganic multi-layer encapsulation film, and more particularly, to a multi-layer encapsulation film, which includes a plasma polymer thin film layer formed using a cross-shaped precursor having Si—O bonding and an inorganic thin film layer, and ensures flexibility and has improved encapsulation.

Abstract: A method of producing a solar cell module including forming a silicon oxide layer by coating a paint containing at least one of silicate hydrolysis products and silica particles on at least one side of a base film; and adhering said silicon oxide layer with a silicone sealing material layer.

Abstract: A solar cell with an electrode lead-out structure that a unitary cell to be easily mounted on and removed from a connection side substrate is provided. A solar cell has a power generation electrode including a transparent electrode, a collector electrode, and a power generation layer formed on a translucent substrate and is arranged opposite an opposite electrode so that the power generation layer is sandwiched between the power generation electrode and the opposite electrode. A through-hole is formed in a substantially central portion of the translucent substrate. Another through-hole is formed in another substrate and its periphery forms an annular exposed portion that does not overlap the opposite electrode. A lead-out portion for the collector electrode is formed on the exposed portion. Metal thin films are connected together to form lead-out portions. Thus, a positive electrode and a negative electrode are led out in the same direction.

Abstract: The present invention provides a solar cell module comprising at least one encapsulant layer which has 1) a total thickness of from about 0.1 to about 20 mils and 2) at least one surface layer made of ionomers containing a finite amount of polymerized residues of ?-olefins and from about 18 to about 25 wt % of polymerized residues of ?,?-ethylenically unsaturated carboxylic acids. The present invention also provides a process of manufacturing the solar cell module.

Abstract: The present invention relates to organic optoelectronic devices and, in particular, to organic photovoltaic devices having a fiber structure. In one embodiment, a photovoltaic device comprises a first electrode comprising an indium tin oxide fiber, at least one photosensitive organic layer surrounding the first electrode and electrically connected to the first electrode, and a second electrode surrounding the organic layer and electrically connected to the organic layer.

Abstract: The present invention disclosure provides a spectrally selective panel that comprises a first material being at least partially transmissive for light having a wavelength in the visible wavelength range and being arranged for guiding suitable light. Further, the panel comprises a diffractive element being positioned in, at or in the proximity of the first material. The diffractive element is arranged to deflect predominantly light having a wavelength in an IR wavelength band. The first material is arranged and the diffractive element is oriented such that at least a portion of energy associated with IR light incident from a transversal direction of the spectrally selective panel is directed along the panel towards a side portion of the panel.

Abstract: A polymeric film or sheet comprising an ionomeric composition comprising ionomeric copolymer of an alpha olefin and about 1 to about 30 wt % of alpha,beta-ethylenically unsaturated carboxylic acid having 3 to 8 carbons, based on the total weight of the ionomeric copolymer, wherein the carboxylic acid is neutralized to a level of 1 to 100 mol %, with one or more metal ions, based on the total number of moles of carboxylate groups in the ionomeric copolymer, and wherein the ionomeric copolymer has a Melt Index of about 20 to about 300 g/10 min. The ionomeric composition preferably comprises an additive selected from the group consisting of silane coupling agent, organic peroxide, and combinations thereof. In addition, an article comprising an interlayer formed of the polymeric film or sheet and an additional layer selected from the group consisting of glass, other polymeric interlayer sheets, polymeric film layers, and metal films or sheets. Examples of articles include safety windows and solar cells.

Abstract: A photovoltaic apparatus includes at least one photovoltaic panel, at least one frame and at least one fastener. The frame includes at least one pair of holding parts, a sidewall and at least one protrusion. The photovoltaic panel is positioned between the holding parts. Part of the sidewall connects the holding parts. The sidewall includes an outside surface opposite to the photovoltaic panel. The protrusion is connected to the outside surface of the sidewall, and includes at least one slot thereon. The fastener includes a buckle part at the top of the fastener. Portion of the buckle part is used for engaged into the slot.

Abstract: According to one aspect, there is provided a solar energy converter, including: a lens; a base plate having a first surface that faces the lens and a second surface that is opposite to the first surface; and a solar cell sandwiched between the lens and the base plate, wherein both the lens and the base plate are each provided with at least one channel for fluid for cooling the solar cell. Also contemplated is provision of at least one fin on both the lens and the base plate for cooling the solar cell. According to a second aspect, there is provided a method for cooling a solar energy converter having a lens, a base, and at least one solar cell sandwiched between said lens and said base plate, the method comprising the step of: cooling the at least one solar cell on two opposing sides.

Abstract: A method for forming a laminated photovoltaic structure includes providing a sheet of transparent material having light concentrating features, disposing adhesive material adjacent to the sheet of transparent material, disposing photovoltaic strips adjacent to the adhesive material, wherein the photovoltaic strips are positioned relative to the sheet of transparent material in response to exitant light characteristics of the light concentrating features, wherein photovoltaic strips are coupled via associated bus bars, wherein gap regions are located between bus bars of neighboring photovoltaic strips, disposing a rigid layer of material adjacent to the photovoltaic strips to form a composite photovoltaic structure; and thereafter laminating the composite photovoltaic structure to fill the gap regions with adhesive material and to form the laminated photovoltaic structure, wherein adhesive material adheres to the bus bars.

Abstract: A solar energy harvester comprises: an elongated stationary solar irradiance converter assembly; a concentrator comprised of a substantially flat array of flat reflective heliostatic slats disposed at tilt angles to concentrate the sun onto the converter assembly, said slats each rotating in elevation about a north-south axis; sun sensor detecting the efficacy of concentration as the sun traverses; and control circuitry and drive motor positioning the collector in elevation according to the sun sensor so that the slat array tracks and faces the sun whenever the solar incident energy is greater than a selectable threshold level.

Abstract: An energy collection system is provided. The system can include an energy collection device and an energy concentration device disposed proximate at least a portion of the energy collection device. The energy concentration device includes a non-periodic, sub-wavelength, dielectric grating.

Abstract: Nanoparticles are used to enhance the light gathering and converting abilities of a photo voltaic (PV) cell. The nanoparticles may be incorporated into a substrate and disposed a desired distance from the PV cell to create a plasmon. The nanoparticles may effect a wavelength shift (e.g., a “red shift”) to better align the wavelength of available light with the sensitivity of the PV cell. The nanoparticles may also be used to trap the light above the PV cell to effect better absorption of the light. The nanoparticles may include composite nanoparticles having, for example, a metallic core and a substantially transparent shell or coating about the core. The nanoparticles may be constructed to provide uniform distribution in a carrier medium.

Abstract: A solar module with a front support, a back support, and a photovoltaic active material located between the front and back supports. An electrically insulative light transmissive seal is located at the peripheral edges of the front support and back support to electrically isolate the active material from the outer surfaces of the solar module.

Abstract: An organic electronic device includes at least an organic-inorganic layered barrier layer, a plastic support, a transparent electrode layer, an organic active layer, a metal electrode layer and an upper sealing member, and contains a strong acid polymer, wherein an n-type oxide semiconductor layer is provided adjacent to the metal electrode layer on the plastic support-side of the metal electrode layer.

Abstract: An energy conversion device includes a holographic lens arranged between a glass slab and the first solar cell. The holographic lens is configured to concentrate a portion of a first component of impinging electromagnetic radiation onto the first solar cell and direct a portion of a second component of the electromagnetic radiation away from the first solar cell. The first solar cell is a back contact solar cell configured to convert the first component of the electromagnetic radiation into electrical energy.

Abstract: In an example, a solar energy system includes multiple PV modules, multiple reflectors, and a racking assembly. Each of the reflectors is positioned opposite a corresponding one of the PV modules. The racking assembly mechanically interconnects the PV modules and the reflectors to form an interconnected system. The racking assembly defines gaps within the racking assembly and between adjacent PV modules and reflectors. The interconnected system includes multiple contact points associated with the gaps. The gaps and contact points configure the interconnected system to accommodate surface unevenness of an installation surface up to a predetermined surface unevenness.

Abstract: Embodiments of the invention include a solar cell and methods of forming a solar cell. Specifically, the methods may be used to form a passivation/anti-reflection layer having desired functional and optical properties on a solar cell substrate. In one embodiment, a method of forming an anti-reflection layer on a solar cell substrate, the method includes flowing a first processing gas mixture into a processing chamber, wherein the first processing gas mixture includes at least a silicon containing gas and a nitrogen containing gas, wherein a ratio by flow volume of the silicon containing gas to the nitrogen containing gas supplied to the first processing gas mixture is controlled at between about 2:1 to about 1:5, applying a source RF power to the processing chamber in the presence of the first processing gas mixture, controlling the process pressure under 100 mTorr, and forming a silicon nitride containing layer on the substrate.

Abstract: A solar cell receiver for use in a concentrating solar system which concentrates the solar energy onto a solar cell for converting solar energy to electricity. The solar cell receiver may include a solar cell mounted on a support and with one or more III-V compound semiconductor layers. An optical element may be positioned over the solar cell and have an optical channel with an inlet that faces away from the solar cell and an outlet that faces towards the solar cell. A frame may be positioned over the support and extend around the solar cell with the frame having an inner side that extends above the support and faces towards the optical element. An encapsulant may be positioned over the support and contained between the optical element and the frame. The encapsulant may have enlarged heights at contact points with the optical element and the frame and a reduced height between the contact points away from the optical element and the frame. The solar cell receiver may be used in a solar cell module.

Abstract: A device for dissipating heat from a photovoltaic cell is disclosed. A first thermally conductive layer receives heat from the photovoltaic cell and reduces a density of the received heat. A second thermally conductive layer conducts heat from the first thermally conductive layer to a surrounding environment. An electrically isolating layer thermally couples the first thermally conductive layer and the second thermally conductive layer.

Abstract: An apparatus for collecting solar energy, including a first panel, wherein the first panel allows at least 50% of incident light having a wavelength in the range of 1 nm to 1,500 nm to pass through said panel and a second panel, wherein the second panel allows at least 50% of incident light having a wavelength in the range of 410 nm to 650 nm to pass through said panel. A photovoltaic cell is disposed between the first panel and second panel, which includes a first electrode disposed adjacent to the first panel, a second electrode disposed adjacent to the second panel, a photovoltaic component contacting the first and second electrodes. The photovoltaic component absorbs at least 50% of light having a wavelength in one of the following ranges: greater than 650 nm, less than 410 nm and combinations thereof.

Abstract: A device for dissipating heat from a photovoltaic cell is disclosed. A first thermally conductive layer receives heat from the photovoltaic cell and reduces a density of the received heat. A second thermally conductive layer conducts heat from the first thermally conductive layer to a surrounding environment. An electrically isolating layer thermally couples the first thermally conductive layer and the second thermally conductive layer.

Abstract: A light concentrator of an embodiment includes: a first high refractive index layer, a first low refractive index layer, and a second high refractive index layer stacked in sequence, wherein a surface on the first low refractive index layer side of the first high refractive index layer has a periodic concavoconvex region.

Abstract: A thin film photovoltaic cell structure (1) comprises a substrate (2); a first dielectric layer (3) on the substrate (2); an active layer (4) on the first dielectric layer (3); and a plasmonic light concentrator arrangement (5) on the active layer (4) for coupling incident light at a first wavelength band into the active layer (4). According to the present invention, the thin film photovoltaic cell structure (1) further comprises a second dielectric layer (6) formed of a dielectric material which is transparent at the first wavelength band and at a second wavelength band on the plasmonic light concentrator arrangement (5); the first dielectric layer (3), the active layer (4), the plasmonic light concentrator arrangement (5), and the second dielectric layer (6) being configured to form a resonant cavity for coupling incident light at the second wavelength band into a standing wave confined in the resonant cavity.

Abstract: An apparatus for generating electricity using an optical fiber cable light source and for directing the electricity to an electrical circuit configured to be coupled with an electric utility's electric grid. The apparatus includes an enclosure having an input configured to be coupled with the light source for directing light into the enclosure. The apparatus further includes a photovoltaic module contained within the enclosure and configured to generate electricity from the light. The apparatus further includes an electrical output cable coupled with the photovoltaic module and configured to be coupled with the electrical circuit.

Abstract: A light trapping optical cover employing an optically transparent layer with a plurality of light deflecting elements. The transparent layer is configured for an unimpeded light passage through its body and has a broad light input surface and an opposing broad light output surface. The light deflecting elements deflect light incident into the transparent layer at a sufficiently high bend angle with respect to a surface normal and direct the deflected light toward a light harvesting device adjacent to the light output surface. The deflected light is retained by means of at least TIR in the system formed by the optical cover and the light harvesting device which allows for longer light propagation paths through the photoabsorptive layer of the device and for an improved light absorption. The optical cover may further employ a focusing array of light collectors being pairwise associated with the respective light deflecting elements.

Abstract: Provided is a solar module with improved reliability. A solar module (1) is provided with a solar cell (10), a wiring member (11), a resin adhesive layer (12), and a buffer region (40). The wiring member (11) is electrically connected to the solar cell (10). The resin adhesive layer (12) bonds the solar cell (10) and the wiring member (11) to one another. The buffer region (40) is provided at least partially between the wiring member (11) and the solar cell (10). The buffer region (40) contains a non-crosslinked resin.

Abstract: This disclosure provides systems, methods and apparatus that can generate PV power and simultaneously provide artificial lighting. The devices disclosed herein include a first optical structure having a plurality of focusing elements that can collect and focus ambient light onto a first set of light redirecting elements that is optically coupled to one or more photovoltaic (PV) cells. The devices also include one or more illumination sources that are optically coupled to a light guide including a second set of light redirecting elements that can direct light from the one or more illumination sources out of the device to provide artificial lighting. The devices further include a second optical structure disposed below the first optical structure such that the one or more illumination sources and the one or more PV cells are disposed along the edges of the first or the second optical structure.

Abstract: A silicon wafer-based photovoltaic module is described, which includes a first outer protective layer and a second outer protective layer, wherein both outer protective layers comprise a low- or no-sodium glass or low- or no-alkali compositions. The photovoltaic modules show resistance to water ingress, no or reduced potential-induced sodium ion drift, and reduced potential induced degradation.

Abstract: A machine, manufacture, article, process, and product produced thereby, as well as necessary intermediates, which in some cases, pertains to power sources, units thereof, etc. Illustratively, the machine can include a convertor, such as a photovoltaic cell, located to produce current that is not essentially steady direct current by repeatedly shadowing the photovoltaic convertor from exposure to radiation such that at least some of the radiation shadowed from the photovoltaic convertor either produces electricity or is reflected to an emitter which subsequently reemits radiation to the photovoltaic convertor or to another photovoltaic convertor.

Abstract: A solar energy collector system (32) has a fixed array (34) of reflectors (40) extending in parallel rows, and a common focal receiver (36) located above the fixed array (34) and extending parallel to the rows of reflectors (40). Incident solar radiation from all of the reflectors is reflected upon the receiver (36) which includes a heat absorbing medium adapted to absorb heat from the reflected radiation. There is an elevated support structure (38) for the fixed array (34) of reflectors and the receiver (36). The support structure (38) orients each row of reflectors at a respective fixed angle relative to the support structure. The support structure (38) is pivotally mounted to an upright elevation assembly (77) to allow controlled rotation of the fixed array (34) and receiver (36) simultaneously about a pivotal axis (39) extending parallel to the rows of reflectors (40) so as to track the movement of the sun.

Abstract: A concentrator photovoltaic device includes: an optical concentrator; a solar battery cell; a homogenizer; a sealant; and a light transmission preventing layer. The homogenizer has a trapezoidal shape in which a sectional area at the optical concentrator side is larger than a sectional area at the solar battery cell side, a relationship of nh>nf>nt is satisfied among a refractive index nh of the homogenizer, a refractive index nf of the sealant, and a refractive index nt of the light transmission preventing layer, a thickness (H) of the light transmission preventing layer is equal to or larger than 0.1 mm and equal to or smaller than 1.2 mm, and a relationship of 0.5?b/a<1.0 is satisfied between a height (b) of the light transmission preventing layer and a height (a) of the sealant at a position where the light transmission preventing layer is formed.

Abstract: A protective transparent enclosure (such as a glasshouse or a greenhouse) encloses a concentrated solar power system (e.g. a thermal and/or a photovoltaic system). The concentrated solar power system includes one or more solar concentrators and one or more solar receivers. Thermal power is provided to an industrial process, electrical power is provided to an electrical distribution grid, or both. In some embodiments, the solar concentrators are dish-shaped mirrors that are mechanically coupled to a joint that enables rotation at a fixed distance about respective solar collectors that are fixed in position with respect to the protective transparent enclosure. In some embodiments, the solar collectors are suspended from structure of the protective transparent enclosure and the solar concentrators are suspended from the solar collectors. In some embodiments, the greenhouse is a Dutch Venlo style greenhouse.

Abstract: Provided is an encapsulant for a solar cell which is highly anticorrosive and can form a solar cell module with a long life. Also provided is an interlayer film for laminated glass, which is highly anticorrosive and can form a laminated glass with long-term durability. The encapsulant for a solar cell or the interlayer film for laminated glass includes a material having a polyvinyl acetal content of 40% by mass or more and a chlorine content of 25 ppm or less and having a plasticizer content of 10 parts by mass or less based on 100 parts by mass of polyvinyl acetal.

Abstract: The present invention relates to a solar cell capable of maximizing a concentrating area and cell efficiency by disposing a cell in a progress direction of light, that is, in a vertical direction to a concentrating direction.

Abstract: A low-cost system for increasing the electricity generation of flat panel photovoltaic (PV) farms in which sunlight redirecting elements are positioned in offset spaces provided between adjacent panel assemblies and serve to redirect otherwise unused sunlight onto solar cells disposed on one of the panel assemblies. The redirecting elements are located in a prismatic volume bounded at its upper end by an inclined upper plane that extends across the offset space separating adjacent PV panel assemblies. The redirecting elements are either mounted to at least one of the PV panel assemblies, or placed on the ground between the assemblies. Each redirecting element includes multiple reflecting and/or refracting surfaces that utilize a disclosed microoptical arrangement (e.g., focus and steer or reorient and scatter) to distribute the redirected sunlight in a substantially homogenous (uniform) distribution on the solar cells.

Abstract: A solar cell unit comprising a cylindrical shaped solar cell and a transparent tubular casing is provided. The tubular shaped solar cell comprises a back-electrode, a semiconductor junction circumferentially disposed on the back-electrode and a transparent conductive layer disposed on the semiconductor junction. The transparent tubular casing is circumferentially sealed onto the transparent conductive layer of the cylindrical shaped solar cell. A solar cell unit comprising a cylindrical shaped solar cell, a filler layer, and a transparent tubular casing is provided. The cylindrical shaped solar cell comprises a cylindrical substrate, a back-electrode circumferentially disposed on the cylindrical substrate, a semiconductor junction circumferentially disposed on the back-electrode, and a transparent conductive layer disposed on the semiconductor junction.