Abstract: The present invention is premised upon an improved photovoltaic device (“PV device”), more particularly to an improved photovoltaic device (10) with a multilayered photovoltaic cell assembly (100) and a body portion (200) joined at an interface region (410) and including an intermediate layer (500), at least one interconnecting structural member (1500), relieving feature (2500), unique component geometry, or any combination thereof.

Abstract: A multijunction solar cell including an upper first solar subcell, and the base-emitter junction of the upper first solar subcell being a homojunction; a second solar subcell adjacent to said first solar subcell; a third solar subcell adjacent to said second solar subcell. A first graded interlayer is provided adjacent to said third solar subcell. A fourth solar subcell is provided adjacent to said first graded interlayer, said fourth subcell is lattice mismatched with respect to said third subcell. A second graded interlayer is provided adjacent to said fourth solar subcell; and a lower fifth solar subcell is provided adjacent to said second graded interlayer, said lower fifth subcell is lattice mismatched with respect to said fourth subcell.

Abstract: A solar panel positioning assembly having at least one fluid filled tank that is connected to at least one piston. The fluid filled tank is shaded by a solar panel when the panel is perpendicular to the sun. When the panel is not perpendicular to the sun, the fluid filled tank is heated by the sun, causing the fluid to expand and increase pressure in the piston. As the pressure increases the piston moves the solar array until the solar panel is perpendicular to the sun.

Abstract: The invention provides processes for the manufacture of conductive transparent films and electronic or optoelectronic devices comprising same.

Abstract: A solar module having improved photoelectric conversion efficiency is provided. The solar module (1) is provided with a bifacial light-receiving solar cell (10), a transparent member (15), a weather-resistant member (14), and a bonding layer (13). The bonding layer (13) includes at least two media (13b, 13c) having different refractive indices. Interfaces (22, 23) are formed by at least two media (13b, 13c) and are positioned in a region unoccupied by the solar cells (10). The interfaces (22, 23) are configured such that at least some of the light that is incident on the interfaces (22, 23) in a direction (z) perpendicular to the solar module (1) is guided to the back surface (10b) of the solar cells (10).

Abstract: A structure capable of folding into a compact form for transporting, and for simple unfolding for attachment to a base, the structure including: two or more hingably interconnected solar panel arrays each having a two or more of solar panels, a solar panel support channel, and a support beam; wherein the two or more solar panels are attached to top portions of the solar panel support channel, and a bottom portion of the solar panel support channel is attached to a top portion of the support beam, the support beam having a hinged joint for cooperating in folding into mutual, near coplanar juxtaposition; and where the structure, when unfolded includes a solar canopy and is L-shaped viewed on end.

Abstract: The invention relates to a manufacturing method of an organic solar cell. First deposit in order a first electrode and a first transmission layer on a substrate. Then coat a photoresist layer having a preferred thickness ranging from 1000 nm to 1600 nm on the surface of the first transmission layer by a spin coater at a preferred spin-coating speed ranging from 3000 rpm and 6000 rpm for 30 seconds. Then develop an area by a photolithograph process, and coat an organic active layer in the area and on the surface of the photoresist layer by use of the spin coater at a preferred spin-coating speed ranging from 500 rpm and 800 rpm, in which the organic active layer has a thickness ranging from 230 nm to 320 nm at 500 rpm. Final deposit a second transmission layer and a second electrode on the organic active layer to obtain the organic solar cell.

Abstract: A paste containing a silica polymer, made by substituting at least some of the surface functional groups thereof with alkyl groups, and solvent-removable inorganic particles is prepared, and the paste is applied and fired to form a transparent insulating film in a dye-sensitized solar cell.

Abstract: A method of manufacturing a graphene-containing electrolyte includes, in the order recited: (a) deoxidizing graphene oxide to form graphene; (b) dissolving the graphene in a carbonate solvent to provide a graphene-containing solution; and (c) adding an oxidation-reduction agent composed of 1-butyl-2,3-dimethylimidazolium iodide (BDI) and optionally iodine (I2) into the graphene-containing solution to provide the graphene-containing electrolyte. Deoxidizing the graphene oxide may be accomplished by dissolving the graphene oxide in an aqueous solvent that is a mixture of water and an alkyl imidazole-based iodine to form a solution; and centrifuging the solution to obtain the graphene. A dye-sensitized solar cell may include the graphene-containing electrolyte to fill a space defined between first and second electrodes.

Abstract: A multi-layer thermoelectric module and a fabricating method thereof are provided. The module includes two thermoelectric element sets and a metal electrode set, in which the thermoelectric element sets are corresponding to different operating temperature ranges. Each thermoelectric element set includes a thermoelectric unit, an interfacial adhesion layer, a diffusion barrier layer and a high melting-point metal layer. In the method, the thermoelectric unit, the interfacial adhesion layer, and the diffusion barrier layer are sequentially formed on the thermoelectric unit. Then, two high melting-point metal layers are formed respectively on the electrode layers of the metal electrode set.

Abstract: A photoelectric conversion device includes a first cell including a photoelectric conversion layer, a second cell over the first cell including a photoelectric conversion layer formed of a material having a wider band gap than that of the first cell, first and second electrodes under a surface of the first cell which is opposite to the second cell, and a third electrode over a surface of the second cell which is opposite to the first cell. The first and second cells each include a p-n or p-i-n junction, the first and second cells are in contact with each other and a p-n junction is formed in a contact portion therebetween, the first cell is electrically connected to the first and second electrodes to form a back contact structure, and the second cell is electrically connected to the third electrode.

Abstract: A solar energy collection system can include support devices made with bearings formed from sheet material. These bearings can be optionally formed so as to provide tool-less connections to their associated bearing housings. The bearings can be formed with an open configuration allowing a shaft to be inserted into an open bite of the bearing. Optionally, the bearing can be made from an ultrahigh molecular weight polyethylene plastic material. Additionally, two open-type bearing assemblies can be mounted axially offset and opposed to one another.

Abstract: In one embodiment, harmful solar cell polarization is prevented or minimized by providing a conductive path that bleeds charge from a front side of a solar cell to the bulk of a wafer. The conductive path may include patterned holes in a dielectric passivation layer, a conductive anti-reflective coating, or layers of conductive material formed on the top or bottom surface of an anti-reflective coating, for example. Harmful solar cell polarization may also be prevented by biasing a region of a solar cell module on the front side of the solar cell.

Abstract: [Problem] To provide a photovoltaic device capable of generating power whether day or night, without affecting the appearance of a structure or reducing lighting or other functions, and able to inhibit rises in room temperature by converting thermal radiation into electrical energy. [Means to Solve Problems] Provide a photoelectric conversion element 3 with a photovoltaic device 1 on structural members 2a-2d facing the outside of a house or other structure. Power generated by the photoelectric conversion element 3 is extracted via a power extraction unit 4. The power conversion element 3 includes a semiconductor layer 11, conductive layer 20, a metal nanostructure 30 having multiple periodic structures 33, a first electrode 41 and a second electrode 42. The first and second electrodes 41, 42 are separated in the direction of the surface of the photoelectric conversion element 1 with the terminals 71, 81 of the power extraction unit 4 respectively connected.

Abstract: A solar cell element includes: a transparent body; a LixAg1-x layer (0.001?x?0.05) having a thickness (2-15 nm); a ZnO layer having an arithmetical mean roughness (20-760 nm); a transparent conductive layer; and a photoelectric conversion layer including n-type and p-type layers, further includes n-side and p-side electrodes, the ZnO layer is composed of ZnO columnar crystal grains grown on the LixAg1-x layer; each ZnO grain has a longitudinal direction along a normal line of the body, and has a width increasing from the LixAg1-x layer toward the transparent conductive layer, and has a width which appears by cutting each ZnO grain along the normal line, and has a R2/R1 ratio (1.1-1.6); where R1 represents the width of one end of the ZnO grain, the one end being in contact with the surface of the LixAg1-x layer; and R2 represents the width of the other end of the ZnO grain.

Abstract: Substrates may be bonded according to a method comprising contacting a first bonding surface of a first substrate with a second bonding surface of a second substrate to form an assembly; and compressing the assembly in the presence of an oxidizing atmosphere under suitable conditions to form a bonding layer between the first and second surfaces, wherein the first bonding surface comprises a polarized surface layer; the second bonding surface comprises a hydrophilic surface layer; the first and second bonding surfaces are different.

Abstract: The present invention provides a compound useful as a photoelectric conversion dye having excellent photoelectric conversion performance. The compound according to the present invention is a thiazole-based compound represented by the following general formula (1), a tautomer or stereoisomer thereof, or a salt thereof. In the general formula (1), R1 represents a hydrogen atom, a substituted or unsubstituted, linear or branched alkyl group, or a substituted or unsubstituted aryl group, R2 represents a hydrogen atom, a substituted or unsubstituted, linear or branched alkyl group, or a cyano group, D represents an organic group comprising an electron-donating substituent, Z represents a linking group having a heteroaromatic ring or at least one hydrocarbon group selected from the group consisting of an aromatic ring, a vinylene group (—CH?CH—), or an ethynylene group (—C?C—), and M represents a hydrogen atom or a salt-forming cation.

Abstract: Providing a dye-sensitized solar cell having high durability and thermal resistance, and preventing elution of a platinum group catalyst from a catalytic electrode: by surface-treating the catalytic electrode with (a) a specific sulfur material having a molecular weight of 32 to 10,000 containing a sulfur atom having an oxidation number of ?2 to 0, (b) another specific sulfur material containing no sulfur atom having an oxidation number of ?2 to 0, but containing a sulfur atom having an oxidation number of +1 to +4 [with the proviso that the sulfur material (b) is such a material that a surface of the surface-treated catalyst electrode has a photoelectron peak within a binding energy range of 161 to 165 eV in an X-ray photoelectron spectrum], or (c) a mixture of the sulfur materials (a) and (b); and/or by adding the sulfur material into the electrolyte layer.

Abstract: An electrode for a photovoltaic device includes a Mo layer and a sulfurization-resistant layer formed on the Mo layer. The sulfurization-resistant layer contains at least one element X selected from a group consisting of Nb, Ti, Ta, Au, V, Mn, and W. A molar ratio of the element X to Mo contained in the sulfurization-resistant layer preferably satisfies X/(Mo+X)>about 0.5. A thickness (initial thickness) of the sulfurization-resistant layer before being exposed to sulfurizing atmosphere is preferably about 3 to about 200 nm.

Abstract: A power converter is provided and includes a heat collector surface, n- and p-legs formed of n- and p-type thermoelectric materials, respectively, which are each disposed in thermal communication with the heat collector surface, parallel electric busses electrically coupled to the n- and p-legs and a housing, which is electrically decoupled from the busses, to support the heat collector surface at a predefined distance from a heat pipe.