Abstract: A thin film solar cell module includes a substrate, at least one first cell positioned in a central area of the substrate, and at least one second cell positioned in an edge area of the substrate. Each of the first and second cells includes a first electrode, a second electrode, and at least one photoelectric conversion unit positioned between the first electrode and the second electrode. An amount of germanium contained in the photoelectric conversion unit of the first cell is less than an amount of germanium contained in the photoelectric conversion unit of the second cell positioned on the same level layer as the photoelectric conversion unit of the first cell.

Abstract: An embedded optical element package module uses a thermocouple, which increases the optical output efficiency of an optical element, dissipates high-temperature heat generated by the optical element having high output to prevent degradation, converts waste heat into electrical energy, and supplies the electrical energy as a power source for the optical element to reutilize resources, thereby reducing the amount of power consumed by the optical element and minimizing costs.

Abstract: The invention, the Concentrated Solar Thermoelectric Power System, herein abbreviated as C-STEPS, is a thermo-optical system configuration for the purpose of achieving a high solar energy-to-electricity conversion efficiency based on thermoelectric (TE) devices that use the Seebeck effect. It does so by implementing a system for concentrated solar energy using a design that combines a dual-function reflector/radiator component with an active or passive heat convection mechanism to ensure that TE module operation is maintained in a safe elevated temperature range with respect to the ambient temperature. Unsafe module temperatures are avoided by automatically adjusting the TE module hot side temperature directly or indirectly by regulating the TE cold side temperature using a variety of passive or active mechanisms, including the reflector/radiator component, phase change material, or convection/conduction mechanisms.

Abstract: Methods and devices for increase power output from solar devices. In one embodiment, the technique enables the front hot solar panel surface to be cooled by attachment of a thermoelectric multilayer stack to the back solar panel surface. The thermoelectric stack cools the solar panel front surface by drawing heat from the front to the back of the panel. That heat is transformed into mechanical vibrations using an inverse Peltier effect and that mechanical energy then transformed into electrical energy using a piezoelectric effect. Power output is first increased by lower operating temperature on front, resulting in a higher power conversion efficiency for the photovoltaic effect taking place in the CIGS/CdS active layers or other thin films, then from an additional power output from secondary electrical energy created from mechanical arising from the temperature-gradient driven occurrence of the thermoelectric effect.

Abstract: The invention relates to a photovoltaic device for direct conversion of solar energy into electrical energy, which comprises a concentrator lens system and at least one solar cell. Furthermore the invention relates to a method for producing a concentrator lens system which can be used in a corresponding photovoltaic device but also in other devices for, e.g. thermal, use of radiation.

Abstract: A solar cell employing nanocrystalline superlattice material and amorphous structure and method of constructing the same provides improved efficiency when converting sunlight to power. The photovoltaic (PV) solar cell includes an intrinsic superlattice material deposited between the p-doped layer and the n-doped layer. The superlattice material is comprised of a plurality of sublayers which effectively create a graded band gap and multi-band gap for the superlattice material. The sublayers can include a nanocrystalline Si:H layer, an amorphous SiGe:H layer and an amorphous SiC:H layer. Varying the thickness of each layer results in an effective energy gap that is graded as desired for improved efficiency. Methods of constructing single junction and parallel configured two junction solar cells include depositing the various layers on a substrate such as stainless steel or glass.

Abstract: Disclosed is a solar cell apparatus and manufacturing method thereof. A solar cell apparatus includes: a support substrate; a first back electrode disposed on the support substrate; a light absorber part disposed on the first back electrode; a buffer disposed on the light absorber part; and a barrier film disposed on a side surface of the light absorber part and extending from the buffer.

Abstract: In an embodiment of the disclosure, there is provided a strain isolation layer assembly. The assembly has a rigid solar layer; a strain isolation layer having a discontinuous configuration, a vertical rigidity, and a horizontal shear flexibility; and an underlying substrate layer. The strain isolation layer is coupled between the rigid solar layer and the underlying substrate layer to form a strain isolation layer assembly, such that the strain isolation layer isolates the rigid solar layer to reduce one or more strains induced on the rigid solar layer.

Abstract: A convective method is employed to cool a solar concentrator device. The convective method employs formation of a vortex gas circulation inside an enclosure of the solar concentrator device, which is bounded by at least one light-path altering component, sidewalls, and a back panel. Optionally, a heat sink assembly can be provided within the enclosure. Internal convention through the vortex gas circulation transfers the heat generated at a photovoltaic cell to all surfaces of the solar concentrator device to facilitate radiative and/or convective cooling at the outside surfaces of the enclosure.

Abstract: A wire harness connects multiple solar panel junction boxes to a recombiner box. The wire harness includes in-line fuse assemblies, with optional blocking diodes, so each string of solar panels is associated with one fuse. In the event of a blown fuse, only one upstream solar panel string is affected. Entire wire harnesses and/or individual in-line fuse assemblies can be easily swapped out, thereby decreasing the time and expense of troubleshooting and repairing.

Abstract: Disclosed is a multijunction compound semiconductor solar cell having a buffer layer between a first cell and a second cell. In the buffer layer, a plurality of semiconductor layers is arranged such that lattice constants thereof have larger values in order from the first cell side to the second cell side. Of the plurality of semiconductor layers, two layers having the largest difference in lattice constant among each two adjacent layers are disposed closer to the first cell than the center in the thickness direction of the buffer layer.

Abstract: A thermoelectric material including a compound represented by Formula 1 below: (R1-aR?a)(T1-bT?b)3±y??Formula 1 wherein R and R? are different from each other, and each includes at least one element selected from a rare-earth element and a transition metal, T and T? are different from each other, and each includes at least one element selected from sulfur (S), selenium (Se), tellurium (Te), phosphorus (P), arsenic (As), antimony (Sb), bismuth (Bi), carbon (C), silicon (Si), germanium (Ge), tin (Sn), boron (B), aluminum (Al), gallium (Ga), and indium (In), 0?a?1, 0?b?1, and 0?y<1.

Abstract: The disclosure provides a thermoelectric module and a method for fabricating the same. The thermoelectric module includes a plurality of p-type and n-type segmented thermoelectric elements disposed in a planar array, wherein the p-type and n-type segmented thermoelectric elements are coupled in series via a plurality of first electrodes and second electrodes. Each segmented thermoelectric element includes at least two vertically homogeneous thermoelectric segments, and at least two adjacent thermoelectric segments have a fusion-bonding layer therebetween. The fusion-bonding layer includes a tin-containing material and a plurality of spacers disposed among the tin-containing material, wherein the melting point of the spacers is higher than the liquidus temperature of the tin-containing material.

Abstract: The present invention is premised upon an improved photovoltaic device (“PV device”), more particularly to an improved photovoltaic device with a multilayered photovoltaic cell assembly and a body portion joined at an interface region.

Abstract: Disclosed is an organic photoelectric conversion element which has excellent photoelectric conversion efficiency and excellent temperature stability with respect to power generation. The organic photoelectric conversion element comprises at least one photoelectric conversion layer and at least one carrier transport layer between a first electrode and a second electrode, and is characterized in that the carrier transport layer contains the salt of an alkali metal or an alkaline earth metal or the complex thereof of an alkali metal or an alkaline earth metal.

Abstract: A solar conversion assembly comprises: a) a type III-V multiple cell stack solar cell device b) a silicon solar cell device c) a band splitting device located relative to the type III-V solar cell device and the silicon solar cell device. The band splitting device splits light falling on the splitting device into a plurality of wavelength bands and directs a first of said bands to the type III-V solar cell device and the second of said bands to the silicon solar cell device.

Abstract: Disclosed is a dye-sensitized solar cell. The dye-sensitized solar cell includes a working electrode and a counter electrode configured to join the working electrode. The working electrode includes a photo electrode having a plurality of photo electrode cells coated on a transparent conductive substrate and arranged in linear rows and a collector having a plurality of collector cells coated on the transparent conductive substrate and arranged along perimeters of the photo electrode and between the photo electrode cells and a collector bottom portion integrally interconnecting the collector cells. The collector cells have a same length or the collector cells arranged along the perimeters have a different length from the collector cells arranged between the photo electrode cells to increase an active area of the photo electrode.

Abstract: A foldable, portable, lightweight photovoltaic module has a carrier layer divided into equal sections separated by hinge spaces, a substrate layer on the carrier layer, and a photovoltaic cell layer on the substrate layer, wherein the hinge spaces each have a free space between opposing edges of the adjacent sections to enable them to be folded in accordion-like fashion for storage. The carrier layer may be made of rip-stop fabric and preferably supports 6 sections each with 6 PV cells of crystalline silicon of up to about 22% conversion efficiency. The module has a power output of about 122 watts at 24 volts, and weighs about 7.4 pounds (3.36 kg), with a power-to-size ratio of 14 watts/sft or more, and a power-to-weight ratio of 16.5 watts/pound or more. An improved method of lamination applies heat and pressure on upper and lower sides of the laminate layers through upper and lower chambers with respective pressure bladders and heaters that are independently controllable.

Abstract: The invention relates to a concentrator arrangement for solar radiation which has a beam splitter for deflecting solar radiation by means of total reflection. Furthermore, the invention relates to a device for concentrating and converting solar energy which has such a concentrator and at least one device for the conversion of solar energy. Such devices for the conversion of solar energy are for example solar cells, solar modules or thermal solar collectors. The concentrators according to the invention are used for concentrating solar radiation just as in sun protection panels.

Abstract: Proposed is a composite photovoltaic device with parabolic collector and different solar cells, wherein the high photoelectric conversion efficiency is achieved along with significant material cost reduction. The device comprises two or three solar cells formed on opposite sides of a transparent substrate, and a parabolic collector attached to the back side of the substrate. First thin film solar cell formed on the front side receives and converts to electricity a short-wavelength portion of the incoming Sun radiation, and transmits the long-wavelength portion. A second solar cell receives and converts to electricity a concentrated long-wavelength portion of the Sun radiation, which is re-directed toward a focal point by the parabolic collector. In one embodiment a third solar cell is included for converting an IR portion of the radiation. Thus, each solar cell utilizes a favorable part of the Sun spectrum, which allows for an enhancement of photoelectric efficiency and significant material cost reduction.