Abstract: Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for a dynamic solar tile network. In one aspect, a method includes designating a first solar tile in a set of solar tiles as a control tile. Selecting a subset of solar tiles in the set of solar tiles as controlled tiles that are each controlled by the control tile to form a solar tile network that includes the control tile and the controlled tiles. Receiving, at the control tile, status information from each of the controlled tiles. Determining, by the control tile, an operational state for each of the controlled tiles based on the status information. Transmitting, by the control tile, operation instructions to the controlled tiles that cause each controlled tile to switch to the operational state determined by the control tile.

Abstract: A solar cell apparatus according to the embodiment includes a substrate including a top surface and a bottom surface which are opposite to each other; a back electrode layer on the top surface of the substrate; a light absorbing layer on the back electrode layer; a front electrode layer on the light absorbing layer; a connecting member on the bottom surface of the substrate; and a bus bar connected to the connecting member, wherein the bus bar comprises: an electrode contact portion making contact with the back electrode layer; and a substrate contact portion making contact with the substrate.

Abstract: A multiple layer composition and method for deposition of a solar energy harvesting strip onto a driving surface that will allow electric cars to charge by an inductive coupling is provided. The multiple layer composition includes at least one magnetic material for generating a magnetic field, wherein at least one of the multiple layers comprises the magnetic material. Further, the a multiple layer composition includes at least one solar energy harvesting material for converting at least one of thermal and photonic energy into electrical energy, wherein at least one of the multiple layers comprises the at least one solar energy harvesting material and wherein the at least one solar energy harvesting material is located within a magnetic field generated by the at least one magnetic material. One of the layers may also include a thermal energy harvesting material for converting thermal energy into electrical energy.

Abstract: A thermoelectric module having a first and second housing element, at least two thermoelectric elements arranged between the housing elements and are each connected electrically to one another via first or second electrical contacts or are connected electrically to an electrical circuit via first and/or second electrical contacts. The first electrical contacts are assigned to the first housing element and the second electrical contacts are assigned to the second housing element. The first housing element and/or the second housing element have at least one opening, which is covered by at least one section of the first electrical contacts and/or the second electrical contacts. The first electrical contacts and/or the second electrical contacts are connected to the first housing element and/or the second housing element.

Abstract: Disclosed is a solar cell apparatus. The solar cell apparatus includes a first substrate including a first region and a second region adjacent to the first region, a plurality of solar cells in the first region, and a second substrate provided in the first region to expose the second region and provided on the solar cells.

Abstract: A photosensitive device and method includes a top cell having an N-type layer, a P-type layer and a top intrinsic layer therebetween. A bottom cell includes an N-type layer, a P-type layer and a bottom intrinsic layer therebetween. The bottom intrinsic layer includes a Cu—Zn—Sn containing chalcogenide.

Abstract: According to the embodiment, there is provided a solar cell including: a back electrode layer; a light absorbing layer on the back electrode layer; a buffer layer on the light absorbing layer; and a front electrode layer on the buffer layer, wherein the front electrode layer comprises an intrinsic region and a doping region having a conductive dopant, and a concentration of the conductive dopant is gradually lowered in upward and downward directions from an excess doping region of the doping region.

Abstract: A photovoltaic (PV) device including: (a) a p-n junction having (i) p-type silicon substrate with an Al-doped P++ surface, (ii) a wide band intrinsic AlP region having a first side formed on the Al-doped P++ surface of the silicon substrate, and (iii) an Si-doped n++ surface formed on a second side of the AlP region that is opposite to the first side; (b) charged quantum dots formed on the Si-doped n++ surface of the p-n junction and optionally (c) an electrode connected to each side of the device; wherein the charged quantum dots are operatively linked to the p-n junction to enable electrons harvested from IR photons absorbed by the quantum dots to be harvested with electrons harvested from photons absorbed by the p-n junction and wherein the wide band intrinsic AlP region is configured to inhibit leakage of hole current. Also, a method for forming the PV device.

Abstract: A photovoltaic (PV) module includes an absorber layer coupled to an optic layer. The absorber layer includes an array of PV elements. The optic layer includes a close-packed array of Keplerian telescope elements, each corresponding to one of an array of pupil elements. The Keplerian telescope substantially couple radiation that is incident on their objective surfaces into the corresponding pupil elements. Each pupil element relays radiation that is coupled into it from the corresponding Keplerian telescope element into the corresponding PV element.

Abstract: Electrical power is produced by a first process component, a first heat pipe formed in part by a first cavity within the first process component, and a thermoelectric generator assembly. The thermoelectric generator assembly is thermally coupled on one side to a heat sink and on the other side to the first heat pipe. The first process component is in direct contact with a first process fluid and the first cavity is proximate the first process fluid. The thermoelectric generator assembly produces electrical power.

Abstract: Embodiments disclosed herein relate to a foldable array of three-dimensional panels, which may include one or more functional electrical components. For instance, the three-dimensional multi-panel array may be reconfigured from a substantially planar configuration into a three-dimensional configuration.

Abstract: Apparatus and methods of generating electricity include using an optically and thermally responsive material comprising single-walled Carbon nanotubes and Copper sulfide nanoparticles. This material acts as a thermoelectric generator lacking rectifying effects. In some forms, the generator may generate electricity from a light source alone, a heat source alone, or a source of both light and heat. Some forms exhibit enhanced optical and thermal switching characteristics, light absorption, photocurrent and thermocurrent generation under light illumination or/and thermal radiation, providing a new route to obtain thermoelectricity without any cooling or heat-sink component. Moreover, measurements showed thin films of SWNT CuS NPs had significantly increased light absorption (up to 80%) compared to untreated SWNT thin films.

Abstract: A photovoltaic cell mounting substrate includes a substrate; and a plurality of grooves provided at one surface of the photovoltaic cell mounting substrate, the plurality of grooves including a first groove and a second groove that is placed at a circumferential side of the first groove, at the one surface of the substrate, the second groove being formed deeper than the first groove, with respect to the one surface of the substrate.

Abstract: In various embodiments, optoelectronic devices are described herein. The optoelectronic device may include an optoelectronic cell arranged so as to wrap around a central axis wherein the cell includes a first conductive layer, a semi-conductive layer disposed over and in electrical communication with the first conductive layer, and a second conductive layer disposed over and in electrical communication with the semi-conductive layer. In various embodiments, methods for making optoelectronic devices are described herein. The methods may include forming an optoelectronic cell while flat and wrapping the optoelectronic cell around a central axis. The optoelectronic devices may be photovoltaic devices. Alternatively, the optoelectronic devices may be organic light emitting diodes.

Abstract: A compact low concentration photovoltaic (LCPV) apparatus totally enclosed in a protective clear dome against harsh environment without active cooling. A conical mirror reflector, a circular lens refractor and a planar circular crystalline silicon photovoltaic solar panel rotate simultaneously inside the dome to concentrate sun rays and instantly produce electricity. The mirror increases electrical current three times and the lens increases one time for total four times using low overall concentration of five to twenty times sun. The lens is offset from the plane parallel to the photovoltaic solar panel, while the panels forming the mirror are angled offset to a center axis perpendicular to the solar panel. The optical assembly and solar panel are mounted in a conical aluminum cage which is pivoted from a rotary turntable for the daily azimuth and altitude rotations.

Abstract: Provided are novel building integrable photovoltaic (BIP) modules having specially configured attachment structures for securing these modules to building structures and other BIP modules. In certain embodiments, a BIP module includes a base sheet supporting photovoltaic cells and having a rigid polymer portion and a flexible polymer portion. The flexible portion is designed to be penetrated with mechanical fasteners during installation. The flexible portion may include fastening pointers and/or through holes for identifying specific penetration locations. The rigid portion provides necessary structural rigidity and support to the module and more specifically to the photovoltaic cells. In certain other embodiments, a BIP module includes an adhesive bumper strip disposed along one edge of the module and configured for secure this module with respect to another module. During installation, the strip is positioned between a back sealing sheet of one module and a front sealing sheet of another module.

Abstract: Apparatuses, methods, and systems are disclosed to use thermoelectric generating (TEG) devices to generate electricity from heat generated by a power cable. An apparatus includes multiple thermoelectric generating (TEG) devices. Each of the TEG devices has a first surface configured to be positioned in thermal communication with an outer surface of the power cable and a second surface configured to be positioned proximate to an ambient environment around the power cable. The apparatus also includes a set of terminals electrically coupled to the TEG devices. When a temperature differential exists between the first surface and the second surface, the TEG devices convert heat into electricity presented at the set of terminals.

Abstract: A masonry unit including a photovoltaic cell for generation of electricity is described herein. More particularly a photovoltaic-clad concrete block that combines the structural attributes of concrete block (or other masonry unit) and the energy production of solar photovoltaics is described herein. Methods for manufacturing, installing, and electrically connecting such photovoltaic-clad concrete blocks are also described herein.

Abstract: Disclosed are a solar cell and a method of fabricating the same. The solar cell includes a molybdenum layer on a support substrate; an ohmic layer on the molybdenum layer; a light absorbing layer on the ohmic layer; and a front electrode layer on the light absorbing layer, wherein the ohmic layer comprises a first ohmic layer and a second ohmic layer having crystal structures different from each other.

Abstract: A high transmittance thin film solar panel includes a transparent substrate, a front electrode layer, a light absorption layer and a rear electrode layer. The light absorption layer is formed with opening patterns with the same width at positions aligned correspondingly to form at least one first opening trench, a plurality of second opening trenches with continuously and periodically sinusoidal-wave shape, and a plurality of third opening trenches parallel to, interlace with or superpose the second opening trenches, and extend in a direction orthogonal to the direction of the first opening trench. The high transmittance thin film solar panel of the present invention is mainly used for green buildings. The opening trenches of the high transmittance thin film solar panel are formed in a manner of curve shape by an oscillating laser head, and can enhance the transmittance by more than about 3% in comparison with the conventional one.