Abstract: A solar panel capable of exhibiting excellent aesthetics and power generation efficiency, and capable of easily forming a protection plate in a manufacturing process is provided. The solar panel of the present invention comprises a protection plate 1 having translucency from a front surface 1a to a back surface, a solar battery cell, and an encapsulant that is integrally provided on the back surface, and fixes the solar battery cell to the back surface in sealed state. The protection plate is formed from a resin with polycarbonate as a main component by injection molding. The front surface serves as a design surface. A portion of the back surface that faces the solar battery cell serves as an offset surface that is offset with respect to the solar battery cell, and differs from the design surface in shape.

Abstract: A thermoelectric device includes a plurality of thin-film thermoelectric elements. Each thin-film thermoelectric element is a Seebeck-Peltier device. The thin-film thermoelectric elements are electrically coupled in parallel with each other. The thermoelectric device may be fabricated using conventional semiconductor processing technologies and may be a thin-film type device.

Abstract: A stacked and integrated electric power generating device for capturing multiple light sources for power generation has a first concentrating photovoltaic module and a second concentrating photovoltaic module. The first concentrating photovoltaic module 10 has a transparent solar concentrating panel and a thin film solar cell. The second concentrating photovoltaic module is positioned below the first concentrating photovoltaic module with an interval, such that the first and second concentrating photovoltaic modules are in the form of a stacked and integrated structure, and the second concentrating photovoltaic module can absorb the light concentrated by the transparent solar concentrating panel to generate electric power.

Abstract: Techniques for providing high-capacity, re-workable connections in concentrated photovoltaic devices are provided. In one aspect, a lead frame package for a photovoltaic device is provided that includes a beam shield; and one or more lead frame connectors affixed to the beam shield, wherein the lead frame connectors are configured to provide connection to the photovoltaic device when the photovoltaic device is assembled to the lead frame package. A photovoltaic apparatus is also provided that includes a lead frame package assembled to a photovoltaic device. The lead frame package includes a beam shield and one or more lead frame connectors affixed to the beam shield, wherein the lead frame connectors are configured to provide connection to the photovoltaic device.

Abstract: Provided are a dye-sensitized solar cell wherein a counter electrode composed of a stable counter electrode conductive layer and a catalyst layer is formed on a porous insulation layer, and a dye-sensitized solar cell module wherein the dye-sensitized solar cell is utilized. A dye-sensitized solar cell includes a supporting body made of a light-transmissive material, and a laminate wherein a conductive layer, a photoelectric conversion layer having a porous semiconductor layer with a dye adsorbed therein, a porous insulation layer, a counter electrode conductive layer, and a catalyst layer are laminated in the order presented. The photoelectric conversion layer and the porous insulation lay are filled with a carrier transport material.

Abstract: For directly converting heat to electrical energy, for example in a spacecraft operating in space, at least one thermoelectric generator module is arranged in an evacuated chamber so as to receive thermal radiation from a heat source through the interior vacuum within the interior of the chamber. The thermoelectric generator module converts a portion of the received heat to electrical energy and rejects a portion of the heat by thermal conduction to a thermally conducting cooling body such as the chamber wall or directly by thermal radiation to the surrounding vacuum of space.

Abstract: A solar collector assembly includes a photovoltaic panel having first and second sides, a frame, and a first gas-filled chamber on the first side of the photovoltaic panel. The first gas-filled chamber is at least partially defined by a portion of the frame and by a portion of the first side of the photovoltaic panel. A gas functions as a heat exchange fluid and collects heat from solar energy and/or heat generated by the photovoltaic panel. The photovoltaic panel accumulates and converts solar energy to electrical energy. The solar collector assembly may include a second gas-filled chamber provided on the second side of the photovoltaic panel. The second gas-filled chamber is at least partially defined by a portion of the frame and by a portion of the second side of the photovoltaic panel. Solar collector systems and methods of generating electrical energy and/or thermal energy are also described.

Abstract: A solar energy heat to electricity conversion device is provided that includes a thermally conductive solar receiver having a cylinder with an open end and a cup-shape closed end and a thermally conductive fin disposed on an outside surface of the cup-shape closed end, where the thermally conductive solar receiver is capable of absorbing solar energy directed into the cylinder, a thermoelectric module (TEM) that includes a first plate and a second plate, where the first plate is in contact with a surface of the thermally conductive fin, where the conductive fin is capable of transferring heat to the first plate, and a thermally conductive water block in contact with the TEM that is capable of cooling the TEM, where the water block includes a fluid input and a fluid output, where the TEM generates electricity according to a temperature difference between the first plate and the second plate.

Abstract: An industrial thermoelectric generation assembly and method are provided. A plurality of thermoelectric generation elements is provided. Each element has a first side, a second side opposite the first side, and a lateral surface. A thermally insulative material surrounds the lateral surface of each thermoelectric element. The first side of each thermoelectric element is disposed to contact a process heat source, and the second side is configured to be exposed to an ambient environment. At least two of the plurality of thermoelectric generation elements are wired in series. The thermoelectric generation elements, being good thermal insulators, provide good thermal insulation to the process. Withholding heat within the process (which is desired), is converted to electricity.

Abstract: A high-efficiency solar cell including an Indium, Gallium, Aluminum and Nitrogen (in a combination comprising InGaN, or InAlN, or InGaAlN) alloy which may be blended with a polyhedral oligomeric silsesquioxane (POSS) material, and which may include an absorption-enhancing layer including one of more of carbon nanotubes, quantum dots, and undulating or uneven surface topography.

Abstract: A photovoltaic device that includes an upper cell that absorbs a first range of wavelengths of light and a bottom cell that absorbs a second range of wavelengths of light. The bottom cell includes a heterojunction comprising a crystalline germanium containing (Ge) layer. At least one surface of the crystalline germanium (Ge) containing layer is in contact with a silicon (Si) containing layer having a larger band gap than the crystalline (Ge) containing layer.

Abstract: A system for collecting solar energy and fresh water may be disclosed. The system may include one or more assemblies of collector modules, each of which module may contain a photovoltaic cell and a thermal fluid. The thermal fluid may be used to heat a building and/or produce electricity. The assembly may further be coupled to a collection shaft which may collect water and/or disseminate light through a building. Various configurations of single modules, single assemblies, or multiple large-scale assemblies are also possible. If integrated with a house, the system may reduce the net energy consumption of the household.

Abstract: A solar cell apparatus according to the embodiment includes a support substrate; a back electrode layer on the support layer; a light absorbing layer on the back electrode layer; a first buffer layer having first conductivity on the light absorbing layer; a second buffer layer having second conductivity on the first buffer layer; and a window layer on the second buffer layer.

Abstract: A solar cell includes a back electrode, a silicon substrate, a doped silicon layer and an upper electrode arranged in that order. The silicon substrate comprises a number of three-dimensional nano-structures aligned side by side adjacent to the upper electrode. The doped silicon layer is located on a surface of the three-dimensional nano-structures. A cross section of each three-dimensional nano-structure is M-shaped.

Abstract: A thermoelectric module includes a cold side, a hot side and thermoelectric elements disposed between the two sides. At least one heat conducting layer is disposed between the thermoelectric elements and at least the cold side or the hot side and the heat conducting layer can be compressed. A method for producing a thermoelectric module having at least one heat conducting layer is also provided.

Abstract: An apparatus, system and method provides electrical power in a subterranean well. A radioisotope thermoelectric generator may be positioned and installed in a downhole location in a wellbore. The location of the radioisotope thermoelectric generator may be within a completion string. A radioisotope thermoelectric generator comprises a core having a radioisotope for producing heat, and a thermocouple. The thermocouple comprises at least two different metals, and is positioned adjacent to the core. The radioisotope thermoelectric generator flows heat from the core to the thermocouple to produce electricity that may be stored in an energy storage device, or used to power a component. The produced electrical power may be employed to activate downhole sensors, valves, or wireless transmitters associated with the operation and production of an oil or gas well.

Abstract: Provided is a photoelectric conversion device which includes a positive electrode, a negative electrode, a photoelectric conversion layer including poly-[N-9?-heptadecanyl-2,7-carbazole-alt-5,5-(4?,7?-di-2-thienyl-2?,1?,3?-benzothiadiazole)] as a p-type organic semiconductor material and fullerene or a fullerene derivative as an n-type organic semiconductor material; and a buffer layer, provided between the positive electrode and the photoelectric conversion layer, including MoO3, in which device the proportion of the p-type organic semiconductor material in a first region being in contact with the buffer layer in the photoelectric conversion layer is higher than the proportion of the p-type organic semiconductor material in the entirety of the photoelectric conversion layer, and the proportion of the p-type organic semiconductor material in a second region on the negative electrode side than the first region in the photoelectric conversion layer is lower than the proportion of the p-type organic semiconducto

Abstract: A thermoelectric energy harvesting system may include a thermoelectric generator that may produce a voltage in response to a temperature difference across the thermoelectric generator. The thermoelectric generator may be captured between the housing and the base member. The system may include at least one mechanical fastener coupling the housing to the base member and including a shoulder spacer formed of thermally-insulating material and positioned under the mechanical fastener.

Abstract: Certain example embodiments relate to techniques for creating improved photovoltaic (PV) modules. In certain example embodiments and first and second glass substrate are provided. A PV array is provided between the first and second glass substrates. The first and second substrates are laminated together with the PV array between the glass substrates. In certain example embodiments the PV module is dimensioned to be similar to an existing roof system (e.g., a sunroof) in a vehicle.

Abstract: In an embodiment, a photovoltaic system includes multiple photovoltaic modules and a module-to-module bus. Each photovoltaic module defines a first end and a second end opposite the first end. Each photovoltaic module includes multiple photovoltaic cells and multiple converters. Energy generated by each photovoltaic cell has multiple paths through the photovoltaic cells to the second end. The converters are electrically coupled to the photovoltaic cells at the second end such that energy generated by each photovoltaic cell is receivable at any of the converters. The module-to-module bus is electrically coupled to each of the photovoltaic modules. The module-to-module bus has an output. Energy generated by each photovoltaic module is receivable at the output independent of any other of the photovoltaic modules.