Abstract: The one or more embodiments of the present invention propose a novel photovoltaic system. The system can include a housing and at least one layer of photovoltaic panels inside the housing. Photovoltaic cells can be arranged on the panel. Light is reflected in many ways and recycled within the housing either continuously or intermittently. This can reduce the loss of light energy back into the atmosphere due to reflections from the panel and can also improve the working efficiency of the photovoltaic cells by creating multiple passes for the light either continuously or intermittently.

Abstract: Systems and methods for positioning solar energy collection devices are disclosed. In one embodiment, an integrated unit combines the necessity of solar panel repositioning with water filtration. While also providing clean water for the end user, the integrated unit uses controlled weight displacement to rotate a solar panel to follow the sun from east to west—a process also known as horizontal (azimuth) solar tracking.

Abstract: A thermoelectric material including a 3-dimensional nanostructure, wherein the 3-dimensional nanostructure includes a 2-dimensional nanostructure connected to a 1-dimensional nanostructure.

Abstract: A thermoelectric energy harvesting system may include a thermoelectric generator and an electronics module. The thermoelectric generator may produce a voltage in response to a temperature difference across the thermoelectric generator and generate power when coupled to a load. The system may include a housing mounted on top of the thermoelectric generator. The housing may include a cavity containing the electronics module. The electronics module may condition the power generated by the thermoelectric generator. The cavity may be enclosed by an inner surface of the housing. A radiation shield may cover at least a portion of the inner surface and may block radiative heating of the cavity from the housing.

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: Disclosed is a method of fabricating a microlens. The method includes forming a self assembly monolayer having a strong hydrophobicity on a substrate; forming a plurality of ink droplets on the self assembly monolayer by jetting a transparent ink using an inkjet apparatus, the transparent ink including a first solvent having a first boiling point, a second solvent having a second boiling point lower than the first boiling point and a silicon oxide (SiOx) solid material dispersed in the first and second solvents; and drying the plurality of ink droplets.

Abstract: A photoelectric cell includes at least one photoelectric conversion module. The at least one photoelectric conversion module includes a first photoelectric conversion element and a second photoelectric conversion element. The first photoelectric conversion element includes a first absorbing part and a first non-absorbing part. An angle between the first absorbing part and the first non-absorbing part is less than 90 degrees. The second photoelectric conversion element includes a second non-absorbing part and a second absorbing part electrically connected with the second absorbing part. An angle between the second absorbing part and the second non-absorbing part is less than 90 degrees. The first absorbing part is electrically connected with the second absorbing part.

Abstract: A conducting material can include a fibrous substrate and a conductive polymer coating on a surface of the fibrous substrate.

Abstract: A first surface of a first section of a connection member includes a first conductive region, and a second surface of a second section of the connection member includes a second conductive region. The first conductive region is formed along an n-side electrode included in one solar cell, and is electrically connected to the n-side electrode. The second conductive region is formed along a p-side electrode included in a different solar cell, and is electrically connected to the p-side electrode. The first conductive region and the second conductive region are electrically connected to each other.

Abstract: A deployable photovoltaic array comprising a plurality of photovoltaic modules attached to a collapsible support unit, where said support unit is made up of a pair of laterally spaced similar pantographs. Each pantograph has the form of a plurality of interconnected rhombs made by pivotally joined elongated arms. Two opposite sides of each solar module are attached to a pair of corresponding nearest parallel arms on the opposite sides of said pantographs. Said array in its deployed condition for large solar elevation angles acquires a characteristic staircase-like form. Angles of said rhombs may further be adjusted to achieve an optimal inclination of said solar modules with respect to the current direction to the sun. In the stowed configuration said array may be held in a protecting container, and is readily portable.

Abstract: Disclosed is a solar cell module wherein deterioration of the strength of adhering between a solar cell panel and a terminal box can be suppressed, while reducing the quantity of an adhesive to be used. The solar cell module (1) is provided with the terminal box (3) which is adhered to the solar cell panel (2) with the adhesive (4) therebetween. The adhesive surface (31a) of the terminal box, said adhesive surface having the solar cell panel (2) adhered thereon, includes a top portion (31f) where the distance to the surface of the solar cell panel (2) is shortest, and an inclined portion (31g) which is configured such that the distance to the surface of the solar cell panel increases toward the side far from the top portion.

Abstract: A solar energy enclosure unit having a housing defining a central cavity in which there is located a turntable upon which is mounted a solar panel; the turntable and solar panel rotated at low revolutions per minute by an associated electric motor, the enclosure having a convex transparent dome covering the solar panel, the transparent convex dome having prismatic facets formed thereon for magnifying, concentrating, and focusing solar rays onto the solar panel regardless of the position of the sun, in the sky, relative to the housing.

Abstract: Disclosed are a solar cell and a method for manufacturing the same. The solar cell includes a support substrate; a back electrode layer on the support substrate, the back electrode layer being formed with at least one first through hole to expose a part of a top surface of the support substrate; a light absorbing layer on the back electrode layer; a buffer layer on the light absorbing layer; a window layer on the buffer layer; and a high-resistance region on a lateral side of the back electrode layer forming the first through hole. The high-resistance region has a resistance value higher than a resistance value of the light absorbing layer.

Abstract: A transportable photovoltaic system includes a plurality of photovoltaic devices, a composite frame to which the plurality of photovoltaic devices are affixed, and a base structure to which the composite frame is movably attached through at least one variable-angle mount structure. The orientation of the frame and the light concentrating elements relative to the base structure can be altered employing the at least one variable-angle mount structure. The frame and the plurality of photovoltaic devices can be assembled prior to shipping, and the base structure can be manufactured on site. The transportable photovoltaic system is not affixed to ground or other fixture, but can be picked up at any time during the operational lifetime. The transportable photovoltaic system can be rapidly deployed with little or no site preparation requirement other than generally level ground, and can be retracted to a lower exposure position to avoid storm and/or hazardous conditions.

Abstract: A solar cell including a base region, a back surface field layer and a delta doping layer positioned between the base region and the back surface field layer.

Abstract: A transportable photovoltaic system includes a plurality of photovoltaic devices, a composite frame to which the plurality of photovoltaic devices are affixed, and a base structure to which the composite frame is movably attached through at least one variable-angle mount structure. The orientation of the frame and the light concentrating elements relative to the base structure can be altered employing the at least one variable-angle mount structure. The frame and the plurality of photovoltaic devices can be assembled prior to shipping, and the base structure can be manufactured on site. The transportable photovoltaic system is not affixed to ground or other fixture, but can be picked up at any time during the operational lifetime. The transportable photovoltaic system can be rapidly deployed with little or no site preparation requirement other than generally level ground, and can be retracted to a lower exposure position to avoid storm and/or hazardous conditions.

Abstract: A photovoltaic module cord plate is disclosed. The cord plate has a base and channel.

Abstract: A solar cell having a molded lead frame, and method of manufacture of same, is disclosed. Specifically, a plurality of solar cells is manufactured from a strip of lead-frames and soft solder techniques for die assembly and component assembly. After wire bonding, glass attachment and transfer molding, a trim and form process produces individual solar cells having a molded lead frame.

Abstract: A heat dissipation structure is provided and includes a plurality of heat conduction bases and at least one flexible fin. Each of the heat conduction bases includes a first surface and a second surface. A positioning groove is formed in the first surface of each of the heat conduction bases, and the second surface of each of the heat conduction bases is assembled to a backlight surface of a solar module. The fin is coupled to the positioning grooves and connected between the heat conduction bases.

Abstract: A polarization resistant solar cell using an oxygen-rich interface layer is provided. The oxygen-rich interface layer may be comprised of SiOxNy, which may have a graded profile that varies between oxygen-rich proximate to the solar cell to nitrogen-rich distal to the solar cell. A silicon oxide passivation layer may be interposed between the solar cell and the SiOxNy graded dielectric layer. The graded SiOxNy dielectric layer may be replaced with a non-graded SiOxNy dielectric layer and a SiN AR coating.