Abstract: A heat-rejecting optic comprising an optical element and receiving element or layer with intermediate layer between is provided. Refractive indices of the optical element and receiving element or layer are greater than the intermediate layer. The optic may be part of a concentrator assembly or lens concentrator system for photovoltaic cells. The heat-rejecting optic functions to redirect wavelengths of light for which power conversion by a photovoltaic cell is inefficient and which cause undesirable photovoltaic cell heating and damage, reducing photovoltaic cell life. The receiving element or layer and intermediate layer modify the optical element to frustrate the total internal reflection of light that would otherwise occur within the optical element and divert that light into the receiving element or layer.

Abstract: The solar cell modular unit has a minimal number of components which are easily manufactured and have a relatively economical cost. It has a laminar substrate having an electrically conductive layer on its top surface with a printed electrical circuit. The middle layer is heat conductive and not electrically conductive. The bottom layer is thermally conductive. A solar cell is centrally mounted on the printed circuit board. A base assembly covers the solar cell and has a vertical tunnel extending from its top surface to the solar cell. A sun shield has an aperture in its top panel that aligns with the tunnel. The sun shield snap-locks onto the base assembly top. A secondary optical element telescopically mates with the aperture in the sun shield and the base assembly tunnel. A primary light ray refractive member is positioned at a predetermined spaced location above the SOE.

Abstract: Apparatus and methods are described including an individual solar power generating and sun sensing cell formed to have a plurality of electrically isolated portions, the output of each portion being monitored and analyzed to determine whether the solar cell is optimally positioned relative to the direction of solar rays to optimize power generation of the solar cell, and also of an array of solar cells which includes the solar power generating and sun sensing cell.

Abstract: A heat-rejecting optic comprising an optical element and receiving element or layer with intermediate layer between is provided. Refractive indices of the optical element and receiving element or layer are greater than the intermediate layer. The optic may be part of a concentrator assembly or lens concentrator system for photovoltaic cells. The heat-rejecting optic functions to redirect wavelengths of light for which power conversion by a photovoltaic cell is inefficient and which cause undesirable photovoltaic cell heating and damage, reducing photovoltaic cell life. The receiving element or layer and intermediate layer modify the optical element to frustrate the total internal reflection of light that would otherwise occur within the optical element and divert that light into the receiving element or layer.

Abstract: An increased efficiency Concentrator Photovoltaic System having a plurality of solar cells laterally spaced from each other on a substrate panel. The solar cells are mounted on electrically conductive areas of an otherwise non-conductive top surface of the substrate with each cell isolated from another by a non-conductive area. The individual cells are connected using ribbons or wires, between the front contact of the solar cells to the conductive area of another cell to form a circuit connecting the cells in a desired configuration. A plurality of tubular enclosures for concentrating light on the solar cells are mounted directly above the solar cells.

Abstract: The solar cell modular unit has a minimal number of components each of which are easily manufactured and which also have a relatively economical cost. It has a laminar substrate having an electrically conductive layer on its top surface that includes the printed electrical circuit. The middle layer is heat conductive and not electrically conductive. The bottom layer is made of thermally conductive material. A solar cell is centrally mounted on the printed circuit board. A base assembly covers the solar cell and it has a vertical tunnel extending from its top surface to the solar cell. An elongated sun shield has an aperture in its top panel that aligns with the tunnel of the base assembly. The sun shield snap-locks onto the top of the base assembly. A secondary optical element telescopically mates with the aperture in the sun shield and the tunnel of the base assembly. A primary light ray refractive member is positioned at a predetermined spaced location above the SOE.

Abstract: A lightweight, high-stiffness structural beam having a web and a chord, which features a cross-sectional geometry featuring a plurality of sides arranged in an asymmetrical, non-closed, convex polygon shape. At least three of the sides of the chord are substantially parallel to one another, and are substantially perpendicular to the web. The beam is easily manufactured using fully-automated fabrication machinery and may serve as the main, flexure-resistant structural component of a sunlight-concentrating photovoltaic module.

Abstract: A lightweight, high-stiffness structural beam having a web and a chord, which features a cross-sectional geometry featuring a plurality of sides arranged in an asymmetrical, non-closed, convex polygon shape. At least three of the sides of the chord are substantially parallel to one another, and are substantially perpendicular to the web. The beam is easily manufactured using fully-automated fabrication machinery and may serve as the main, flexure-resistant structural component of a sunlight-concentrating photovoltaic module.

Abstract: A solar collector tracking system that has a solar collection device having multiple lens assemblies mounted on its front surface. An exoskeleton structure is secured to the rear surface of the solar collection device and it is pivotally secured about a horizontal axis to the front end of an azimuth platform assembly. A hydraulic elevation actuator is pivotally mounted in the azimuth platform assembly about a horizontal axis and the front end of its piston rod is pivotally connected to the rear surface of the solar collection device and this allows it to be pivoted approximately 90 degrees between a vertical operating position and a horizontal storage position. The azimuth platform assembly is journaled on the top end of a tower extending up from the ground. A tubular post is rigidly secured to the top end of the post. A drive head extends horizontally from the tubular post and it has a pivot pin that extends upwardly therefrom.

Abstract: Each of a plurality of solar cells is disposed on a base member made from an electrically insulating material. Each of the solar cells has first and second cell portions separated by an insulating gap, the first cell portion being positive and the second portion being negative. A third cell portion may be provided in each solar cell with the first portion being disposed between, and in insulated relationship to, the second and third portions and with the third portion being negative. Each of the solar cells may include a positive termination extending from the first cell portion and a negative termination extending from the second (and third) cell portion(s) and separated from the first cell portion by an insulating gap. Each of a plurality of diodes is disposed on an individual one of the base members across the insulating gap between the positive and negative terminations of an individual one of the solar cells on the base member.