A solar collector includes a roller rotatably attached to a vehicle. A carrier fabric panel is attached on one end to the roller. Side guides are attached the sides of the carrier fabric panel. Solar cells are connected in series and are attached to the carrier fabric panel. The solar cells are connected to an electrical power storage system. Electrical leads are attached to the carrier fabric and electrically coupled to the solar cells. Electrical conductors are attached to the carrier fabric between the solar cells and the right and left guides or are provided with retainer strips. A slip ring connector is disposed on the roller for electrically coupling the electrical conductors to an electrical power storage system. The solar energy collected may be used to power actuatable accessories or passive systems that may draw power when the vehicle is not being operated.

A system for mounting one or more solar panels is provided. One version of the system includes a post, a central portion interconnected to the post, and a solar panel support member arranged to slidably receive an edge of a solar panel and including a female portion adapted to receive the at least one male portion of the elongated member, the solar panel support member adapted for pivotal movement about the longitudinal axis of the elongated member to provide a corresponding pivotal movement of the solar panel mounted thereto.

A system for mounting one or more solar panels is provided. One version of the system includes a post, a central portion interconnected to the post, and a solar panel support member arranged to slidably receive an edge of a solar panel and including a female portion adapted to receive the at least one male portion of the elongated member, the solar panel support member adapted for pivotal movement about the longitudinal axis of the elongated member to provide a corresponding pivotal movement of the solar panel mounted thereto.

A method for binding photovoltaic cells to a substrate, each photovoltaic cell comprising a rear face and a front face, comprises: providing the substrate, said substrate being flexible and impregnable; impregnating portions of the substrate with a crosslinkable polymer material, said portions being impregnated along the thickness of the substrate with a view to bonding the photovoltaic cells to the substrate; bringing the rear faces of the photovoltaic cells into contact with the impregnated portions of the substrate crosslinking the crosslinkable polymer material.

A shading textile is characterized in that it comprises a plurality of strip-shaped photovoltaic lamellas which, aligned next to one another or spaced apart from one another in their longitudinal direction, form a continuous product by means of a yarn system, wherein the yarn system is designed to be elastic in at least one direction, so that by tensioning the shading textile, a spacing between adjacent photovoltaic elements can be varied perpendicular to the longitudinal direction.

A shading textile is characterized in that it comprises a plurality of strip-shaped photovoltaic lamellas which, aligned next to one another or spaced apart from one another in their longitudinal direction, form a continuous product by means of a yarn system, wherein the yarn system is designed to be elastic in at least one direction, so that by tensioning the shading textile, a spacing between adjacent photovoltaic elements can be varied perpendicular to the longitudinal direction.

A solar cell assembly having a flexible circuit is described. The solar cell assembly includes a solar cell having a solar-facing surface and a non-solar-facing surface, the solar cell comprising a cell corner. The solar cell assembly further includes a flexible circuit coupled to the non-solar-facing surface of the solar. The flexible circuit is substantially coextensive with the solar cell. The flexible circuit includes a flexible insulator including a plurality of edges aligned with the solar cell, a flexible corner extending past the cell corner, and a flexible tab extending from an edge of the plurality of edges. The flexible circuit includes a circuit substantially embedded in the flexible insulator. The circuit comprises a first electric contact exposed at a solar-facing side of the flexible corner, and a second electric contact exposed at a solar-facing side of the flexible tab.

A solar cell assembly having a flexible circuit is described. The solar cell assembly includes a solar cell having a solar-facing surface and a non-solar-facing surface, the solar cell comprising a cell corner. The solar cell assembly further includes a flexible circuit coupled to the non-solar-facing surface of the solar. The flexible circuit is substantially coextensive with the solar cell. The flexible circuit includes a flexible insulator including a plurality of edges aligned with the solar cell, a flexible corner extending past the cell corner, and a flexible tab extending from an edge of the plurality of edges. The flexible circuit includes a circuit substantially embedded in the flexible insulator. The circuit comprises a first electric contact exposed at a solar-facing side of the flexible corner, and a second electric contact exposed at a solar-facing side of the flexible tab.

A solar panel awning device may include a solar panel having first and second opposing ends, first and second opposing sides extending between the first and second opposing ends, and first and second opposing major surfaces. The first major opposing surface defines a photovoltaic surface. The solar panel awning device may include first and second arms respectively coupled to the first and second opposing ends of the solar panel, and an actuator coupled to one of the first and second arms and configured to switch the solar panel between an extended position and a retracted position. In the retracted position, the solar panel is flat against a side of a building; in the extended position, the first opposing side is proximal to the side of the building and spaced apart from the side of the building; and the second opposing side is distal to the side of the building.

An electronics charging station for powering and charging an electronic device is provided. The electronics charging station comprises an umbrella. The umbrella comprises a main shaft having a first end and a second end a plurality of ribs extending from the main shaft, and a canopy having a top surface and a bottom surface with the bottom surface of the canopy mounted to the ribs. At least one solar panel is mounted to the top surface of the canopy. At least one rechargeable battery is provided for capturing and storing the energy from the at least one solar panel. An outlet box is electrically connected to the at least one solar panel and the at least one rechargeable battery. Upon connecting the electronic device to the outlet box, the electronic device Is powered and charged.