Frames and processes of manufacture using single-wall frame sections coupled to other single-wall frame sections or double-wall frame sections using a connecting key are provided. The connecting key can be metallic, polymer, ceramic, a laminate, and combinations thereof.

Frames and processes of manufacture using single-wall frame sections coupled to other single-wall frame sections or double-wall frame sections using a connecting key are provided. The connecting key can be metallic, polymer, ceramic, a laminate, and combinations thereof.

A double-glass photovoltaic assembly includes a laminate member, a junction box, and a first frame and a second frame disposed only at two long sides of the laminate member. The laminate member includes a cover plate glass, a first encapsulation adhesive film, a battery string, a second encapsulation adhesive film, a back plate glass, and a busbar. A through-hole is provided at the back plate glass. An end of the busbar is connected to the battery string. Another end of the busbar passes through the through-hole, and is bent to form a bent edge to be connected to the junction box. The bent edge of the busbar does not contact an edge of the through-hole. The double-glass photovoltaic assembly adopting a double-frame design can meet the requirements of load capacity.

A double-glass photovoltaic assembly includes a laminate member, a junction box, and a first frame and a second frame disposed only at two long sides of the laminate member. The laminate member includes a cover plate glass, a first encapsulation adhesive film, a battery string, a second encapsulation adhesive film, a back plate glass, and a busbar. A through-hole is provided at the back plate glass. An end of the busbar is connected to the battery string. Another end of the busbar passes through the through-hole, and is bent to form a bent edge to be connected to the junction box. The bent edge of the busbar does not contact an edge of the through-hole. The double-glass photovoltaic assembly adopting a double-frame design can meet the requirements of load capacity.

The present invention relates to a photovoltaic facility (1) comprising a solar tracker (2) and at least one square or rectangular photovoltaic panel (3) mounted on the solar tracker (2), this solar tracker (2) enabling the inclination of the photovoltaic panel (3) to be varied with respect to the horizontal, so that two opposite edges of the photovoltaic panel, referred to as horizontal edges (31), are always horizontal whatever the inclination of the photovoltaic panel (3).

This facility is characterised in that it comprises at least one gutter (4) for recovering rainwater, in that this gutter (4) is mounted along one of the two horizontal edges (31) of the photovoltaic panel (3) using at least two anchoring devices (5), to which it is suspended, so that it can oscillate under the action of its own weight, about a horizontal axis of rotation (Y-Y′), so as to remain horizontal whatever the inclination of the photovoltaic panel (3).

An energized mounting bracket includes a bracket body with one or more cavities and a charge controller and one or more rechargeable batteries located in the one or more cavities. One or more solar panels can be mounted directly to the bracket body or mounted to a housing of an awning unit and the awning unit coupled to the mounting bracket. The one or more solar panels, the one or more rechargeable batteries, and the charge controller can be wired together to enable charging of the rechargeable batteries with the one or more solar panels. Power from the rechargeable batteries can power a motor mounted with the awning unit and optionally power DC outlets.

An energized mounting bracket includes a bracket body with one or more cavities and a charge controller and one or more rechargeable batteries located in the one or more cavities. One or more solar panels can be mounted directly to the bracket body or mounted to a housing of an awning unit and the awning unit coupled to the mounting bracket. The one or more solar panels, the one or more rechargeable batteries, and the charge controller can be wired together to enable charging of the rechargeable batteries with the one or more solar panels. Power from the rechargeable batteries can power a motor mounted with the awning unit and optionally power DC outlets.

A solar carport system has a framework comprising metal tubing and connection fittings, the framework having a length, a width and a height and rectangular faces on top, ends and sides, a plurality of wheel assemblies at a lowermost location on the framework, enabling the framework to be moved on the wheels on a supporting surface, a plurality of solar panels assembled to the framework in the top rectangular face, such that an active surface of each solar panel faces upward, and circuitry and wiring connecting the solar panels to a cable ending in a connector compatible with and connected to an inverter.

A solar carport system has a framework comprising metal tubing and connection fittings, the framework having a length, a width and a height and rectangular faces on top, ends and sides, a plurality of wheel assemblies at a lowermost location on the framework, enabling the framework to be moved on the wheels on a supporting surface, a plurality of solar panels assembled to the framework in the top rectangular face, such that an active surface of each solar panel faces upward, and circuitry and wiring connecting the solar panels to a cable ending in a connector compatible with and connected to an inverter.

The invention relates to cooling element (5) having a fastening device (16) for upgrading any standard, commercially available photovoltaic module (1) for increasing the efficiency of the photovoltaic module (1). According to the invention, it comprises a heat insulation mat (6) having an upper surface (7), in which pipe channels (8) aligned parallel with each other are created, wherein the borders of the pipe channels (8) and the upper surface (7) of the heat insulation mat (6) are constructed with heat conduction plates (9), preferably aluminium plates. It further comprises a pipe (10) that is routed in loops (11) in all of the pipe channels (8) constructed with the heat conduction plates (9). The invention also relates to a method for attaching a cooling element (5) according to the invention to a photovoltaic module (1).