A foldable solar panel assembly is configured to support solar panels in a compact and folded, undeployed position, and in an unfolded, deployed position, and to fold and unfold between its deployed and undeployed position.

A solar panel carriage is disclosed. The solar panel carriage may include a cross-piece, a pivot shaft connected to the cross piece, a center hinging mechanism connected to the cross-piece, one or more arms extending outwardly from the cross-piece and connected to the cross piece the center hinging mechanism, a flange disposed at an end of the one or more arms, and, a knobbed bolt configured to be inserted through the flange, and through a first side of a solar panel, and threaded into the flange on a second side of the solar panel. The one or more arms of the solar panel carriage may be configured to fold into a position parallel to the cross-piece via a movement of the center hinging mechanism.

The disclosure provides a solar device. The solar device includes: a solar panel, having a first surface and a second surface arranged oppositely; and a support assembly, used to support the solar panel, herein the support assembly includes a support base and a support rod, the support base is arranged on the second surface, the support base is provided with an upper mounting hole and a lower mounting hole, the upper mounting hole and the lower mounting hole are arranged on the support base at intervals along a vertical direction, and the support rod may be selectively connected with the upper mounting hole or the lower mounting hole to adjust the inclination angle of the solar panel. Through a technical scheme provided by this disclosure, problems in an existing technology that the transportation is inconvenient and the power generation efficiency is low may be solved.

A Mobile Autonomous Solar-Wind Electrical Station (MASWES) comprises an offshore container (2), which equipped with a reinforced case (18); a reinforced grillage (19) provided by at least two beams laid along, and plurality beams laid across the container (2); at least two reinforced internal columns (42) arranged in opposite comers of the container (2) and between the grillage (19) and the middle part of the reinforced case (18); a plurality of light reflecting mats (21); a plurality of movable screw-piles (22), which in the transport position are stored in the plurality of cylindrical channels (38); at least two monolithic towers or telescopic masts (52) of powerful horizontal-axis wind turbines (23) providing at least 10 kW power each with blades and wind vanes taken off in the transport position. The reinforced internal columns (42) are the bases for the monolithic towers or the telescopic masts (52) and equipped with a hydraulic mechanism or an electric actuator (54) and an erection tool for installation of mentioned monolithic towers or telescopic masts (52). The container (2) comprises gondolas, which in the transport position are arranged horizontally in opposite ends of the container (2); a plurality of photovoltaic double-sided panels (24); a plurality of multifold frameworks for photovoltaic panel arrays (25) with at least 30 kW power total and at least one charging point (28) stored inside the container and at least one rechargeable battery (31).

A method and a kit for building a protective structure, the method and the kit including supplying a carrying structure, including a plurality of parallel carrying rails; supplying a group of panels, the panels being able to be engaged on and slide on the carrying rails; and transferring the panels from the storage position to a final position bearing on the carrying rails, by transferring at least one of the panels from the storage position to an insertion position on the carrying rails; using a transfer device lifting the at least one panel upward; placing the transferred panels one after the other bearing on the carrying rails; and moving the transferred panels along the carrying rails.

A deployable solar array apparatus. There is a telescoping mast, being actuatable between an extended mode and a retracted mode; a pivoting head, coupled to a top portion of the telescoping mast; a plurality of arms, circumferentially and pivotally coupled to the head and extending outwardly therefrom, and actuatable between an extended mode and a retracted mode; and a plurality of solar panels coupled to exterior surfaces of the head and arms.

A Mobile Autonomous Solar-Wind Electrical Station (MASWES) comprises an offshore container (2), which equipped with a reinforced case (18); a reinforced grillage (19) provided by at least two beams laid along, and plurality beams laid across the container (2); at least two reinforced internal columns (42) arranged in opposite corners of the container (2) and between the grillage (19) and the middle part of the reinforced case (18); a plurality of light reflecting mats (21); a plurality of movable screw-piles (22), which in the transport position are stored in the plurality of cylindrical channels (38); at least two monolithic towers or telescopic masts (52) of powerful horizontal-axis wind turbines (23) providing at least 10 kW power each with blades and wind vanes taken off in the transport position. The reinforced internal columns (42) are the bases for the monolithic towers or the telescopic masts (52) and equipped with a hydraulic mechanism or an electric actuator (54) and an erection tool for installation of mentioned monolithic towers or telescopic masts (52). The container (2) comprises gondolas, which in the transport position are arranged horizontally in opposite ends of the container (2); a plurality of photovoltaic double-sided panels (24); a plurality of multifold frameworks for photovoltaic panel arrays (25) with at least 30 kW power total and at least one charging point (28) stored inside the container and at least one rechargeable battery (31).

An extended photovoltaic module unit comprises: a main body (10) having a first photovoltaic power generation module (1) fixed on a plurality of support parts (11) protruding from the upper surface thereof, and a third photovoltaic power generation module (3) slidably provided as a drawer type in an accommodation space (14) formed from the outer surface of one side thereof to the inside direction; a hinge part (20) formed at one side of an upper part of the main body (10); and an auxiliary body (30) having one side rotatably connected to the main body (10) via the hinge part (20), and having a second photovoltaic power generation module (2) fixed at a module supporting groove (31) of a lower end thereof.

A system for tracking the sun has a bottom frame and a top frame hingedly coupled at a first end to the bottom frame. Further, the system has a solar panel removably coupled to the top frame via at least one clamp on a second end of the top frame. Also, the system has a processor configured to adjust the solar panel horizontally and vertically to align with the sun for maximum efficiency.

A solar module mounting bracket assembly includes a rail configured to support a solar module thereon, and a pair of braces. The braces each have a first end portion movably coupled to the rail. The braces are movable relative to the rail between a collapsed configuration and an expanded configuration. In the expanded configuration, the braces cooperatively define a channel dimensioned for receipt of a frame member.