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.

The invention relates to a carrier structure for solar panels. The invention also relates to a beam (3) for use in a carrier structure according to the invention. The invention then relates to a carrier (4,5) for use in a carrier structure according to the invention. The invention furthermore relates to an assembly of at least one carrier structure and at least one solar panel. In addition, the invention relates to a method for producing a carrier structure according to the invention.

Structures and techniques for solar collectors are described. In accordance with the described techniques, a structural assembly of a solar collector may include various members that are configured to carry torsional and bending loads with relatively low deflections between a reflector and a receiver. In some examples, the described structural assemblies may include a set of edge-sharing tetrahedra or tetrahedral volumes aligned along an axis, which may be supported by chord members that are parallel to the axis. In some examples, the described structural assemblies may include sets of co-rotating and counter-rotating helical structural paths, which may be connected or supported by structural members that are perpendicular to an axis of the helical structural paths, or members that are parallel to an axis of the helical structural paths, or various combinations thereof.

Structures and techniques for solar collectors are described. In accordance with the described techniques, a structural assembly of a solar collector may include various members that are configured to carry torsional and bending loads with relatively low deflections between a reflector and a receiver. In some examples, the described structural assemblies may include a set of edge-sharing tetrahedra or tetrahedral volumes aligned along an axis, which may be supported by chord members that are parallel to the axis. In some examples, the described structural assemblies may include sets of co-rotating and counter-rotating helical structural paths, which may be connected or supported by structural members that are perpendicular to an axis of the helical structural paths, or members that are parallel to an axis of the helical structural paths, or various combinations thereof.

A tiered mounting system includes a base plate including a mounting guide rail having a plurality of mounting grooves that extend along opposing sides of the guide rail. The system also includes an object mount connector having a plurality of mounting ridges. The object mount connector is configured to: slidingly engage the mounting guide rail via insertion of one or more of the plurality of mounting ridges within a corresponding one or more of the plurality of mounting grooves, and lock in place along the mounting guide rail via a bolt placed through the object mount connector and secured tightly to an inner track of the mounting guide rail.

A tiered mounting system includes a base plate including a mounting guide rail having a plurality of mounting grooves that extend along opposing sides of the guide rail. The system also includes an object mount connector having a plurality of mounting ridges. The object mount connector is configured to: slidingly engage the mounting guide rail via insertion of one or more of the plurality of mounting ridges within a corresponding one or more of the plurality of mounting grooves, and lock in place along the mounting guide rail via a bolt placed through the object mount connector and secured tightly to an inner track of the mounting guide rail.

Solar trackers that may be advantageously employed on sloped and/or variable terrain to rotate solar panels to track motion of the sun across the sky include bearing assemblies and other mechanical features configured to address mechanical challenges posed by the sloped and/or variable terrain that might otherwise prevent or complicate use of solar trackers on such terrain.

Solar trackers that may be advantageously employed on sloped and/or variable terrain to rotate solar panels to track motion of the sun across the sky include bearing assemblies and other mechanical features configured to address mechanical challenges posed by the sloped and/or variable terrain that might otherwise prevent or complicate use of solar trackers on such terrain.

Multi-functional barrier walls equipped with solar panels, Structural Solar Panels (SSPs) and/or wind turbines along liner boundaries, farmlands, fire zones, highways, railroads, liner terrains or linearly configured spaces to produce electricity from solar and wind energy. The barrier walls may be used as boundary walls, security barriers, sound attenuating barriers, fire barriers, wind barriers or dust barriers. A method of financing the said barrier walls by the electricity produced by the said solar panels, said Structural Solar Panels (SSPs) and/or wind turbines.

Multi-functional barrier walls equipped with solar panels, Structural Solar Panels (SSPs) and/or wind turbines along liner boundaries, farmlands, fire zones, highways, railroads, liner terrains or linearly configured spaces to produce electricity from solar and wind energy. The barrier walls may be used as boundary walls, security barriers, sound attenuating barriers, fire barriers, wind barriers or dust barriers. A method of financing the said barrier walls by the electricity produced by the said solar panels, said Structural Solar Panels (SSPs) and/or wind turbines.