A solar tracker system includes a photovoltaic panel and an actuator coupled to the photovoltaic panel and configured to actuate to rotate the photovoltaic panel around a base. A controller communicatively coupled to the actuator is configured to detect a direction from which wind is incident on the photovoltaic panel. Based on the direction from which wind is incident on the photovoltaic panel, the controller adaptively controls the actuator to set a stow position of the photovoltaic panel.

A solar canopy has a solar panel assembly including a first solar panel coupled to a second solar panel and oriented non-parallel with respect to the second solar panel. The solar panel assembly has an effective solar-panel-assembly wind loading less than a sum of a first-solar-panel effective wind loading and a second-solar-panel effective wind loading determined individually. An actual load applied by the solar panel assembly to a solar-panel-assembly support structure coupled thereto when the solar panel assembly is subject to a wind loading is less than a design load for the solar panel assembly subject to the wind loading based on a sum of a first-solar-panel net pressure and a second-solar-panel net pressure determined independently.

A solar tracking system including a plurality of bases, a torque tube supported by the plurality of bases and configured to support a plurality of solar modules, and a drive device operably connected to the torque tube and arranged to translate the torque tube in a direction parallel to its longitudinal axis. The solar tracking system also includes a plurality of helical guides operably connected to the torque tube, and a plurality of cam assemblies, wherein upon linear movement of the torque tube, interaction between the helical guides and cam assemblies causes the torque tube to rotate about its linear axis.

A support basement adapted to support fixedly mounted or extensible and collapsible photovoltaic panels that comprises a plurality of triangular arrays (53) interconnected by tubular members (21) and constructed with links (54, 55) and radially extending tubular members (1). Profile members (24, 30, 84) extending longitudinally along each photovoltaic panel connect the profile frames (37, 39, 69) of the photovoltaic panels to underlying triangular arrays (53) by means of connector assemblies comprising bolts (10) and nuts (12). Adjustable connector assemblies comprising bolts (27) and nuts (29a, 29b) are used to connect bottom links (55) of triangular arrays (53) with profile members (41) based onto ground pillars (51). A retraction mechanism of the photovoltaic panels offering protection from adverse weather conditions and during night periods comprises sequentially connected X-configured assemblies with an elongate screw (72) rotatable within nuts (71) at the ends of a terminal X-configured assembly proximally to the protective housing (86).

The invention relates to an assembly for installing solar panels on a base, and in particular a substantially flat base, comprising at least two solar panels and a mounting system for coupling the solar panels to one another, wherein the solar panels, in a position in which they are installed on the base, enclose an angle with respect to one another. The invention also relates to a mounting system comprising a connecting element which can be subjected to compressive loads, for connecting sides of two solar panels which face one another in the installed position and a connecting element which can be subjected to tensile loads, for limiting the angle enclosed by the solar panels with respect to one another. The invention additionally relates to a method for installing solar panels on a base, and in particular a substantially flat base, by means of an assembly according to the invention.

A solar canopy has a solar panel assembly including a first solar panel coupled to a second solar panel and oriented non-parallel with respect to the second solar panel. The solar panel assembly has an effective solar-panel-assembly wind loading less than a sum of a first-solar-panel effective wind loading and a second-solar-panel effective wind loading determined individually. An actual load applied by the solar panel assembly to a solar-panel-assembly support structure coupled thereto when the solar panel assembly is subject to a wind loading is less than a design load for the solar panel assembly subject to the wind loading based on a sum of a first-solar-panel net pressure and a second-solar-panel net pressure determined independently.

A solar canopy has a solar panel assembly including a first solar panel coupled to a second solar panel and oriented non-parallel with respect to the second solar panel. A solar panel assembly support structure is coupled to the solar panel assembly. One or more components of the support structure are manufactured by cold rolling. The solar panel assembly has an effective solar-panel-assembly wind loading less than a sum of a first-solar-panel effective wind loading and a second-solar-panel effective wind loading determined individually. An actual load applied by the solar panel assembly to a solar-panel-assembly support structure coupled thereto when the solar panel assembly is subject to a wind loading is less than a design load for the solar panel assembly subject to the wind loading based on a sum of a first-solar-panel net pressure and a second-solar-panel net pressure determined independently.

A photovoltaic apparatus includes: a power generation part; an angle changeable mechanism configured to support the power generation part so as to be able to change an elevation of the power generation part; a post configured to support the power generation part and the angle changeable mechanism; and a hinge mechanism configured to support the post so as to be able to change an angle of the post relative to an installation surface for the photovoltaic apparatus.

A solar panel assembly comprises a plurality of solar panel arrays, each substantially parallel, where the plurality of solar panel arrays comprises a windward array located at an upwind perimeter of the solar panel assembly, where each of the plurality of solar panel arrays comprises a plurality of racking structures. The rotatable shaft of the windward array comprises a thickness and a length that provides a torsional stiffness, which allows the rotatable shaft of the windward array to deflect 60-80 degrees from a horizontal plane, that is perpendicular to length of the stationary structural member, in response to an applied torque from wind speeds on the windward array in excess of 70 mph, thus positioning the solar panels mounted to the windward array to shield the plurality of solar panel arrays located downwind from the windward array from high wind loads.

A damper assembly for single-axis tracker supported by truss foundations. Truss leg damper brackets are attached to each truss leg and provide a fixed mounting point for the lower end of a damper spring. Different techniques may be used to effect mechanical engagement between the leg bracket and truss leg to prevent movement under load. Aligning each damper spring with a truss leg may eliminate moments that must ordinarily be resisted when damper springs are attached to a monopile foundation.