A support assembly for mounting photovoltaic modules on a support surface and a mounting system including the same are disclosed herein. The support assembly may comprise a the body portion including a base portion and at least one upright support member coupled to the base portion, the at least one upright support member comprising an integrally formed ballast tray slot in one side thereof for receiving an upturned edge of a ballast tray; and at least one clamp subassembly coupled to the at least one upright support member of the body portion, the at least one clamp subassembly configured to be coupled to one or more photovoltaic modules. In addition to a plurality of support assemblies, the mounting system may further comprise at least one ballast tray support bracket, the ballast tray support bracket supporting a portion of a ballast tray on the support surface.

An A-Frame solar panel array system is configured to produce a high amount of electrical power for a given amount of ground space with a plurality of solar panels on both a forward beam and a plurality of solar panels on a trailing beam in an elevated position above the ground. This elevated positioning enables more solar panels to be configured over a given amount of ground area. The solar panels are spaced along the trailing and forward beams with a vertical offset between the trailing and forward beams to enable sunlight to pass therethrough to enable exposure to sunlight, through the forward beam array of solar panels onto the trailing beam array of solar panels. A solar panel actuator is configured to rotate the solar panels for increasing solar panel exposure throughout the year. The solar panels may only be configured to rotate trailing/forward.

The invention relates to a system and a method for mounting at least one solar panel on a substantially flat mounting surface. The system comprises thereto a base element, a support structure configured for supporting at least part of at least one solar panel, which is connected to the base element and wherein the support structure comprises a retaining element for retaining at least part of an upper edge of the solar panel and a clamping element configured for clampingly engaging at least part of a lower edge the solar panel.

A truss foundation for supporting single-axis solar tracker drive motors and center structures. An adapter joins a pair of adjacent truss legs and provides a mounting platform to support a drive motor and/or center structure of a solar tracker. The adapter has a pair of connecting portions that are received in the legs of the truss foundation. The adapter may be a unitary structure or consist of a pair of slidably connected members that are joined with fasteners to accommodate truss legs spaced apart at different distances.

A truss foundation for supporting single-axis solar tracker drive motors and center structures. An adapter joins a pair of adjacent truss legs and provides a mounting platform to support a drive motor and/or center structure of a solar tracker. The adapter has a pair of connecting portions that are received in the legs of the truss foundation. The adapter may be a unitary structure or consist of a pair of slidably connected members that are joined with fasteners to accommodate truss legs spaced apart at different distances.

A floating platform for solar panels is provided. The floating platform may include a plurality of plates. Each of the plurality of plates may have a ballast chamber filled with a ballast material. Each of the plurality of plates may further have a float chamber disposed over the ballast chamber. Each of the plurality of plates may further have a channel passing through the ballast chamber and the float chamber. The channel may further have one or more openings to pass water into the ballast chamber and an opening to pass air from the channel. Each of the plurality of plates may further have a locking member. Each of the plurality of plates may further have one or more connection sections for placing one or more strap assemblies. The strap assemblies may be provided for disposing one or more solar panels on the plurality of plates.

A floating platform for solar panels is provided. The floating platform may include a plurality of plates. Each of the plurality of plates may have a ballast chamber filled with a ballast material. Each of the plurality of plates may further have a float chamber disposed over the ballast chamber. Each of the plurality of plates may further have a channel passing through the ballast chamber and the float chamber. The channel may further have one or more openings to pass water into the ballast chamber and an opening to pass air from the channel. Each of the plurality of plates may further have a locking member. Each of the plurality of plates may further have one or more connection sections for placing one or more strap assemblies. The strap assemblies may be provided for disposing one or more solar panels on the plurality of plates.

The invention relates to a system and a method for mounting at least one solar panel on a substantially flat mounting surface. The system comprises thereto a base element, a support structure configured for supporting at least part of at least one solar panel, which is connected to the base element and wherein the support structure comprises a retaining element for retaining at least part of an upper edge of the solar panel and a clamping element configured for clampingly engaging at least part of a lower edge the solar panel.

Fixed-tilt solar arrays constructed from screw anchors. In some cases, purlins are attached directly to truss legs. In others, they are attached to truss caps joining the free end of each truss leg. In still further ones, screw anchors are driven in rows and interconnected by a pair of hinged members, one of which provides a mounting plane for solar panels. Each screw anchor may serve as a connection point for the trailing hinged member of the first foundation and the leading hinged member of the next foundation. In still further cases, a hinged truss cap may be used to accommodate different tilt angles with the same foundation.

Fixed-tilt solar arrays constructed from screw anchors. In some cases, purlins are attached directly to truss legs. In others, they are attached to truss caps joining the free end of each truss leg. In still further ones, screw anchors are driven in rows and interconnected by a pair of hinged members, one of which provides a mounting plane for solar panels. Each screw anchor may serve as a connection point for the trailing hinged member of the first foundation and the leading hinged member of the next foundation. In still further cases, a hinged truss cap may be used to accommodate different tilt angles with the same foundation.