A method for installing a solar collector can include slip-forming a concrete track including a groove; curing the concrete track; placing a foot of a support structure of a solar collector in the groove; and applying adhesive between the foot and groove. Curing the concrete track optionally can include maintaining wetness of the concrete track for a sufficient period of time after slip-forming the concrete track. The foot optionally can include at least one of an aperture and a tab, and the adhesive flows through the aperture or around the tab. A foot of a support structure of a solar collector also is provided. The foot can be configured to be inserted into a groove and comprising a back wall, a first side wall including a first side tab, a second side wall including a second side tab, a third side wall, a fourth side wall, and a bottom wall.

An aspect of the present disclosure provides solar panel mounting and charging system comprising a hub and a girder assembly. The hub may comprise a plurality of attachment points on its exterior. The girder assembly may comprise a plurality of top girders configured to be mechanically fastened to each other at their proximal ends, and having a distance between their distal ends that is greater than a distance between the proximal ends of the top girders. The girder assembly may also comprise a plurality of bottom girders configured to be mechanically fastened to each other at their proximal ends and the plurality of top girders at their distal ends. The system may further comprise an electric vehicle charging system affixed to the pole, wherein the electric vehicle charging system is configured to receive electrical power from at least one solar panel affixed to the girder assembly.

An A-frame shaped truss foundation system for a single-axis tracker with moderately sloped legs that translate lateral loads into tension and compression without substantially increasing the magnitude of the lateral load force while optimizing material usage. Several such truss foundation systems are installed in a row to support a torque tube of a single-axis solar tracker. An adapter joins ends of adjacent upper legs and separates the truss legs by an angle more than 35-degrees up to 70-degrees. In some cases, the adapter may have an integrated bearing.

An A-frame shaped truss foundation system for a single-axis tracker with moderately sloped legs that translate lateral loads into tension and compression without substantially increasing the magnitude of the lateral load force while optimizing material usage. Several such truss foundation systems are installed in a row to support a torque tube of a single-axis solar tracker. An adapter joins ends of adjacent upper legs and separates the truss legs by an angle more than 35-degrees up to 70-degrees. In some cases, the adapter may have an integrated bearing.

Provided are a helical pile and a bracket module comprising the same. The helical pile includes a column body, at least a helical blade and a loading member. The column body has a fixing end, a loading end opposite to the fixing end, and a body section between the fixing end and the loading end. The helical blade is disposed on the column body between the fixing end and the loading end. The loading member is connected to the loading end of the column body and includes a flange. The ratio of the body diameter of the column body to the blade diameter of the helical blade ranges from 1:3 to 1:7. The helical pile features excellent compression bearing capacity and uplift bearing capacity due to its specific element-size ratio, and is applicable for installation in areas subject to harsh conditions or with peculiar geological features or soil conditions.

Provided are a helical pile and a bracket module comprising the same. The helical pile includes a column body, at least a helical blade and a loading member. The column body has a fixing end, a loading end opposite to the fixing end, and a body section between the fixing end and the loading end. The helical blade is disposed on the column body between the fixing end and the loading end. The loading member is connected to the loading end of the column body and includes a flange. The ratio of the body diameter of the column body to the blade diameter of the helical blade ranges from 1:3 to 1:7. The helical pile features excellent compression bearing capacity and uplift bearing capacity due to its specific element-size ratio, and is applicable for installation in areas subject to harsh conditions or with peculiar geological features or soil conditions.

A single-axis solar tracker consisting of a series of A-frame shaped foundation with actuators attached to each leg that are connected at one end to a common rotating assembly supporting multiple solar panels. Concerted action of the actuators causes the common rotating assembly to rotate about an axis of rotation. The system may include a central torque tube supported by the series of A-frame foundations or a frame assembly that is hingedly attached to each A-frame foundation via a torque arm.

A cross canal support structure for photovoltaic cells is disclosed. The structure includes a major frame having disconnectable and hinged connections to anchors at its corners, on either side of the canal. The major frame carries a plurality of minor frames, which are inclinable at an angle with respect to the major frame with the use of fixed or adjustable mounting plates. The combination of the major frame's tilt and the minor frame tilt enables fabrication of support structures that hold panels at latitude inclination for various portions of a canal.

A solar panel assembly includes a substrate and a solar array coupled to the substrate. The solar array includes a plurality of photovoltaic cells. An optical layer is disposed over the solar array. The optical layer, the solar array, and the substrate together form a solar assembly. A frame surrounds the solar assembly and includes a plurality of frame members. Each frame member of the plurality of frame members includes an arcuate member that forms an aerodynamic outer edge of the frame member.

A center structure support for single-axis trackers to support tracker driver motors and tracker center structures that transfer torque across rows to enable a single tracker motor to rotate the torque tubes of several adjacent rows. A pair of driven screw anchors are joined above ground with a center structure support and a pair of clamp assemblies that capture the driving coupler at the upper end of each screw anchor. The clamp assemblies are captured in distal ends of the center structure support via bolts that enable adjustment center structure relative to the driven legs.