The invention relates to a lattice-form support beam having three side members that extend in parallel in a main direction of extension of the beam and are connected together by cross members and tie rods via securing plates secured to the side members. Each securing plate (8c) secured to a given side member (4) has two radial flat fins (11a, 11b), each comprising a securing orifice. The first fin (11a) is used to removably secure the ends of a first cross member (6), of a first tie rod (9a) and of a second tie rod (9b), which are secured to one another by a first single bolt system (14) passing through the securing orifice of the first fin. The second fin (11b) is used to removably secure the ends of a second cross member (7), of a third tie rod (9c) and of a fourth tie rod (9d), which are secured to one another by a second single bolt system (17) passing through the securing orifice of the second fin.

A motorized platform comprising one or more rails of solar panels is disclosed. The motorized platform includes one or more solar panel support devices. The solar panel support devices include a solar panel base configured to support one or more solar panels. The solar panel support devices include a compression ball joint connected to the solar panel base comprising axial rotational movement. The solar panel support devices include a plurality of wire rods configured to provide tension to the solar panel base. The motorized platform also includes one or more motors and springs.

The present disclosure relates to a simple, lightweight, cost-effective, aesthetically pleasing, and strong system for mounting solar panel tiles (or other tiles/panels) over a roof (surface). The system includes frames (footage) parallelly positioned over the surface using reference bars passing through the frames, and bolts/screws to couple the frames to the surface. The frames include C-shaped grooves at both ends. Each groove is configured with a flat spring that is coupled to the grooves using a spring fixing bracket. Further, Z-shaped clamps are coupled at the bottom surface of the tiles to form a tile assembly. The spring is adapted to be pressed upon application of a force while mounting the tile assembly in the frames, which allows one side of the tile assembly, and the Z-shaped clamp on the other side of the tile assembly to be accommodated and locked in the two opposite C-shaped grooves of the frames.

Systems and methods for providing and controlling solar panel arrays are provided. The solar panel array may include one or more articulating joints that may provide variability in the arrangement of solar panels, which may allow the solar panel array to be distributed over varying types of underlying surfaces. The articulating joints may allow orientations of solar panels to be different relative to one another. The articulating joints may convey rotational force across the joints, so that a rotational force used to drive a first solar panel may also be conveyed across the joint and used to drive a second solar panel. The controls system may include row-specific semi-autonomous, or autonomous, controllers as well as controllers to interface with multiple rows. The controllers may include sensors to measure system power generation and basic operations aspects of the solar field to directly measure, or infer, module shading within the solar field. The controller may use this shading and operations data to identify shading, mitigate shading, identify methods to increase power generation, and identify optimum tilt angles for the tracker rows.

Systems and methods for providing and controlling solar panel arrays are provided. The solar panel array may include one or more articulating joints that may provide variability in the arrangement of solar panels, which may allow the solar panel array to be distributed over varying types of underlying surfaces. The articulating joints may allow orientations of solar panels to be different relative to one another. The articulating joints may convey rotational force across the joints, so that a rotational force used to drive a first solar panel may also be conveyed across the joint and used to drive a second solar panel. The controls system may include row-specific semi-autonomous, or autonomous, controllers as well as controllers to interface with multiple rows. The controllers may include sensors to measure system power generation and basic operations aspects of the solar field to directly measure, or infer, module shading within the solar field. The controller may use this shading and operations data to identify shading, mitigate shading, identify methods to increase power generation, and identify optimum tilt angles for the tracker rows.

An earth mount enabled utility scale solar photovoltaic array having a plurality of solar panels is supported on the ground at edge portions of the solar panels. The panels are interconnected in at least one series-connected string, in which said at least one series-connected string extends along adjacent or closely adjacent solar panels along at least two rows so that the string has a distance between terminal ends of the series connection less than a lengthwise dimension of the solar panels constituting the string.

An earth mount enabled utility scale solar photovoltaic array having a plurality of solar panels is supported on the ground at edge portions of the solar panels. The panels are interconnected in at least one series-connected string, in which said at least one series-connected string extends along adjacent or closely adjacent solar panels along at least two rows so that the string has a distance between terminal ends of the series connection less than a lengthwise dimension of the solar panels constituting the string.

A solar tracker, solar array, and method of designing a solar tracker or array including a plurality of piers, a torque tube supported by the piers, each pier having a common reveal from the earth and the torque tube has a relative angle from a first pier to a second pier of between 0.25 and about 0.75 degrees.

A solar tracker, solar array, and method of designing a solar tracker or array including a plurality of piers, a torque tube supported by the piers, each pier having a common reveal from the earth and the torque tube has a relative angle from a first pier to a second pier of between 0.25 and about 0.75 degrees.

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 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.