A solar tracking system includes a first solar tracking row and a second solar tracking row, each of the first and second solar tracking rows including a plurality of support piers, a torque tube rotatably supported on the plurality of support piers, a plurality of solar modules coupled to the torque tube, and at least one damper coupled to the plurality of support piers at a first end and coupled to a portion of the torque tube at a second, opposite end, and a connecting rod coupled to a portion of each torque tube of the first and second solar trackers such that rotation of the torque tube of the first solar tracker row effectuates movement of the connecting rod, which in turn, effectuates rotation of the torque tube of the second solar tracking row.

A photovoltaic chip is designed to receive light energy from a light box arranged above it. The light can be sunlight guided by optical-fibers. For ease of replacement the photovoltaic chips can be supported in a carrier which is movably housed in a block. The blocks are housed on racks and are movable for ease of repair and replacement.

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.

A horizontal solar tracker (1) with a configuration that ensures the transmission of the turning movement generated by the drive element to the rotating beam and to the connecting rod-crank mechanism, prevents possible breaks and weaknesses in the joining areas, and is easy to transport. It comprises at least one front rotating beam (3) and at least one rear rotating beam (12) that can turn, joined by means of a connecting rod-crank mechanism (4). A drive assembly (2) generates the turning movement in a mobile element (22). The front rotating beam (3) has a first joining sector (31) that can be coupled to the mobile element (22) and the connecting rod-crank mechanism (4) comprises a tubular portion (42) that clasps the rotating beam (3) and a second joining sector (43) that can be coupled to the mobile element (22).

A connection system of a transmission rod for solar trackers of rows of solar panels, the transmission rod of which connects a main rotation shaft to a motorised rotation module to a driven shaft with a rotation module without a motor, being connectable to the rotation modules by universal joints that are fastened to the connection output, wherein the universal joint has at one connection end corresponding to the connection output, and at the other end of the universal joint corresponding to a tubular connection output with a polygonal cross section for connection with the transmission rod correspondingly having a polygonal configuration, and with a first end longitudinally slidably connectable to the connection output of a first universal joint and with a second end fixedly connectable to the connection output of a second universal joint.

A track-wheel based device is disclosed. The track-wheel based device may include a longitudinal member substantially perpendicular to an axis of motion of the track-wheel based device. The track-wheel based device may further include a first lateral member and a second lateral member, each being substantially parallel to the axis of motion of the track-wheel based device. The longitudinal member may be coupled to the first lateral member at a first location of the first lateral member and to the second lateral member at a first location of the second lateral member. The first lateral member and the second lateral member may be configured to undergo a relative angular rotation, in response to a planar misalignment of four or more points of contact between two or more guide tracks for the track-wheel based device and the track-wheel based device.

The present invention concerns a solar tracker (1000) comprising at least: A drive module (1100) comprising at least one mobile device comprising at least: At least one additional module (1200) configured to be driven by the drive module (1100), each additional module (1200) comprising at least one additional mobile device comprising at least:
characterized in that: Said solar tracker (1000) comprises at least one kinematic device (1300) for coupling said drive module (1100) and said additional module (1200); Said kinematic coupling device (1300) comprising at least one first part (1330) and at least one second part (1340), said first part (1330) being entirely supported by the mobile device of the drive module (1100) and said second part (1340) being entirely supported by the additional mobile device of the additional module (1200).

A multi-drive solar-tracking photovoltaic (PV) system having several PV modules mounted on a torque tube is described. In an example, several motor drives input torque to the torque tube, and the motor drives are controlled by a single controller. The torque tube may include several sections joined by a torque tube coupler. For example, the torque tube coupler may having a medial section and end sections to join to the torque tube sections. The medial section and the adjoined torque tube sections may have a same outer diameter.

The present invention concerns a solar tracker (1000) comprising at least: a mobile device (1100) comprising at least: a table (1110) comprising at least one solar energy collector device (1112); a support structure (1120); first support arch (1130) and a second support arch (1150) configured to support the support structure (1120); a first ground support (1140) and a second ground support (1160) configured to support the first support arch (1130) and the second support arch (1150), respectively; a kinematic drive device (1141);
the solar tracker (1000) being characterized in that: the support structure (1120) is a beam formed of a lattice structure comprising: at least one first, one second and one third longitudinal members; a plurality of crossmembers; a plurality of tie rods (1225).

A calibration process of a solar panel installation measures current from a plurality of tracker tables, and based upon the time of day of the detected shade transitions, day of the year and the location of the solar panel installation, the time difference of the detected shade transition for each tracker panel can be used to determine the relative elevation of adjacent tracker tables. The calculation is performed using the known angle of the tracker and the elevation of the sun when the transition occurred to calculate the height offset of the tables. This transition of charging current marks the point where shading ended and the sun elevation is used to calculate the height offset of adjacent tables. This calculation uses the known angle of the tracker and the elevation of the sun when shading ended to calculate the height offset of the tables.