A variable length shaft is installed between one of the posts in the single axis tracker and a yardarm extending from the row tube, perpendicular to it. Stops in the variable length shaft correspond to the shaft length when the single axis tracker is at its maximum rotation angle to the east and to the west. The shaft provides a structural support that bears some of the self-weight torque. In this way the tracker table will not exceed the design maximum tilt to the east or west and the tracking accuracy of the system will meet the desired level.

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 absorber system solves problems of known absorber systems for use in solar fields in that the absorber tube is suspended on a rail below an absorber cover. The design also makes it possible to move measuring and cleaning robots and the like along the absorber tube more and allows the absorber tube and the secondary reflector to be jointly suspended, whereby an exact mutual alignment between the two components is enabled.

An improved bushing assembly for a solar tracker is provided. The bushing assembly includes a bushing that is seated within a ring-shaped bracket. The bushing includes an annular ridge that is disposed within an annular channel in the bracket. Alternatively, the bracket includes an annular ridge that is disposed within an annular channel in the bushing. In each configuration, the bushing is retained in position during installation of the bracket. The bushing defines an internal passage for a solar tracker crossbar and provides complete rotational freedom for the crossbar about its lengthwise axis and limited rotational freedom for the crossbar about the remaining orthogonal axes. Additional features including side skirts for minimizing the entry of debris between the bushing and the bracket, a resilient latch for securing bracket sections together, and vertical openings in the bracket sections to allow debris to escape.

A method of installing a solar panel assembly that includes a first beam, a second beam and a third beam where the first and second beams are parallelly spaced and perpendicular to the third beam, and further includes a plurality of purlins, a semicircular ring fastened to the third beam, and a plurality of photovoltaic panels between adjacent ones of the plurality of purlins to form the solar panel assembly, the method comprising lifting the solar panel assembly and rotatably attaching it to a post by inserting a pin into a first bore in a flange extending from the third beam and into a second bore in the post, where the first and second bores are coaxial such that the solar panel assembly has a range of rotational motion about the pin, and fastening proximate and distal ends of the first and second beams to distal and proximate ends of adjacent solar panel assemblies.

A solar tracker with orientable solar panels arranged in rows, having at least two rows of photovoltaic modules (1) carrying the solar panels (2), arranged on pillars (6), the solar panels (2) mounted on respective rotation axes (3) longitudinally associated with each other by rotation transmission (5), driven by at least one motor (4) establishing the movement of all the solar panels (2) from a single actuation point, the rows of photovoltaic modules (1) related to each other by at least one transmission bar (7), joined by universal joints (8), to respective rotation transmission (5), the drive motor (4) is coupled in longitudinal alignment with respect to a transverse transmission (12) that meshes with a rotation transmission (5) and with respect to which the universal joint (8) of one end of the corresponding transmission bar (7) is joined in longitudinal alignment on the other side.

In an example, the solar tracker has a clamp assembly configured to pivot a torque tube. In an example, the assembly has a support structure configured as a frame having configured by a first and second anchoring region. In an example, the support structure is configured from a thickness of metal material. In an example, the support structure is configured in an upright manner, and has a major plane region. In an example, the assembly has a pivot device configured on the support structure, a torque tube suspending on the pivot device and aligned within an opening of the support, and configured to be normal to the plane region. In an example, the torque tube is configured on the pivot device to move about an arc in a first direction or in a second direction such that the first direction is in a direction opposite to the second direction.

A distributed torque, single axis solar tracking system includes a plurality of spaced apart mounting posts with selected posts having an electrically controlled actuator mounted thereon. A torque structure extends between the actuators to distribute rotational torque on the torque structure. A plurality of solar panels is connected to the torque structure. Electrical apparatus is coupled to each actuator and designed to be coupled to a power source so that when the electrical apparatus is coupled to the power source, the plurality of actuators is energized to rotate simultaneously a desired amount. Whereby the plurality of solar panels is rotated the desired amount as the plurality of actuators rotates.

A driveline joint may include a driveline shaft that has a plurality of slots and a shaft coupling positioned in an interior of the driveline shaft in which the shaft coupling includes one or more openings with each of the openings corresponding to one or more respective slots of the plurality of slots included in the driveline shaft. The driveline joint may include one or more spherical bearings that are each positioned between an interior lateral surface of the driveline shaft and an exterior lateral surface of the shaft coupling and against one of the openings of the shaft coupling. The driveline joint may include one or more fasteners, wherein each of the fasteners extends through one of the slots and one of the openings of the shaft coupling.

In an example, the solar tracker has a clamp assembly configured to pivot a torque tube. In an example, the assembly has a support structure configured as a frame having configured by a first and second anchoring region. In an example, the support structure is configured from a thickness of metal material. In an example, the support structure is configured in an upright manner, and has a major plane region. In an example, the assembly has a pivot device configured on the support structure, a torque tube suspending on the pivot device and aligned within an opening of the support, and configured to be normal to the plane region. In an example, the torque tube is configured on the pivot device to move about an arc in a first direction or in a second direction such that the first direction is in a direction opposite to the second direction.