A deployable solar array apparatus. There is a telescoping mast, being actuatable between an extended mode and a retracted mode; a pivoting head, coupled to a top portion of the telescoping mast; a plurality of arms, circumferentially and pivotally coupled to the head and extending outwardly therefrom, and actuatable between an extended mode and a retracted mode; and a plurality of solar panels coupled to exterior surfaces of the head and arms.

A solar tracker including a drive device, a D-shaped torque tube section configured to be rotated by the drive device, and at least one bearing configured to receive the D-shaped torque tube section, the D-shaped torque tube being suspended between the drive device and the bearing.

One or more embodiments of a system including a laser emitting device and a target is disclosed. The laser emitting device includes a connector configured to connect to a device having a flat top extending in a first plane and a flat side extending in a second plane, and a laser emitter connected to the connector such that when the connector is connected to the device, the laser emitter is configured to emit a laser in a first direction parallel to the first plane and the second plane. The target includes a body, a tray including at least one slit in a front side of the tray configured to allow passage of the laser into the tray, a neck connecting the body to the tray, and legs connected to the body and configured to support the body, neck, and tray.

One or more embodiments of a system including a laser emitting device and a target is disclosed. The laser emitting device includes a connector configured to connect to a device having a flat top extending in a first plane and a flat side extending in a second plane, and a laser emitter connected to the connector such that when the connector is connected to the device, the laser emitter is configured to emit a laser in a first direction parallel to the first plane and the second plane. The target includes a body, a tray including at least one slit in a front side of the tray configured to allow passage of the laser into the tray, a neck connecting the body to the tray, and legs connected to the body and configured to support the body, neck, and tray.

A solar tracker bearing assembly has a rotating element sandwiched between two mounting brackets and held together by fasteners. The rotating element includes an arc-shaped slot such that the rotating element can pivot against the fixed mounting brackets. Bearings may be positioned within the arc-shaped slot. The rotating element can be configured to accept toque tubes of various cross-sections.

A solar tracking system including a plurality of bases, a torque tube supported by the plurality of bases and configured to support a plurality of solar modules, and a drive device operably connected to the torque tube and arranged to translate the torque tube in a direction parallel to its longitudinal axis. The solar tracking system also includes a plurality of helical guides operably connected to the torque tube, and a plurality of cam assemblies, wherein upon linear movement of the torque tube, interaction between the helical guides and cam assemblies causes the torque tube to rotate about its linear axis.

A solar tracking system for tracking the orientation of solar energy is disclosed. The solar tracking system may be integrated with solar cells and solar concentrators. The solar tracking system may have a first (22) and second (24) tracker module array that are opposite from another, aligned in substantially identical orientation, and form a tracker module pair array (1000). Tracker module pairs (12, 14; 12, 144) may allow motion relative to one another while maintaining substantially identical orientation. Solar concentrators may be attached to opposing tracker modules of a tracker module pair forming an array of solar concentrators. A base bar array (28) may be coupled to at least one tracker module pair. A transmission may operably rotate the base bar array and the tracker module pair array simultaneously.

A solar tracker bearing apparatus mountable to an upright support post for rotatably supporting a torque tube beam of a solar tracker assembly and including: a rotatable bearing assembly supported for rotation about an axis of rotation by a stationary saddle assembly. The rotatable bearing assembly includes a central portion and first and second spaced apart arcuate peripheral portions, the central portion defining a torque tube beam slot, the first arcuate peripheral portion including a first arcuate rim bearing and the second arcuate peripheral portion including a second arcuate rim bearing, and the first and second rim bearings being spaced apart in a direction parallel to the axis of rotation of the rotatable bearing assembly. The stationary saddle assembly includes a first arcuate bearing race slidably supporting the first arcuate rim bearing and a spaced apart second arcuate bearing race slidably support the second arcuate rim bearing.

A pivoting unit for a tracking apparatus for solar modules, comprising at least one cross member pivotable about a pivot axis, at least one drive arch, which is connected to the at least one cross member and has a plurality of drive recesses and a plurality of retaining recesses, and at least one rotatably mounted drive unit, the rotatably mounted drive unit being designed such that it engages in at least one of the drive recesses of the drive arch in order to pivot the at least one cross member. The drive unit is designed in such a way that it engages in at least one of the retaining recesses in order to hold the cross member in a pivoted position.

A single axis slew driving system with integrated sensors and transducers including a housing defining a cavity, a rotor assembly rotatably mounted within the cavity supporting an axle with a gear plate affixed thereto and gear teeth positioned along a periphery thereof, a driving gear rotatably mounted in the housing meshing with the gear teeth, and a drive motor attached to the driving gear for rotation of the driving gear and one of: a thermocouple embedded in the housing to provide an indication of the temperature adjacent the driving gear; an absolute position sensing system including a movement tracking device mounted in the housing and extending into the cavity of the housing; limit switches mounted on the outer periphery of the housing; an integrated accelerometer and communication assembly; and an integrated torque routing solenoid mounted on an outer periphery of the housing.