A system for use on a surface to collect solar energy from the sun has a stand, a module, and solar collector(s). The stand supportable on the surface has rotational points rotatably supporting the module so it can rotate about a first axis of rotation. A first drive disposed on the stand is operable to provide first rotation, and a cable connected between a hoop pulley of the module and the first drive on the stand can rotate the module about the first axis to direct the solar collector(s) toward the sun. The solar collector(s) disposed on the module can be photovoltaic cells for collecting solar energy. A second drive on the module can rotate an adjacent solar collectors on the module using pulleys and cable. Reflectors on the collectors can focus the sun rays to photovoltaic cells. The second drive can rotate the collectors about a second axis, carried by the first axis, to direct the solar collector(s) toward the sun.

A system for use on a surface to collect solar energy from the sun has a stand, a module, and solar collector(s). The stand supportable on the surface has rotational points rotatably supporting the module so it can rotate about a first axis of rotation. A first drive disposed on the stand is operable to provide first rotation, and a cable connected between a hoop pulley of the module and the first drive on the stand can rotate the module about the first axis to direct the solar collector(s) toward the sun. The solar collector(s) disposed on the module can be photovoltaic cells for collecting solar energy. A second drive on the module can rotate an adjacent solar collectors on the module using pulleys and cable. Reflectors on the collectors can focus the sun rays to photovoltaic cells. The second drive can rotate the collectors about a second axis, carried by the first axis, to direct the solar collector(s) toward the sun.

Solar-operated adjustment device for a solar installation including, at least one retaining element for fixing at least one solar element, a swivel device which is designed and intended to swivel the retaining element around a support point, wherein the swivel device includes at least one liquid tank, wherein a float of the retaining element is arranged at least in part beneath a filling level of the liquid tank and the float is supported on a perimeter of the liquid tank, and the retaining element can only be swiveled around a support point with respect to a longitudinal axis of the liquid tank by means of its buoyancy and is mounted above the filling level, at least indirectly on the edge of the liquid tank.

An integrated drive leg and mount suitable for solar power devices, such as trough solar concentrators or PV panels. A drive system including a linear actuator is integrated into the support structure. A pulley assembly converts the linear force into rotational motion, thereby providing tracking adjustments for a solar power device following the sun avoiding larger external electric drive motor which are situated between successive solar power devices. The integrated nature enables a smaller gap between solar power devices in solar installations, reduces the effect of induced shadowing, and enables greater collection of solar energy.

Separable bearings for suspended solar enhanced oil recovery concentrators and receivers, and associated systems and methods. A representative bearing includes a receiver attachment member having a first bushing portion and a second bushing portion removably coupled to the first bushing portion, the first bushing portion having an outwardly-facing bearing surface, the receiver attachment member further including a plurality of engagement surfaces positioned to contact an outer surface of a receiver conduit. The bearing can further include a concentrator attachment member having a first element and a second element removably coupled to the first element, the first and second elements each having an inwardly-facing bearing surface positioned to rotatably engage with the outwardly-facing bearing surface of the first bushing portion, the concentrator attachment member further having first and second attachment elements positioned to couple to a solar concentrator.

Drive mechanisms for solar concentrators, and associated systems and methods are disclosed. A representative solar energy collection system includes an at least partially transparent enclosure, a receiver positioned in the enclosure to receive solar radiation passing into the enclosure, a concentrator positioned within the enclosure to focus incoming solar radiation on the receiver, and a drive system operatively coupled to the concentrator to rotate the concentrator relative to the receiver. The drive system can include a drive chain operatively coupled to the concentrator, a drive gear engaged with the drive chain, and a drive motor coupled to the drive gear to rotate the drive gear and rotate the concentrator relative to the receiver.

Solar tracker systems include an array of solar panels, a drive for rotating the array about a longitudinal axis, and a mounting assembly including a plurality of posts and a pivotable frame assembly supporting the array of solar panels on the posts. The frame assembly includes a first frame tube connected to the drive and extending therefrom in a direction parallel to the longitudinal axis and a second frame tube laterally offset from the first frame tube and extending parallel to the first frame tube. The first frame tube and second frame tube are sized to support at least one solar panel of the array of solar panels thereon. The frame assembly further includes a lateral beam attached to the first frame tube and the second frame tube.

A robotic coupling joint system and method are discussed herein, which may be utilized with a daylighting system or photovoltaic system to track sunlight. The system may provide a spherical joint allowing axial motion about two or more axes of the spherical joint. The joint comprises a first plate with four or more sockets, a second plate, a connector, and one or more spheres positioned between the first and second plates. The connector secures the sphere between the first and second plates. The system may also include a stand, an end effector coupled to the stand by the spherical joint, and a mobility system that is capable of actuating the end effector. The mobility system includes two or more linking elements coupled to the end effector, and a motor coupled to the linking elements to actuate the end effector to track sunlight.

Solar tracker systems include an array of solar panels, a drive for rotating the array about a longitudinal axis, and a mounting assembly including a plurality of posts and a pivotable frame assembly supporting the array of solar panels on the posts. The frame assembly includes a first frame tube connected to the drive and extending therefrom in a direction parallel to the longitudinal axis and a second frame tube laterally offset from the first frame tube and extending parallel to the first frame tube. The first frame tube and second frame tube are sized to support at least one solar panel of the array of solar panels thereon. The frame assembly further includes a lateral beam attached to the first frame tube and the second frame tube.

A solar tracking system comprising a platform, a system housing, at least one solar panel, at least one motor, and a cable. The at least one solar panel is attached to the platform and configured to generate electricity from photons. The platform further comprises a sensor device configured to gather information relating to light and temperature. The at least one motor connects to the platform by the cable and is configured to rotate the platform. The at least one motor may also be connected to an actuator on the at least one solar panel and may be configured to adjust the tilt of the at least one solar panel. The system housing comprises a processor communicatively connected to the sensor device and the at least one motor. The processor is configured to activate the at least one motor based on information gathered by the sensor device.