A dual axis solar array tracker for supporting a plurality of solar energy harvesting elements at a plurality of solar collector nodes. Two perpendicular axes of movement, specifically a rotation axis at a rotatable transverse beam and a tilt axis relative to the axis of the transverse beam, enable accurate orientation in a stable configuration. The dual axis design of the solar tracker enables the movement of solar collectors such that they can be directed towards the sun wherein incoming solar rays are perpendicular to the solar cell element of the solar collector to optimize collection of solar radiation. The present solar tracker array also enables integrated solar, electrical and/or thermal energy cogeneration.

Modular tracker systems that include at least first and second tables or are continuous without the use of tables, a single motor driving the first and second tables, first and second intra-table drive shafts and an inter-table drive shaft. Each table includes a support structure including first and second mounting posts, a frame supported by the support structure, at least one solar panel supported by the frame, and first and second gearboxes being concentrically aligned for each table. The first and second gearboxes are each configured to produce first and second outputs. The first output has a first rotational speed, and the second output has a second rotational speed less than the first rotational speed, and is operatively coupled to the frame. The inter-table drive shaft couples the second gearbox of the first table with the first gearbox of the second table, whereby the first and second tables are rotated synchronously.

The application relates to a quantitative output apparatus and a group-control tracking support. The quantitative output apparatus includes: an actuator comprising an output wheel, an auxiliary wheel, and a passage portion; a transmission rope guided between the output wheel and the auxiliary wheel and passing through the passage portion; and a driving device for driving the transmission rope to move in the passage portion of the actuator. The transmission rope comprises a thick rope portion and a thin rope portion. When the thin rope portion passes through the to passage portion, the thin rope portion does not drive the output wheel to rotate. When the thick rope portion passes through the passage portion, the thick rope portion frictionally drives the output wheel to rotate.

The present invention relates to a two axis tracking system (100). The present invention includes a frame (102), a solar panel PV module (112), an upper beam (114), a selectively flexible bracket (116), a first supporting pillar (118), a second supporting pillar (140), a lower beam (120), first strut (126), a second strut (146). The first supporting pillar (118) and the second supporting pillar (140) together act as the fixed link. The frame (102) acts as the rotating link and the lower beam (120) acts as the translating link. The first strut (126) and the second strut (146) together act as the fourth link connecting the frame (102) and the lower beam (120). The translation of the lower beam (120) causes rotation of the frame (102) in north-south direction. The PV module (112) is mounted on the frame (102) are rotated in east-west direction by translation motion of the upper beam (114).

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 solar tracker waterless cleaning system for cleaning solar panels of a solar tracker being able to be positioned at a pre-determined angle, including a docking station and an autonomous robotic cleaner (ARC), the docking station coupled with an edge of the solar tracker, the

ARC including at least one rechargeable power source, at least one cleaning cylinder and a controller, the cleaning cylinder including a plurality of fins which rotates for generating a directional air flow for pushing dirt off of the surface of the solar tracker without water, the controller including a motion sensor for determining an angle of the solar tracker and a heading of the ARC, the docking station including at least one electrical connector for recharging the rechargeable power source, the controller for controlling a cleaning process of the ARC and for transmitting and receiving signals to and from the ARC.

The solar tracking arrangement enables a plurality of parallel arranged PTCs to be directed towards the travelling sun. The solar tracking arrangement comprises a drive means, a transmission means, and a plurality of conversion means. The transmission means are connected with the drive means and to each of the plurality of conversion means. The transmission means is configured to convey an operating movement caused by the drive means to the plurality of conversion means, and each of the conversion means is configured to convert the conveyed operating movement into a pivoting movement of a respective one of the plurality of PTCs about a focus line, such that each of the pivoting movements directs the respective PTC towards the travelling sun. One or more of the conversion means are adjustably connected with the transmission means in a direction along the transmission means.

The present invention relates to a photovoltaic plant including a plurality of units each having at least one respective photovoltaic panel, a support structure of the plurality of units designed to support the latter at a distance from the ground (GR).

A solar tracker waterless cleaning system for cleaning solar panels of a solar tracker being able to be positioned at a pre-determined angle, including a docking station and an autonomous robotic cleaner (ARC), the docking station coupled with an edge of the solar tracker, the ARC including at least one rechargeable power source, at least one cleaning cylinder and a controller, the cleaning cylinder including a plurality of fins which rotates for generating a directional air flow for pushing dirt off of the surface of the solar tracker without water, the controller including a motion sensor for determining an angle of the solar tracker and a heading of the ARC, the docking station including at least one electrical connector for recharging the rechargeable power source, the controller for controlling a cleaning process of the ARC and for transmitting and receiving signals to and from the ARC.

A handling system for receptor devices of solar energy suitable for allowing the handling of said devices on a first axis and on a second axis, substantially orthogonal with respect to each other, said system being constrainable on fixed structures composed of supporting poles kept in position by a network of tie-rods. The system comprises a main tube rotating around said first axis, to which a plurality of secondary tubes are connected, also rotating around their own axis, fixed substantially perpendicularly to the main tube, the receptor devices being fixed on said secondary tubes. The main rotating tube comprising both the handling mechanism around the first axis and the handling mechanism around the second axis activated by a respective first motor and second motor.