A clamping apparatus secures a photovoltaic module to a rail. The clamping apparatus includes a bolt extending between a first end and a second end of the bolt. The clamping apparatus includes a clamp defining a bolt opening into which the bolt is received and a support structure. The support structure positions the clamp at a first location on the bolt. The first location is a first distance from a top rail surface plane within which a top surface of the rail lies. The support structure is adjustable to position the clamp at a second location on the bolt. The second location is a second distance from the top rail surface plane. The first distance is different than the second distance. The support structure has a support structure thickness corresponding to a third distance that is less than the first distance and less than the second distance.

A PV array rail mounting system for use on support structures. In an aspect, the PV array rail mounting system includes rails and splice foot connectors. In an aspect, the splice foot connectors can support one or two rails, eliminating the need of a splice.

Systems and methods for mounting solar panels include a curb assembly coupled to a top surface of a roof. An end of a solar panel rests on a portion of the assembly. An astragal is located with a portion of the astragal extending over the edge of the solar panel. A fastener is engaged through the astragal and the curb assembly such that a portion of the astragal contacts and compressively engages the top surface of the supported solar panel edge, whereby the solar panel is mounted to the roof.

A modular solar skid includes a base including a skid, a panel support structure extending from the skid, at least one solar panel coupled to the panel support structure, and at least one enclosure coupled to the skid. The at least one enclosure is located within a cavity defined between the skid and the panel support structure.

A panel (assembly) having an inner panel member (sheet) and an outer panel member (sheet), with the member being secured to the member so that the member applies an outward force to the first member.

A modular solar skid includes a base including a skid, a panel support structure extending from the skid, at least one solar panel coupled to the panel support structure, and at least one enclosure coupled to the skid. The at least one enclosure is located within a cavity defined between the skid and the panel support structure.

Systems and methods for mounting solar panels include a curb assembly coupled to a top surface of a roof. An end of a solar panel rests on a portion of the assembly. An astragal is located with a portion of the astragal extending over the edge of the solar panel. A fastener is engaged through the astragal and the curb assembly such that a portion of the astragal contacts and compressively engages the top surface of the supported solar panel edge, whereby the solar panel is mounted to the roof.

A solar tracking carport comprises a supporting structure including a foundation and at least two columns connected or connectable to the foundation; a three-dimensionally rigid canopy deck having a length from a first edge to a second edge of at least one car, the three-dimensionally rigid canopy deck including one or more upper blocks, each of the upper blocks being rigid at least in its longitudinal direction, each of the upper blocks including at least one solar panel; a deck frame configured to support the one or more upper blocks, the deck frame including a torque transmitting member; a rotation enabling connection configured to rotatably connect at least the torque transmitting member of the three-dimensionally rigid canopy deck to the at least two columns of the supporting structure; and a drive system configured to control tilting of the three-dimensionally rigid canopy deck about the supporting structure over one axis of rotation to a first maximum angle in a first direction and to a second maximum angle in a second direction, the first maximum angle preventing the first edge of the three-dimensionally rigid canopy deck from going below a first minimum threshold height, the second maximum angle preventing the second edge of the three-dimensionally rigid canopy deck from going below a second minimum threshold height.

The invention discloses an automatic surface cleaning vehicle for photovoltaic (PV) panels (102) that is capable of moving on the surface of the said panel. The system comprises of a surface cleaning device (816) mounted on a retractable supporting frame which is collectively called as an Unmanned Autonomous Vehicle (UAV) (101). The invention provides for an automatic cleaning system that also collects data about the amount of dust accumulated on the surface of the photovoltaic panel (102) and details of any damage found on the surface. A motor driving circuit is further comprised in the unmanned, autonomous vehicle (101) to control direction and motion of the unmanned, autonomous vehicle (101).

The present invention provides a solar heat collecting device having good heat collection efficiency. A uniaxial solar-tracking reflective mirror group is arranged such that each longitudinal axis thereof faces the same direction. A first biaxial solar-tracking reflective mirror group and a second biaxial solar-tracking reflective mirror group are arranged lined up in a direction orthogonal to the longitudinal axis direction of uniaxial solar-tracking reflective mirrors. The uniaxial solar-tracking reflective mirror group is arranged so as to be sandwiched on both sides by the first biaxial solar-tracking reflective mirror group and the second biaxial solar-tracking reflective mirror group. Each mirror group sends solar heat received during uniaxial or biaxial tracking in accordance with the position of the sun, to a heat collecting device.