In various embodiments, a stabilization assembly may comprise a shaft, a foot, a snap plate and a nut. The foot may be operatively coupled to the shaft. The snap plate may be configured to surround and retain the shaft. The nut may be installable on the shaft and engagable to raise and lower a foot. The stabilization assembly may be installed in a solar panel coupling. The foot may be driven to engagement with a roof surface in response to the coupling being installed on the roof.

A drive arrangement is provided comprising at least one drive device, which is rotatable about a rotational axis, comprises at least one drive element and at least one retaining element, the drive element being arranged offset in the radial direction in relation to the retaining element, and at least one output unit, which is rotatable or pivotable about an axis, the output unit comprising at least one drive recess and at least one retaining recess, the drive element being associated with the at least one drive recess and engaging in the drive recess to drive the output unit, and the retaining element being associated with the retaining recess and engaging in the retaining recess to hold the output unit in a set position, the drive element having a cross section that is different from a circular cross section and that is curved at least in some sections, and/or the drive recess widening in the radial direction in order to define an entry opening for the drive element.

A solar panel assembly includes a first torque tube and a mounting rail including a cutout portion that attaches to the first torque tube. The mounting rail including an upper portion configured for mounting multiple solar panels. The mounting rail establishes and maintains an electrical ground path from the solar panel assembly to the first torque tube.

An example device for mounting for a solar array may include a solar panel carrier configured to receive a solar array to form a panel assembly; a pivot configured to pivotably secure the solar panel carrier with respect to a support structure; and/or a restoring moment element operatively connected to the solar panel carrier and configured to exert a restoring moment on the solar panel carrier opposite in direction and approximately equal in magnitude to a gravitational moment of the panel assembly when the solar panel carrier is tilted to various angular positions. When the solar panel carrier is at a nominal angular position, a center of gravity of the panel assembly may be above and substantially vertically aligned with the pivot axis.

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.

In various embodiments, a stabilization assembly may comprise a shaft, a foot, a snap plate and a nut. The foot may be operatively coupled to the shaft. The snap plate may be configured to surround and retain the shaft. The nut may be installable on the shaft and engagable to raise and lower a foot. The stabilization assembly may be installed in a solar panel coupling. The foot may be driven to engagement with a roof surface in response to the coupling being installed on the roof.

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.

The adjustable bracket for a solar panel is configured for use with a solar panel array and the associated panel rack. The adjustable bracket for a solar panel aligns each of the one or more solar panels during the attachment of the one or more solar panels to the panel rack. The adjustable bracket for a solar panel comprises plurality of rafters and a panel support. The panel support attaches to the plurality of rafters. The plurality of rafters attaches to the panel rack. The panel support prevents movement by the one or more solar panels in the direction of the pitch. The plurality of rafters prevent lateral movement of the one or more solar panels relative to the pitch.

A mounting bracket (320) for trapezoidal rib profiles is disclosed. This mounting bracket (320) includes an upper section (330) and a lower section (350). A first leg (352a) in a second leg (352b) extend from a lower portion of the upper section (330) in diverging relation to one another. Each of these legs (352a, 352b) is deflectable through a certain range of motion to accommodate installation of the mounting bracket (320) on a variety of different trapezoidal rib profiles.

A system includes a first torque tube with a weld seam. A mounting rail includes a cutout portion with a weld seam alignment slot. The first torque tube is configured for placement in the cutout portion. The weld seam of the first torque tube is configured for placement within the weld seam alignment slot.