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 photovoltaic cleaning device and a windproof device thereof are provided according to the present application. The windproof device of the photovoltaic cleaning device includes a locking bracket, a locking arm, and a drive device configured to drive the locking arm to move relative to the locking bracket. The locking arm has a locking position of extending into a restricting position of the locking bracket, and a cleaning working position of exiting the restricting position of the locking bracket. During the mounting of the photovoltaic cleaning device, one of the locking arm and the locking bracket is mounted to the cleaning module, and the other is mounted to the supporting frame of the photovoltaic module.

A securing fixture for a photovoltaic cell module that includes a first frame member that extends in a first direction; and a second frame member that extends in a second direction and is adjacent to the first frame member, the second direction being orthogonal to the first direction, the securing fixture being enclosed by a frame member having a corner portion formed by the first frame member and the second frame member. The securing fixture includes an abutting part that is fixed to a trestle and abuts on the trestle; and a holding part that holds the photovoltaic cell module, including a first protrusion that protrudes in a direction opposite to the abutting part, and abuts on an inner surface of the corner portion of the frame member, and a placing part on which the second frame member is placed.

A fastening device which reduces the work by screwing and shortens the installation time has been desired. A fastening device 100 which fastens and supports a plurality of solar cell modules 20 includes a base part 111, a first module support part 113 which has a first support surface 113a and which is provided at the base part to be able to elastically displace, a second module support part 114 which has a second support surface 114a and which is provided at the base part, wherein the second support surface is arranged so that the second support surface is away from the first support surface of the first module support part when not elastically displaced at a constant first interval T2, a third module support part 123 which has a third support surface 123a and which is provided at the base part to be able to elastically displace, and a fourth module support part 124 which has a fourth support surface 124a, which fourth module support part is arranged a constant second interval T3 which is smaller than the first interval T2.

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.

A mechanical solar tracking and solar concentrating system having a Fresnel lens, moveable frame, track, retaining mechanism, and solar collector. The lens focuses solar energy at the collector; the frame holds the collector and lens, keeping them aligned as the frame rotates; and the track guides the frame to maintain a perpendicular orientation to the Sun. The solar collector receives the Sun's rays and the retaining mechanism releases, at established intervals, allowing the frame to rotate to the next location. The cycle repeats, tracking the Sun and concentrating its rays at a focal point, to generate temperatures at the focal point in excess of 500 C. These high temperatures can be exploited in several applications, such as producing drinking water from dirty water; cooking food; disinfecting medical instruments; accelerating fermentation of certain types of flora to produce electricity; generating work for generic purposes; etc.

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.

Support plate adapted for fitting into a photovoltaic panel and allowing the fixing and the integration of this panel onto a building roof, said plate comprising leaktight vertical overlap means, leaktight leteral fitting means adapted for cooperating with a neighboring plate, protruding studs for positioning the plate which are raised, characterized in that the plate comprises a central portion forming a hood which is deliminated by a front face designed to be arranged opposite the photovoltaic panel and a rear face, said hood comprising an aperture adapted for allowing the recovery of air interposed between the photovoltaic panel and the front face of the hood.

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 roof mount system supports a solar panel above a roof and includes a base positioned on the roof and a first fastener connected to the base and extending away from the roof and moveable along the base in a direction generally parallel to the roof. A first clamp supports a bottom surface of a solar panel frame and adjusts the height of the solar panel above the roof by moving the first clamp along a first fastener in a direction perpendicular to the roof. A second clamp is connected to a second fastener and moves with respect to the first clamp perpendicular to the roof. The solar panel is clamped between the first clamp and the second clamp portion. A protrusion extends from the first or second clamp to form an electrical bond between the solar panel frame and the respective first or second clamp.