A system and method for cleaning surfaces is disclosed. The system includes an elongated blade configured to remove at least one of dirt, dust, debris and film from a smooth surface. A drive system is provided for causing the blade to contact the entire smooth surface, thereby removing at least a portion of at least one of dirt, dust, debris, and film. A cleaning device automatically cleans the blade before and after the blade is cleaning the smooth surface. In one example, system is part of a heliostat system for use in a solar collection field as part of a concentrated solar power (CSP) plant.

A rotation locking device for use in a row-level sun tracking solar energy collection system includes a housing, a first locking member, a second locking member, and an actuator. The housing is configured to be mounted to a pile and configured to permit a torque tube to extend through the housing. The first locking member has a plurality of circumferentially spaced projections attached to and rotatable with the torque tube. The second locking member is connected to the housing and has a plurality of mating elements for engaging projections of the first locking member. The actuator is configured to relatively move the first and second locking members between an unlocked position in which the mating elements are disengaged from the projections and a locked position in which the mating elements are engaged with the projections to inhibit rotation of the torque tube with respect to the housing.

A solar collector may include a frame for supporting a plurality of photovoltaic (PV) panels. The frame may be adapted to removably attach to a base. The solar collector may include a first panel assembly, including at least one of the plurality of PV panels, pivotally attached to the frame about a first axis. The solar collector may also include a second panel assembly, including at least one of the plurality of PV panels, pivotally attached to the first panel assembly. The second panel assembly may collectively move with the first panel assembly about the first axis and to pivot relative to the frame, and to pivot about a second axis that is substantially parallel to and radially offset from the first axis, to move between a deployed position and a retracted position.

A frame enhancer may include a body, a first extension extending from the body and including a first notch, a second extension extending from the body, and a third extension extending from the body and including a second notch. The first extension and the second extension may define a first slot. The second extension and the third extension define a second slot. The first slot may be configured to receive a first side of a support arm, and the second slot may be configured to receive a second side of the support arm. The first notch may be configured to lock the first side of the support arm in the first slot, and the second notch may be configured to lock the second side of the support arm in the second slot. At least a portion of the first and third extensions may be configured to support a flange.

A reflective concentrator can include a primary reflector and a secondary reflector located radially outward of the primary reflector. The primary reflector can be a rotationally-symmetric, convex conical shape, radial sections of which may include an off-axis parabolic reflector with a focal point radially outward of the primary reflector. A secondary reflector may be located radially outward of the primary reflector, and may include a rotationally symmetric section of a toroidal space surrounding the primary reflector. In some embodiments, the secondary reflector may be convex or concave. Incident sunlight generally aligned with a rotational axis of symmetry of the primary reflector may be reflected off of the primary reflector, off of the secondary reflector, and back towards a point near the central peak of the primary reflector. The reflective concentrator may be aerodynamically stable, and may include an aerodynamic fairing on its read side to further increase the aerodynamic stability of the structure.

A single axis tracker system including at least one photovoltaic panel, a mounting structure, and a tracker control system. The tracker control system being attached to the at least one photovoltaic panel and to the mounting structure so as to apply torque to the at least one photovoltaic panel to rotate the at least one photovoltaic panel into an allowable orientation. A wind tracking device is coupled to the single axis tracker system and connected to the tracker control system. The wind tracking device determines current wind speed and direction information and couples the wind speed and direction information to an algorithm in the tracker control system. The algorithm uses the wind speed and direction information to calculate an allowable photovoltaic panel orientation for the current conditions.

Photovoltaic tracking systems with a ratcheting stow mechanism are provided. In particular, tracking systems allow for controlled movement of photovoltaic panels adapted for solar tracking to a stowed configuration without requiring electrical power. Such mounting systems can include a partially toothed ring gear with a pair of pawls pivotally mounted adjacent the ring gear with a pair of solenoids that when de-energized, move the pawls into engagement with the ring gear such that ratcheting movement of the pair of pawls along the ring gear in response to back-and-forth oscillating movement of the panel incrementally moves the panels into a stowed configuration without requiring use of electrical power.

A folded down support (12) allows for stronger solar panels (10) and the support replaces most of the solar racking required for solar installation which further reduces the cost of the photovoltaic solar system. The solar panels (10) can be arranged so that solar panels form a solar collector solar panel array. The solar panel (10) can be set on a surface by itself or with ballast (43). It can also be attached to the surface by fastening the solar panel to the side supports. If the solar panel frame and supports are electrically conductive, the design allows for self electrical grounding between these conductive parts when the side supports are pivoted to the down position. The folded up support allows for high density storage and shipping.

A hail strike recording device is operable to provide quantifiable information about a hail storm event experienced by a roof. The recording device is operable to be installed on a roof and includes a panel component and a mounting assembly. The panel component presents a hail impact zone to sense one or more hail strikes, with the recording device operable to provide recorded data associated with the sensed one or more hail strikes.

A photovoltaic apparatus includes: a power generation part; an angle changeable mechanism configured to support the power generation part so as to be able to change an elevation of the power generation part; a post configured to support the power generation part and the angle changeable mechanism; and a hinge mechanism configured to support the post so as to be able to change an angle of the post relative to an installation surface for the photovoltaic apparatus.