A solar mount, for use with a bracket attachment, has an open and a closed state. In the open state, grip flanges on two hinged arms can pass through a slot opening on the bracket attachment. In the closed state, the grip flanges cooperate with respective groves in the bracket attachment to secure the solar mount to the bracket attachment. In the closed state, a fastener attaches a solar accessory, such as a rail, and holds the two hinged arms together. A flexible mount helps hold the two hinged arms together in the open state, and also helps hold the two hinged arms in the closed state.

A solar mount, for use with a bracket attachment, has an open and a closed state. In the open state, grip flanges on two hinged arms can pass through a slot opening on the bracket attachment. In the closed state, the grip flanges cooperate with respective groves in the bracket attachment to secure the solar mount to the bracket attachment. In the closed state, a fastener attaches a solar accessory, such as a rail, and holds the two hinged arms together. A flexible mount helps hold the two hinged arms together in the open state, and also helps hold the two hinged arms in the closed state.

A travel path is arranged on the end faces of the solar panels and on which a service robot can travel, can rotate in place by a suitable rotational device, and can continue on a line. In this manner, the service robot can travel completely autonomously. For each row of adjacent solar panels, a centering opening is paired with the travel path, wherein the service robot has a centering pin which can engage into the centering opening, or the travel path is made of multiple sub-surfaces which form a respective rotary table in the region of the end faces of the solar panels, and the rotary table can be rotated about a perpendicular rotational axis running through the rotary table.

A solar powered electric motorized scooter is provided for use with a battery, the solar powered electric motorized scooter comprising a base, a flexible foot pad which has a margin, the margin attached to the base, a plurality of flexible solar cells mounted on the base, an electric motor which is in electrical communication with the flexible solar cells, a front wheel, a back wheel, the wheels rotatably disposed on the base and in motive communication with the motor, a steering tube rotatably mounted to the base and attached to a bracket that retains the axle of the front wheel and a handlebar, which terminates the steering tube, wherein the flexible foot pad is configured to flatten under the pressure of a rider and to curve upward when not under pressure of the rider.

A mobile electronic vehicle (EV) charging station is provided. The charging station may include one or more charging bays for charging electric vehicles (EVs). The charging station includes a plurality of batteries within an interior compartment to supply power for charging the EVs. There is a power delivery subsystem to control supply of electrical power from the batteries to the charging bays. The charging station self-driving to move between a first position to a second position. In some cases, the charging station includes a drive subsystem that controls speed and/or steering based on wireless communications.

Features for a solar generation system. The system includes a solar generator that may be installed on a shipping container. The solar generator includes one or more deployable rotating solar arrays. The rotating solar arrays may be deployed and stowed using actuators. The rotating solar arrays may be stowed for transport of the system on ships or to remote locations. The solar panels of the array are unexposed when stowed. A base frame with corner castings may attach to standard connections on cargo containers. The solar generators may be stacked on top of each other when stowed for transport. An actuation system may include linear actuators with two arms connecting at a moving pivot point that attach to a base frame and to the panels for deployment. Another actuation system may include end-mounted linear actuation arms with panel backside-mounted deployment arms.

Features for a solar generation system. The system includes a solar generator that may be installed on a shipping container. The solar generator includes one or more deployable rotating solar arrays. The rotating solar arrays may be deployed and stowed using actuators. The rotating solar arrays may be stowed for transport of the system on ships or to remote locations. The solar panels of the array are unexposed when stowed. A base frame with corner castings may attach to standard connections on cargo containers. The solar generators may be stacked on top of each other when stowed for transport. An actuation system may include linear actuators with two arms connecting at a moving pivot point that attach to a base frame and to the panels for deployment. Another actuation system may include end-mounted linear actuation arms with panel backside-mounted deployment arms.

An electronic device includes a solar cell, a first light modulating layer, a transmittance-adjustable lens and a control circuit. At least a portion of the first light modulating layer is disposed on the solar cell. The control circuit is electrically connected to the solar cell and the transmittance-adjustable lens.

A drive arrangement has a rotary driveshaft (1) bearing a drive finger (10) parallel and offset in the radial direction in relation to the axis of rotation and a locking device (11) offset radially with respect to the finger (10). The drive arrangement also has a coupling unit with a device in the shape of an arc which bears the drive or locking recesses disposed in alteration so as to enable relative rotation/prevent rotation between the unit and the driveshaft (1) when the finger (10) engages in one of the drive/locking recesses. The locking device (11) and the finger (10) are offset along the axis of rotation, and the coupling device has a part bearing the locking recesses and a part bearing the drive recesses, the two parts being positioned parallel and offset along the axis of rotation so as to be able to interact with the locking device (11) or the finger (10), respectively.

A solar panel supporting base or structure configured to allow one or more predominantly horizontal solar panels to be lifted or tilted to a vertical position, thereby facilitating maintenance or cleaning of the solar panel or underlying surface.