In an example, the solar tracker has a clamp assembly that is configured to pivot a torque tube. In an example, the assembly has a support structure configured as a frame having configured by a first anchoring region and a second anchoring region. In an example, the support structure is configured from a thickness of metal material. In an example, the support structure is configured in an upright manner, and has a major plane region. In an example, the assembly has a pivot device configured on the support structure and a torque tube suspending on the pivot device and aligned within an opening of the support and configured to be normal to the plane region. In an example, the torque tube is configured on the pivot device to move about an arc in a first direction or in a second direction such that the first direction is in a direction opposite to the second direction.

A solar panel mounting system may include a solar panel mounting assembly for mounting to a support structure. The solar panel mounting assembly may include a restraining element, a retaining element and a biasing assembly that supports the restraining and retaining elements. The support structure may include an upper surface and a lower surface spaced from the upper surface. The biasing assembly may further include a biasing element that resiliently urges the retaining element toward a securing element for supporting a solar panel that is positioned between the retaining element and the upper surface of the support structure, and resiliently urges the restraining element toward the lower surface of the support structure. A retention device may resiliently bias the solar panels of a solar panel assembly together on a support structure.

A solar panel mounting system may include a solar panel mounting assembly for mounting to a support structure. The solar panel mounting assembly may include a restraining element, a retaining element and a biasing assembly that supports the restraining and retaining elements. The support structure may include an upper surface and a lower surface spaced from the upper surface. The biasing assembly may further include a biasing element that resiliently urges the retaining element toward a securing element for supporting a solar panel that is positioned between the retaining element and the upper surface of the support structure, and resiliently urges the restraining element toward the lower surface of the support structure. A retention device may resiliently bias the solar panels of a solar panel assembly together on a support structure.

The invention relates to a holding device (1) for a solar panel (2) on a parapet (3) of a balcony, said device having at least the following components: a connection arrangement (4) for connecting an element to be held, wherein the connection arrangement has at least one support (5, 6, 7, 8) for placing on a parapet; and at least one transverse strut (9, 10) for bridging a parapet width, wherein the at least one transverse strut is connected to the connection arrangement and has at least one flange (12, 13) for placing on a parapet, wherein by means of a movement of the at least one flange towards the connection arrangement, the at least one flange and the at least one support press in opposite directions against the parapet. The invention disclosed relates to a holding device which allows for greater flexibility with regard to the structure of a balcony parapet.

The invention relates to a holding device (1) for a solar panel (2) on a parapet (3) of a balcony, said device having at least the following components: a connection arrangement (4) for connecting an element to be held, wherein the connection arrangement has at least one support (5, 6, 7, 8) for placing on a parapet; and at least one transverse strut (9, 10) for bridging a parapet width, wherein the at least one transverse strut is connected to the connection arrangement and has at least one flange (12, 13) for placing on a parapet, wherein by means of a movement of the at least one flange towards the connection arrangement, the at least one flange and the at least one support press in opposite directions against the parapet. The invention disclosed relates to a holding device which allows for greater flexibility with regard to the structure of a balcony parapet.

A support device for supporting a solar panel above a base surface includes a body having an upper mounting surface, a lower base surface, and integral ballast. The upper mounting surface is sloped relative to the lower base surface. The support device further includes at least one mounting element projecting upwardly from the upper mounting surface and configured to support a solar panel. A solar panel support system includes first and second support devices spaced apart from one another, each including a body having an upper mounting surface, a lower base surface, and integral ballast, the upper mounting surface being sloped relative to the lower base surface. Each support device further includes first and second mounting elements projecting upwardly from the upper mounting surface and configured to support solar panels. First and second purlins are supported by and extend between the first and second support devices, and are configured to support the solar panels.

A support device for supporting a solar panel above a base surface includes a body having an upper mounting surface, a lower base surface, and integral ballast. The upper mounting surface is sloped relative to the lower base surface. The support device further includes at least one mounting element projecting upwardly from the upper mounting surface and configured to support a solar panel. A solar panel support system includes first and second support devices spaced apart from one another, each including a body having an upper mounting surface, a lower base surface, and integral ballast, the upper mounting surface being sloped relative to the lower base surface. Each support device further includes first and second mounting elements projecting upwardly from the upper mounting surface and configured to support solar panels. First and second purlins are supported by and extend between the first and second support devices, and are configured to support the solar panels.

The invention is directed to a solar tracking apparatus containing a polar axis aligned shaft which rotates continuously or intermittently at a rate simulating the apparent approximate fifteen degree per hour movement of the sun across the sky. A Fresnel lens, photovoltaic panel, parabolic dish or other solar collection/concentration device is adjustably mounted to about twenty three degrees either side of perpendicular to the axis of the shaft and directly at the Sun, collecting, focusing or concentrating the solar radiation on a receiving device, which stores the solar energy in the form of heat, re-directs the light or converts the energy into electricity.

The invention is directed to a solar tracking apparatus containing a polar axis aligned shaft which rotates continuously or intermittently at a rate simulating the apparent approximate fifteen degree per hour movement of the sun across the sky. A Fresnel lens, photovoltaic panel, parabolic dish or other solar collection/concentration device is adjustably mounted to about twenty three degrees either side of perpendicular to the axis of the shaft and directly at the Sun, collecting, focusing or concentrating the solar radiation on a receiving device, which stores the solar energy in the form of heat, re-directs the light or converts the energy into electricity.

The solar energy and solar farms are used to generate energy and reduce dependence on oil (or for environmental purposes). The maintenance, operation, optimization, and repairs in big farms become very difficult, expensive, and inefficient, using human technicians. Thus, here, we teach using the robots with various functions and components, in various settings, for various purposes, to improve operations in big (or hard-to-access) farms, to automate, save money, reduce human mistakes, increase efficiency, or scale the solutions to very large scales or areas, e.g., for repair, operation, calibration, testing, maintenance, adjustment, cleaning, improving the efficiency, and tracking the Sun.