A support structure for solar panels including a frame having a base plate for abutment on a receiving surface, the base plate extending laterally between a first lateral end and a second lateral end; a first supporting plate projecting from the base plate at the first lateral end thereof; a second supporting plate projecting from the base plate at the second lateral end thereof; a first hook-shaped body secured to the first supporting plate for supporting at least one first solar panel; and a second hook-shaped body secured to the second supporting plate for supporting at least one second solar panel.

In an example, the system has a mechanical isolator comprising an elastic material configured to separate the panel rail from the torque tube cause destructive interference with a natural resonant frequency of the system without the mechanical isolator to reduce a mechanical vibration of the system.

A snap-on mounting bracket assembly suitable for connecting a mounting rail to a torque tube is provided. The mounting bracket assembly includes an upper clamp piece and a lower clamp piece. The upper clamp piece has a first member defining a tube insertion aperture and an open bottom space and includes an upper partial fastener. The lower clamp piece has a second member with a lower partial fastener configured to mate with the upper partial fastener such that the lower clamp piece is attachable to the upper clamp piece. In exemplary embodiments, the lower clamp piece further comprises two opposing support members configured to attach to the mounting rail. Solar tracker assemblies incorporating snap-on open mounting brackets are provided. Methods of mounting framed or unframed solar modules are also described. A mounting rail is attached to an upper clamp piece of a mounting assembly. Then the upper clamp piece is snapped onto a torque tube. A lower clamp piece of the mounting assembly is then attached to the upper clamp piece by mating a lower partial fastener of the lower clamp piece with an upper partial fastener of the upper clamp piece. When the upper and lower clamp pieces are attached, the open bottom space is closed and the mounting rail is secured to the torque tube.

A solar panel frame structure includes a rectangular solar panel having two pairs of opposite sides. Each side frame has a top plate, a vertical plate and a bottom plate. The top plate is arranged above the vertical plate and protrudes from both sides of the vertical plate. The bottom plate is arranged on one side of the vertical plate, the section of the top plate where the top plate and the bottom plate are positioned on the same side of the vertical plate is defined as an inner section, and the section of the top plate where the top plate and the bottom plate are positioned on different sides of the vertical plate is defined as an outer section. An accommodating area is formed between the inner section and the bottom plate for accommodating one side of the solar panel. The vertical plate has a combined section protruding downwards from the bottom plate, and a through hole located in the combined section.

The present invention relates to a photovoltaic plant including a plurality of units each having at least one respective photovoltaic panel, a support structure of the plurality of units designed to support the latter at a distance from the ground (GR).

The present invention discloses a ground mounting system, particularly for mounting solar photovoltaic panels on a planar or inclined surface or a surface that is partly planar and partly inclined The disclosed invention is a system that comprised of an array of soil nails, inserted in the ground; a plurality of adapting apparatus, each on top of each the nails; and a resulting structure supports racks, made of metal or plastic, or other structural profiles designed to enable mounting photovoltaic panels on it, wherein the racks are installed on the array of nail using the adapting apparatus.

A solar tracking system including a plurality of bases, a torque tube supported by the plurality of bases and configured to support a plurality of solar modules, and a drive device operably connected to the torque tube and arranged to translate the torque tube in a direction parallel to its longitudinal axis. The solar tracking system also includes a plurality of helical guides operably connected to the torque tube, and a plurality of cam assemblies, wherein upon linear movement of the torque tube, interaction between the helical guides and cam assemblies causes the torque tube to rotate about its linear axis.

The invention relates to a frame for photovoltaic modules into which connection sockets and module electronics can be integrated so as to be easily accessible and which is simultaneously used as a guide system for connection cables.

Device for securing an orientation of photovoltaic panels includes a stem for supporting an array assembly of photovoltaic panels for producing an electrical current when exposed to sunlight. The array assembly also includes eye blades positioned on a side opposite to a photovoltaic panel carrying side. The device further includes a joint interconnecting the stem and the eye blades of the array assembly. The joint includes a hollow horizontal conduit and a bolting mechanism for adjustably coupling the eye blades to lateral ends of the horizontal conduit. A side of each eye blade facing the horizontal conduit carries an eye blade gear that cooperatively meshes with a conduit gear carried at or near a lateral end of the horizontal conduit to secure the array assembly at a predetermined angle relative to a longitudinal axis passing through the stem.

An absorber system solves problems of known absorber systems for use in solar fields in that the absorber tube is suspended on a rail below an absorber cover. The design also makes it possible to move measuring and cleaning robots and the like along the absorber tube more and allows the absorber tube and the secondary reflector to be jointly suspended, whereby an exact mutual alignment between the two components is enabled.