In an example, the present invention provides a solar tracker apparatus. In an example, the apparatus comprises a center of mass with an adjustable hanger assembly configured with a clam shell clamp assembly on the adjustable hanger assembly and a cylindrical torque tube comprising a plurality of torque tubes configured together in a continuous length from a first end to a second end such that the center of mass is aligned with a center of rotation of the cylindrical torque tubes to reduce a load of a drive motor operably coupled to the cylindrical torque tube. Further details of the present example, among others, can be found throughout the present specification and more particularly below.

An energy capturing device is positionable above a roof of a building, structure, or object. Each of a plurality of lifting components has a short leg with an inner end coupled to the building, structure, or object and has a long leg with an upper end positionable above the building, structure or object. An upper pivot member couples the upper ends of the long legs to the energy capturing device. A lower pivot member pivots the energy capturing device between a raised operative orientation above the building, structure, or object and a lowered inoperative orientation beneath the building, structure, or object. A control system allows positioning the energy capturing device with respect to the building, structure, or object.

A solar device alignment system enabling greater adjustment of solar devices during installation is provided. The alignment system enables both translational and rotational adjustments in multiple degrees of freedom, allowing solar device installers to make greater adjustments to allow greater tolerances in installing solar devices and limit the need for extensive and expensive surveying and/or redesign of the installation to account for those tolerances.

A method for installing a solar structure includes the steps of: a) planting at least two anchoring feet in an area on the ground (S); b) arranging a pivot support having a pivot axis (X) on the free end that extends above the area of ground of each of the anchoring feet; c) aligning the pivot axes of the pivot supports with each other; d) attaching the pivot supports to the respective anchoring foot thereof; and e) positioning the solar structure on the pivot supports.

An attachment point apparatus and system for photovoltaic arrays is disclosed as well as an installed photovoltaic array using attachment apparatus. One embodiment provides a rail for receiving a PV module, including a rail member located substantially beneath at least a portion of a second photovoltaic module and having a first end located near a gap between a first and second photovoltaic modules. An embodiment also provides a second photovoltaic module which is substantially coplanar with and located between a first and third photovoltaic modules and wherein said rail member is connected to the first, second, and third photovoltaic modules and attached to a support structure by a first and second attachment brackets. A further embodiment provides a lever clip, said lever clip comprising a head portion connecting a photovoltaic module to a rail, a lever portion extending away from a head portion, and a retaining portion near an end of a lever portion wherein the lever portion acts as a lever to rotate the head portion during installation such that the head portion secures the photovoltaic module to a frame.

A solar power system is mounted to a solar power componentry support structure suspended above a pre-existing surface by a collective of solar collector suspension base supports. Suspended solar power system row support structure members and suspended solar power system column support structure members may for a solar component position lattice to which a matrix of individual solar power components such as solar panels can be attached. Solar module quick-fasten assemblages may serve also as solar componentry emergency releases and may include loose axis retainers and firm axis fasteners such as dual component, single point operative emergency releases and fasteners. Slide-in retainers and corner slot tabs can be included as well as frame alignment notches. Fulcrum pivot fasteners and slide wedge releases can aid in installation and release. Pre-sealed roof base supports such as semidome base supports can include a sandwiched membrane.

In various representative aspects, an assembly for securing array skirts and solar panel modules in an array on a roof by providing a leveling system that utilizes a barrel bolt and barrel nut to vertically adjust the assembly. Improved electrical bonding by utilizing bonding pins installed in mounting plates of a support clamp are also provided. Additionally, an improved array skirt design that is installed on the outer row of the array, as well as improved designs in the support clamp and splice mechanisms are also provided. Finally, an improved wire management system is included as well as a method of installation of the array assembly.

A plurality of mounting posts are each configured to be driven into ground. The mounting post includes opposing parallel sidewalls, a third sidewall extending between, and a fourth sidewall extending between the opposing sidewalls, and opposing and in parallel to the third sidewall. The fourth sidewall includes a longitudinal extending slot with coaxial mounting through holes in the first and second sidewalls at a distal end. A plurality of north-south beams are each mounted on the distal end of an associated one of the posts. Each of the north-south beams comprises a web and first and second flanges extending from the first web. The first and second flanges include first coaxial beam mounting through holes, and include second flanges and second coaxial beam mounting through holes. The first coaxial beam mounting through holes are located closer to the north end than the second coaxial beam mounting through holes, where for each of the north-south beams the web is placed over the distal end of the associated mounting post such that the first coaxial mounting through holes coaxially align with the coaxial beam mounting through holes. A fastener extends through the first coaxial mounting through holes and the coaxial beam mounting through holes to fasten the north-south beam to its associated mounting post.

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 PV module framing and coupling system which enables the attachment of PV modules to a roof or other mounting surface without requiring the use of separate structural support members which attach directly to and span between multiple PV modules in a formed PV array and a cable management system that holds, directs, organizes, and otherwise manages cables, wires, cord, and similar components of and relating to a PV array.