The invention relates to a workshop (18) for the construction of pre-assembled structures for solar trackers, each structure comprising a support beam, at least two stands supporting the beam and each comprising a support cradle, the two cradles being spaced apart by a predetermined inter-cradle distance. The workshop (18) comprises two consecutive assembly zones (Z.sub.1-Z.sub.3), and at least two trolleys (20a, 20b) capable of being moved on the ground, for the construction of a single pre-assembled structure, on rolling tracks (19a, 19b) connecting the zones (Z.sub.1-Z.sub.3) The zones comprise: —an initial assembly zone (Z.sub.1) in which the stands are assembled directly on the trolleys (20a, 20b); and a second assembly zone (Z.sub.2) comprising two locations (23a, 23b) holding the trolleys (20a, 20b) n position for assembly of the support beam onto the cradles while ensuring that the cradles are spaced apart by said predetermined inter-cradle distance.

A photovoltaic (“PV”) module support system including a first PV module having a first PV panel adapted to generate electrical energy from sunlight. The first PV panel has an upper surface and a lower surface and a first frame secured to the lower surface of the first PV panel. The first frame having a pair of first frame members including an elongate slot. A first joining rail has a body and a first wall projecting outwardly from the body. The first wall is inserted within the elongate slot of one of the pair of the first frame members. A fastener is connected to the one of the pair of first frame members and movable to clamp the wall within the slot, wherein the first PV module is positionally fixed relative to the joining rail.

The present application provides methods for loading and unloading high capacity storage equipment to a solar power canopy. The methods and structures may include horizontal support members have mechanisms to engage corresponding mechanisms on a compartment housing the high capacity storage equipment. The mechanisms may include plates, flanged surfaces, rails, tracks, hook assemblies, and ridges. The methods and structures may include a superstructure that is coupled to an moves with respect to the solar power canopy frame. The superstructure may pivot and/or rotate to allow loading and unloading. The methods and structures also may include cabinets or cubicles sized to receive one or more compartments housing the high capacity storage equipment.

A cost-effective solar energy collection system, including: 1) new solar PV panel wiring and power conversion system designed to allow tracking panel-to-panel shading while maintaining maximized power output, 2) the companion new combined structural and electrical inter-panel connector system supporting the new wiring scheme, and 3) the new panel structural support for the new inter-panel connector system, 4) the robotic array assembly and installation system used to assemble the new inter-panel connector and new panel structural support system into solar array sections in the field with a robotic crawler to move the assembled solar array sections to their final positions, and 5) the post system and installer for supporting the solar array sections. It is a fully integrated solar energy system for rapid installation and higher energy output which together creates a transformative change for the solar energy field.

A solar table mobile transport is described that moves a solar table to a point of installation. The solar table mobile transport comprises multiple motors that allow movement within a three-dimensional coordinate system as well as provide angular controls of pitch, yaw and roll. These motors enable at least one alignment process used to install the solar table to a mounting structure within a solar system.

A method and a kit for building a protective structure, the method and the kit including supplying a carrying structure, including a plurality of parallel carrying rails; supplying a group of panels, the panels being able to be engaged on and slide on the carrying rails; and transferring the panels from the storage position to a final position bearing on the carrying rails, by transferring at least one of the panels from the storage position to an insertion position on the carrying rails; using a transfer device lifting the at least one panel upward; placing the transferred panels one after the other bearing on the carrying rails; and moving the transferred panels along the carrying rails.

A floating platform for solar panels is provided. The floating platform may include a plurality of plates. Each of the plurality of plates may have a ballast chamber filled with a ballast material. Each of the plurality of plates may further have a float chamber disposed over the ballast chamber. Each of the plurality of plates may further have a channel passing through the ballast chamber and the float chamber. The channel may further have one or more openings to pass water into the ballast chamber and an opening to pass air from the channel. Each of the plurality of plates may further have a locking member. Each of the plurality of plates may further have one or more connection sections for placing one or more strap assemblies. The strap assemblies may be provided for disposing one or more solar panels on the plurality of plates.

In various embodiments, a mounting system may comprise a downslope rail, an upslope rail, a first clamp and a second clamp. The downslope rail may have a first profile and comprising a downslope face and an upslope shelf. The upslope rail may have a second profile and comprising a downslope shelf and an upslope face. The first clamp may be configured to engage the downslope face and accept the installation of a first end of a solar panel. The second clamp may be configured to engage the upslope face and retain a second end of the solar panel against a downslope shelf

A solar power generation assembly includes a first canopy wing positioned at a first predetermined inclination and a second canopy wing positioned at a second predetermined inclination, wherein the first and second canopies form a dual-incline structure and a main gutter is disposed between the first and second canopies. Additionally, at least one mounting rail gutter extends perpendicular to the main gutter and a secondary gutter extends parallel to the main gutter, wherein the secondary gutter directs precipitation to the mounting rail gutter and the mounting rail gutter directs precipitation into the main gutter, wherein the secondary gutter, the mounting rail gutter, and the main gutter are configured to provide both mounting and precipitation management functionality to the solar power generation assembly.

A solar power system may include rails, solar modules, and a plurality of clamps to secure the solar modules to the rails. An end clamp may be partially disposed inside a rail at an end of the rail. The end clamp may secure a solar module to the rail by coupling to the frame of the solar module. The end clamp may include a fastener that may be tightened to engage the end clamp and secure the solar module by holding it on top of the rail. The end clamp may establish an electrical grounding connection between the frame of the solar module and the rail.