Embodiments disclosed herein are directed to a rapidly deploying transportable power system for generating power. The rapidly deploying transportable power system embodiment disclosed herein can have a plurality of frame members containing a plurality of solar panels. Any embodiments of the rapidly deploying transportable power system can also have a transport enclosure configured to support the plurality of frame members and a rail system coupleable with the transport enclosure, the rail system being configured to support the plurality of frame members outside of the transport enclosure. In any embodiments, the plurality of frame members can be positionable within the transport enclosure with one frame member positionable above another frame member. Furthermore, the plurality of frame members can be movable along the rail system to positions outside of the transport enclosure along the track system.

An adaptor for connecting a ground screw to an upright beam of a solar panel support assembly includes (a) a cylindrical connector having an open ground-screw receiving bottom end and a top end, the cylindrical connector having an inner circumferential surface with a diameter slightly larger than that of the ground screw and at least two sets of bolt holes, each set of bolt holes including at least three bolt holes uniformly distributed circumferentially about the cylindrical connector at an axial level, and the at least two sets of bolt holes being axially distanced from one another; (b) an intermediate plate having a top surface and a bottom surface fixed to the top end of the cylindrical connector; and (c) an upright beam connector fixed to the top surface of the intermediate plate and extending upward from the intermediate plate.

An adaptor for connecting a ground screw to an upright beam of a solar panel support assembly includes (a) a cylindrical connector having an open ground-screw receiving bottom end and a top end, the cylindrical connector having an inner circumferential surface with a diameter slightly larger than that of the ground screw and at least two sets of bolt holes, each set of bolt holes including at least three bolt holes uniformly distributed circumferentially about the cylindrical connector at an axial level, and the at least two sets of bolt holes being axially distanced from one another; (b) an intermediate plate having a top surface and a bottom surface fixed to the top end of the cylindrical connector; and (c) an upright beam connector fixed to the top surface of the intermediate plate and extending upward from the intermediate plate.

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.

Embodiments disclosed herein are directed to a rapidly deploying transportable power system for generating power. The rapidly deploying transportable power system embodiment disclosed herein can have a plurality of frame members containing a plurality of solar panels. Any embodiments of the rapidly deploying transportable power system can also have a transport enclosure configured to support the plurality of frame members and a rail system coupleable with the transport enclosure, the rail system being configured to support the plurality of frame members outside of the transport enclosure. In any embodiments, the plurality of frame members can be positionable within the transport enclosure with one frame member positionable above another frame member. Furthermore, the plurality of frame members can be movable along the rail system to positions outside of the transport enclosure along the track system.

A truss foundation for supporting single-axis solar tracker drive motors and center structures. An adapter joins a pair of adjacent truss legs and provides a mounting platform to support a drive motor and/or center structure of a solar tracker. The adapter has a pair of connecting portions that are received in the legs of the truss foundation. The adapter may be a unitary structure or consist of a pair of slidably connected members that are joined with fasteners to accommodate truss legs spaced apart at different distances.

Support platforms for one or more solar panels and systems and methods for securing support platforms are provided. In one embodiment, a frame of a support platform includes a plurality of support legs, each leg including a shoe plate. One or more toggle anchors with rod and/or cable are provided that include an anchor portion and a toggle portion pivotally coupled to the anchor portion, and a rod and/or cable is coupled to the toggle portion. Each anchor is driven into the ground with a driving rod such that an exposed end of the rod and/or cable extends from the ground. The driving rod is removed, and the rod and/or cable is pulled to deploy the anchor, and which the anchor is pull tested and measured in real time soil conditions whereupon the exposed end is coupled to the shoe plate of one of the support legs to apply a desired tensile force between the exposed end and the anchor to secure the support leg and, consequently, the support platform relative to the ground.

A mounting assembly for securing fixtures to a mounting structure may include a first fastener, a washer, a mounting bracket, and second fastener. The first fastener may be coupled to the mounting structure through a mounting aperture. The washer may be disposed around shaft of the first fastener between a head of the first fastener and the mounting surface. The mounting bracket may be disposed on top of the first fastener. The second fastener may be disposed through the mounting bracket and coupled to head of the first fastener. The washer may be a sealing washer that dispenses liquid sealant under compressive force to moisture-proof the securement of the first fastener to the mounting surface.

A mounting system for attaching an object to a roof structure includes a roof membrane placed on to the roof structure, a mounting plate, an elastic membrane secured to the roof membrane. The mounting plate includes a fastener, the fastener being secured to the mounting plate and extending therefrom, the fastener is configured to secure the mounting plate to the roof structure, which in turn secures the roof membrane to the roof structure, the fastener is configured to extend through a thickness of the roof membrane; and a protrusion extending from a top surface of the mounting plate, the protrusion is configured to secure the object to the mounting plate.

The deployable solar tracker system comprises a single-axis solar tracker (1) including a plurality of foldable panel array sections (10, 10a). Each foldable panel array section (10, 10a) comprises a shaft section (11), a plurality of support ribs (12) hinged to the shaft section (11), a plurality of solar panels (13) attached to the support ribs (12) and a handling element (28) attached on top of the shaft section (11). The handling element (28) has one or more handle openings (29, 30) dimensioned for receiving one or more lift members oriented in a transversal direction perpendicular to the shaft section (11). The handle openings (29, 30) of the handling elements (28) of the plurality of the foldable panel array sections (10, 10a) are mutually aligned when the plurality of foldable panel array sections (10, 10a) are arranged in a shipping arrangement.