A solar tracking assembly includes a spine and a plurality of paired brackets connected to the spine. The brackets are positioned on opposite sides of the spine and at least one of the paired brackets includes wheels to allow rolling movement of the spine. An array arm is attached to each bracket and is moveable from a shipping position to a deployed position, and at least one solar array panel is secured to each array arm. A method of installing a solar panel assembly includes assembling in a secondary automated process at least one solar panel assembly in an offsite location, loading the solar panel assembly in the shipping position on a truck, transporting the truck to a deployment site, and off-loading the solar panel assembly from said truck.

A method and apparatus are provided that combine solar technology and agriculture in a symbiotic relationship that optimizes revenue from both sources. An array of reconfigurable solar collector assemblies is deployed in a crop field. As various crops benefit from varying degrees of shade through their development cycles, and are prone to damage from high winds and hail, the array of adaptable, reconfigurable solar collectors is deployed in the crop field and allows for the easy reconfiguration of each solar collector assembly to vary the amount of shade that is applied to the crops below the assembly, and to provide maximum hail and wind protection when necessary.

A rapidly deployed photovoltaic (PV) apparatus (2) providing a PV array (10) housed within an easily transportable standardized container. The PV array (10) is movable between a stowed position in a V-shape configuration and a fully deployed flat position. Dual function hydraulic cylinders are provided for movement of the array (10) in the fully deployed position and movement of the container when the array (10) is in the stowed position. Solar tracking of the array (10) is facilitated by linear compensation translators which are attachable to the hydraulic cylinders upon full deployment. A retractable roof structure is provided which allows trickle charging to occur when the array (10) is in the V-shaped stowed position.

Disclosed is an apparatus for a solar power generator as it relates to a portable and expandable solar power generator that can form a micro-grid power system comprising any elements described, either individually or in combination with any other elements, in any order.

A folded down support (12) allows for stronger solar panels (10) and the support replaces most of the solar racking required for solar installation which further reduces the cost of the photovoltaic solar system. The solar panels (10) can be arranged so that solar panels form a solar collector solar panel array. The solar panel (10) can be set on a surface by itself or with ballast (43). It can also be attached to the surface by fastening the solar panel to the side supports. If the solar panel frame and supports are electrically conductive, the design allows for self electrical grounding between these conductive parts when the side supports are pivoted to the down position. The folded up support allows for high density storage and shipping.

A solar module mounting bracket assembly includes a rail configured to support a solar module thereon, and a pair of braces. The braces each have a first end portion movably coupled to the rail. The braces are movable relative to the rail between a collapsed configuration and an expanded configuration. In the expanded configuration, the braces cooperatively define a channel dimensioned for receipt of a frame member.

A field-deployable solar panel stand configured to transition between a collapsed configuration for carrying and an expanded configuration for use. The stand includes a plurality of linear posts, cross members, legs and support members interconnected through a plurality of joint assemblies configured to slide along a length of the linear posts to transition the stand between the collapsed and expanded configurations.

A telescopic retractable mast system for deploying a solar panel array comprising a one or more of masts, each mast comprising sections, means for retracting and extending each mast and means for mounting and deploying a plurality of solar panel thereon such that the solar panels are and may be adjustable as to maximize the electrical output therefrom. When in use, the mast system may be extended upwards to allow solar generation to take place and when conditions are not appropriate, such as inclement weather, the mast and therefore the solar panels may be retracted into a protected configuration, such as into an enclosure.

A field-deployable solar panel stand configured to transition between a collapsed configuration for carrying and an expanded configuration for use. The stand includes a plurality of linear posts, cross members, legs and support members interconnected through a plurality of joint assemblies configured to slide along a length of the linear posts to transition the stand between the collapsed and expanded configurations.

A solar mounting system stored within a shipping container prior to deployment and wherein the mounting system includes: laterally extending beams that extend outwardly from the top of the shipping container; support mounts connected to the laterally extending beams at positions over the top of the shipping container and at the ends of the laterally extending beams; a first set of higher longitudinal beams spanning between the support mounts; a second set of lower longitudinal beams spanning between ends of the laterally extending beams at positions beside the shipping container; a plurality of PV module support rails extending between the first and second sets of longitudinal beams; and PV modules mounted onto the PV module support rails such that the PV modules slope downwardly from above the center to beyond the sides of the shipping container.