A new system of solar construction, technology and methods for making off structure constructed panel blocks are disclosed.

A stacking spacer for a photovoltaic module frame comprises a main body, extending in a longitudinal direction, a connecting member, extending in the longitudinal direction and protruding from the main body, adapted for being inserted in at least one lateral profile groove of the photovoltaic module frame, and two opposed support members, arranged on respective opposed longitudinal sides of the main body, extending in the longitudinal direction, wherein the two opposed support members have complementary forms, whereby at least two stacking spacers can be securely stacked on top of each other. Photovoltaic module frames and tracking device assemblies may include photovoltaic modules comprising such stacking spacers.

A system and method of providing, assembling and maintaining floating rows and/or arrays of photovoltaic solar panels and terrestrial or elevated based rows and/or arrays of photovoltaic solar panels.

A solar panel mounting base and system for solar panel installation uses a mounting base that is injection molded to include different connection locations which provide flexibility when installing solar panels to the mounting bases. Attachment clamps are secured to the mounting base using carriage bolts which are secured to the mounting base in an attachment well and allow the installer to attach solar panels from the top which makes installation easy and fast. The attachment clamps have a horizontal and vertical portion that use grooves to adjustably secure the two together when in the desired location. Ballast blocks are used to provide a non-invasive installation. In an array, multiple bases are used to provide the structure to support the solar array. Installers may vary the angle the solar panels form 5 degrees to 10 degrees by selecting the appropriate connection location.

The present invention relates to a tool for mounting, rotating and loading sections of solar trackers on autonomous transportation means in order to transport them to the specific location of said solar trackers in the field, wherein the fastening and rotating tool for mounting sections of photovoltaic solar trackers makes the pre-assembly, transportation and installation of the solar tracker section possible, reducing the mounting time of each operation. The invention also relates to an associated system and method that makes use of the fastening and rotating tool for mounting sections of photovoltaic solar trackers.

Photovoltaic module assemblies are mounted onto a solar tracker array torque tube via photovoltaic module brackets. The photovoltaic module brackets provide for stacking photovoltaic module assemblies in a nested configuration. The photovoltaic module assemblies are pre-assembled off-site, at a location different than the photovoltaic array installation site, and the nested configuration allows for efficient transportation of pre-assembled photovoltaic module assemblies to the installation site.

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.

In an embodiment, a solar energy system includes multiple photovoltaic modules, each oriented substantially at a same angle relative to horizontal. The angle is independent of a latitude of an installation site of the solar energy system and is greater than or equal to 15 degrees. The solar energy system defines a continuous area within a perimeter of the solar energy system. The solar energy system is configured to capture at the photovoltaic modules substantially all light incoming towards the continuous area over an entire season.

The invention includes a solar canopy a brace assembly for stabilizing a foldable solar canopy structure including: a first brace clamp comprising a first U-shaped body removable attached to a flat body; a second brace clamp comprising a second U-shaped body removable attached to a flat body, wherein the second brace clamp is adapted to encircle and securely attach to a beam and wherein the first brace clamp is removably attached on one side to the second brace clamp at one side; a third brace clamp comprising a third U-shaped body removable attached to a flat body; and a strut member for attaching the third brace clamp to the second brace claim, removably attached at one end to a side of the third brace clamp at on the opposing end to the side of the second brace clamp opposite the side attached to the first brace clamp, thereby forming a linear assembly.

A support assembly for supporting one or more photovoltaic modules on a support surface, such a generally flat roof, is disclosed herein. The support assembly includes a ballast tray configured to accommodate one or more ballasts; at least one tubular member coupled to the ballast tray, the at least one tubular member configured to support one or more photovoltaic modules above a support surface; and at least one clamp member coupled to the at least one tubular member. In one or more embodiments, the support assembly further includes at least one channel member coupling said at least one tubular member to said ballast tray. A mounting system including a plurality of support assemblies is also disclosed herein.