The embodiments are apparatuses, systems and methods of water management and icicle prevention for solar carports, and are designed to catch drips between rows of, and water run-off from, the low side of inclined photovoltaic modules arranged to form the roof of the solar carport or canopy.

Solar panels are coupled to elongated purlins by solar panel clamps. A single strip of sheet metal is folded to form a first mounting portion, a second mounting portion opposed to the first mounting portion, and a first section of an upright wall extending perpendicularly therebetween. A first and second mounting shelves extend perpendicularly from the first section of the upright wall. A second section of the upright wall extends perpendicularly from between the first and second mounting shelves. A plurality of solar panel clamps affix the plurality of solar panels to the mounting shelves of the elongated purlins.

Solar panels are coupled to elongated purlins by solar panel clamps. A single strip of sheet metal is folded to form a first mounting portion, a second mounting portion opposed to the first mounting portion, and a first section of an upright wall extending perpendicularly therebetween. A first and second mounting shelves extend perpendicularly from the first section of the upright wall. A second section of the upright wall extends perpendicularly from between the first and second mounting shelves. A plurality of solar panel clamps affix the plurality of solar panels to the mounting shelves of the elongated purlins.

A mounting assembly includes a rail configured to support a photovoltaic module. The rail includes a first slot, a second slot, and a web extending between the first slot and the second slot. The web being offset from a plane extending along an outer surface of the rail, so as to form a recess in the second side of the rail. The mount assembly further includes a clip configured to be secured to the rail and to a secondary structure. The clip includes a base having a flange extending from an end of the base, and an arm extending from the base in a second direction opposite the first direction, the flange being inserted in the second slot when the clip is secured to the rail and the secondary structure and at least a portion of the arm abuts the recess of the rail when the clip is secured to the rail.

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 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.

An interlocking system for connecting photovoltaic module frames to a torque tube, including: (a) an interlock dimensioned to be positioned between the sides of two adjacent photovoltaic module frames; (b) a pair of couplings or flanges, wherein the couplings or flanges connect the interlock to both of the adjacent photovoltaic module frames; and (c) a U-lock connected to the interlock, wherein the U-lock is dimensioned to be connected to a torque tube.

A solar panel racking system that can include end clamps, mid clamps, bottom clamps, L-foot adapter assemblies, rails, and L-foot assemblies. The solar panel racking system minimizes the use of tools by snapping many of the mounting components in place. The end clamps, mid clamps, and bottom clamps can snap over the rail sides and lock into upper detented portions of the rail sides. The upper detented portions are structured to prevent upward movement of the end clamps, mid clamps, and bottom clamps. The L-foot adapter body of the L-foot adapter assembly snaps over lower detented portions of rail sides and secures the rail to an L-foot assembly. The end clamps, mid clamps, bottom clamps, rails, and L-foot adapter assemblies are independent of the L-foot assembly, allowing a selection of L-foot assemblies to be used as appropriate with the solar panel racking system.

The embodiments are apparatuses, systems and methods of water management and icicle prevention for solar carports, and are designed to catch drips between rows of, and water run-off from, the low side of inclined photovoltaic modules arranged to form the roof of the solar carport or canopy.

A solar rack for supporting a solar panel, said solar rack including a pair of support frames, each support frame including a front member, a bottom member, and a rear member, wherein the front member, the bottom member, and the rear member cooperate to form a triangularly shaped structure; and a trough including two ends and a base, each end of the trough is configured to be attached to a portion of each of the support frames to form a support upon which the solar panel is disposed, the support having bottom surfaces, wherein the base of the trough is configured to be offset with respect to the bottom surfaces of the support.