A solar panel mounting system for forming a solar array includes longitudinal support rails mounted to a support structure such as a roof. A first solar panel disposed on the rails has a peripheral frame including a locking frame member with deformable clamping portion configured for slideably receiving a peripheral frame portion of an adjacent second solar panel. A pair of captive T-bolt sets passing through the clamping portion include T-bolts having locking heads and nuts frictionally engaged with the T-bolts to rotate the T-bolts. The heads are each inserted and rotationally locked into fastening channels of respective support rails. The second solar panel is inserted into the first panel clamping portion and the nuts are fully tightened producing a clamping action which locks the first and second panels together. Power/control cables may be routed inside covered cable compartments on rears of the panels for protection against rodent damage.

A solar panel mounting assembly including a cap that includes a secure-side wing, a catch-side wing, and an integral vertical leg that protrudes downwardly from the catch-side wing. The vertical leg is integral with the catch-side wing and has a top end and a bottom end. A plurality of inwardly facing corrugations are disposed at the bottom end of the vertical leg. The solar panel mounting assembly further includes a base that includes a secure-side support surface, a tilted spring support ledge on a catch-side, and a plurality of outwardly-facing corrugations disposed on an upper horizontal portion of the base. An inwardly-facing corrugation of the vertical leg contacts and engages an outwardly-facing corrugation on the upper horizontal portion of the base, and the base is vertically adjustable with respect to the cap.

An insertion rail for a solar panel mounting system is provided. The insertion rail has a mounting wall configured for connection to the solar panel mounting system, wherein the mounting wall is posited at a lower end of a first side of the insertion rail, a vertical leg coupled to the mounting wall at at least one location, wherein the vertical leg is positioned at a second side of the insertion rail, and at least one mating section located at an upper end of the insertion rail. The mating section has an upper tab, a lower tab and the upper tab and lower tab are configured to receive and secure a solar panel integrally therewith using an interference fit.

In various embodiments, a stabilization assembly may comprise a shaft, a foot, a snap plate and a nut. The foot may be operatively coupled to the shaft. The snap plate may be configured to surround and retain the shaft. The nut may be installable on the shaft and engagable to raise and lower a foot. The stabilization assembly may be installed in a solar panel coupling. The foot may be driven to engagement with a roof surface in response to the coupling being installed on the roof.

In various embodiments, a stabilization assembly may comprise a shaft, a foot, a snap plate and a nut. The foot may be operatively coupled to the shaft. The snap plate may be configured to surround and retain the shaft. The nut may be installable on the shaft and engagable to raise and lower a foot. The stabilization assembly may be installed in a solar panel coupling. The foot may be driven to engagement with a roof surface in response to the coupling being installed on the roof.

Disclosed herein is an integrated bonding mid clamp device for solar panel mounting and grounding, as well as a related system and method. The integrated bonding mid clamp includes a deformable toothed washer for breaking an anodized layer of a solar panel frame. The deformable toothed washer is capable of deforming to avoid obstructing proper contact between the mid clamp and the solar panel frame.

A corrugated washer for use with a corrugated L-foot mounting bracket and a structural mounting rail prevents vertical shear at the joint between the rail and the corrugated L-foot bracket when mounting photovoltaic modules (i.e., solar panels) to a roof of a building or other structure. The design locks the T-bolt from falling off the rail slot, and always aligns the T-bolt in the correct orientation and prevents back-rotation. The corrugations on the washer and L-foot help for making height adjustments, too.

A system for mounting a service component to a building structure has a plurality of elongate feet, and a plurality of connectors that each interconnect a respective one of the feet with the service component. Each foot is configured to affix to a surface of the building structure and then to resist disengagement from that surface. The connectors each interconnect a respective one of the feet with the service component, and secure the relative position of the respective foot and the service component. An elongate beam can be connected or connectable to the service component, such that in the installed system the beam is to be positioned to extend obliquely across the feet.

An apparatus, system, and method for conveying an assembly along a track. A rail can include a first planar side, a second planar side, and a third planar side. The first, second, and third planar sides can be arranged to form at least two acute angles. A carriage assembly can include a drive wheel and at least two roller sets. The drive wheel can be configured to contact the first planar side and is configured to translate the carriage assembly along the rail. The at least two roller sets can be configured to contact the two other sides to maintain the carriage in contact with the rail.

A solar panel assembly includes a substrate and a solar array coupled to the substrate. The solar array includes a plurality of photovoltaic cells. An optical layer is disposed over the solar array. The optical layer, the solar array, and the substrate together form a solar assembly. A frame surrounds the solar assembly and includes a plurality of frame members. Each frame member of the plurality of frame members includes an arcuate member that forms an aerodynamic outer edge of the frame member.