The present disclosure relates to the field of sensor manufacturing technology, particularly discloses a method for manufacturing a micro-sensor body, comprising the steps of S1: applying a wet colloidal material on a substrate to form a colloidal layer, and covering a layer of one-dimensional nanowire film on the surface of the colloidal layer to form a sensor embryo; S2: drying the colloidal layer of the sensor embryo to an extent that the colloidal layer cracks into a plurality of colloidal islands, a portion of the one-dimensional nanowire film contracting into a contraction diaphragm adhered to the surface of the colloidal islands while the other portion of the one-dimensional nanowire film being stretched into a connection structure connected between the adjacent contraction diaphragms. By the method for manufacturing a micro-sensor body of the present disclosure, the contraction diaphragms and connection structures formed by stretching the one-dimensional nanowire film are connected stably, which enhances the stability of the sensor devices; and the cracking manner renders it easy to obtain a large-scale of sensor bodies with connection structure arrays in stable suspension.

A u-shaped splice that is used to connect two solar mounting rails, includes barbs that interact with the rails, requiring more force to remove the splice from the rails than the force required to insert the splice into the rails. Wedges, located at a mid-point between ends of the splice interact with the rails, creating an interference fit between the splice and the rails.

A racking system is configured to install at least one photovoltaic panel on a rooftop. The racking system includes a plurality of rails. A splice bar is connected the plurality of rails and configured to mechanically strengthen the plurality of rails. A ground lug is attached to an extrusion of a side channel on each of the plurality of rails by sliding the ground lug through a rail opening. A ground wire is held in a serrated opening for safely grounding the racking system. A clamp is attached to a top channel of at least one rail such that the at least one rail and the at least one photovoltaic panel are operatively coupled to the clamp and such that the clamp is under pressure due to a spring but is able to freely rotate around a longitudinal axis.

The present invention relates to a mounting structure comprising a structural member having a first surface adapted to engage a support and at least one first flange extending outwardly from a second surface, wherein the first surface is distal from the first flange; and at least one securing member comprising at least one second flange extending outwardly from a surface of the securing member, wherein the securing member is operable to juxtapose with the structural member via the first surface, and engage with the structural member to secure a side of a panel between the first flange and the second flange. The present invention also relates to a mounting structure assembly and method of assembling the same.

A photovoltaic module mounting system is disclosed. The system includes a rail with an elongated body with opposing first and second shoulders and opposing first and second sides. A first track is defined by the first shoulder, a second track is defined by the first side, and a third track is defined by the second side. The first track has a first channel and a first slot, the second track has a second channel and a second slot, and the third track has a cavity. A connector bracket has a first flange, a second flange, and an elbow, the first flange forming a substantially right angle with the second flange, and the elbow being substantially L-shaped and extending at a substantially right angle from the second flange. In an operative configuration, the elbow of the connector bracket is engaged within the cavity of the rail.

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.

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 engageable 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.

An apparatus and method for mounting a solar panel array on a surface is disclosed. The solar panel array includes a plurality of solar panel modules and a hybrid solar panel module mounting assembly. The hybrid solar panel module mounting assembly includes a component of a rail-based mounting system and a component of a rail-less mounting system. At least one of the plurality of solar panel modules is mounted on the component of the rail-based mounting system and at least one of the plurality of solar panel modules is mounted on the component of the rail-less mounting system.

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.

A system for attaching a solar panel to a support, includes a support connector and a solar panel connector, where the support connector includes a U-shaped profile having a lower wall and two side walls, where an upper end of the side walls is bent inwards to provide vertical rails for receiving the panel connector; and the panel connector include a profile having: an upper C-shaped portion configured for receiving a side edge of a solar panel; a lower, upwardly oriented channel portion configured for receiving the vertical rail of the support connector; and at least one box-shaped portion connecting the upper C-shaped portion and the lower channel portion.