A tile system comprises at least two tiles and at least one elongate support. Each tile is generally rectangular in shape and has a first edge, and a second edge, the second edge being generally opposite the first edge. Each elongate support has an attachment portion and a support portion. Proximate the first edge each tile is provided with a groove, the groove being configured to receive the support portion of one of the elongate supports and a portion of an adjacent tile proximate its second edge.

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.

Mounting clamps may be utilized to quickly and easily secure solar panel modules relative to mounting rails, which may in turn be secured relative to a mounting surface (e.g., a roof). The mounting clamps may be configured to quickly secure the solar pane modules relative to the mounting rails by tightening a tightening element to pull a clamp element toward the surface of a mounting rail, thereby clamping a portion (e.g., a frame) of a solar panel module between the clamping element and an outer surface of the mounting rail.

Mounting clamps may be utilized to quickly and easily secure solar panel modules relative to mounting rails, which may in turn be secured relative to a mounting surface (e.g., a roof). The mounting clamps may be configured to quickly secure the solar pane modules relative to the mounting rails by tightening a tightening element to pull a clamp element toward the surface of a mounting rail, thereby clamping a portion (e.g., a frame) of a solar panel module between the clamping element and an outer surface of the mounting rail.

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.

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.

A modular, roof-mounted solar energy apparatus includes a mounting frame having a plurality of brackets. Each bracket having a first arm connected to a second arm at a connection point. The plurality of first arms form a first plane. The plurality of second arms form a second plane. Solar panels populate the planes. Also, there are ridge brackets and hip brackets for connecting various mounting frame portions over a ridgeline of a roof and across a hip of a hip roof.

Mounting clamps may be utilized to quickly and easily secure solar panel modules relative to mounting rails, which may in turn be secured relative to a mounting surface (e.g., a roof). The mounting clamps may be configured to quickly secure the solar pane modules relative to the mounting rails by tightening a tightening element to pull a clamp element toward the surface of a mounting rail, thereby clamping a portion (e.g., a frame) of a solar panel module between the clamping element and an outer surface of the mounting rail.

Mounting clamps may be utilized to quickly and easily secure solar panel modules relative to mounting rails, which may in turn be secured relative to a mounting surface (e.g., a roof). The mounting clamps may be configured to quickly secure the solar pane modules relative to the mounting rails by tightening a tightening element to pull a clamp element toward the surface of a mounting rail, thereby clamping a portion (e.g., a frame) of a solar panel module between the clamping element and an outer surface of the mounting rail.