Disclosed are a floating photovoltaic panel installation structure and a buoyancy body for the installation of the floating photovoltaic panel, which may have excellent strength and buoyancy performance even while having light-weight characteristics, and stably support a photovoltaic panel on the water even during the flowing of a water surface due to waves. In the floating photovoltaic panel installation structure according to an embodiment of the present disclosure, as the floating photovoltaic panel installation structure including at least one unit floating type structure for supporting a photovoltaic panel on the water, the unit floating type structure includes a plurality of buoyancy bodies arranged to be spaced apart from each other, a photovoltaic panel support structure supported on the plurality of buoyancy bodies, a triangular bracket coupled with a plurality of photovoltaic panel support structures, a ball joint hinge apparatus for connecting the plurality of photovoltaic panel support structures, and at least one photovoltaic panel supported by the photovoltaic panel support structure. At least one buoyancy body among the plurality of buoyancy bodies is made of a material in which Polyethylene and Waste Carbon Fiber Reinforced Plastics have been blended. For maintaining stable position and posture, the buoyancy body may include a cylindrical body having both side surfaces protruded convexly, and both side surfaces of the cylindrical body may be designed to have a shape in which a curvature radius of an upper area is smaller than a curvature radius of a lower area including a portion positioned below the water surface. In order to stably support the photovoltaic panel against the movement of waves, adjacent unit floating type structures may be connected in a joint structure by the ball joint hinge apparatus of a plastic material connected to the end portion of square tubes of the photovoltaic panel support structure.

In one embodiment, a portable photovoltaic assembly is disclosed. In particular, in one example embodiment, the portable photovoltaic assembly described herein comprises: a solar panel platform; a plurality of solar panel holders affixed to a front of the solar panel platform and configured to hold one or more solar panels; a back support extending from a back of the solar panel platform at an angle between the solar panel platform and the back support; and one or more link arms removably connected between the solar panel platform and the back support to hold the angle between the solar panel platform and the back support. Other embodiments are further described herein that provide for portability and adjustability in an easy-to-use manner.

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.

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 roof integrated photovoltaic mounting system includes a plurality of aluminum rails mountable in horizontal spaced relationship on a roof for receiving courses of photovoltaic panels or photovoltaic tiles. The PV panels or tiles have an extruded attachment feature along their forward edge portions that defines a downwardly projecting forwardly facing hook. Panels or tiles are installed by placing each panel or tile on a pair of rails and sliding the panel or tile down until its forward facing hook engages beneath a rear facing tongue on a rail below. A PV panel or tile in a next lower course is installed by slipping its rear edge beneath the forward edge of a panel or tile in a next higher course. The panel is then hinged down about its rear edge until its forward edge portion engages a support rail below. The panel is then slid down until the hook of its attachment fixture engages beneath the tongue of the downslope rail. When the entire array is installed in this manner, the forward edges of the panels are held down by the hook and tongue engagements and the rear edges are held down by being underneath the forward edges of panels in a next higher course. The procedure is reversed to remove a panel for servicing or replacement. In the case of solar glass tiles, water troughs are installed on the rails underlying abutting ends of tiles in a course to collect rainwater and direct it onto the upper surface of a tile in a next lower course.

A deployable solar photovoltaic power generation system includes an array of photo voltaic panels mounted to expandable truss. In response to environmental input data, the array of photovoltaic panels can be deployed or stowed.

A device and method for a rotatable photovoltaic (PV) panel mount is described. A moving frame, comprising a standard PV panel, connects via a hinge to a fixed frame. In an operative position, the moving frame and its PV panel are coplanar with a larger, fixed array of PV panels. A spring between the fixed frame and the moving frame powers the moving frame to rotate around the hinge pivot from horizontal (operative) to vertical (roof access), when an emergency handle releases a latch. This roof access position now allows roof access through a portion of the roof that was covered by the moving frame in its operative position. A damper, such as a flywheel, limits the rotational speed and prevents injury or damage. Embodiments include kits, installation of embodiments, and use of the invention to access a roof portion in a fire emergency.

Discussed are solar panel systems as well as devices and methods for mounting the solar panel systems to roofs and building structures. Catch clamp, mid clamp, and optionally end clamp assemblies can be preinstalled to the solar panels at the job site before placing and securing the resulting solar panel assemblies to the building structure such as a roof. After an installer places and secures a first solar panel assembly to the building structure, they can install each subsequent solar panel assemblies by attaching the leading edge of the subsequent solar panel assembly to the trailing edge of the previous solar panel assembly using a catch and catch receiver, hook and slot, tab and slot, or similar mechanism.

Discussed are solar panel systems as well as devices and methods for mounting the solar panel systems to roofs and building structures. Catch clamp, mid clamp, and optionally end clamp assemblies can be preinstalled to the solar panels at the job site before placing and securing the resulting solar panel assemblies to the building structure such as a roof. After an installer places and secures a first solar panel assembly to the building structure, they can install each subsequent solar panel assemblies by attaching the leading edge of the subsequent solar panel assembly to the trailing edge of the previous solar panel assembly using a catch and catch receiver, hook and slot, tab and slot, or similar mechanism.

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.