A floating territory is made of at least two floatable building components having the shape of a prism with a regular polygon base, such as a triangle, a square, a pentagon, a hexagon, etc. combined with sliding dovetails and dovetail grooves for sliding attachment to neighboring construction elements. The attachments allow the floatable building components to slide vertically relative to each other, thereby permitting the floating territory to follow the upward and downward movement of the waves. A method of converting floating ocean waste into structures, in particular, floating territories is also provided.

A turbine comprises a shaft (20), a mass (10) eccentrically mounted for rotation about shaft (20), having its center of gravity at a distance from the shaft (20) and a motion base (15). Motion base (15) rigidly supports the shaft (20), and is configured for moving the shaft (20) in any direction of at least two degrees of movement freedom, except for heave.

A floating vessel-turbine (120), encloses entirely the eccentrically rotating mass (10) and the motion base (15). The turbine converts ocean wave energy into useful energy, very efficiently.

The present disclosure provides a wave-dissipating and wave-resisting integrated floating photovoltaic device capable of resisting severe sea conditions, comprising at least one floating photovoltaic unit, wherein the floating photovoltaic units are connected through connecting pieces, and the connecting pieces can avoid collision between the floating photovoltaic units. The floating photovoltaic unit comprises a floating system, photovoltaic systems and a walkway system; the floating system is used for supporting the photovoltaic systems and bearing wave load impact; the photovoltaic systems are photovoltaic power generation systems; the walkway system is arranged between the photovoltaic systems, and the walkway system provides convenience for later maintenance of the floating photovoltaic device.

A system for controlling the position and orientation of a floating solar array, having: (a) a floating solar array; (b) a plurality of retractable, bi-directional thrusters mounted to the floating solar array and extending below the floating solar array; (c) a control system on the floating solar array for controlling power level of each of the plurality of thrusters, and (d) a power cable connecting the floating solar array to an onshore grid by way of a power cable connector at a bottom central location on the floating solar array. Submerged baffles, perimeter floats and a method of stowing the floating solar array in high winds by rotating the floating solar array into a direction perpendicular to the direction of the high winds are also included.

A set of connectors for modular support platforms is provided. The connectors are used to aggregate at least two support elements, forming a support platform which can be rearranged by adding new support elements and connectors. The set of connectors is used to form a modular support platform for a solar panel power plant, allowing its installation in water surfaces.

Provided is a floating type solar power generation equipment stage (10) device, comprising a carrier (1) and a plurality of floating collars (2). The carrier (1) is made of a hard material, and has an outer frame portion (11) in a horizontal direction and a link bar (12) disposed at the center of the outer frame portion (11). Further, the outer frame portion (11) is vertically disposed with a plurality of straight strip-shaped bonding columns (13) downwards, and an adjustment portion (14) for adjusting the buoyancy of the stage is disposed on the carrier (1). Each of the plurality of floating collars (2) is a buoyant hollow ring, and its center has a sleeve hole (114) into which the bonding column (13) can be inserted so that the floating collars (2) can be arranged vertically up and down on the bonding column (13), and the stage (10) can be floated on the water with vertical buoyancy. Moreover, there is a water flow spacing between the vertically arranged floating collars (2), thereby having better floating stability and maintaining ecological functions.

A floating solar system comprising a grid comprising a plurality of rod-cables, at least some of the rod-cables comprising fiber reinforced polymer, the grid providing a support structure for the floating solar system. The floating solar system further including a plurality of solar floats to provide buoyancy, each solar float coupled to the grid, the plurality of solar floats not providing structural support. The floating solar system designed to support a plurality of solar panels, each solar panel coupled to a corresponding solar float, the solar panel providing shade for the corresponding solar float.

Example implementations include a system and method of using plastic from bodies of water and creating a floating platform by collecting plastic from a body of water, cleaning the collected plastic, melting and compacting the plastic, molding a plurality of hexagonal blocks from the compacted plastic, stacking the plurality of hexagonal blocks, wherein a system of springs and an energy storage device is provided between each of the plurality of hexagonal blocks, and coating the stacked blocks with a non-toxic material. Through the use of various onboard functionalities, energy may be generated to regulate temperature and provide electricity, oxygen may be supplied, and water may be purified.

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 general, the present invention is directed to floating solar photovoltaic platforms, which may include one or more high-density polyethylene resin encapsulating expanded polystyrene foam floats, one or more lift bars, and one or more module frames, wherein: the frames may support one or more solar photovoltaic modules, the platforms may be anchored by any number of means, and the position of the floats may be adjusted. In some embodiments, the floats may utilize a non-roto-rolled high-density polyethylene resin.