A solar vapor generator includes an absorber to absorb sunlight and an emitter, in thermal communication with the absorber, to radiatively evaporate a liquid under less than 1 sun illumination and without pressurization. The emitter is physically separated from the liquid, substantially reducing fouling of the emitter. The absorber and the emitter may also be heated to temperatures higher than the boiling point of the liquid and may thus may be used to further superheat the vapor. Solar vapor generation can provide the basis for many sustainable desalination, sanitization, and process heating technologies.

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.

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.

A porphyrine organic framework (POF) material is introduced with a one-pot method for photothermal material fabrication. The POF material may be deposited on a porous substrate, such as for solar steam generation.

The present invention has been devised to solve the problem mentioned above and a purpose thereof is to provide a solar panel support having a buoyant body, which has excellent buoyancy retention, enables easy maintenance, and even during maintenance, can maintain maximum supportability. A solar panel support according to one aspect of the present invention comprises a buoyant body for supporting a solar panel, wherein the buoyant body comprises: a parent buoyant body including a coupling hole formed therethrough; and a child buoyant body detachably and fittedly inserted to the coupling hole.

Present invention provides a float capable of suppressing deformation of the synthetic resin body even if internal gas expands and contracts due to environmental temperature change.

A float 10 comprises a float body 20 made of a synthetic resin molded in a hollow shape, a projecting portion 202 projecting from the upper surface of the float body 20 and having a vent hole 201, and a microporous membrane 203 adhered to the outside of the vent hole 201.

Present invention provides a float capable of suppressing deformation of the synthetic resin body even if internal gas expands and contracts due to environmental temperature change.

A float 10 comprises a float body 20 made of a synthetic resin molded in a hollow shape, a projecting portion 202 projecting from the upper surface of the float body 20 and having a vent hole 201, and a microporous membrane 203 adhered to the outside of the vent hole 201.

A floating photovoltaic power station and a load-bearing system thereof are provided according to the present application. The load-bearing system of the floating photovoltaic power station includes an aisle floating body providing buoyancy and forming a first operation and maintenance passage. The aisle floating body is provided with a fixing portion for fixedly connecting with a front side of a photovoltaic assembly, and one photovoltaic assembly is only fixedly connected to one aisle floating body located on the front side of the photovoltaic assembly. In the load-bearing system of the floating photovoltaic power station, the aisle floating body can support the photovoltaic assembly, and can provide buoyancy at the same time.

A floating structure having at least one row of floating rectangular parallelepipedal modular blocks, one block having four vertical peripheral faces that meet at four vertical edges, each vertical edge bearing an assembly lug in which an assembly system can be received in order to join the block to one or more adjacent blocks, each row having a plurality of blocks joined to one another by assembly systems arranged in two diagonally opposite lugs of each block, with the exception of two end blocks, the floating structure being configured so that each block is joined to an adjacent block by a single assembly lug.

A support apparatus for a photovoltaic module and a photovoltaic system are provided. The support apparatus for a photovoltaic module is to be arranged on a water surface, and includes: a support body for mounting the photovoltaic module; and a floating body connected to the support body and configured to provide buoyancy for the support apparatus. A connection function for providing connection with the photovoltaic module and a buoyancy function for providing the buoyancy are separated. The support body having the connection function may be used for providing only connection with the photovoltaic module and not for providing buoyancy. In manufacturing and installation processes, it is unnecessary for the support body to be watertight, thus the manufacturing process of the support body may be greatly simplified, and the manufacturing cost can be reduced.