A solar window system for a building is provided. The solar window system includes multiple heat generation encasements. Air inside each heat generation encasement is heated by solar energy. The solar window system further includes a storage tank for storing heat from the heated air. The solar window system also includes a set of connection pipes, wherein the set of connection pipes draw cold air from an indoor space inside the building into the plurality of heat generation encasements, connect each of the heat generation encasements to at least two other heat generation encasements, and transfer the heated air from the set of heat generation encasements to the storage tank.

A flat solar chimney in accordance with the invention reduces a building's cooling load by dissipating the solar energy outside the building. What Applicants have done is construct an outer wall having an inner air space before the building structure. The solar light is absorbed by the outside layer which includes a porous metal layer. The heated high surface area foam metal creates a convective air flow in the channel that extends vertically with openings at the bottom and top. This flow dissipates the absorbed heat and is totally external to the building's interior.

In a further embodiment of the invention, a plurality of rectangular slats either horizontally or vertically disposed act as venetian style blinds. The dynamic blinds allow visual function or the solar chimney as per need.

This invention pertains to a system that generates electricity by capturing the energy of raising solar-heated air in suspended above the ground flexible multi-layered ducts. The system for electricity generation is provided with protection against damages caused by severe weather conditions, and its construction requires minimal ground preparation earthworks.

In general terms the present invention proposes a device 100 for harvesting renewable energy. The device 100 comprises a wind turbine 140, a channel 160 for directing wind 198 to the wind turbine 140, and a solar receiver 155 positioned on an internal of the channel 160 for receiving sunlight 194 entering the channel 160.

A renewable-energy power plant including a first structure, a second structure, a first flue, a second flue and a turbine arrangement comprising at least one turbine, wherein the first structure includes a primary fluid inlet and the second structure includes a secondary fluid inlet and a primary fluid outlet, wherein the secondary fluid inlet is connected to the first flue, wherein the primary fluid inlet is located lower than the secondary fluid inlet and the primary fluid outlet is located lower than the secondary fluid inlet, wherein the turbine arrangement is provided inside the second flue, wherein the power plant includes wetting means arranged to discharge an additive fluid to the working fluid passing through the secondary fluid inlet, wherein the turbine arrangement is arranged to generate power due to the working fluid flowing in a downwards direction inside the second flue and passing through the turbine arrangement.

An elevated or ground level vertical cylinder houses one or more propellers and/or turbines that are rotated by heated air convection within or around or above the cylinder. The rotating shafts of the propellers generate electricity in an area at bottom of or below the cylinder. For added, improved air flow directions and volumes; and, for stabilization of the rotating shaft or shafts, a circular pyramid collar structure is disposed below the cylinder. Heat is directed to the cylinder by a plurality of sun tracking concave mirrors that are positioned in concentric circles at various heights. The cylinder may be composed of concrete, ceramics, metal compounds or other materials and operate with a surface temperature that may range 70 to 1,300 degrees Fahrenheit. An optimized system may be constructed on less than one, one or more than one acre of land that could appear as a park like setting.

An inverted funnel-shaped columnar tower (115) includes a window region (120), a heat absorbing surface (130), an air entrance (116) and exit (117). Solar energy passes through the window region and heats the heat absorbing surface. A plurality of fans (145), each connected to a generator (150), are suspended within the tower and extract energy from convectively rising air, generating electricity. A fan (160) outside the tower intercepts wind and turns an internal fan (145) that aids the convective flow, providing a self-starting feature. A plurality of rotors (100) with wings (705) are connected in groups to generators (725) and all are arranged adjacent the tower. The rotors intercept wind energy and deliver it to the generators for conversion to electricity. The rotors include a flap (800) that predetermines the direction of rotation of the rotor, providing a second self-starting feature. The convection and wind-capture functions operate independently.

Invention relates to the field of solar energy. Power station, which has the air stream directional body, at least a pair of generator connected with wind turbines, tough combined greenhouse to the lower end of the body, the external surface of the of which is painted by matt black paint, and due to invention, it (body) is situated on the slope of the mountain, the greenhouse is being realized in the form of body entrance section, and the entrance of which is widened due to the height and width toward body. Before the greenhouse the black color material layer is located on the surface of the earth, and inside there are full of water reservoirs. The power station additionally has electrical air heaters located along the body, heat exchange system and least one horizontal acceleration cell, which is toughly connected with the upper end of the body and has a narrowing transverse cross section. At the free narrowing end of the acceleration cell, a passing cell is situated, at the exit of which a generator fixed to turbine is located. Heat exchange system has a lower radiator, which is located at the body entrance section and an upper radiator; located at the acceleration cell entrance section. Lower and upper radiators are connected with each other by pipes located along the body. The objective of the invention is to rise the EC of the power plant.

A solar window system for a building is provided. The solar window system includes multiple heat generation encasements. Air inside each heat generation encasement is heated by solar energy. The solar window system further includes a storage tank for storing heat from the heated air. The solar window system also includes a set of connection pipes, wherein the set of connection pipes draw cold air from an indoor space inside the building into the plurality of heat generation encasements, connect each of the heat generation encasements to at least two other heat generation encasements, and transfer the heated air from the set of heat generation encasements to the storage tank.

Various examples are provided for power generation using buoyancy-induced vortices. In one example, among others, a vortex generation system includes an array of hybrid vanes comprising a first vane section in a surface momentum boundary layer and a second vane section above the first vane section. The first vane section is configured to impart a first angular momentum on the preheated air in the surface momentum boundary layer and the second vane section is configured to impart a second angular momentum on preheated air drawn through the second vane section. In another embodiment, a method for power extraction from a buoyancy-induced vortex includes imparting angular momentum to preheated boundary layer air entrained by a thermal plume to form a stationary columnar vortex. The angular momentum can be imparted to the preheated boundary layer air at a plurality of angles by an array of hybrid vanes distributed about the thermal plume.