A vertical-axis wind turbine generator includes two or more rotor assemblies, each rotor assembly having two or more wind turbine blades mounted for rotation, preferably those having a Savonius configuration. A cowling includes a nose portion forming a bifurcating wind diverter, in which the bifurcated airflow is directed in order to cause counter directional flow of the wind turbine blades. According to at least one version, the cowling further includes a cover portion that defines a venturi chamber above the rotating blades to draw air into the top of the turbine above the rotating blades and create a vacuum, thereby reducing resistance. The cowling can be part of an existing wind turbine or alternatively replace an original cowling as a retrofit.

An energy conversion device may include a shaft including a first portion and a second portion wherein the first portion of the shaft is configured to rotate relative to the second portion of the shaft. A rotor may be coupled to the first portion of the shaft and a stator may be coupled to the second portion of the shaft. A first one-way bearing may be coupled to the first portion of the shaft and configured to transfer rotational input to the first portion of the shaft in a first direction. A second one-way bearing may be coupled to the second portion of the shaft and configured to transfer rotational input to the second portion of the shaft in a second direction opposite the first direction.

A sea wave energy converter system, including a plurality of pioneer devices each of which is mounted on individual towers installed at a seabed, wherein each of the pioneer device includes an assembly having a set of gears connected to at least one fly wheel, at least one paddle, and a generator, wherein each of the pioneer devices mounted on the individual towers are lined-up in a particular arrangement covering a length of a sea crest so that incoming kinetic forces of sea waves rotates seriatim the at least one paddle of each of the pioneer devices to rotate the generator through the set of gears to generate electricity individually by each of the pioneer devices and wherein the particular arrangement is one of a diagonal arrangement, a cross arrangement, and a ‘V’ shaped arrangement.

Various fluid turbine systems and methods are described. The turbine can be a vertical axis wind turbine configured to generate power from wind energy. The turbine system can have a blade assembly. The blade assembly can have a plurality of blades rotatable about an axis. The turbine system can have a concentrator positionable upwind and in front of a return side of the blade assembly. The concentrator can define a convex surface facing the wind. The turbine system can also have a variable concentrator positionable upwind of a push side of the blade assembly. The variable concentrator can be adjustable between a first position and a second position, the variable concentrator being capable of deflecting more wind toward the turbine in the first position than in the second position.

To provide a wind power generation device that can be suitably increased in size while increasing the electricity generation efficiency. A wind power generation device (10) is characterized by being provided with: a first wind turbine unit (12) comprising multiple wind turbines (30a to 30d) aligned in one line; a pair of blade units (16), each of the blade units being disposed adjacent to the first wind turbine unit (12) and having an inner-side shape extending along the circumferences of circles defined by rotation of the wind turbines (30a to 30d) to enhance collection of wind by the rotation; and a conversion unit for converting energy obtained by the rotation of the first wind turbine unit (12) to electricity.

A large-scale, modular, wind power generating structure and system involving a toroidal or ovoidal shaped wind amplification structure/module that can be stacked vertically to form a tower that passively accelerates a wind flow that moves around each of the modules due to the Bernoulli Principle. Each amplification level includes a plurality of vertical axis wind turbine and generator assemblies, fairings, and vanes that form a synergistic system wherein the efficiency of the vertical axis turbine and generator assemblies and the amount of energy that can be produced per module are substantially improved compared to the turbine assemblies operating outside the integrated and amplified wind system.

A floating heat pump system including a superstructure supporting a wind turbine and at least one electric generator mechanically connected to the wind turbine. Wind-induced rotation of the wind turbine causes the electric generator to generate electricity. The generated electricity may be supplied to a power grid, or a portion of the generated electricity may be used to power a heat pump also supported at least in part by the superstructure to extract heat from the ocean or another large body of water. The heat may be stored in transportable thermal storage medium. Heat stored in the thermal storage media may be used at the system or remotely for regional or district heating and cooling, industrial purposes, or to generate electricity.

Various fluid turbine systems and methods are described. The turbine can be a vertical axis wind turbine configured to generate power from wind energy. The turbine system can have a blade assembly. The blade assembly can have a plurality of blades rotatable about an axis. The turbine system can have a concentrator positionable upwind and in front of a return side of the blade assembly. The concentrator can define a convex surface facing the wind. The turbine system can also have a variable concentrator positionable upwind of a push side of the blade assembly. The variable concentrator can be adjustable between a first position and a second position, the variable concentrator being capable of deflecting more wind toward the turbine in the first position than in the second position.

A vertical axis wind turbine structure is provided that comprises an upstanding structure having a plurality of levels, each level supporting a vertical axis wind turbine assembly therein. Each vertical axis wind turbine assembly drives a generator that develops electrical power. The wind turbine assemblies further comprise a plurality of rotor arms, each supporting a louvered vane assembly thereon. The louvered vane assemblies have louvered vanes supported within a frame that adjust based on the wind front direction. Finally, the outer surface of each of level comprises a rotatable outer surface, whereby an opening through the outer surface allows air flow into the interior thereof and across the louvered vane assemblies. The outer surface of the structure and the louvered vane assemblies adjust based on wind front direction. Overall, the present invention provides a new wind turbine construction that is efficient, modular, and reactive to wind conditions.

A vortex windmill run by incoming air flow to power a generator by which mechanical energy is converted into electrical energy in order to charge a battery. The vortex windmill includes a plurality of elongated blades having bulbous-shaped edges that are spaced from and connected to a rotatable central shaft, and which are located and rotatable within a cylindrical outer cage, such that when the incoming air flow rotates the blades and central shaft a vortex is formed around the central shaft which aids in maintaining the rotational velocity and momentum of the blades and central shaft during operation and for a period of time after the volume of incoming air flow or the velocity of the incoming air flow decreases, thereby increasing the efficiency of the windmill and the amount of energy produced from the air flow received by the windmill.