A fluid power generation device is configured to provide electric power generation using fluid action, and comprises multiple power generation mechanisms. Each power generation mechanism comprises: a casing that allows a fluid to pass through its internal space; and a power generation unit arranged within the casing, and configured to perform electric power generation using the fluid action. The casing is configured to generate vortexes in the vicinity of its fluid outlet. The multiple casings are arranged with spaces as intervals between them. Each casing generates vortexes in the vicinity of its fluid outlet. Furthermore, such an arrangement provides an interaction effect between the vortexes generated in the vicinity of the fluid outlets of the multipole casings arranged with the spaces as intervals between them. This provides a synergistic effect for accelerating the inner flow based on the interaction between the power generation mechanisms.

A buoyant wave energy device is disclosed that incorporates an open-bottomed tube of substantial length in which is partially enclosed a first body of water that oscillates in response to wave action. The device incorporates a buoy to which an upper end of the tube is connected and inside of which is trapped a second body of water of substantial mass. A differential phase in the oscillations of the water trapped in the tube, and the oscillations of the buoy of augmented mass, result in the periodic compression of a pocket of air trapped at the top of the tube, and in the subsequent expulsion of pressurized air through a turbine, thereby generating electrical power.

An apparatus for selectively amplifying wind speed adjacent a turbine rotor includes a first deflection panel, having a curved front profile for selective placement laterally on a first side of turbine rotor in a working configuration. A second deflection panel has a curved front profile for selective placement laterally on a second side of the turbine rotor, laterally opposite the first side, in a working configuration. The first and second deflection panels are both configured to amplify wind speed adjacent the turbine rotor when in the working configuration, and to have minimal effect upon the wind speed adjacent the turbine rotor when in a stowed configuration. A method of selectively amplifying wind speed adjacent a turbine rotor is also described.

Disclosed is a system and method for both consumer and utility scale energy extraction from flow-based energy sources. The passive system may utilize directing perforations on a surface in order to create and air jet vortex generators. Alternatively the system may provide for flow through discrete orifices aligned with the span of an aerodynamic assembly in a co-flow direction, utilizing a Coanda effect. Further additional configurations include directing flow through a perforated surface skin that is near the trailing edge on the suction side. Even further are embodiments for blowing air directly out of the trailing edge of an airfoil. The disclosed systems and methods support a wide variety of scenarios for fluid flow energy extraction, such as wind or water flow, as well as for related products and services.

The present invention relates to a wind tower (10) for delivering wind flow to a turbine. The wind tower (10) including includes a support structure (12) mounted to a support surface (14) and a wind intake section 16 rotatably mounted to the support structure (12) and elevated with respect to the support surface (14). The intake section (16) includes a plurality of internal passageways (32) extending between a plurality of wind-facing inlets (22) and a plurality of outlets (34). The plurality of inlets (22) are orientated for concurrently receiving an oncoming wind-flow W. Each of the inlets (22) are in fluid communication with one of the outlets 34 via one of the passageways (32). The wind tower (10) further includes an output passageway (42) for collecting wind flow W from the plurality of outlets (34). The output passageway (42) is in fluid communication with the outlets (34) and extends downwardly from the intake section (16) toward the support surface (14) for delivering wind flow W to a turbine located at or proximate to the support surface (14).

This disclosure provides an apparatus, system and method for an energy capturing pod (ECP). The ECP includes a specialized funnel shell, a first turbine, and a second turbine. The specialized funnel shell is designed to accelerate in coming wind speed and is structured with a first choke point and a second choke point for wind. The first turbine is located at the first choke point. The second turbine is located at the second choke point.

A structure adapted to traverse a fluid environment includes an elongate body having a root, a wingtip, a leading edge and a trailing edge; and a plurality of rigid projections each extending from a respective position along the leading edge and/or the trailing edge generally along the same plane as a front surface of the body.

The invention provides for a diffuser (1) for a wind turbine (2). The diffuser (1) comprises an inner diffuser element (8) including a number of vanes (4, 5, 6), wherein at least a first vane (4) and a second vane (5) is arranged in continuation of each other. At least the first vane (4) and the second vane (5) are angled in relation to each other to form a curved cross sectional diffuser profile (7) and a free space (10) is arranged between the neighbouring first vane (4) and second vane (5) to enable air flow between the first vane (4) and second vane (5). The diffuser (1) further comprises at least one further diffuser element (9), wherein at least a first further diffuser element (9) of the at least one further diffuser element (9) is arranged in a further element distance (ED) from the inner diffuser element (8) on an outside (13) of the inner diffuser element (8) in radial direction, so that the further diffuser element (9) substantially encircles the inner diffuser element (8) and so that an open flow-channel (24) is established all the way between the inner diffuser element (8) and the at least one further diffuser element (9), wherein the flow-channel (24) enables air flow all the way through the open flow-channel (24) and out into a wake (25) behind the diffuser (1).

Use of diffuser (1) and a wind turbine (2) comprising a diffuser (1) is also disclosed.

An auxiliary wind energy device comprising a valve device embodied as a rotating aperture plate located adjacent a fixed aperture plate to cyclically operate between open and closed positions to produce intermittent flow at the inlet of the housing and piezoelectric oscillator blades subject to said intermittent flow bending forwardly and backwardly to generate electrical current.

Architecture that harnesses energy from natural atmospheric wind and water currents and self-generated wind and water currents from moving vehicles and natural fluid flow found in nature for moving or stationary applications. The power generation system harnesses energy from natural atmospheric sources utilizing pneumatic and/or hydraulic turbines with compound nozzles, meteorological sensors, computer controlled harmonic resonance valves, a control system, and other components.