An energy conversion system for converting wind energy into electrical energy includes at least one rotor having a substantially horizontal rotational axis and a plurality of rotor blades extending radially with respect to the rotational axis; a rotor mantle which fully surrounds the rotor; a plurality of wind funnels, including a first wind funnel arranged upstream of the rotor mantle and tapering towards the rotor mantle, and a second wind funnel arranged downstream of the rotor mantle and widening in a direction leading away from the rotor mantle; and a fixed frame which supports the rotor mantle and/or the plurality of wind funnels, wherein at least one adjustment device is provided, which is arranged and configured to orient the energy conversion system in a position corresponding to a prevailing wind direction.

A fluid-turbine system has an improved means of mitigating the effects of excessive fluid velocity on turbine structural components. Spoilers provide a simple mechanical solution that reduces lift, with minimal increase in drag. Spoilers installed on a duct control aerodynamic lift on ducted turbines, specifically in high-wind conditions. An example embodiment comprises a ducted (shrouded) turbine with articulated segments or spoilers, which may be raised toward the central axis. These spoilers reduce or maintain a tower base moment as constant and dampen support structure oscillations.

Apportioned segments from the surface of a duct in a ducted turbine may be articulated to reduce the surface area of the duct. The apportioned segments are employed to reduce the surface area and therefore the wind resistance of the duct, in excessive wind conditions where excessive side loads are exerted upon the ducted turbine.

The present disclosure relates to a shrouded fluid turbine comprising: a turbine shroud surrounding a rotor and an ejector shroud in fluid communication with the trailing edge of the turbine shroud. Further disclosed is a method and apparatus having a unique configuration that provides a means of mitigating loads on structural components. An example embodiment includes the use of the electrical generation equipment as a counterweight. Other embodiments may include axial motion of components to reduce the moment arm of heavy components and to reduce fluid-stream thrust-force on the support structure and a means of controlling the mean-turbine power production in an array of turbines by controlling downstream wake vortices and power output of an upstream turbine while increasing the free-stream flow to, and power output of, a downstream turbine.

An aerodynamic form mounted at the interface between a building's wall and roof having an aerodynamic form that intercepts oncoming wind and directs it over the edge of the roof as laminar flow directed toward a wind turbine mounted on or proximal to the roof. This directed airflow channeled toward the rotors of the one or more wind turbines increases power generation while reducing noise from turbulent flow.