Carts with aerofoils move around an elongated, looped track under the force of the wind. Carts are connected to each other in a train on the windward side of the track and collectively rotate gear wheels at the side of the track, via racks mounted on the carts that engage with the gears. The gears ultimately power an electrical generator mounted in the base of the system. The system has multiple tracks stacked one above the other and mounted on a rotatable structure that can be turned to optimize wind energy harvesting. The angle of the aerofoils is adjusted at different locations of the cart on the track when desired. Intervening buffer carts without aerofoils are used to space the carts with aerofoils. The speed of the carts is a fraction of the wind speed.

Carts with aerofoils move around an elongated, looped track under the force of the wind. Carts are connected to each other in a train on the windward side of the track and collectively rotate gear wheels at the side of the track, via racks mounted on the carts that engage with the gears. The gears ultimately power an electrical generator mounted in the base of the system. The system has multiple tracks stacked one above the other and mounted on a rotatable structure that can be turned to optimize wind energy harvesting. The angle of the aerofoils is adjusted at different locations of the cart on the track when desired. Intervening buffer carts without aerofoils are used to space the carts with aerofoils. The speed of the carts is a fraction of the wind speed.

Wind electric generator includes vertical posts attached to support surface, a closed loop rail above support surface, and coupled to vertical posts; sequentially interconnected cars coupled to rail by rollers; frame of each car coupled to first and second vertically-oriented wings; first wing mounted above rail; second wing mounted under rail; turning mechanism coupled to one wing for changing angular orientation relative to wind direction; generator mounted on each frame, having a shaft with a wheel, the wheel engaged to the rail; second rail track below the rail; additional sequentially interconnected cars on second rail track and hingedly coupled with lower end of second wing; and wherein turning mechanism is a flap generating aerodynamic force, coupled to first wing using tail beams; a drive for changing angular position of flap; first and second wings are rigidly coupled using vertical rod; and second wings hingedly coupled to cars on second rail.

Wind electric generator includes vertical posts attached to support surface, a closed loop rail above support surface, and coupled to vertical posts; sequentially interconnected cars coupled to rail by rollers; frame of each car coupled to first and second vertically-oriented wings; first wing mounted above rail; second wing mounted under rail; turning mechanism coupled to one wing for changing angular orientation relative to wind direction; generator mounted on each frame, having a shaft with a wheel, the wheel engaged to the rail; second rail track below the rail; additional sequentially interconnected cars on second rail track and hingedly coupled with lower end of second wing; and wherein turning mechanism is a flap generating aerodynamic force, coupled to first wing using tail beams; a drive for changing angular position of flap; first and second wings are rigidly coupled using vertical rod; and second wings hingedly coupled to cars on second rail.

The subject of the invention is an energy generating apparatus for utilizing the energy of a flow medium having a support structure (13), at least one waving element (1), at least two fastening elements (4), a drive and control unit (5), and an energy recovery and transfer unit (10), wherein the waving element (1) is connected to the fastening elements (4), the drive and control unit (5) is connected to the fastening elements (4). It is characterized in that it comprises at least one turbulizer element (2), the waving element (1) between two fastening elements (4) is described as a regular waveform, determined by a function, and comprises at most one full wave period. The subject of the invention also includes the method for application of the apparatus.

Traction air device with multiple wing contours for a wind power generation plant and wind power generation plant utilizing the air device.

Traction air device with multiple wing contours for a wind power generation plant and wind power generation plant utilizing the air device.

Wind electric generator includes vertical posts attached to support surface, a closed loop rail above support surface, and coupled to vertical posts; sequentially interconnected cars coupled to rail by rollers; frame of each car coupled to first and second vertically-oriented wings; first wing mounted above rail; second wing mounted under rail; turning mechanism coupled to one wing for changing angular orientation relative to wind direction; generator mounted on each frame, having a shaft with a wheel, the wheel engaged to the rail; second rail track below the rail; additional sequentially interconnected cars on second rail track and hingedly coupled with lower end of second wing; and wherein turning mechanism is a flap generating aerodynamic force, coupled to first wing using tail beams; a drive for changing angular position of flap; first and second wings are rigidly coupled using vertical rod; and second wings hingedly coupled to cars on second rail.

Wind electric generator includes vertical posts attached to support surface, a closed loop rail above support surface, and coupled to vertical posts; sequentially interconnected cars coupled to rail by rollers; frame of each car coupled to first and second vertically-oriented wings; first wing mounted above rail; second wing mounted under rail; turning mechanism coupled to one wing for changing angular orientation relative to wind direction; generator mounted on each frame, having a shaft with a wheel, the wheel engaged to the rail; second rail track below the rail; additional sequentially interconnected cars on second rail track and hingedly coupled with lower end of second wing; and wherein turning mechanism is a flap generating aerodynamic force, coupled to first wing using tail beams; a drive for changing angular position of flap; first and second wings are rigidly coupled using vertical rod; and second wings hingedly coupled to cars on second rail.

An apparatus for extracting power includes a track and an airfoil coupled to the track. The track includes first and second elongate sections, where the first elongate section is positioned above the second elongate section. The airfoil is moveable in opposite directions when alternately coupled to the first elongate section and second elongate section.