An electric power generating apparatus includes: a cage rotating around a cage axis and including a cage shaft; a plurality of turbines located within the cage, wherein each of the plurality of turbines includes one or more turbine blades and a turbine shaft, and is configured by two end points to fully rotate in a 360-degree circular path around a respective turbine axis different from the cage axis; and an electric power generating motor coupled to the cage shaft, wherein the motor is configured to convert kinetic energy to electric energy, from rotation of the cage around the cage axis.

An apparatus with rotating turbine including: a cage rotating around a cage axis, wherein the rotation of the cage around the cage axis induces a lift of the apparatus above the ground; and a plurality of turbines located within the cage, each turbine rotating around a respective turbine axis different from the cage axis, and including a turbine blade having an adaptable shape; a frame including a first frame portion and a second frame portion coupled to the first frame portion, and wherein the first frame portion pivots relative to the second frame portion; a connection between an end of the frame and a region of the frame away from the end of the frame.

A wind turbine of a VAWT type (Vertical Axis Wind Turbine) having axis of rotation substantially perpendicular to the wind direction, with Flettner rotors (7) having axes substantially parallel to the axis of rotation of the turbine, said Flettner rotors (7) arranged in a rotary body of the turbine, the turbine having an inner cylinder (6) situated between the Flettner rotors (7), said inner cylinder (6) rotating in the direction opposite to the direction of rotation of said rotary body and Flettner rotors (7). The cylinder (6) is situated at a distance from the rotors (7) such that its rotary motion causes an increase of a pressure difference on sides of the rotors (7), resulting from the Magnus effect.

A thrust generating device has a simple structure and can effectively control the magnitude of a Magnus force generated at a cylindrical blade in accordance with the direction of a flow acting on the cylindrical blade. A Magnus-type thrust generating device includes a first member that has a first rotational axis and that can rotate about the first rotational axis; and a second member that is disposed at a rear surface side in an advancement direction of the first member 1. (M?L)/L<2 is satisfied, where L is the distance from the first rotational axis to the most distant part of the surface of the first member and M is the distance from the first rotational axis to the closest part of the surface of the second member in a plane perpendicular to the first rotational axis of the Magnus-type thrust generating device.

A wind power rotor has a first and second rotor device. The first rotor device rotates about a first axis of rotation and has at least two rotor blades moving on a peripheral track about the first axis of rotation. The rotor blades are such that they describe a virtual first shell surface of a virtual first rotating body upon rotation about the first axis of rotation. The second rotor device rotates about a second axis of rotation and has a second rotating body with a closed second shell surface. The second rotating body is arranged at least partially inside of the virtual first rotating body. The first rotor device can be driven by wind in a first direction of rotation and the second rotor device has a drive device, and can be driven in a second direction of rotation which is opposite that of the first direction of rotation.

An apparatus may include a cage that rotates around a cage axis and a turbine located at an end of the cage and rotating around a turbine axis. A turbine blade may have an adaptable shape. A frame of the turbine blade may have a first frame portion that pivots relative to the second frame portion. The curvature of the turbine blade may be controlled by shortening a connection while concurrently lengthening another connection. Controllers may control the rotation of the cage(s) and/or turbine(s) based on a speed, a direction, a velocity, an acceleration of wind, and/or a load carried by the apparatus. The apparatus may be a Savonius machine. Rotation of the cage(s) and/or turbine(s) may induce a Magnus effect. A seat and user controls near the seat may be included. The user controls may control the rotation of the cage(s) and/or turbine(s).

An apparatus may include a cage that rotates around a cage axis and a turbine located at an end of the cage and rotating around a turbine axis. A turbine blade may have an adaptable shape. A frame of the turbine blade may have a first frame portion that pivots relative to the second frame portion. The curvature of the turbine blade may be controlled by shortening a connection while concurrently lengthening another connection. Controllers may control the rotation of the cage(s) and/or turbine(s) based on a speed, a direction, a velocity, an acceleration of wind, and/or a load carried by the apparatus. The apparatus may be a Savonius machine. Rotation of the cage(s) and/or turbine(s) may induce a Magnus effect. A seat and user controls near the seat may be included. The user controls may control the rotation of the cage(s) and/or turbine(s).