The exemplary embodiments herein provide an airborne power generation assembly comprising an airborne power generation unit, a submersible platform, an electrified tether winch attached to the submersible platform, an electrified tether connecting between the electrified tether winch and the airborne power generation unit, and a power output exiting from the submersible platform. Embodiments include an underwater docking station with a docking station tether connecting the submersible platform to the underwater docking station. The submersible platform or the underwater docking station may be anchored to the sea bed. Other embodiments include winches for the sea bed anchor tethers and docking station tether.

A hybrid kite having an integrated compartment that is inflated with a gas which is lighter than air; the kite is further equipped with a wind turbine generator for the purpose of generating electricity at a high altitude, which can be utilized by the kite or be relayed to the ground for practical use. The kite is anchored in the air as a result of an upward pulling/push force (drag) created by wind, and a combination of buoyancy, to keep the generator/s aloft for an extended period of time beyond 24 hours.

The kite may also serve the purpose of an antenna, to send and receive wireless communication from a base. Moreover the kite can serve as a surveillance vantage point, when equipped with a camera, video camera, microphone and lights, to give an aerial vantage point of a given location.

Numerous other applications for the invention will be realized in conjunction with the primary purpose of providing electricity directly from the generator, which is tethered to the kite, for domestic, industrial & nautical use.

A hybrid kite having an integrated compartment that is inflated with a gas which is lighter than air; the kite is further equipped with a wind turbine generator for the purpose of generating electricity at a high altitude, which can be utilized by the kite or be relayed to the ground for practical use. The kite is anchored in the air as a result of an upward pulling/push force (drag) created by wind, and a combination of buoyancy, to keep the generator/s aloft for an extended period of time beyond 24 hours.

The kite may also serve the purpose of an antenna, to send and receive wireless communication from a base. Moreover the kite can serve as a surveillance vantage point, when equipped with a camera, video camera, microphone and lights, to give an aerial vantage point of a given location.

Numerous other applications for the invention will be realized in conjunction with the primary purpose of providing electricity directly from the generator, which is tethered to the kite, for domestic, industrial & nautical use.

A method of using a bagged power generation system comprising windbags and waterbags integrated with drones and adapting drone technologies for harnessing wind and water power to produce electricity. An extremely scalable and environmentally friendly method, system, apparatus, equipment, techniques and ecosystem configured to produce renewable green energy with high productivity and efficiency.

A method of using a bagged power generation system comprising windbags and waterbags integrated with drones and adapting drone technologies for harnessing wind and water power to produce electricity. An extremely scalable and environmentally friendly method, system, apparatus, equipment, techniques and ecosystem configured to produce renewable green energy with high productivity and efficiency.

Disclosed is a multiple blade wind turbine (MBWT). The MBWT includes: at least one rotor comprising two closed loop tracks positioned parallel or equidistant to one another and a plurality of airfoils interspaced within the tracks. The plurality of airfoils are connected at each end to one of said tracks and are fully rotatable with respect to said closed loop tracks. A transmission is connected to one of the tracks. The track drives the transmission and an electric generator is connected to said transmission for generating electricity. The rotors are oriented vertically or horizontally with respect to a vertical support structure that is used to support the rotors. The MBWT's design allows the electric generator(s) and transmission system to be housed relatively close to ground level. This configuration reduces the mass of the central support tower and reduces the construction and ongoing maintenance costs.

Disclosed is a multiple blade wind turbine (MBWT). The MBWT includes: at least one rotor comprising two closed loop tracks positioned parallel or equidistant to one another and a plurality of airfoils interspaced within the tracks. The plurality of airfoils are connected at each end to one of said tracks and are fully rotatable with respect to said closed loop tracks. A transmission is connected to one of the tracks. The track drives the transmission and an electric generator is connected to said transmission for generating electricity. The rotors are oriented vertically or horizontally with respect to a vertical support structure that is used to support the rotors. The MBWT's design allows the electric generator(s) and transmission system to be housed relatively close to ground level. This configuration reduces the mass of the central support tower and reduces the construction and ongoing maintenance costs.

The invention utilizes a ski lift for wind power generation outside of the ski season. The carriers on the ski lift are replaced by wind catching structures that pull the haul rope either uphill or downhill, depending on the prevailing wind. The haul rope rotates the electrical drive motor of the ski lift, causing it to generate electrical energy.

The invention utilizes a ski lift for wind power generation outside of the ski season. The carriers on the ski lift are replaced by wind catching structures that pull the haul rope either uphill or downhill, depending on the prevailing wind. The haul rope rotates the electrical drive motor of the ski lift, causing it to generate electrical energy.

The invention relates to the field of energy, in particular to devices converting wind energy into electricity. The wind energy conversion method into electrical energy consisting in that the wind energy is converted by means of receivers mounted on the casing of moving wind energy conversion modules, moving linearly along the guide belt, into movement energy of wind energy conversion modules and electric energy by means of electrical energy generating device, mounted on the casing. Wherein there is performing continuous control, depending on the external conditions of the total area of all wind energy receivers guided to the guide belt. In particular embodiments, there is performing continuous control, depending on the external conditions of setting angles of the wind energy receivers relative to the wind energy conversion modules, the movement speeds of the wind energy conversion modules, the aerodynamic profile, and the area of each wind energy receiver, for which it is preferable to use wings with a composite aerodynamic profile, including the main profile, and at least one tilt flap. Also the system for the method embodiment is claimed.