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Ferris Wheel Energy

The next generation renewable energy system

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Synopsis

The trough is filled with water.

For the implementation of the first rotation of the turbine, the compressor is powered by an external power source.

At this point, following the rotational direction of the turbine, the sensors connected to the electronic control boxes on the turbine, and the fixed sensors underneath the trough exchange data.

The control unit activates the pneumatic valves, opening the air ducts, allowing compressed air to be directed to associated airbags, inflating them in the process.

The buoyancy of the airbags help them to rise to the surface of the water.

Once the airbags reach the surface of the water, the fixed sensors at the top of the trough makes contact with the sensors on the turbine, and the control unit opens the exhaust valves in the airbags to deflate.

 Bubbling certain areas of the water facilitates the deflated airbags to move with ease to the bottom.

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24/7 Constant, Clean Energy

Due to Ferris Wheel Energy's closed system, and It does not use solar, wind, or other natural resources, therefore it can run 24/7, producing clean, steady energy.

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Zero Carbon Footprint

We plan to generate energy with emitting any carbon dioxide gases.

Sustainable

The closed system does not affect the environment.

Reliable

Our system does not need any other energy source after starting it.

1 MW+ Production

Out system produces more than 1 megawatt of energy.

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Synopsis

  1. The trough is filled with water.

  2. For the implementation of the first rotation of the turbine, the compressor is powered by an external power source.

  3. At this point, following the rotational direction of the turbine, the sensors connected to the electronic control boxes on the turbine, and the fixed sensors underneath the trough exchange data.

  4. The control unit activates the pneumatic valves, opening the air ducts, allowing compressed air to be directed to associated airbags, inflating them in the process.

  5. The buoyancy of the airbags help them to rise to the surface of the water.

  6. Once the airbags reach the surface of the water, the fixed sensors at the top of the trough makes contact with the sensors on the turbine, and the control unit opens the exhaust valves in the airbags to deflate.

  7.  Bubbling certain areas of the water facilitates the deflated airbags to move with ease to the bottom.

​

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