Construction and Principle of the Raptor Turbine
The Principle of the Wind Turbine Rotor as a Large Valve
Dynamic Response to Wind:
The rotor functions as a valve – it automatically adjusts to wind speed.
Response to Stronger Wind: The rotor blades adjust to capture wind energy as efficiently as possible.
Response to Weaker Wind: The blades adapt to utilize even weaker winds.
Adaptation to Power Settings:
Power Adjustment: The rotor responds to the required power based on the connected load.
At Higher Energy Demand: The rotor adjusts to provide the necessary power.
At Lower Load: The rotor optimizes efficiency and reduces output when less energy is needed.
Structure and Design:
Rotor Blades: Designed for efficient wind energy capture and minimal resistance.
Adjustment Mechanism: Adjusts blade position based on wind speed and required power.
Explanation of the Principle:
Wind hits the rotor blades – the blades begin to rotate.
Adjustment Mechanism: Automatically adjusts blade position for optimal wind capture.
Adaptation to Changes: The rotor dynamically adapts to changes in wind speed and power demands.
This simple and efficient principle allows the turbine to function as a large valve, dynamically responding to various wind conditions and power requirements. I'll explain in detail the entire principle of the turbine, which uses the valve concept to dynamically change its geometry, aerodynamics, and speed, which is crucial for a wind turbine. Using several cleverly assembled "wings," shafts, and springs, I'll build a turbine that "swims like a fish" against the wind and "brakes like a parachute" with the wind to capture as much wind energy as possible. And the better the parachute, the more energy you produce (the more weight it can lift).
The rotor functions as a valve – it automatically adjusts to wind speed.
Response to Stronger Wind: The rotor blades adjust to capture wind energy as efficiently as possible.
Response to Weaker Wind: The blades adapt to utilize even weaker winds.
Power Adjustment: The rotor responds to the required power based on the connected load.
At Higher Energy Demand: The rotor adjusts to provide the necessary power.
At Lower Load: The rotor optimizes efficiency and reduces output when less energy is needed.
Rotor Blades: Designed for efficient wind energy capture and minimal resistance.
Adjustment Mechanism: Adjusts blade position based on wind speed and required power.
Wind hits the rotor blades – the blades begin to rotate.
Adjustment Mechanism: Automatically adjusts blade position for optimal wind capture.
Adaptation to Changes: The rotor dynamically adapts to changes in wind speed and power demands.
On the last three images, something is missing that "brings the turbine to life." Let's see if anyone can figure it out... 🤔
(Hint: "mousetrap")