Wind Turbine Power Calculator
Reference data and engineering information about wind turbine power calculator for dynamics applications.
Overview
Engineering reference data for Wind Turbine Power Calculator in dynamics.
Key Formulas
Newton's Second Law
Force = mass × acceleration.
Kinetic Energy
Energy of motion.
Momentum
Mass × velocity.
Work
Force × displacement × cos(angle).
Variables
| Symbol | Description | Unit |
|---|---|---|
| Force | N | |
| Mass | kg | |
| Acceleration | m/s² | |
| Velocity | m/s | |
| Kinetic energy | J |
Wind Speed and Power Relationship
Wind turbine power output is not linear with wind speed. It increases with the cube of the wind speed, meaning a small increase in wind speed results in a significant increase in power. However, this relationship holds only within the turbine's operational range.
The theoretical power available in a wind stream is given by:
where:
- is the air density (kg/m³),
- is the rotor swept area (m²),
- is the wind speed (m/s).
Actual electrical power extracted () is less due to the turbine's efficiency, characterized by its power coefficient ():
The power coefficient has a theoretical maximum (the Betz limit) of . Modern turbines typically achieve values between 0.35 and 0.45.
Key Operational Zones:
- Cut-in Speed: The minimum wind speed at which the turbine begins generating power.
- Rated Speed: The wind speed at which the turbine reaches its maximum rated power output.
- Cut-out Speed: The maximum safe operating wind speed; the turbine shuts down above this limit to prevent damage.
This cubic relationship means that doubling the wind speed increases the theoretical power available by a factor of eight (), highlighting the critical importance of site selection for wind energy projects.