RMSE POWER COEFFICIENT OF WIND TURBINES WITH INVERSE TOQUE-SPEED CONTROL

Rishikesh Choudhary; Kumar Jyotiraditya; Dipo Mahto

doi:10.29121/shodhkosh.v5.i6.2024.2409

Authors

Rishikesh Choudhary Assistant Professor, Department of Electrical Engineering, Bhagalpur College of Engineering, Bhagalpur, India
Kumar Jyotiraditya Assistant Professor, Department of Mechanical Engineering, Bhagalpur College of Engineering, Bhagalpur, India
Dipo Mahto Professor & Head, Department of Physics, Bhagalpur College of Engineering, Bhagalpur, India

DOI:

https://doi.org/10.29121/shodhkosh.v5.i6.2024.2409

Keywords:

RMSE Power Coefficient, Static Power Coefficient, BEM, Constant Power Scheme, Inverse Power Scheme

Abstract [English]

The Blade Element Momentum (BEM) method stands out among various turbine modelling techniques due to its integration of airfoil aerodynamics with momentum theory, allowing detailed force calculations on blade elements. While traditional methods like BEM and Wake Models are efficient for initial turbine design, advancements in computational power have enabled the use of Computational Fluid Dynamics (CFD) for more accurate simulations. Although these models are precise, they are computationally intensive, leading to the continued use of simpler empirical methods, such as the static power coefficient approach, in power system studies. Future research aims to validate and implement dynamic estimation models to account for wind variability and turbine control dynamics. Traditional constant torque-speed control strategies maintain a constant generator speed by using a fixed electromagnetic torque command and adjusting the pitch angle when wind speed exceeds the rated value. However, if the pitch control does not respond quickly enough, rotor acceleration can occur, leading to increased power beyond the generator’s rating. To mitigate this, the pitch control mechanism must react promptly to adjust the turbine's torque profile, ensuring convergence to the rated operating point and avoiding prolonged generator overload. To reduce the burden on the pitch-control system, an inverse torque-speed control approach is proposed, where the electromagnetic torque is dynamically adjusted based on real-time rotor speed data. This method aims to achieve rated power operation with improved responsiveness and reduced stress on the pitch-control mechanism.

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