A New Theory for Estimating Maximum Power from Wind Turbines: A Fundamental Newtonian Approach

TL;DR

This paper introduces a Newtonian mechanics-based method for estimating wind turbine power output, offering a fundamental approach that could enhance optimization and environmental impact understanding.

Contribution

It presents a novel, physics-based model for wind turbine power calculation, contrasting with traditional aerodynamic methods based on Betz limit and interception rates.

Findings

Provides a new torque-based power estimation method.

Highlights potential heat production and environmental impacts.

Offers a framework for optimizing turbine design.

Abstract

A novel method for calculating power output from wind turbines using Newtonian mechanics is proposed. This contrasts with current methods based on interception rates by airfoils of kinetic energy to estimate power output, governed by the Betz limit of propeller theory. Radial action generates torques from impulses from air molecules at differing radii on rotor surfaces, both windward and leeward. Dimensionally, torque is a rate of action. Integration of the windward torque is achieved numerically using inputs of rotor dimensions, the angle of incidence of elastic wind impulse on the blade surface, chord and blade lengths and the tip speed ratio with wind speed. The rate of leeward or back torque in the plane of rotation is estimated from radial impulses from the blades rotation on material particles, with magnitude varying with the square of the blade radius and its angular velocity. The net torque from these rates of action and reaction is converted to power by its product with the angular velocity of the turbine rotors, considered as an ideal cycle for wind turbines. Its design should assist optimization of the aerodynamic elements of turbine operation. A matter of concern must be predictions for a significant rate of heat production by wind turbines, represented partly by the magnitude of the leeward reaction torque but also by a greater release of heat downwind caused by a turbulent cascade in the wake of air flow following its impacts with the blades. Given the widespread occurrence of wind farms as sources of renewable energy and a need to minimize environmental impacts this new method should promote improved theory and practice regarding wind energy.