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{{Further|Wind turbine design}}▼
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The loads on both [[horizontal-axis wind turbine]]s (HAWTs) and [[vertical-axis wind turbine]]s (VAWTs) are cyclic;
▲The loads on both [[horizontal-axis wind turbine]]s (HAWTs) and [[vertical-axis wind turbine]]s (VAWTs) are cyclic; that is, the [[thrust]] and [[torque]] acting on the blades is dependent on where the blade is. In a horizontal axis wind turbine, both the apparent wind speed seen by the blade and the [[angle of attack]] depend on the position of the blade. This phenomenon is described as [[Rotational sampling in wind turbines|rotational sampling]]. This article will provide an insight into the cyclic nature of the loads that arise because of rotational sampling for a horizontal axis wind turbine.
Rotational sampling can be divided into two parts: [[Deterministic system|deterministic]] and [[Stochastic process|stochastic]]. Deterministic processes present themselves as spikes on a [[Power spectral density|power spectrum]],
▲{{Further|Wind turbine design}}
==Background==
[[Analysis]] of the loads on a [[wind turbine]] can be carried out through the use of [[power spectra]]. A power spectrum is defined as the power [[spectral density]] function of a signal plotted against frequency. The power spectral density function of a plot is defined as the [[Fourier transform]] of the [[covariance function]].<ref>Remote sensing: models and methods for image processing, R. a. Schowengerdt</ref><ref>Remote Sensing: Models and Methods for Image Processing, Robert A. Schowengerd</ref> Regarding the analysis of loads,
==Deterministic processes==
===Sources of deterministic processes===
Upon completing a single revolution, a blade has produced an ever-changing [[torque]], and so power. Some of these changes are due to deterministic processes, i.e., processes that can be determined and do not require statistical methods. Examples of deterministic processes are listed below:
* [[Mass|Gravitational loading]]
* Tower shadow <ref>Time-Domain Modeling of Tower Shadow and Wind Shear in Wind Turbines,
Swagata Das, Neeraj Karnik, and Surya Santoso</ref>
* [[Wind shear]]
Swagata Das, Neeraj Karnik, and Surya Santoso</ref>
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</math>
where ''r'' is the length of the blade, ''m'' is the mass of the blade, ''g'' is the [[Gravitational constant|gravitational field strength]], ''t'' is the time, and <math>\Omega_0</math> is the angular [[velocity]] of the blade.
====Tower shadow====
In [[fluid dynamics]], the flow of a [[fluid]] is dependent upon [[Boundary conditions in fluid dynamics|boundary conditions]]. Boundary conditions are influenced by the presence of solid bodies. In a wind turbine, the presence of the tower results in a reduction of the wind [[speed]] directly in front of it; that is, the blades experience a reduced wind speed when they pass in front of the tower.
====Wind shear====
In fluid dynamics, there exists the [[No-slip condition|no slip]] boundary condition. This states that the velocity of a fluid at the surface of a [[solid]] body, such as the [[Earth]], is zero. A consequence of that is that the wind speed varies with height above ground. This effect is known as [[wind shear]]. As a result, a blade at the highest part of its cycle will experience a greater [[wind speed]] than that of one at the lowest part of its cycle.
===Power spectral density functions===
====Drivetrain components====
The [[drivetrain]] of a wind turbine comprises the hub, the low speed shaft, the [[Transmission (mechanical device)|gearbox]], the high speed shaft, and the generator. The torque at the hub is strongly influenced by the [[Rotordynamics|rotor dynamics]]. The instantaneous hub torque is found by summing all the torques from all the blades of the wind turbine at any instant in time.
Consider an <math>n</math> bladed wind turbine. Each [[blade]] is separated angularly from a
The [[torque]] acting on the blade is defined as the z-component of <math>\textbf{r}\times\mathbf{F}</math>, where '''r''' is the radius from the axis of rotation (in this case the hub), and '''F''' is the force acting on the blade. If the torque is defined as the z-component of this cross product, then the torque is simply ''rF''<sub>perp</sub> where ''F''<sub>perp</sub> is the force perpendicular to the radius vector, or tangential to the instantaneous velocity of the blade (See figure below)
From the figure above, it can be seen that the torque, ''T'', due to gravitational forces acting on a single blade is given by the following expression:
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</math>
The [[covariance]] function of a sum of [[Sinusoidal model|sinusoids]] is itself a sum of [[sinusoidal
====Blades====
For analysis of torque on a single blade, the spikes occur at <math>k'\Omega_0</math> where ''k''' is 1,2,3,..<ref>Aerodynamics of Wind Turbines, Martin O. L. Hansen</ref> This can be seen from taking the autocovariance of equation 1, and then taking the [[Fourier transform]] of this result.
==Structural loads==
[[Spectral analysis (disambiguation)|Spectral analysis]] of component loading is useful in [[fatigue analysis]].
==References==
{{Reflist}}
[[Category:Wind turbines]]▼
{{Improve categories|date=June 2023}}
▲[[Category:Wind turbines]]
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