Effects of finite sampling on fatigue damage estimation of wind turbine components: A statistical study

Shadan Mozafari; Katherine Dykes; Jennifer Marie Rinker; Paul Veers

doi:10.1177/0309524X231163825

Effects of finite sampling on fatigue damage estimation of wind turbine components: A statistical study

Shadan Mozafari^*, Katherine Dykes, Jennifer Marie Rinker, Paul Veers

^*Corresponding author for this work

National Renewable Energy Laboratory

Research output: Contribution to journal › Journal article › Research › peer-review

Abstract

The variability of the wind turbine loads complicates fatigue assessment in the design phase, as performing simulations covering the entire lifetime is computationally expensive. The current work provides important information for assessing the uncertainty in fatigue damage estimation due to finite data. We study the sample size effect on mean, variance, and skewness of damage in each wind bin, identify the important wind bins, and study the uncertainty propagation from each wind bin to the lifetime damage using 3600 aeroelastic simulations and bootstrapping. To achieve less than 1 at least 100 turbulence seeds are needed. Damage in different wind bins follows a lognormal distribution when using the conventional approach of six seeds. The provided insights and information allow the designer to achieve a specific level of accuracy for a given computational cost using strategic bin sampling.

Original language	English
Journal	Wind Engineering
Volume	47
Issue number	4
Pages (from-to)	799-820
Number of pages	22
ISSN	0309-524X
DOIs	https://doi.org/10.1177/0309524X231163825
Publication status	Published - 2023

Keywords

Wind turbine fatigue
Finite-sampling error
Gaussian fatigue damage
Central limit theorem
Fatigue damage variance

Access to Document

10.1177/0309524X231163825

OpenUrl availability

Full text

Cite this

@article{39937e11694c4fd58b8db72fce21a324,

title = "Effects of finite sampling on fatigue damage estimation of wind turbine components: A statistical study",

abstract = "The variability of the wind turbine loads complicates fatigue assessment in the design phase, as performing simulations covering the entire lifetime is computationally expensive. The current work provides important information for assessing the uncertainty in fatigue damage estimation due to finite data. We study the sample size effect on mean, variance, and skewness of damage in each wind bin, identify the important wind bins, and study the uncertainty propagation from each wind bin to the lifetime damage using 3600 aeroelastic simulations and bootstrapping. To achieve less than 1 at least 100 turbulence seeds are needed. Damage in different wind bins follows a lognormal distribution when using the conventional approach of six seeds. The provided insights and information allow the designer to achieve a specific level of accuracy for a given computational cost using strategic bin sampling.",

keywords = "Wind turbine fatigue, Finite-sampling error, Gaussian fatigue damage, Central limit theorem, Fatigue damage variance",

author = "Shadan Mozafari and Katherine Dykes and Rinker, {Jennifer Marie} and Paul Veers",

year = "2023",

doi = "10.1177/0309524X231163825",

language = "English",

volume = "47",

pages = "799--820",

journal = "Wind Engineering",

issn = "0309-524X",

publisher = "SAGE Publications",

number = "4",

}

TY - JOUR

T1 - Effects of finite sampling on fatigue damage estimation of wind turbine components: A statistical study

AU - Mozafari, Shadan

AU - Dykes, Katherine

AU - Rinker, Jennifer Marie

AU - Veers, Paul

PY - 2023

Y1 - 2023

N2 - The variability of the wind turbine loads complicates fatigue assessment in the design phase, as performing simulations covering the entire lifetime is computationally expensive. The current work provides important information for assessing the uncertainty in fatigue damage estimation due to finite data. We study the sample size effect on mean, variance, and skewness of damage in each wind bin, identify the important wind bins, and study the uncertainty propagation from each wind bin to the lifetime damage using 3600 aeroelastic simulations and bootstrapping. To achieve less than 1 at least 100 turbulence seeds are needed. Damage in different wind bins follows a lognormal distribution when using the conventional approach of six seeds. The provided insights and information allow the designer to achieve a specific level of accuracy for a given computational cost using strategic bin sampling.

AB - The variability of the wind turbine loads complicates fatigue assessment in the design phase, as performing simulations covering the entire lifetime is computationally expensive. The current work provides important information for assessing the uncertainty in fatigue damage estimation due to finite data. We study the sample size effect on mean, variance, and skewness of damage in each wind bin, identify the important wind bins, and study the uncertainty propagation from each wind bin to the lifetime damage using 3600 aeroelastic simulations and bootstrapping. To achieve less than 1 at least 100 turbulence seeds are needed. Damage in different wind bins follows a lognormal distribution when using the conventional approach of six seeds. The provided insights and information allow the designer to achieve a specific level of accuracy for a given computational cost using strategic bin sampling.

KW - Wind turbine fatigue

KW - Finite-sampling error

KW - Gaussian fatigue damage

KW - Central limit theorem

KW - Fatigue damage variance

U2 - 10.1177/0309524X231163825

DO - 10.1177/0309524X231163825

M3 - Journal article

SN - 0309-524X

VL - 47

SP - 799

EP - 820

JO - Wind Engineering

JF - Wind Engineering

IS - 4

ER -

Effects of finite sampling on fatigue damage estimation of wind turbine components: A statistical study

Abstract

Keywords

Access to Document

OpenUrl availability

Fingerprint

Cite this