Probabilistic analysis of wind turbine performance degradation due to blade erosion accounting for uncertainty of damage geometry

School of Engineering

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https://doi.org/10.1016/j.rser.2023.113254
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Keywords

Wind turbine predictive maintenance, Leading edge erosion, Eroded blade aerodynamics, Uncertain field records of blade erosion, Probability distribution function of turbine energy yield, Stochastic and deterministic methods for uncertainty propagation

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Probabilistic analysis of wind turbine performance degradation due to blade erosion accounting for uncertainty of damage geometry. / Campobasso, Sergio ; Castorrini, Alessio ; Ortolani, Andrea et al.
In: Renewable and Sustainable Energy Reviews, Vol. 178, 113254, 31.05.2023.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Bibtex

@article{56ed7bac67b44819ae93dee36821d72a,

title = "Probabilistic analysis of wind turbine performance degradation due to blade erosion accounting for uncertainty of damage geometry",

abstract = "Geometry alterations of wind turbine blades due to erosion reduce the blade aerodynamic performance, yielding turbine power and energy losses. This study proposes a novel probabilistic analysis framework combining computational fluid dynamics, probabilistic and deterministic uncertainty propagation, and high-performance computing to assess this performance degradation accounting for the unavoidable uncertainty on field records of blade erosion. This uncertainty presently prevents using erosion records for improving wind turbine maintenance planning, increasing energy yield, and thus further reducing the wind energy cost. The technology is demonstrated by quantifying the statistical moments of power and energy yield losses of an eroded utility-scale turbine at a North Sea offshore site and a southern European onshore site. The expectations of the offshore and onshore annual energy production losses are found to be 2 and 3% of the corresponding nominal values, respectively, with corresponding standard deviations of 0.1 and 0.15%. In the realistic scenario of erosion varying with high radial frequency, these low standard deviations result from partial compensation of the impact of mild and severe damages. These low standard deviations indicate that present uncertainty levels of erosion geometry records can be handled with uncertainty analysis in predictive maintenance for further reducing wind energy costs. With the frequent assumption of small or no radial variation of erosion, the standard deviation of the loss is misleadingly higher. For the first time, the study reports on the significant impact of turbulence intensity of the installation site on the turbine loss variability with the site wind characteristics.",

keywords = "Wind turbine predictive maintenance, Leading edge erosion, Eroded blade aerodynamics, Uncertain field records of blade erosion, Probability distribution function of turbine energy yield, Stochastic and deterministic methods for uncertainty propagation",

author = "Sergio Campobasso and Alessio Castorrini and Andrea Ortolani and Edmondo Minisci",

year = "2023",

month = may,

day = "31",

doi = "10.1016/j.rser.2023.113254",

language = "English",

volume = "178",

journal = "Renewable and Sustainable Energy Reviews",

issn = "1364-0321",

publisher = "Elsevier Limited",

}

RIS

TY - JOUR

T1 - Probabilistic analysis of wind turbine performance degradation due to blade erosion accounting for uncertainty of damage geometry

AU - Campobasso, Sergio

AU - Castorrini, Alessio

AU - Ortolani, Andrea

AU - Minisci, Edmondo

PY - 2023/5/31

Y1 - 2023/5/31

N2 - Geometry alterations of wind turbine blades due to erosion reduce the blade aerodynamic performance, yielding turbine power and energy losses. This study proposes a novel probabilistic analysis framework combining computational fluid dynamics, probabilistic and deterministic uncertainty propagation, and high-performance computing to assess this performance degradation accounting for the unavoidable uncertainty on field records of blade erosion. This uncertainty presently prevents using erosion records for improving wind turbine maintenance planning, increasing energy yield, and thus further reducing the wind energy cost. The technology is demonstrated by quantifying the statistical moments of power and energy yield losses of an eroded utility-scale turbine at a North Sea offshore site and a southern European onshore site. The expectations of the offshore and onshore annual energy production losses are found to be 2 and 3% of the corresponding nominal values, respectively, with corresponding standard deviations of 0.1 and 0.15%. In the realistic scenario of erosion varying with high radial frequency, these low standard deviations result from partial compensation of the impact of mild and severe damages. These low standard deviations indicate that present uncertainty levels of erosion geometry records can be handled with uncertainty analysis in predictive maintenance for further reducing wind energy costs. With the frequent assumption of small or no radial variation of erosion, the standard deviation of the loss is misleadingly higher. For the first time, the study reports on the significant impact of turbulence intensity of the installation site on the turbine loss variability with the site wind characteristics.

AB - Geometry alterations of wind turbine blades due to erosion reduce the blade aerodynamic performance, yielding turbine power and energy losses. This study proposes a novel probabilistic analysis framework combining computational fluid dynamics, probabilistic and deterministic uncertainty propagation, and high-performance computing to assess this performance degradation accounting for the unavoidable uncertainty on field records of blade erosion. This uncertainty presently prevents using erosion records for improving wind turbine maintenance planning, increasing energy yield, and thus further reducing the wind energy cost. The technology is demonstrated by quantifying the statistical moments of power and energy yield losses of an eroded utility-scale turbine at a North Sea offshore site and a southern European onshore site. The expectations of the offshore and onshore annual energy production losses are found to be 2 and 3% of the corresponding nominal values, respectively, with corresponding standard deviations of 0.1 and 0.15%. In the realistic scenario of erosion varying with high radial frequency, these low standard deviations result from partial compensation of the impact of mild and severe damages. These low standard deviations indicate that present uncertainty levels of erosion geometry records can be handled with uncertainty analysis in predictive maintenance for further reducing wind energy costs. With the frequent assumption of small or no radial variation of erosion, the standard deviation of the loss is misleadingly higher. For the first time, the study reports on the significant impact of turbulence intensity of the installation site on the turbine loss variability with the site wind characteristics.

KW - Wind turbine predictive maintenance

KW - Leading edge erosion

KW - Eroded blade aerodynamics

KW - Uncertain field records of blade erosion

KW - Probability distribution function of turbine energy yield

KW - Stochastic and deterministic methods for uncertainty propagation

U2 - 10.1016/j.rser.2023.113254

DO - 10.1016/j.rser.2023.113254

M3 - Journal article

VL - 178

JO - Renewable and Sustainable Energy Reviews

JF - Renewable and Sustainable Energy Reviews

SN - 1364-0321

M1 - 113254

ER -

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