Wind turbine main bearing rating lives as determined by IEC 61400‐1 and ISO 281: A critical review and exploratory case study

Kenworthy, Jarred; Hart, Edward; Stirling, James; Stock, Adam; Keller, Jonathan; Guo, Yi; Brasseur, James; Evans, Rhys

doi:10.1002/we.2883

Cited by 3 publications

(3 citation statements)

References 39 publications

(150 reference statements)

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“…We can express the PCA reduction as follows by first computing the covariance matrix δ as in (4). After that, we perform a Singular Value Decomposition (SVD) σ on the covariance matrix δ, as in (5).…”

Section: Ubo-erexmentioning

confidence: 99%

“…However, ensuring the reliable operation of wind turbines is crucial for maximizing energy output and minimizing maintenance costs [3,4]. Among the various components of wind turbines, bearings are particularly susceptible to degradation, which can lead to costly downtimes and safety risks [5,6]. Therefore, effective prognostics of bearing health are essential for predictive maintenance and planning, enabling timely interventions to prevent failures and optimize operational efficiency [7][8][9].…”

Section: Introductionmentioning

confidence: 99%

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UBO-EREX: Uncertainty Bayesian-Optimized Extreme Recurrent EXpansion for Degradation Assessment of Wind Turbine Bearings

Berghout,

Benbouzid

2024

Electronics

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Maintenance planning is crucial for efficient operation of wind turbines, particularly in harsh conditions where degradation of critical components, such as bearings, can lead to costly downtimes and safety threats. In this context, prognostics of degradation play a vital role, enabling timely interventions to prevent failures and optimize maintenance schedules. Learning systems-based vibration analysis of bearings stands out as one of the primary methods for assessing wind turbine health. However, data complexity and challenging conditions pose significant challenges to accurate degradation assessment. This paper proposes a novel approach, Uncertainty Bayesian-Optimized Extreme Recurrent EXpansion (UBO-EREX), which combines Extreme Learning Machines (ELM), a lightweight neural network, with Recurrent Expansion algorithms, a recently advanced representation learning technique. The UBO-EREX algorithm leverages Bayesian optimization to optimize its parameters, targeting uncertainty as an objective function to be minimized. We conducted a comprehensive study comparing UBO-EREX with basic ELM and a set of time-series adaptive deep learners, all optimized using Bayesian optimization with prediction errors as the main objective. Our results demonstrate the superior performance of UBO-EREX in terms of approximation and generalization. Specifically, UBO-EREX shows improvements of approximately 5.1460 ± 2.1338% in the coefficient of determination of generalization over deep learners and 5.7056% over ELM, respectively. Moreover, the objective search time is significantly reduced with UBO-EREX with 99.7884 ± 0.2404% over deep learners, highlighting its effectiveness in real-time degradation assessment of wind turbine bearings. Overall, our findings underscore the significance of incorporating uncertainty-aware UBO-EREX in predictive maintenance strategies for wind turbines, offering enhanced accuracy, efficiency, and robustness in degradation assessment.

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Section: Ubo-erexmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

UBO-EREX: Uncertainty Bayesian-Optimized Extreme Recurrent EXpansion for Degradation Assessment of Wind Turbine Bearings

Berghout,

Benbouzid

2024

Electronics

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“…The operational lifespan evaluation of complex dynamic systems, which is crucial for the robust and long-lasting design of a variety of offshore structures exposed to in situ environmental pressures, is carried out in this study by employing a novel Gaidai risks evaluation methodology. For recent studies on WT safety and reliability, see (Cuesta 2024;Sharar and Hoover 2024;Kenworthy, et al 2024). In the following Sect.…”

Section: Introductionmentioning

confidence: 99%

Lifetime assessment of semi-submersible wind turbines by Gaidai risk evaluation method

Gaidai,

Ashraf,

Cao

et al. 2024

J Mater. Sci: Mater Eng.

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As the global agenda turns more towards the so-called challenge of climate change and lowering carbon emissions, research into green, renewable energy sources becoming nowadays more and more popular. Offshore wind power, produced by FOWTs (i.e., Floating Offshore Wind Turbines), is one such substitute. It is a significant industrial part of the contemporary offshore wind energy industry and produces clean, renewable electricity. Accurate operational lifetime assessment for FOWTs is an important technical safety issue, as environmental in situ loads can lead to fatigue damage as well as extreme structural dynamics, which can cause structural damage. In this study, in situ environmental hydro and aerodynamic environmental loads, that act on FOWT, given actual local sea conditions have been numerically assessed, using the FAST coupled nonlinear aero-hydro-servo-elastic software package. FAST combines aerodynamics and hydrodynamics models for FOWTs, control and electrical system dynamics models, along with structural dynamics models, enabling coupled nonlinear MC simulation in the real time. The FAST software tool enables analysis of a range of FOWT configurations, including 2- or 3-bladed horizontal-axis rotor, pitch and stall regulation, rigid and teetering hub, upwind and downwind rotors. FAST relies on advanced engineering models—derived from the fundamental laws, however with appropriate assumptions and simplifications, supplemented where applicable with experimental data. Recently developed Gaidai reliability lifetime assessment method, being well suitable for risks evaluation of a variety of sustainable energy systems, experiencing nonlinear, potentially extreme in situ environmental loads, throughout their designed service life. The main advantage of the advocated Gaidai risks evaluation methodology being its ability to tackle simultaneously a large number of dynamic systems' degrees of freedom, corresponding to the system's critical components.

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Review of rolling contact fatigue life calculation for oscillating bearings and application-dependent recommendations for use

Menck,

Stammler

2024

Wind Energ. Sci.

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Abstract. In contrast to the multitude of models in the literature for the calculation of rolling contact fatigue in rotating bearings, literature on oscillating bearings is sparse. This work summarizes the available literature on rolling contact fatigue in oscillating bearings. Publications which present various theoretical models are summarized and discussed. A number of errors and misunderstandings are highlighted, information gaps are filled, and common threads between publications are established. Recommendations are given for using the various models for any oscillating bearing in any industrial application. The applicability of these approaches to pitch and yaw bearings of wind turbines is discussed in detail.

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Wind turbine main bearing rating lives as determined by IEC 61400‐1 and ISO 281: A critical review and exploratory case study

Cited by 3 publications

References 39 publications

UBO-EREX: Uncertainty Bayesian-Optimized Extreme Recurrent EXpansion for Degradation Assessment of Wind Turbine Bearings

UBO-EREX: Uncertainty Bayesian-Optimized Extreme Recurrent EXpansion for Degradation Assessment of Wind Turbine Bearings

Lifetime assessment of semi-submersible wind turbines by Gaidai risk evaluation method

Review of rolling contact fatigue life calculation for oscillating bearings and application-dependent recommendations for use

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