Reliability-based design optimization of offshore wind turbine support structures using analytical sensitivities and factorized uncertainty modeling

Stieng, Lars Einar S.; Muskulus, Michael

doi:10.5194/wes-2019-61

Cited by 5 publications

(7 citation statements)

References 48 publications

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“…In other words, surrogate models mimic the behaviour of the simulation model as closely as possible while remaining computationally cheaper to evaluate. Various surrogate modelling approaches have been recently proposed in the literature for OWTs on monopile foundations, including Gaussian Process (GP) regression (8)(9)(10)(11) and for onshore wind turbines using Polynomial Chaos Expansion (12,13). These models significantly improve the computational efficiency of FLS assessment, and therefore also enable structural reliability assessment and the development of probabilistic risk models for OWTs to predict the potential financial impact of OWT failures.…”

Section: Dlcmentioning

confidence: 99%

Impact of climate-change scenarios on offshore wind turbine structural performance

Wilkie

Galasso

2020

Renewable and Sustainable Energy Reviews

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Section: Dlcmentioning

confidence: 99%

Impact of climate-change scenarios on offshore wind turbine structural performance

Wilkie

Galasso

2020

Renewable and Sustainable Energy Reviews

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“…To facilitate quick assessment of computationally-expensive-to-evaluate structural responses, surrogate models have gained popularity. Authors such as [7][8][9] to mention a few, have carried out reliability-based analysis of wind turbines by employing surrogate models. Morató et al [7] carried out reliability analysis of a monopile supported wind turbine using Kriging surrogate models.…”

Section: Introductionmentioning

confidence: 99%

“…[8], only environmental uncertainties and the associated metamodel uncertainty was covered. Surrogate modeling in form of Gaussian process regression was also employed by Stieng and Muskulus [9] in the reliability-based design optimization of an offshore wind turbine (OWT) support structure. Yang et al [10] demonstrated the use Kriging model for reliability-based optimization of a tripod sub-structure.…”

Section: Introductionmentioning

confidence: 99%

“…Modeling uncertainties were neglected in their study as well. A substantial amount of the literature on OWT reliability-based analysis have focused on fixed foundation concepts [7][8][9][10][11]. The structural dynamics of FWTs are different from fixed concepts as floating systems are more compliant to environmental loads implying greater variability in structural loading.…”

Section: Introductionmentioning

confidence: 99%

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Uncertainty modeling in reliability analysis of floating wind turbine support structures

Okpokparoro

Sriramula

2021

Renewable Energy

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Accurate structural reliability assessment of floating wind turbine (FWT) systems is a desideratum for achieving consistent optimal reliability levels and cost-effective design. Such reliability assessment should consider relevant system uncertainties-a nontrivial task. Formulation of the reliability problem requires structural demand in form of load and load effect. Support structure loads are predicted with time-domain dynamic simulations. This represents a challenge when thousands of such simulations are required to capture the uncertainty associated with design variables. Finite element analysis (FEA) is commonly used to evaluate load effects such as stresses, strains etc. This can be computationally expensive if not prohibitive when such evaluation is carried out for every time step. To tackle these issues, a framework for expeditious load effect computation and robust reliability analysis of FWT support structures under ultimate limit state design is presented. The framework employs linear elastic FEA and Kriging surrogate models. The adequacy of Kriging as applied in this study is investigated using high fidelity simulation data. The results highlight the importance of incorporating the Kriging uncertainty in the formulation of the limit state function. With the framework presented, FWT support structures can be designed at consistent reliability levels leading to cost reductions.

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“…The optimization is rarely approached using a coupled model and the definition of the optimization problem along with the optimization algorithm used is very different from research to research. Significant contributions can be found in [4]- [8]. Most works share the use of analytical sensitivities, but the treatment of the dynamic problem differs.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Response Optimization of Steel Jackets for Offshore Wind Turbines With Fatigue and Time-Dependent Constraints

Couceiro

París

Navarrina

et al. 2020

WIT Transactions on the Built Environment

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In this work, a methodology for the shape and sizing optimization of steel jackets for offshore wind turbines considering the full dynamic response of the structure in a fully-coupled model is presented. The coupled model includes the jacket, the transition piece, the tower of the turbine, the rotor-nacelle assembly and the blades. The rotation of the blades is also included in the model. Ultimate limit state (ULS), fatigue limit state (FLS) and natural frequency constraints are imposed to the model and the weight of the steel jacket is optimized using design variables that control the size of the elements and the overall geometry of the structure. A new formulation is introduced to deal with time-dependent ULS constraints allowing an efficient treatment of the constraints while being suitable for gradientbased optimization. The formulation reduces the size of the large-scale constrained optimization problem and the constraints are satisfied at every time-step of the dynamic analysis. This work represents the first optimization approach to tackle the optimization of the jackets in fully-coupled models with constraints in the complete dynamic response and in the fatigue damage. A numerical example is shown and optimized achieving a significant reduction of half of the weight of the structure and a considerable change in the overall geometry of the structure.

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Reliability-based design optimization of offshore wind turbine support structures using analytical sensitivities and factorized uncertainty modeling

Cited by 5 publications

References 48 publications

Impact of climate-change scenarios on offshore wind turbine structural performance

Impact of climate-change scenarios on offshore wind turbine structural performance

Uncertainty modeling in reliability analysis of floating wind turbine support structures

Dynamic Response Optimization of Steel Jackets for Offshore Wind Turbines With Fatigue and Time-Dependent Constraints

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