Abstract
Wind turbines are complex multidisciplinary systems that are challenging to design because of the tightly coupled interactions between different subsystems. Computational modeling attempts to resolve these couplings so we can efficiently explore new wind turbine systems early in the design process. Low-fidelity models are computationally efficient but make assumptions and simplifications that limit the accuracy of design studies, whereas high-fidelity models capture more of the actual physics but with increased computational cost. This paper details the use of multifidelity methods for optimizing wind turbine designs by using information from both low- and high-fidelity models to find an optimal solution at reduced cost. Specifically, a trust-region approach is used with a novel corrective function built from a nonlinear surrogate model. We find that for a diverse set of design problems—with examples given in rotor blade geometry design, wind turbine controller design, and wind power plant layout optimization—the multifidelity method finds the optimal design using 38 %–58 % the computational cost of the high-fidelity-only optimization. The success of the multifidelity method in disparate applications suggests that it could be more broadly applied to other wind energy or otherwise generic applications.
Highlights
This paper details the use of multifidelity methods for optimizing wind turbine designs by using information from both low- and high-fidelity models to find an optimal solution at reduced cost
We find that for a diverse set of design problems—with examples given in rotor blade geometry design, wind turbine controller design, and wind power plant layout optimization—the multifidelity method finds the optimal design using 38%–58% the 10 computational cost of the high-fidelity-only optimization
We have shown that multifidelity optimization methods are effective for a variety of wind energy applications to decrease 345 the computational cost needed to find an optimal design
Summary
Wind turbines are complex systems, where aerodynamic, structural, acoustic, controls, manufacturing, logistics, and technoeconomic considerations are all design drivers. To design the optimal wind energy system, multidisciplinary design optimization 15 (MDO) approaches help capture the interconnected trade-offs among these disciplines while dramatically reducing the times and costs of design processes compared to sequential single-discipline design approaches. The past two decades have seen the development of a variety of MDO models for wind turbine design, such as Giguere and Selig (2000); Fuglsang and Madsen (1999); Ning et al (2014); Ashuri et al (2014); Fischer et al (2014); Pourrajabian et al (2016); Ning and Petch (2016); Bortolotti et al (2016); Barlas et al (2020), among many others. 20 Choosing the correct fidelity level of analyses used in the MDO process is a crucial decision for the designer, who must meet the need of reasonable accuracy with tractable computational costs. Higher computational costs can be tolerated only when doing spot-checks and potential design changes are small
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