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Structural design and optimization of a series of 13.2 MW downwind rotors

Shulong Yao, Mayank Chetan, D. Todd Griffith

2021Wind Engineering17 citationsDOIOpen Access PDF

Abstract

The quest for reduced LCOE has driven significant growth in wind turbine size. A key question to enable larger rotor designs is how to configure and optimize structural designs to constrain blade mass and cost while satisfying a growing set of challenging structural design requirements. In this paper, we investigate the performance of a series of three two-bladed downwind rotors with different blade lengths (104.3-m, 122.9-m, and 143.4-m) all rated at 13.2 MW. The primary goals are to achieve 25% rotor mass and 25% LCOE reduction. A comparative analysis of the structural performance and economics of this family rotors is presented. To further explore optimization opportunities for large rotors, we present new results in a root and spar cap design optimization. In summary, we present structural design solutions that achieve 25% rotor mass reduction in a SUMR13i design (104.3-m) and 25% LCOE reduction in a SUMR13C design (143.4-m).

Topics & Concepts

Rotor (electric)Reduction (mathematics)Cost of electricity by sourceTurbineSeries (stratigraphy)EngineeringSparMechanical engineeringAutomotive engineeringStructural engineeringMarine engineeringAerospace engineeringElectricity generationPower (physics)MathematicsGeologyPhysicsPaleontologyGeometryQuantum mechanicsWind Energy Research and DevelopmentWind and Air Flow StudiesAdvanced Aircraft Design and Technologies
Structural design and optimization of a series of 13.2 MW downwind rotors | Litcius