Your search keyword '"wind turbine rotor design"' showing total 5 results

1. Editorial: Towards Innovation in Next Generation of Wind Turbine Rotor Design

Author

Wei Jun Zhu, Wen Zhong Shen, and Taeseong Kim

Subjects

wind turbine rotor design, wind turbine aerodynamics, wind turbine aeroelastics, wind turbine aeroacoustics, cost of energy, General Works

Published

2021

2. A gravo-aeroelastically scaled wind turbine rotor at field-prototype scale with strict structural requirements.

Author

Yao, Shulong, Griffith, D. Todd, Chetan, Mayank, Bay, Christopher J., Damiani, Rick, Kaminski, Meghan, and Loth, Eric

Subjects

*WIND turbines, *WIND turbine aerodynamics, *WIND turbine blades, *STRUCTURAL dynamics, *COMPRESSOR blades, *ROTORS, *WIND tunnels, *TECHNICAL specifications

Abstract

A new sub-scale field-prototype design solution is developed to realize the dynamics, structural response, and distributed loads (gravitational, aerodynamic, centrifugal) that are characteristic of a full-scale large, modern wind turbine rotor. Prior work in sub-scale wind turbine testing has focused on matching aerodynamic/aero-elastic characteristics of full-scale rotors at wind tunnel scale. However, large-scale rotor designs must expand beyond this limited set of scaling parameters for cost-effective prototyping and meet strict requirements for structural safety for field testing. The challenge lies in producing a structural design meeting two competing objectives: novel scaling objectives that prescribe the sub-scale blade to have low mass and stiffness; and traditional structural safety objectives that drive the design to have higher stiffness and mass. A 20% gravo-aeroelastically scaled wind turbine blade is developed successfully that satisfies these competing objectives. First, it achieved close agreement for non-dimensional tip deflection and flap-wise blade frequency (both within 2.1%) with a blade mass distribution constrained to produce target gravitational and centrifugal loads. Second, the entire blade structure was optimized to ensure a safe, manufacturable solution meeting strict strength requirements for a testing site that can experience up to 45 m / s wind gusts. The prototype-scale blade was fabricated and successfully proof-load tested. • A 20% gravo-aeroelastically scaled rotor to replicate a full-scale 13.2 MW rotor. • Design solution meets scaling targets within 2.1% for deflection/frequency. • Design solution also satisfies strict structural load safety requirements. • Prototype-scale blade was successfully proof load tested prior to field testing. • First-ever prototype meeting gravo-aeroelastic scaling and loads requirements. [ABSTRACT FROM AUTHOR]

Published

2020

3. Aerodynamic rotor design for a 25 MW offshore downwind turbine.

Author

Jeong, Michael, Loth, Eric, Qin, Chris, Selig, Michael, and Johnson, Nick

Subjects

*AEROFOILS, *REYNOLDS number, *SIMULATED annealing, *WIND turbine aerodynamics, *ROTORS, *TURBINES, *WIND turbines

Abstract

Continuously increasing offshore wind turbine scales require rotor designs that maximize power and performance. Downwind rotors offer advantages in lower mass due to reduced potential for tower strike, and is especially true at large scales, e.g., for a 25 MW turbine. In this study, three 25 MW downwind rotors, each with different prescribed lift coefficient distributions were designed (chord, geometry, and twist) and compared to maximize power production at unprecedented scales and Reynolds numbers, including a new approach to optimize rotor tilt and coning based on aeroelastic effects. To achieve this objective the design process was focused on achieving high power coefficients, while maximizing swept area and minimizing blade mass. Maximizing swept area was achieved by prescribing pre-cone and shaft tilt angles to ensure the aeroelastic orientation when the blades point upwards was nearly vertical at nearly rated conditions. Maximizing the power coefficient was achieved by prescribing axial induction factor and lift coefficient distributions which were then used as inputs for an inverse rotor design tool. The resulting rotors were then simulated to compare performance and subsequently optimized for minimum rotor mass. To achieve these goals, a high Reynolds number design space was developed using computational predictions as well as new empirical correlations for flatback airfoil drag and maximum lift. Within this design space, three rotors of small, medium and large chords were considered for clean airfoil conditions (effects of premature transition were also considered but did not significantly modify the design space). The results indicated that the medium chord design provided the best performance, producing the highest power in Region 2 from simulations while resulting in the lowest rotor mass, both of which support minimum LCOE. The methodology developed herein can be used for the design of other extreme-scale (upwind and downwind) turbines. • Three 25 MW downwind offshore rotors with varying chord and twist were designed. • Blade geometry and rotor swept area were considered for maximizing power production. • Empirical correlations were found to estimate flatback airfoil characteristics. • A design space was created to validate prescribed lift coefficient distributions. • Simulations were performed to predict power production and optimize rotor mass. [ABSTRACT FROM AUTHOR]

Published

2024

4. Aerodynamic design optimization of wind turbine rotors under geometric uncertainty.

Author

Campobasso, M. Sergio, Minisci, Edmondo, and Caboni, Marco

Subjects

WIND turbines, ROTORS, AEROFOILS, AIRPLANE design, MONTE Carlo method, UNIVARIATE analysis, STOCHASTIC analysis

Abstract

Presented is a robust optimization strategy for the aerodynamic design of horizontal axis wind turbine rotors including the variability of the annual energy production because of the uncertainty of the blade geometry caused by manufacturing and assembly errors. The energy production of a rotor designed with the proposed robust optimization approach features lower sensitivity to stochastic geometry errors with respect to that of a rotor designed with the conventional deterministic optimization approach that ignores these errors. The geometry uncertainty is represented by normal distributions of the blade pitch angle, and the twist angle and chord of the airfoils. The aerodynamic module is a blade-element momentum theory code. BothMonte Carlo sampling and the univariate reduced quadrature technique, a novel deterministic uncertainty analysis method, are used for uncertainty propagation. The performance of the two approaches is assessed in terms of accuracy and computational speed. A two-stage multi-objective evolution-based optimization strategy is used. Results highlight that, for the considered turbine type, the sensitivity of the annual energy production to rotor geometry errors can be reduced by reducing the rotational speed and increasing the blade loading. The primary objective of the paper is to highlight how to incorporate an efficient and accurate uncertainty propagation strategy in wind turbine design. The formulation of the considered design problem does not include all the engineering constraints adopted in real turbine design, but the proposed probabilistic design strategy is fairly independent of the problem definition and can be easily extended to turbine design systems of any complexity. [ABSTRACT FROM AUTHOR]

Published

2016

5. Editorial: Towards Innovation in Next Generation of Wind Turbine Rotor Design

Author

Zhu, Wei Jun, Shen, Wen Zhong, Kim, Taeseong, Zhu, Wei Jun, Shen, Wen Zhong, and Kim, Taeseong

Abstract

The development of renewable energy is an inevitable response to the dual challenges of the energy crisis and global warming. In many countries, wind energy has become the most cost effective renewable energy relative to other energy sources. In order to reduce the cost of electricity, modern wind turbines are increasing in rotor size and unit power. The big wind turbines currently in the market are reaching 15 MW rated power and will be possibly increased to 20 MW in a few years. In such a scenario, the continued development in wind energy has led to large rotors that are much lighter and cheaper per kilowatt than before. The main innovations include higher tip speed, higher lift and thicker airfoils, resulting in more slender and lighter blades. In the meanwhile, the coupled effects of aeroelastic and aeroacoustic behaviour and modelling have become the key research challenges. Therefore, research in many aspects of wind energy innovation is important, such that the overall objectives of low cost of energy, high system reliability and environmental-friendliness can be achieved. Several rotor design concepts have emerged to satisfy the up-scale trend, but a crucial problem is managing the large inertial loads and aeroelastic response while retaining high aerodynamic efficiency. Further utilizations of wind energy research meet the critical challenge to continuously grow in size and continuously decrease in price per kilowatt.

Published

2021