Experimental Study of Wake Evolution under Vertical Staggered Arrangement of Wind Turbines of Different Sizes

Zhang, Lidong; Feng, Zhengcong; Zhao, Yuze; Xu, Xiandong; Feng, Jiangzhe; Ren, Huaihui; Zhang, Bo; Tian, Wenxin

doi:10.3390/jmse12030434

Cited by 5 publications

(1 citation statement)

References 46 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Xu et al [25] found that by improving the Caputo-Fabrizio fractional order derivative SR in the vibration diagnosis of wind turbine systems, the weak vibration signals are amplified, which effectively improves the vibration detection efficiency of wind turbines operating in strong turbulence environments. Zhang et al [26] proposed a new layout method for wind turbines. They studied the evolution process of wind turbine wake through the wind tunnel test, and analyzed the speed distribution and turbulence characteristics of wind farms through the turbulence intensity and other factors.…”

Section: Introductionmentioning

confidence: 99%

Effect of Turbulence Intensity on Aerodynamic Loads of Floating Wind Turbine under Wind–Wave Coupling Effect

Tian,

Shi,

Zhang

et al. 2024

Sustainability

Self Cite

View full text Add to dashboard Cite

This study first employs TurbSim and OpenFAST (Fatigue, Aerodynamics, Structures, Turbulence) programs for secondary development to comprehensively model the NREL-5MW semi-submersible wind turbine and OC4-DeepC wind floating platform with wind–wave interaction. Next, we investigate the dynamic response of floating wind turbines under the complex coupling of turbulent winds and irregular waves. Turbulent wind fields were simulated using the IEC Kaimal model with turbulence intensities of 5% and 20%. Additionally, two irregular waves were simulated with the Pierson–Moskowitz (P–M) spectrum. The results indicate that in turbulent wind conditions, the aerodynamic power of the wind turbine and the root bending moments of the blades are significantly influenced by turbulence, while the impact of waves is minimal. The coupled motion response of the floating platform demonstrates that turbulence intensity has the greatest impact on the platform’s heave and pitch motions, underscoring the importance of turbulence in platform stability. This study provides essential insights for designing and optimizing floating wind turbines in complex wind–wave coupling offshore environments.

show abstract

Section: Introductionmentioning

confidence: 99%

Effect of Turbulence Intensity on Aerodynamic Loads of Floating Wind Turbine under Wind–Wave Coupling Effect

Tian,

Shi,

Zhang

et al. 2024

Sustainability

Self Cite

View full text Add to dashboard Cite

show abstract

Front Deflector Effects on the Aerodynamic Characteristics of Horizontal Axis Wind Turbines: A Reynolds‐Averaged Navier–Stokes Simulation Study

Zhang,

Yang,

Tian

et al. 2024

Energy Tech

View full text Add to dashboard Cite

Flow control devices have garnered significant attention from domestic and international wind energy scholars. In an effort to capture more wind energy and boost the output power of wind turbines, this study incorporates flow control devices into the upstream area of the wind turbine. The study then assesses the impact of the spacing, tilt angle, and height of the flow control devices on the turbine's performance. The study demonstrates that the addition of flow control devices does lead to a notable enhancement in wind turbine power, with a maximum power output growth rate of 9.74%. The maximum growth rates for the average output power of the wind turbine due to the three factors (α, H, and Lw) are 4.20%, 3.76%, and 3.54%, respectively. The degree of influence of the three factors is as follows: α > H > Lw.

show abstract

Utilizing WFSim to Investigate the Impact of Optimal Wind Farm Layout and Inter-Field Wake on Average Power

Li,

Zhang,

Zhang

et al. 2024

JMSE

View full text Add to dashboard Cite

This paper presents a comprehensive study on optimizing wind farm efficiency by controlling wake effects using the WFSim dynamic simulation model. Focusing on five key factors—yaw wind turbine position, yaw angle, wind farm spacing, longitudinal wind turbine spacing, and yaw rate—we qualitatively analyze their individual and combined impact on the wind farm’s wake behavior and mechanical load. Through a quantitative approach using the orthogonal test method, we assess each factor’s influence on the farm’s overall power output. The findings prioritize the following factors in terms of their effect on power output: yaw wind turbine position, yaw angle, wind farm spacing, longitudinal spacing, and yaw rate. Most significantly, this study identifies optimal working conditions for maximizing the wind farm’s average power output. These conditions include a wind turbine longitudinal spacing of 7.0D, a wind farm spacing of 15.0D, a yaw angle of 30°, and a yaw rate of 0.0122 rad/s, with the first and second rows of turbines in a yaw state. Under these optimized conditions, the wind farm’s average power output is enhanced to 35.19 MW, marking an increase of 2.86 MW compared to the farm’s original configuration. Additionally, this paper offers an analysis of wake deflection under these optimal conditions, providing valuable insights for the design and management of more efficient wind farms.

show abstract

Experimental Study of Wake Evolution under Vertical Staggered Arrangement of Wind Turbines of Different Sizes

Cited by 5 publications

References 46 publications

Effect of Turbulence Intensity on Aerodynamic Loads of Floating Wind Turbine under Wind–Wave Coupling Effect

Effect of Turbulence Intensity on Aerodynamic Loads of Floating Wind Turbine under Wind–Wave Coupling Effect

Front Deflector Effects on the Aerodynamic Characteristics of Horizontal Axis Wind Turbines: A Reynolds‐Averaged Navier–Stokes Simulation Study

Utilizing WFSim to Investigate the Impact of Optimal Wind Farm Layout and Inter-Field Wake on Average Power

Contact Info

Product

Resources

About