A Feasibility Study to Reduce Infrasound Emissions from Existing Wind Turbine Blades Using a Biomimetic Technique

Jinlei, Lv; Yang, Wu; Zhang, Haiyang; Liao, Daxiong; Ren, Zhaohui; Qin, Chen

doi:10.3390/en14164923

Cited by 5 publications

(2 citation statements)

References 20 publications

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“…Lv et al [148] investigated the feasibility of reducing infrasound emissions from existing wind turbine blades using a biomimetic technique. The proposed technique was inspired by the leading-edge tubercles on the fin of humpback whales, the trailing-edge profile of bird wings, and the strips on the body surface of beetles.…”

Section: Humpback Whalesmentioning

confidence: 99%

Nature-Inspired Designs in Wind Energy: A Review

Omidvarnia,

Sarhadi

2024

Biomimetics

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The field of wind energy stands at the forefront of sustainable and renewable energy solutions, playing a pivotal role in mitigating environmental concerns and addressing global energy demands. For many years, the convergence of nature-inspired solutions and wind energy has emerged as a promising avenue for advancing the efficiency and sustainability of wind energy systems. While several research endeavors have explored biomimetic principles in the context of wind turbine design and optimization, a comprehensive review encompassing this interdisciplinary field is notably absent. This review paper seeks to rectify this gap by cataloging and analyzing the multifaceted body of research that has harnessed biomimetic approaches within the realm of wind energy technology. By conducting an extensive survey of the existing literature, we consolidate and scrutinize the insights garnered from diverse biomimetic strategies into design and optimization in the wind energy domain.

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Section: Humpback Whalesmentioning

confidence: 99%

Nature-Inspired Designs in Wind Energy: A Review

Omidvarnia,

Sarhadi

2024

Biomimetics

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“…This implies that biomimetic features may exhibit distinct functionalities when the turbine operates under different operating conditions. On the other hand, to mitigate the detrimental emission of infrasound from rotating wind turbine blades, a wind turbine blade with semi-cylindrical rings was studied in [21], drawing inspiration from the body features of beetles. The results from both numerical and experimental studies have shown that the application of semi-cylindrical rings not only reduced the infrasound emission by 8.3% but also led to an increase in the power coefficient C p of the wind turbine to varying extents at different TSRs.…”

Section: Introductionmentioning

confidence: 99%

Enhancing Efficiency and Reliability of Tidal Stream Energy Conversion through Swept-Blade Design

Zheng,

Yang,

Wei

et al. 2024

Energies

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The current limited efficiency and reliability of tidal current turbines (TCTs) have posed significant challenges in effectively harnessing tidal stream energy. To address this issue, this paper undertakes both numerical and experimental studies to explore the advantages of swept blades over conventional straight blades in terms of energy capture efficiency and cavitation resistance. It is found that both the sweep length and sweep angle of the blade can influence the power generation efficiency of the TCT. For the particular swept blade investigated in this study, the highest power coefficient is achieved when the sweep length is 0.544 m and the sweep angle is 28.88°. The research also demonstrated that the swept-blade TCT shows a higher power generation efficiency than the straight-blade TCT across a broad range of rotor speeds. To be precise, with the swept blades, the power coefficient of the TCT can be improved by 5–17%, depending on the tip speed ratio. Additionally, swept blades exhibit a superior cavitation resistance. This is evidenced by their higher cavitation numbers across all tip speed ratios in comparison to conventional straight blades.

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