Spring and Power in Hovering Ornithopters

Gih Keong Lau; Yao Wei Chin; Shih Chun Lin; Yu Hsiang Lai; Boo Cheong Khoo

doi:10.1002/aisy.202400477

Spring and Power in Hovering Ornithopters

Gih Keong Lau^*, Yao Wei Chin, Shih Chun Lin, Yu Hsiang Lai, Boo Cheong Khoo

^*此作品的通信作者

研究成果: Review article › 同行評審

摘要

Ornithopters are bird-like flapping-wing robots. Only small ornithopters can hover, with long endurance at hummingbird size. Could larger ornithopters be improved further to hover longer? This paper reviews and examines the drive and power of hovering ornithopters, and elastic means of energy or thrust boosters. While the rotation of flexible wings enhance the thrust generation, two-winged ornithopters did not scale up well because of higher disk loading. In comparison, the X-winged or multiple-V-winged ornithopters enjoy a lower disk loading by beating multiple wings slower, at a smaller stroke angle or a longer span. Further, the clap-and-fling interaction of V and X-wings boosts the thrust generation. Future works can explore the wing flexibility and morphology change to improve the hoverability and flight agility of ornithopters.

原文	English
期刊	Advanced Intelligent Systems
DOIs	https://doi.org/10.1002/aisy.202400477
出版狀態	Accepted/In press - 2024

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10.1002/aisy.202400477

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title = "Spring and Power in Hovering Ornithopters",

abstract = "Ornithopters are bird-like flapping-wing robots. Only small ornithopters can hover, with long endurance at hummingbird size. Could larger ornithopters be improved further to hover longer? This paper reviews and examines the drive and power of hovering ornithopters, and elastic means of energy or thrust boosters. While the rotation of flexible wings enhance the thrust generation, two-winged ornithopters did not scale up well because of higher disk loading. In comparison, the X-winged or multiple-V-winged ornithopters enjoy a lower disk loading by beating multiple wings slower, at a smaller stroke angle or a longer span. Further, the clap-and-fling interaction of V and X-wings boosts the thrust generation. Future works can explore the wing flexibility and morphology change to improve the hoverability and flight agility of ornithopters.",

keywords = "flapping-wing drone, flapping-wing robots, hover efficiency, micro air vehicles, ornithopters",

author = "Lau, {Gih Keong} and Chin, {Yao Wei} and Lin, {Shih Chun} and Lai, {Yu Hsiang} and Khoo, {Boo Cheong}",

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doi = "10.1002/aisy.202400477",

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journal = "Advanced Intelligent Systems",

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AU - Lau, Gih Keong

AU - Chin, Yao Wei

AU - Lin, Shih Chun

AU - Lai, Yu Hsiang

AU - Khoo, Boo Cheong

PY - 2024

Y1 - 2024

N2 - Ornithopters are bird-like flapping-wing robots. Only small ornithopters can hover, with long endurance at hummingbird size. Could larger ornithopters be improved further to hover longer? This paper reviews and examines the drive and power of hovering ornithopters, and elastic means of energy or thrust boosters. While the rotation of flexible wings enhance the thrust generation, two-winged ornithopters did not scale up well because of higher disk loading. In comparison, the X-winged or multiple-V-winged ornithopters enjoy a lower disk loading by beating multiple wings slower, at a smaller stroke angle or a longer span. Further, the clap-and-fling interaction of V and X-wings boosts the thrust generation. Future works can explore the wing flexibility and morphology change to improve the hoverability and flight agility of ornithopters.

AB - Ornithopters are bird-like flapping-wing robots. Only small ornithopters can hover, with long endurance at hummingbird size. Could larger ornithopters be improved further to hover longer? This paper reviews and examines the drive and power of hovering ornithopters, and elastic means of energy or thrust boosters. While the rotation of flexible wings enhance the thrust generation, two-winged ornithopters did not scale up well because of higher disk loading. In comparison, the X-winged or multiple-V-winged ornithopters enjoy a lower disk loading by beating multiple wings slower, at a smaller stroke angle or a longer span. Further, the clap-and-fling interaction of V and X-wings boosts the thrust generation. Future works can explore the wing flexibility and morphology change to improve the hoverability and flight agility of ornithopters.

KW - flapping-wing drone

KW - flapping-wing robots

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KW - micro air vehicles

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JO - Advanced Intelligent Systems

JF - Advanced Intelligent Systems

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Spring and Power in Hovering Ornithopters

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