飞行中昆虫翅膀变形的几何与力学：一种建模方法

The Geometry and Mechanics of Insect Wing Deformations in Flight: A Modelling Approach.

作者信息

Wootton Robin

机构信息

Department of Biosciences, University of Exeter, Address for correspondence 61 Thornton Hill, Exeter EX4 4NR, UK.

出版信息

Insects. 2020 Jul 17;11(7):446. doi: 10.3390/insects11070446.

DOI:10.3390/insects11070446

PMID:32709085

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7412480/

Abstract

The nature, occurrence, morphological basis and functions of insect wing deformation in flight are reviewed. The importance of relief in supporting the wing is stressed, and three types are recognized, namely corrugation, an M-shaped section and camber, all of which need to be overcome if wings are to bend usefully in the morphological upstroke. How this is achieved, and how bending, torsion and change in profile are mechanically interrelated, are explored by means of simple physical models which reflect situations that are visible in high speed photographs and films. The shapes of lines of transverse flexion are shown to reflect the timing and roles of bending, and their orientation is shown to determine the extent of the torsional component of the deformation process. Some configurations prove to allow two stable conditions, others to be monostable. The possibility of active remote control of wing rigidity by the thoracic musculature is considered, but the extent of this remains uncertain.

摘要

本文综述了昆虫飞行中翅膀变形的性质、发生情况、形态学基础及功能。强调了翅脉在支撑翅膀方面的重要性，并识别出三种类型，即波纹状、M形截面和曲面，若翅膀要在形态学上的向上扑动中有效弯曲，所有这些都需要克服。通过简单的物理模型探讨了如何实现这一点，以及弯曲、扭转和外形变化在机械上是如何相互关联的，这些模型反映了高速照片和影片中可见的情况。横向弯曲线的形状显示出反映了弯曲的时间和作用，其方向显示出决定了变形过程中扭转分量的程度。一些构型被证明允许两种稳定状态，另一些则是单稳态的。考虑了胸部肌肉对翅膀刚度进行主动远程控制的可能性，但其程度仍不确定。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4ba9/7412480/55b415502576/insects-11-00446-g001.jpg

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飞行中昆虫翅膀变形的几何与力学：一种建模方法

The Geometry and Mechanics of Insect Wing Deformations in Flight: A Modelling Approach.

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