蜻蜓翅膀的仿生力学分析:网格组合提高结构刚度的可行性

IF 1.5 Q3 MECHANICS
Yangyang Wei, Huidi Guo, S. Zhang, Jingyuan Li, Yihan Wang, Chajuan Liu
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引用次数: 3

摘要

随着时间的推移,物体的节点会出现不同程度的变形和位移,甚至损坏。网格结构是柔性的,不同的网格形状和排列方式会影响物体的结构刚度。蜻蜓翼脉的独特结构使蜻蜓能够承受比自身高数倍的压力,自由飞翔。本研究以蜻蜓翅膀仿生学为基础,对蜻蜓翅膀脉络的几何结构进行了解构。采用绘图软件Auto CAD绘制蜻蜓样图,有限元软件Hyper mesh建立模型,求解器OptiStruct分析蜻蜓在不同荷载作用下的起皱、拱型挠度、z方向最大位移、y方向最大转角、组合位移试验,研究蜻蜓在不同几何形状和三维空间结构下的挠度。结果表明:(1)蜻蜓翼脉网结构可以提高载荷下的刚度。(2)相比之下,四边形和组合六边形的位移变形较小。(3)随着起皱和拱高的增加,四边形六边形的结构刚度增强。(4)膜结构对栅格挠度的改善效果优于无膜结构。根据上述实验结果,四边形起皱和六边形拱起结构对网格的承载和挠度有明显的改善,具有对网格系列产品进行结构优化的潜力,适合实际应用和推广。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Bionic Mechanical Analysis of Dragonfly Wings: The Feasibility of Mesh Combination to Improve Structural Stiffness
The nodes of the object will show different degrees of deformation and displacement or even damage over time. The mesh structure is flexible and different mesh shapes and arrangements will affect the structural stiffness of the object. The unique structure of dragonfly wing veins allows the dragonfly to withstand pressures several times higher than itself and to fly freely. This study is based on dragonfly wing bionics to disassemble the structure of dragonfly wing vein geometry. And it aims to investigate the deflection under different geometries and three-dimensional spatial structures by using the drawing software Auto CAD to draw dragonfly sample graphics, the finite element software Hyper mesh to build the model and the solver OptiStruct to analyze the structure of wrinkling, arching deflection, z-direction maximum displacement, y-direction maximum rotation angle, combined displacement test under the different loads. The results show that: (1) The dragonfly wing vein mesh structure can enhance the stiffness under load. (2) In contrast, the displacement deformation of quadrilateral and combined hexagonal is smaller. (3) The structural stiffness of quadrilateral hexagon is enhanced as the height of wrinkling and arching increases. (4) The improvement of grid deflection with membrane structure is better than that without membrane structure. According to the above experimental results, the quadrilateral wrinkling and hexagonal arching structure has a significant improvement on the load bearing and deflection of the mesh, and has the potential to make structural optimization of the mesh series products, which is suitable for practical application and promotion.
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来源期刊
CiteScore
1.70
自引率
8.30%
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