Engineers have used Oasys GSA software to analyse the dynamic structure and resolve vibration patterns in order to understand the structural behaviour, and seemingly random variations of quadrangular and polygonal patterns, of a dragonfly wing. First presented at ASME, the International Mechanical Engineering Congress in Colorado, the work by Maria Mingallon, senior structural engineer at Arup, and Sakthivel Ramaswamy, director at KRR Engineering, revealed an intriguing feature, dubbed the nodus.
Acting as both reinforcement and shock absorber to the wing, the nodus copes with combined torsion and bending stress concentrations at the junction of the rigid leading-edge and the more flexible sections of the wing. The researchers concluded that the concentration of stresses and bending moments must have imposed strong selection pressure and that the nodus has evolved to combine a stress-absorbing strip of soft cuticle with strong, three-dimensional cross bars across the entire spar between the costal margin and the leading edge.
Oasys GSA Software’s ability to predict and resolve vibration issues is more commonly used in the design of buildings where the trend to use modern lighter materials creates potential vibration issues which must be resolved at the design stage. It has also recently been applied to the analysis of blast damage to human skeleton in war zones in a prize-winning post-graduate project at Imperial College in the UK.
This story originally appeared on HPC Projects. It appears here as part of a cross-publishing agreement with Scientific Computing World.
