Impact of Shell Opening of a Model Razor Clam on the Evolution of Force Chains in Granular Media

Sichuan Huang, Nariman Mahabadi, J. Tao
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引用次数: 4

Abstract

The razor clams alternately inflate the shelled body and the muscular foot when burrowing down to the ground. It is found from previous numerical simulations that inflation of the shelled body not only forms a firm anchor for the foot penetration, but also reduces penetration resistance; on the other hand, further foot penetration relaxes the shell anchorage, which may compromise the burrowing effectiveness and efficiency. This study utilizes a photoelasticity-based technology, augmented with image processing, to validate the numerical findings. A simplified penetrator model composed of an expandable rectangular shell and a protrusible triangular foot is designed and incorporated into a transparent cell containing more than four thousand photoelastic disks. Sequential images are then taken during the model penetration, which include an initial foot penetration, followed by shell expansion and then another foot penetration. An image processing algorithm is developed to detect the evolution of grain contact forces (orientation and magnitude of contact forces) during the shell expansion and foot penetration of the model. Results from this study confirm the existence of the mutual influence between shell expansion pressure and foot penetration resistance: that is, increasing one causes reduction of the other and vice versa.
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模型蛏子壳开度对颗粒介质中力链演化的影响
剃刀蛤在向地下挖洞时交替地使有壳的身体和肌肉发达的脚膨胀。从前人的数值模拟中发现,壳体的膨胀不仅为足部侵穿形成了牢固的锚,而且降低了侵穿阻力;另一方面,足部进一步侵彻会使壳锚松弛,从而影响掘进的有效性和效率。本研究利用基于光弹性的技术,结合图像处理,来验证数值结果。设计了一个由可膨胀的矩形外壳和可伸出的三角形脚组成的简化穿甲弹模型,并将其集成到一个包含4000多个光弹性盘的透明单元中。然后在模型穿透过程中拍摄顺序图像,其中包括初始脚穿透,随后是壳膨胀,然后是另一个脚穿透。提出了一种图像处理算法,用于检测模型在壳体膨胀和足部侵穿过程中颗粒接触力(接触力的方向和大小)的演变。本研究结果证实了壳体膨胀压力与足部侵彻阻力之间存在相互影响,即一方增大另一方减小,反之亦然。
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