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非欧几里得壳体的曲率驱动变形

Curvature-driven morphing of non-Euclidean shells.

作者信息

Pezzulla Matteo, Stoop Norbert, Jiang Xin, Holmes D P

机构信息

Department of Mechanical Engineering, Boston University, Boston, MA 02215, USA.

Department of Mathematics, Massachusetts Institute of Technology-Cambridge, Cambridge, MA 02139, USA.

出版信息

Proc Math Phys Eng Sci. 2017 May;473(2201):20170087. doi: 10.1098/rspa.2017.0087. Epub 2017 May 31.

DOI:10.1098/rspa.2017.0087
PMID:28588415
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5454360/
Abstract

We investigate how thin structures change their shape in response to non-mechanical stimuli that can be interpreted as variations in the structure's natural curvature. Starting from the theory of non-Euclidean plates and shells, we derive an effective model that reduces a three-dimensional stimulus to the natural fundamental forms of the mid-surface of the structure, incorporating expansion, or growth, in the thickness. Then, we apply the model to a variety of thin bodies, from flat plates to spherical shells, obtaining excellent agreement between theory and numerics. We show how cylinders and cones can either bend more or unroll, and eventually snap and rotate. We also study the nearly isometric deformations of a spherical shell and describe how this shape change is ruled by the geometry of a spindle. As the derived results stem from a purely geometrical model, they are general and scalable.

摘要

我们研究薄结构如何响应非机械刺激而改变其形状,这种非机械刺激可被解释为结构自然曲率的变化。从非欧几里得板壳理论出发,我们推导了一个有效模型,该模型将三维刺激简化为结构中面的自然基本形式,并考虑了厚度方向上的膨胀或生长。然后,我们将该模型应用于从平板到球壳的各种薄体,理论与数值计算之间取得了极佳的一致性。我们展示了圆柱体和圆锥体如何弯曲得更多或展开,最终折断并旋转。我们还研究了球壳的近等距变形,并描述了这种形状变化是如何由纺锤体的几何形状决定的。由于推导结果源于一个纯粹的几何模型,它们具有通用性和可扩展性。

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