Yancong Wang, Yifan Qin, Kai Luo, Qiang Tian, Haiyan Hu
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引用次数: 0
Abstract
Hard-magnetic soft (HMS) beams made of soft polymer matrix embedded with hard-magnetic particles can generate large and fast deformation under magnetic stimulation. Dynamic modeling and simulation of HMS beams interacting with complex environment are challenging in terms of computational accuracy and efficiency. This paper presents a method for high-order modeling and efficient computation of HMS beams. The major contribution of the method is a new three-node HMS beam element of absolute nodal coordinate formulation (ANCF), which applies to two material models of nonlinear and linear elasticities (i.e. neoHookean and St. Venant-Kirchhoff) coupled with magnetic energy. To improve the efficiency of the method, the paper presents how to derive the generalized internal forces and their Jacobians via invariant tensors, and how to determine the generalized external forces to model dynamic loads and interactions including gravity, hydrodynamics in fluids, and frictional contact in pipelines. Afterwards, the paper gives both static and dynamic equations with Rayleigh damping and discusses the numerical algorithms. Finally, the paper makes a comparison of static analysis and the experimental observation to validate the accuracy of the proposed modeling method. The paper also discusses the dynamic simulations, including forced vibration, swimming motion, crawling locomotion, and navigating motion to demonstrate the predictive capability and efficacy of the proposed method for dynamic problems.
由嵌入硬磁粒子的软聚合物基体制成的硬磁软(HMS)梁在磁刺激下可产生巨大而快速的变形。对与复杂环境相互作用的 HMS 梁进行动态建模和仿真,在计算精度和效率方面都具有挑战性。本文提出了一种对 HMS 梁进行高阶建模和高效计算的方法。该方法的主要贡献在于采用绝对节点坐标公式(ANCF)的新型三节点 HMS 梁元素,适用于两种与磁能耦合的非线性和线性弹性材料模型(即 neoHookean 和 St.Venant-Kirchhoff)。为了提高该方法的效率,论文介绍了如何通过不变张量推导广义内力及其雅各布系数,以及如何确定广义外力以模拟动态载荷和相互作用,包括重力、流体中的流体力学和管道中的摩擦接触。随后,论文给出了具有瑞利阻尼的静态和动态方程,并讨论了数值算法。最后,论文对静态分析和实验观察进行了比较,以验证所提建模方法的准确性。论文还讨论了动态模拟,包括受迫振动、游泳运动、爬行运动和导航运动,以证明所提方法对动态问题的预测能力和有效性。
期刊介绍:
The International Journal of Engineering Science is not limited to a specific aspect of science and engineering but is instead devoted to a wide range of subfields in the engineering sciences. While it encourages a broad spectrum of contribution in the engineering sciences, its core interest lies in issues concerning material modeling and response. Articles of interdisciplinary nature are particularly welcome.
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Articles that are devoted to the purely mathematical aspects without a discussion of the physical implications of the results or the consideration of specific examples are discouraged. Articles concerning material science should not be limited merely to a description and recording of observations but should contain theoretical or quantitative discussion of the results.