包含表面能效应的空间棒新模型

IF 1.7 4区 工程技术 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Gongye Zhang, Xin-Lin Gao, Ziwen Guo
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引用次数: 0

摘要

利用表面弹性理论,建立了一个包含表面能效应的新的非经典空间杆模型。该模型采用了基于最小总势能原理的变分公式,从而同时确定了平衡方程和完整的边界条件。新开发的空间杆模型包含三个表面弹性常数,以考虑表面能效应。在不考虑表面能效应的情况下,新模型恢复了基于弹性的经典基尔霍夫杆模型。为了说明新的空间杆模型,我们直接应用推导出的一般公式分析解决了两个示例问题。第一个是带有固定销支撑的圆形截面弹性杆的屈曲,另一个是由直杆变形而来的螺旋杆的平衡分析。对轴向压缩的直杆进行扰动所需的临界屈曲载荷推导出了一个解析公式,并得到了螺旋杆变形所需的力和耦合的两个闭式表达式。当表面能效应被抑制时,这些公式还原为基于经典弹性的公式。对于屈曲问题,研究发现当前新模型预测的临界屈曲载荷总是高于基于经典弹性的模型给出的临界屈曲载荷,而且当杆的半径足够小时,两组预测值之间的差异很大,但当杆的半径增大时,差异会减小。对于螺旋杆问题,数值结果表明,当杆半径很小时,当前模型预测的力和耦合分别明显大于和小于经典模型预测的力和耦合,但随着杆半径的增大,两者的差异逐渐减小。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A new model for spatial rods incorporating surface energy effects
A new non-classical model for spatial rods incorporating surface energy effects is developed using a surface elasticity theory. A variational formulation based on the principle of minimum total potential energy is employed, which leads to the simultaneous determination of the equilibrium equations and complete boundary conditions. The newly developed spatial rod model contains three surface elasticity constants to account for surface energy effects. The new model recovers the classical elasticity-based Kirchhoff rod model as a special case when the surface energy effects are not considered. To illustrate the new spatial rod model, two sample problems are analytically solved by directly applying the general formulas derived. The first one is the buckling of an elastic rod of circular cross-section with fixed-pinned supports, and the other is the equilibrium analysis of a helical rod deformed from a straight rod. An analytical formula is derived for the critical buckling load required to perturb the axially compressed straight rod, and two closed-form expressions are obtained for the force and couple needed in deforming the helical rod. These formulas reduce to those based on classical elasticity when the surface energy effects are suppressed. For the buckling problem, it is found that the critical buckling load predicted by the current new model is always higher than that given by the classical elasticity-based model, and the difference between the two sets of predicted values is significantly large when the radius of the rod is sufficiently small but diminishes as the rod radius increases. For the helical rod problem, the numerical results reveal that the force and couple predicted by the current model are, respectively, significantly larger and smaller than those predicted by the classical model when the rod radius is very small, but the difference is diminishing with the increase of the rod radius.
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来源期刊
Mathematics and Mechanics of Solids
Mathematics and Mechanics of Solids 工程技术-材料科学:综合
CiteScore
4.80
自引率
19.20%
发文量
159
审稿时长
1 months
期刊介绍: Mathematics and Mechanics of Solids is an international peer-reviewed journal that publishes the highest quality original innovative research in solid mechanics and materials science. The central aim of MMS is to publish original, well-written and self-contained research that elucidates the mechanical behaviour of solids with particular emphasis on mathematical principles. This journal is a member of the Committee on Publication Ethics (COPE).
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