热超弹性材料中的空穴生成问题

研究热超弹性材料中的空穴生成问题,讨论了温度对空穴生成的影响.球体的材料为考虑温度影响的不可压Gent-Thomas材料,或者说是一种与不可压Gent-Thomas材料对应的热超弹性材料,得到了在表面死载荷作用下球体中空穴生成时的分叉曲线及临界载荷,给出了球体中的应力分布,讨论了温度对临界载荷、分叉曲线和应力分布的影响.     

组合超弹性材料中的空穴生成与增长

本文研究了一种组合不可压超弹性材料圆柱体中空穴的生成与增长问题,得到了这种材料受表面均布拉伸死荷载和轴向拉压共同作用下空穴生成问题的解析解,得到了不同组合情况下圆柱体中空穴生成时的临界载荷及分叉曲线,发现组合材料可以发生右分叉,也可以发生左分叉;给出了空穴生成后的应力分布,并讨论了所存在的应力间断和应力集中问题;通过能量比较分析了解的稳定性,讨论了发生右分叉或左分叉的条件,并分析了材料中预存微孔的增长情况.     

超弹性材料中空穴的动态生成

本文在有限变形动力学的框架下研究了一种不可压超弹性材料圆柱体在表面突加均布拉伸载荷作用下空穴的动态生成问题.除一个相应于均匀变形状态的平凡解外,当外加载荷超过其临界值时,柱体内部还有空穴的突然生成,得到了空穴半径和表面载荷之间的一个精确的微分关系,证明了空穴随时间的演化是非线性的周期性振动.给出了空穴振动的相图、最大振幅、临界载荷及近似的周期.     

超弹性材料中的球形空穴分叉

首先给出了超弹性材料球形空穴分叉问题的数学提法;其次给出了修正Ｂｌａｔｚ－Ｋｏ材料球形空穴分叉问题的两个新的精确解,并计算了空穴生成时,空穴附近的应力集中因子和应力间断,最后数值计算了空穴分支解     

一类可压缩超弹性圆柱体轴线上的空穴现象

对于由一类均匀各向同性可压缩的广义Varga材料组成的实心圆柱体,研究其在给定的外表面拉伸和轴向拉伸或压缩共同作用下的轴对称变形问题.利用能量变分原理得到了问题的控制方程和边界条件,并求得了描述柱体径向对称变形的参数型解析解和描述圆柱体轴线上空穴生成和增长的空穴分岔解.给出了与泊松比和轴向伸长相关的径向临界伸长的表达式和空穴生成后的应力表达式;并通过数值算例讨论了这些参数对圆柱体轴线上空穴生成和增长、圆柱体的径向位移以及应力的集中和突变的影响,同时给出了相应的数值模拟.     

热超弹性材料中空穴增长的分岔问题

研究了受外加均布拉伸死载荷作用的不可压热超弹性材料中空穴突然快速增长的分岔问题.不同于外载荷较小的情况,不可压热超弹性材料球体中的预存微空在外载荷足够大时可以发生突然的快速增长,可视为一类分岔问题.给出了不同温度场下,不同初始半径的微空的增长曲线.预存微空的增长曲线相应于初始半径的极限是实心球体中空穴突然生成的分岔曲线.讨论了均匀和非均匀,升高或降低的温度场对空穴增长问题的影响;给出了预存微空能够发生突然的快速增长的临界载荷,得到了临界载荷与实心球体中空穴突然生成时的临界载荷之间的关系及临界载荷与温度变化之间的关系.     

超塑性材料约束胀形中的空洞损伤与变形局部化

将含有二阶段空洞长大模型的本构关系引入大变形刚黏塑性有限元中,研究了空洞敏感材料向锥台形凹模内超塑约束胀形时空洞化损伤与变形局部化行为,详细阐述静水背压Ｐｈ、初始空洞长大速率β＿０以及模具几何形状（锥角θ,模腔高度Ｈｐ）对局部化以及空洞断裂行为的影响,给出实现完全贴模条件下Ｐｈ－θ,Ｐｈ－β＿０,Ｈｐ－θ以及Ｐｈ－Ｈｐ间临界关系。     

不可压缩超弹性止水材料的粘弹性计算方法研究

发展改进了研究不可压缩超弹性材料的Mooney-Rivlin公式,把材料参数假设成是随时间变化的粘弹性函数,并讨论了粘弹性函数的推导方法,通过工程实例进行了实验计算,并将计算结果与应力松弛试验进行了比较.结果表明,用改进Mooney-Rivlin公式可以简便有效地计算该类材料的粘弹性问题,为解决工程实际问题提供了新的途径.     

短纤维增强三元乙丙橡胶横观各向同性黏-超弹性本构模型

短纤维增强三元乙丙橡胶包覆薄膜,是一种应用于固体火箭发动机缠绕包覆装药的新型复合材料.为了描述其在工作过程中受振动、冲击等载荷作用时的力学行为,基于黏弹性理论和纤维增强连续介质力学理论,提出了一种考虑应变率强化效应的横观各向同性黏-超弹本构模型.模型中应变能函数被分解为超弹性应变能和黏性应变能,其中超弹性应变能包括表征各向同性的橡胶基体应变能和表征各向异性的纤维拉伸应变能,黏性应变能采用表征橡胶和纤维黏性响应的宏观唯象模型.选取表征各应变能的函数形式,经过数学变换、替代、叠加,求解确定最终的应力应变形式,明确模型参数获取的具体步骤,将预测结果与实验结果对比分析,准确性较高.研究表明:该模型能有效预测材料在低应变率下纤维方向为0?～45?的非线性率相关力学特性;模型形式易于实现有限元开发,对固体火箭发动机装药结构完整性分析具有参考价值.     

幂强化材料和超弹性材料组合球体中孔穴的动态生成

在简单加载条件下,研究幂强化材料和超弹性材料组合球体中的动态孔穴生成和增长问题.首先在有限变形动力学的框架下建立了相应的非线性数学模型,得到了应力的表达式,利用变量变换的方法求得了外加载荷和孔穴半径之间的一个精确的微分关系式.证明了当突加载荷超过其临界值时,球体内部有孔穴的突然生成,并随时间呈现非线性的周期振动.通过数值计算,分析了材料参数和球体的半径比对孔穴生成和增长的影响,并与相应的静态结果进行了比较.结果发现,惯性力的影响降低孔穴生成的临界载荷,而且材料的塑性对孔穴生成和增长有明显的影响.     

CAVITATED BIFURCATION FOR INCOMPRESSIBLE HYPERELASTIC MATERIAL

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A physical model for nucleation and early growth of voids in ductile materials under dynamic loading

Spall fracture and other rapid tensile failures in ductile materials are often dominated by the rapid growth of voids. Recent research on the mechanics of void growth clearly shows that void nucleation may be represented as a bifurcation phenomenon, wherein a void forms spontaneously followed by highly localized plastic flow around the new void. Although thermal, viscoplastic, and work hardening effects all play an essential role in the earliest stages of nucleation and growth, the flow becomes dominated by spherical radial inertia, which soon causes all voids to grow asymptotically at the same rate, regardless of differences in initial conditions or constitutive details, provided only that there is the same density of matrix material and the same excess loading history beyond the cavitation stress.These two facts, initiation by bifurcation at a cavitation stress, at which a void first appears, and rapid domination by inertia, are used to postulate a simple, but physically realistic, model for nucleation and early growth of voids in a ductile material under rapid tensile loading. A reasonable statistical distribution for the cavitation stress at various nucleation sites and a simple similarity solution for inertially dominated void growth permit a simple calculation of the initiation and early growth of porosity in the material.Parametric analyses are presented to show the effect that loading rate, peak loading stress, density of nucleation sites, physical properties of the material, etc. have on the applied pressure and distribution of void sizes when a critical porosity is reached.     

A model of dynamic failure in ductile materials

In this paper, a dynamic failure model in ductile materials under the action of a mean tensile stress is developed. The model proposed takes into account nucleation and growth of void as part of the failure process under dynamic loading conditions. In the evolution of porosity , work-hardening behavior and rate-dependent effects are included. Numerical simulations of aluminum, aluminum alloy and OFHC copper spallation processes are performed. The results of computation are in fair agreement with experimental results.Support of this work by the special grant No.9187004 from Natural Science Fundation of China is gratefully acknowledged     

Cavitated bifurcation for composed compressible hyper-elastic materials

The cavitated bifurcation problem in a solid sphere composed of two compressible hyper-elastic materials is examined. The bifurcation solution for the composed sphere under a uniform radial tensile boundary dead-load is obtained. The bifurcation curves and the stress contributions subsequent to the cavitation are given. The right and left bifurcation as well as the catastrophe and concentration of stresses are analyzed. The stability of solutions is discussed through an energy comparison. Project supported by the National Natural Science Foundation of China (No. 19802012).     

CONTINUUM VOID NUCLEATION MODEL FOR Al-Mg ALLOY SHEET BASED ON MEASURED PARTICLE DISTRIBUTION

Void nucleation within measured particle fields of an aluminum alloy is investigated to develop a continuum nucleation model which reflects nucleation at the individual particle scale. A nucleation model for heterogeneous particle distributions is synchronized with the continuum model of Chu and Needleman using the average nucleation strain. The parameters in the continuum model are identified from the particle fields and are evaluated over the range of stress states observed in sheet metal forming. The synchronized continuum nucleation model achieves very good agreement with the nucleation trends for three measured particle fields in uniaxial tension, plane strain, and equal-biaxial tension.     

COUPLING EFFECTS OF VOID SHAPE AND VOID SIZE ON THE GROWTH OF AN ELLIPTIC VOID IN A FIBER-REINFORCED HYPER-ELASTIC THIN PLATE

The growth of a prolate or oblate elliptic micro-void in a fiber reinforced anisotropic incompressible hyper-elastic rectangular thin plate subjected to uniaxial extensions is studied within the framework of finite elasticity. Coupling effects of void shape and void size on the growth of the void are paid special attention to. The deformation function of the plate with an isolated elliptic void is given, which is expressed by two parameters to solve the differential equation. The solution is approximately obtained from the minimum potential energy principle. Deformation curves for the void with a wide range of void aspect ratios and the stress distributions on the surface of the void have been obtained by numerical computation. The growth behavior of the void and the characteristics of stress distributions on the surface of the void are captured. The combined effects of void size and void shape on the growth of the void in the thin plate are discussed. The maximum stresses for the void with different sizes and different void aspect ratios are compared.