Hybridization of a Linear Viscoelastic Constitutive Equation and a Nonlinear Maxwell-Type Viscoelastoplastic Model, and Analysis of Poisson’s Ratio Evolution Scenarios under Creep

IF 1.8 4区 材料科学 Q2 MATERIALS SCIENCE, CHARACTERIZATION & TESTING
A. V. Khokhlov
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引用次数: 0

Abstract

A generalization of a physically nonlinear Maxwell-type viscoelastoplastic constitutive equation with four material functions is formulated, whose general properties and range of applicability were discussed in a series of our previous studies. In order to expand the range of rheological effects and materials that can be described by the equation, it is proposed to add a third strain component expressed by a linear integral Boltzmann–Volterra operator with arbitrary functions of shear and volumetric creep. For generality and for the convenience of using the model, as well as for fitting the model to various materials and simulated effects, a weight factor (degree of nonlinearity) is introduced into the constitutive equation, which allows combining the original nonlinear equation and the linear viscoelastic operator in arbitrary proportions to control the degree of different effects modeled. Equations are derived for families of creep curves (volumetric, shear, longitudinal, and transverse) generated by the proposed constitutive equation with six arbitrary material functions, and an expression is obtained for the Poisson ratio as a function of time. Their general properties and dependence on loading parameters and characteristics of all material functions are studied analytically and compared with the properties of similar relations produced by two combined constitutive equations separately. New qualitative effects are identified which can be described by the new constitutive equation in comparison with the original ones, and it is verified that the generalization eliminates some shortcomings of the Maxwell-type viscoelastoplastic constitutive equation, but retains its valuable features. It is confirmed that the proposed constitutive equation can model sign alternation, monotonic and nonmonotonic changes in transverse strain and Poisson’s ratio under constant stress, and their stabilization over time. Generally accurate estimates are obtained for the variation range, monotonicity and nonmonotonicity conditions of Poisson’s ratio, and its negativity criterion over a certain time interval. It is proven that neglecting volumetric creep (the postulate of bulk elasticity), which simplifies the constitutive equation, greatly limits the range of possible evolution scenarios of Poisson’s ratio in time: it increases and cannot have extremum and inflection points. The analysis shows that the proposed constitutive equation provides ample opportunities for describing various properties of creep and recovery curves of materials and various Poisson’s ratio evolution scenarios during creep. It can significantly expand the range of described rheological effects, the applicability of the Maxwell-type viscoelastoplastic equation, and deserves further research and application in modeling.

Abstract Image

Abstract Image

线性粘弹性构造方程与非线性麦克斯韦型粘弹性模型的混合,以及蠕变条件下泊松比演变情况的分析
摘要 本文提出了具有四个材料函数的物理非线性麦克斯韦型粘弹性结构方程的一般化,我们在以前的一系列研究中讨论了该方程的一般特性和适用范围。为了扩大该方程可描述的流变效应和材料的范围,建议添加第三个应变分量,该分量由线性积分波尔兹曼-伏特拉算子表示,具有剪切和体积蠕变的任意函数。为了通用性和使用模型的方便性,以及将模型拟合到各种材料和模拟效应中,在构成方程中引入了一个权重因子(非线性程度),允许以任意比例结合原始非线性方程和线性粘弹性算子,以控制模型中不同效应的程度。由拟议的构成方程生成的蠕变曲线系列(体积蠕变曲线、剪切蠕变曲线、纵向蠕变曲线和横向蠕变曲线)的方程由六个任意的材料函数导出,并获得了泊松比作为时间函数的表达式。通过分析研究了它们的一般特性以及与加载参数和所有材料函数特性的关系,并将其与两个组合构成方程分别产生的类似关系的特性进行了比较。与原始方程相比,确定了新的质量效应,可以用新的构成方程来描述,并验证了这种概括消除了麦克斯韦型粘弹性构成方程的一些缺点,但保留了其有价值的特征。研究证实,所提出的构成方程可以模拟恒定应力下横向应变和泊松比的符号交替、单调和非单调变化,以及它们随时间的稳定变化。对于泊松比的变化范围、单调性和非单调性条件及其在一定时间间隔内的负性准则,一般都能得到精确的估计。研究证明,忽略体积蠕变(体弹性假设)会简化构成方程,从而极大地限制了泊松比随时间变化的可能范围:泊松比会增大,且不会出现极值和拐点。分析表明,所提出的构成方程为描述材料蠕变和恢复曲线的各种特性以及蠕变过程中的各种泊松比演变情况提供了充分的机会。它可以极大地扩展所描述的流变效应范围和 Maxwell 型粘弹性方程的适用性,值得在建模中进一步研究和应用。
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来源期刊
Physical Mesomechanics
Physical Mesomechanics Materials Science-General Materials Science
CiteScore
3.50
自引率
18.80%
发文量
48
期刊介绍: The journal provides an international medium for the publication of theoretical and experimental studies and reviews related in the physical mesomechanics and also solid-state physics, mechanics, materials science, geodynamics, non-destructive testing and in a large number of other fields where the physical mesomechanics may be used extensively. Papers dealing with the processing, characterization, structure and physical properties and computational aspects of the mesomechanics of heterogeneous media, fracture mesomechanics, physical mesomechanics of materials, mesomechanics applications for geodynamics and tectonics, mesomechanics of smart materials and materials for electronics, non-destructive testing are viewed as suitable for publication.
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