No yield stress required: Stress-activated flow in simple yield-stress fluids

IF 3 2区 工程技术 Q2 MECHANICS Journal of Rheology Pub Date : 2024-01-23 DOI:10.1122/8.0000748
G. Pagani, M. Hofmann, L. E. Govaert, T. Tervoort, J. Vermant
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Abstract

An elastoviscoplastic constitutive equation is proposed to describe both the elastic and rate-dependent plastic deformation behavior of Carbopol® dispersions, commonly used to study yield-stress fluids. The model, a variant of the nonlinear Maxwell model with stress-dependent relaxation time, eliminates the need for a separate Herschel–Bulkley yield stress. The stress dependence of the viscosity was determined experimentally by evaluating the steady-state flow stress at a constant applied shear rate and by measuring the steady-state creep rate at constant applied shear stress. Experimentally, the viscosity’s stress-dependence was confirmed to follow the Ree–Eyring model. Furthermore, it is shown that the Carbopol® dispersions used here obey time-stress superposition, indicating that all relaxation times experience the same stress dependence. This was demonstrated by building a compliance mastercurve using horizontal shifting on a logarithmic time axis of creep curves measured at different stress levels and by constructing mastercurves of the storage- and loss-modulus curves determined independently by orthogonal superposition measurements at different applied constant shear stresses. Overall, the key feature of the proposed constitutive equation is its incorporation of a nonlinear stress-activated change in relaxation time, which enables a smooth transition from elastic to viscous behavior during start-up flow experiments. This approach bypasses the need for a distinct Herschel–Bulkley yield stress as a separate material characteristic. Additionally, the model successfully replicates the observed steady-state flow stress in transient-flow scenarios and the steady-state flow rate in creep experiments, underlining its effectiveness in capturing the material’s dynamic response. Finally, the one-dimensional description is readily extended to a full three-dimensional finite-strain elastoviscoplastic constitutive equation.
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无需屈服应力简单屈服应力流体中的应力激活流动
本文提出了一种弹性粘塑性构造方程,用于描述Carbopol®分散体的弹性和随速率变化的塑性变形行为,该方程通常用于研究屈服应力流体。该模型是非线性麦克斯韦模型的变体,具有随应力变化的松弛时间,无需单独的赫歇尔-布克雷屈服应力。粘度与应力的关系是通过实验确定的,方法是评估恒定剪切速率下的稳态流动应力,以及测量恒定剪切速率下的稳态蠕变速率。实验证实,粘度的应力依赖性遵循 Ree-Eyring 模型。此外,实验还表明,此处使用的 Carbopol® 分散体服从时间应力叠加,这表明所有弛豫时间都具有相同的应力依赖性。通过在对数时间轴上对不同应力水平下测得的蠕变曲线进行水平移动来构建顺应性主曲线,以及通过在不同应用恒定剪切应力下进行正交叠加测量来构建独立确定的存储模量和损耗模量曲线主曲线,都证明了这一点。总之,所提出的构成方程的主要特点是将松弛时间的非线性应力激活变化纳入其中,从而在启动流动实验过程中实现从弹性行为到粘性行为的平稳过渡。这种方法绕过了将不同的赫歇尔-布尔克利屈服应力作为单独材料特性的需要。此外,该模型还成功地复制了瞬态流动情况下观察到的稳态流动应力和蠕变实验中的稳态流速,突出了其捕捉材料动态响应的有效性。最后,一维描述很容易扩展到完整的三维有限应变弹塑性构成方程。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Rheology
Journal of Rheology 物理-力学
CiteScore
6.60
自引率
12.10%
发文量
100
审稿时长
1 months
期刊介绍: The Journal of Rheology, formerly the Transactions of The Society of Rheology, is published six times per year by The Society of Rheology, a member society of the American Institute of Physics, through AIP Publishing. It provides in-depth interdisciplinary coverage of theoretical and experimental issues drawn from industry and academia. The Journal of Rheology is published for professionals and students in chemistry, physics, engineering, material science, and mathematics.
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