Multiplicative, Non-Newtonian Viscoelasticity Models for Rubber Materials and Brain Tissues: Numerical Treatment and Comparative Studies

Ricker, A.; Gierig, Meike; Wriggers, Peter

doi:10.1007/s11831-023-09889-x

Cited by 14 publications

(4 citation statements)

References 55 publications

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“…More likely are relations that contain a power‐law or exponential function. Thereby, the reader is referred to [12], showing different approaches for other materials. Similar approaches should be implemented in further research.…”

Section: Materials Model Formulationmentioning

confidence: 99%

A novel thermo‐mechanically coupled material model for glass above the glass transition temperature

Bögershausen,

Holthusen,

Felder

et al. 2023

Proc Appl Math and Mech

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Thin glass products have a giant field of application in several engineering branches such as for example, electronics, medical equipment, and the automotive industry. The non‐isothermal glass molding is a novel replicative glass processing technology enabling the realization of a cost‐efficient production of surface shapes with high accuracy and complexity. However, the application of this technology to thin glass production still causes shape distortions, cracks, and surface defects in molded parts. Therefore, these glass‐forming processes should be simulated by means of the combination of experimental investigation and mechanical modeling of glass above the glass transition temperature at finite strains. Previous experimental studies have shown that the Maxwell model is a reasonable approach for an appropriate prediction of the material behavior. Based on this viscoelastic formulation, a thermo‐mechanically consistent material law is used enabling the prediction of rheological effects noticed during the experiments. More specifically, the relaxation behavior can be described by a stress‐dependent relaxation time and the dissipation generated is considered as well. Furthermore, isothermal uniaxial compression tests above the glass transition temperature are conducted for different strain rates and temperatures within the experimental investigation. Combining the experimental data with the simulation, a multi‐curve‐fitting leads to suitable material parameters with respect to distinct temperatures employing a nonlinear optimization.

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Section: Materials Model Formulationmentioning

confidence: 99%

A novel thermo‐mechanically coupled material model for glass above the glass transition temperature

Bögershausen,

Holthusen,

Felder

et al. 2023

Proc Appl Math and Mech

View full text Add to dashboard Cite

show abstract

“…Indeed, in the past two years there have been several review papers on constitutive relations, which are either general or specific to a research area such as biomechanics [4,5]. Papers expanding these modeling frameworks are also very common to the current day [6,7]. Further review also shows that the focus in the literature is on solving frequency-domain problems.…”

Section: Introductionmentioning

confidence: 99%

A generalized time-domain constitutive finite element approach for viscoelastic materials

Abercrombie,

Gregory McDaniel,

Walsh

2024

Modelling Simul. Mater. Sci. Eng.

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Despite the existence of time domain finite element formulations forviscoelastic materials, there are still substantial ways to improve the analysis. Tothe authors’ knowledge, the formulation of the problem is always done with respectto a single constitutive relation and so limits the implementer to a single scheme withwhich to model relaxation. Furthermore, all current constitutive relations involvethe finding of fitting parameters for an analytical function, which is a sufficientlypainful process to warrant the study of best fitting procedures to this day. Incontrast, this effort is the first full derivation of the two dimensional problem fromfundamental principles. It is also the first generalization of the problem, which freesusers to select constitutive relations without re-derivation or re-expression of theproblem. This approach is also the first approach to the problem that could leadto the elimination of constitutive relations for representing relaxation in viscoelasticmaterials. Following, the full derivation, several common constitutive relations areoutlined with analysis of how they may best be implemented in the generalized form.Several expressions for viscoelastic terms are also provided given linear, quadratic, andexponential interpolation assumptions.

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“…One of those research directions is the study of viscoelastic properties of rubber-like materials, which have been investigated already for many decades [5,6]. However, due to the complex phenomena, research on rubber viscoelasticity is still ongoing, which can, for example, be seen by the works [2,3,[7][8][9][10][11]. Thereby, one basic procedure is to use an appropriate model to capture time-independent effects and to extend this model by several Maxwell elements [7,10].…”

Section: Introductionmentioning

confidence: 99%

A constitutive modeling approach to simulate time‐dependent phenomena in rubber‐like materials

Landgraf,

Ihlemann

2023

Proc Appl Math and Mech

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Industrial rubber materials and similar rubber‐like materials exhibit complex mechanical behavior including nonlinear stress‐strain behavior up to large strains, hysteresis, Mullins effect, permanent set, as well as time‐dependent effects, like relaxation and rate dependency. The modeling of all these phenomena is a challenging task. One constitutive model that is capable to capture many effects in the large strain regime is the so‐called model of rubber phenomenology (MORPH). However, it is not able to capture any of the mentioned time‐dependent phenomena. Thus, this contribution deals with the extension of this model to simulate relaxation and rate dependency of rubber‐like materials. Thereby, a basic modeling approach is proposed, where only a slight change in the original system of tensorial equations is necessary. This approach is further extended by applying not only a constant relaxation time, but also loading history‐depended relaxation properties. For numerical simulations, a time discretization has to be applied to the constitutive equations, which is briefly shown. Finally, the extended MORPH model is applied to two different materials: an industrial rubber material and a polyurethane based adhesive. In both cases, the extended MORPH model is adjusted to uniaxial tension test data by parameter identification procedures. It will be shown that basic time‐dependent phenomena of rubber‐like materials can be captured well with the proposed extensions.

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Multiplicative, Non-Newtonian Viscoelasticity Models for Rubber Materials and Brain Tissues: Numerical Treatment and Comparative Studies

Cited by 14 publications

References 55 publications

A novel thermo‐mechanically coupled material model for glass above the glass transition temperature

A novel thermo‐mechanically coupled material model for glass above the glass transition temperature

A generalized time-domain constitutive finite element approach for viscoelastic materials

A constitutive modeling approach to simulate time‐dependent phenomena in rubber‐like materials

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