Unified mean-field modeling of viscous short-fiber suspensions and solid short-fiber reinforced composites

Karl, Tobias; Böhlke, Thomas

doi:10.1007/s00419-022-02257-4

Cited by 8 publications

(6 citation statements)

References 117 publications

(320 reference statements)

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“…In order to realize the flow-fiber coupling, the effective viscosity tensor V of the fiber suspension is formulated in terms of fiber orientation tensors N and N. Throughout this study, the effective Cauchy stress tensor σ refers to a generalized incompressible Newtonian fluid. Furthermore, the Mori-Tanaka model [26,[38][39][40] is used reading…”

Section: Volume Of Fluid Approach For Viscous Fiber Suspensionsmentioning

confidence: 99%

“…The polarization tensor P 0 contains information about the fiber geometry and the matrix material and can be computed analytically for spheroidal fibers. In this work the expressions given in Ponte Castañeda and Willis [41] are adapted for viscosity and simplified for incompressible matrix behavior following Karl and Böhlke [40]. The inversion P −1 0 is defined on the symmetric deviatoric subset (symDev) for the considered case of incompressible suspensions with P −1 0 P 0 = P 2 representing the identity on symDev for second-order tensors.…”

Section: Volume Of Fluid Approach For Viscous Fiber Suspensionsmentioning

confidence: 99%

“…(3) the matrix viscosity V M is considered both Newtonian and non-Newtonian in the context of a generalized Newtonian fluid. Within the present study, the shear-thinning Cross-model [45] for the polymer matrix is implemented as follows to be compared against the Newtonian behavior [40,46]…”

Section: Volume Of Fluid Approach For Viscous Fiber Suspensionsmentioning

confidence: 99%

“…For clarity, the basics regarding mean-field modeling are omitted here and the reader is referred to further literature, e.g., Nemat-Nasser and Hori [47] or Kanaun and Levin [48]. Based on the Mori-Tanaka model [26], the effective stiffness tensor reads C = C M + R with the abbreviation R defined as follows [27,40,49]…”

Section: Solid Fiber Reinforced Compositesmentioning

confidence: 99%

“…Further information can be found in the literature, e.g., in Nemat-Nasser and Hori [47] or in Torquato [52]. Regarding the uniform meanfield homogenization of viscous fiber suspensions and solid short-fiber reinforced composites, reference is made to the recent work of Karl and Böhlke [40].…”

Section: Scale Separation and Requirements For Homogenizationmentioning

confidence: 99%

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Influence of flow–fiber coupling during mold-filling on the stress field in short-fiber reinforced composites

et al. 2023

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The anisotropic elastic properties of injection molded composites are fundamentally coupled to the flow of the fiber suspension during mold-filling. Regarding the modeling of mold-filling processes, both a decoupled and a flow–fiber coupled approach are possible. In the latter, the fiber-induced viscous anisotropy is considered in the computation of the flow field. This in turn influences the evolution of the fiber orientation compared to the decoupled case. This study investigates how flow–fiber coupling in mold-filling simulation affects the stress field in the solid composite under load based on the final elastic properties after fluid–solid transition. Furthermore, the effects of Newtonian and non-Newtonian polymer matrix behavior are investigated and compared. The entire process is modeled micromechanically unified based on mean-field homogenization, both for the fiber suspension and for the solid composite. Different numerical stabilization methods of the mold-filling simulation are discussed in detail. Short glass fibers with a typical aspect ratio of 20 and a volume fraction of 20% are considered, embedded in polypropylene matrix material. The results show that the flow–fiber coupling has a large effect on the fiber orientation tensor in the range of over ± 30% with respect to the decoupled simulation. As a consequence, the flow–fiber coupling affects the stress field in the solid composite under load in the range of over ± 10%. In addition, the predictions based on a non-Newtonian modeling of the matrix fluid differ significantly from the Newtonian setup and thus the necessity to consider the shear-thinning behavior is justified in a quantifiable manner.

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Section: Volume Of Fluid Approach For Viscous Fiber Suspensionsmentioning

confidence: 99%

Section: Volume Of Fluid Approach For Viscous Fiber Suspensionsmentioning

confidence: 99%

Section: Volume Of Fluid Approach For Viscous Fiber Suspensionsmentioning

confidence: 99%

Section: Solid Fiber Reinforced Compositesmentioning

confidence: 99%

Section: Scale Separation and Requirements For Homogenizationmentioning

confidence: 99%

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Influence of flow–fiber coupling during mold-filling on the stress field in short-fiber reinforced composites

et al. 2023

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FEM–CM as a hybrid approach for multiscale modeling and simulation of ferroelectric boundary value problems

Wakili,

Lange,

Ricoeur

2023

Comput Mech

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Constitutive modeling of ferroelectrics is a challenging task, spanning physical processes on different scales from unit cell switching and domain wall motion to polycrystalline behavior. The condensed method (CM) is a semi-analytical approach, which has been efficiently applied to various problems in this context, ranging from self-heating and damage evolution to energy harvesting. Engineering applications, however, inevitably require the solution of arbitrary boundary value problems, including the complex multiphysical constitutive behavior, in order to analyze multifunctional devices with integrated ferroelectric components. The well-established finite element method (FEM) is commonly used for this purpose, allowing sufficient flexibility in model design to successfully handle most tasks. A restricting aspect, especially if many calculations are required within, e.g., an optimization process, is the computational cost which can be considerable if two or even more scales are involved. The FEM–CM approach, where a numerical discretization scheme for the macroscale is merged with a semi-analytical methodology targeting at material-related scales, proves to be very efficient in this respect.

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Machine learning assisted discovery of effective viscous material laws for shear-thinning fiber suspensions

Sterr,

Hrymak,

Schneider

et al. 2024

Comput Mech

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In this article, we combine a Fast Fourier Transform based computational approach and a supervised machine learning strategy to discover models for the anisotropic effective viscosity of shear-thinning fiber suspensions. Using the Fast Fourier Transform based computational approach, we study the effects of the fiber orientation state and the imposed macroscopic shear rate tensor on the effective viscosity for a broad range of shear rates of engineering process interest. We visualize the effective viscosity in three dimensions and find that the anisotropy of the effective viscosity and its shear rate dependence vary strongly with the fiber orientation state. Combining the results of this work with insights from literature, we formulate four requirements a model of the effective viscosity should satisfy for shear-thinning fiber suspensions with a Cross-type matrix fluid. Furthermore, we introduce four model candidates with differing numbers of parameters and different theoretical motivations, and use supervised machine learning techniques for non-convex optimization to identify parameter sets for the model candidates. By doing so, we leverage the flexibility of automatic differentiation and the robustness of gradient based, supervised machine learning. Finally, we identify the most suitable model by comparing the prediction accuracy of the model candidates on the fiber orientation triangle, and find that multiple models predict the anisotropic shear-thinning behavior to engineering accuracy over a broad range of shear rates.

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Unified mean-field modeling of viscous short-fiber suspensions and solid short-fiber reinforced composites

Cited by 8 publications

References 117 publications

Influence of flow–fiber coupling during mold-filling on the stress field in short-fiber reinforced composites

Influence of flow–fiber coupling during mold-filling on the stress field in short-fiber reinforced composites

FEM–CM as a hybrid approach for multiscale modeling and simulation of ferroelectric boundary value problems

Machine learning assisted discovery of effective viscous material laws for shear-thinning fiber suspensions

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