Accounting for viscoelastic effects in a multiscale fatigue model for the degradation of the dynamic stiffness of short-fiber reinforced thermoplastics

Magino, Nicola; Köbler, Jonathan; Andrä, Heiko; Welschinger, Fabian; Müller, Ralf; Schneider, Matti

doi:10.1007/s00466-022-02246-y

Cited by 7 publications

(3 citation statements)

References 93 publications

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“…In this regard, the applicability of the Schabosch nonlinear creep-fatigue interaction model for predicting the creep behavior and fatigue life under thermomechanical fatigue was investigated. In [158], Magino et al have proposed a viscoelastic fatigue damage model for a thermoplastic matrix based on the separation of time scales in which both viscoelastic and fatigue damage effects can be observed.…”

Section: Plastic Strain Development (Creep)mentioning

confidence: 99%

Fatigue Damage Assessment and Lifetime Prediction of Short Fiber Reinforced Polymer Composites—A Review

Bogdanov,

Panin,

Kosmachev

2023

J. Compos. Sci.

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This paper reviews the findings in the area of fatigue damage assessment and lifetime prediction of short fiber reinforced polymer composites (SFRPs) under cyclic loading. It is shown that the direct methods of microstructure/damage inspection are the most sensitive and informative, while micro-computed tomography (μ-CT) is more laborious and possesses limitations in sample dimensions. Although the sensitivity of the indirect methods can vary, the most common one is based on stiffness reduction. It is shown that developing models of fatigue processes is impossible without assessing the degree of damage. The latter can be determined by stiffness reduction, the development of creep, or energy dissipation. Since fatigue mechanisms can differ, the most complete information can be obtained by combining these methods. The prediction results for fatigue life models based on plastic strain development showed the greatest agreement with the experimental results in comparison with other prediction models. In addition, some tasks are highlighted as the priority directions for the development of SFRPs and non-destructive testing (NDT) methods for their monitoring under fatigue.

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Section: Plastic Strain Development (Creep)mentioning

confidence: 99%

Fatigue Damage Assessment and Lifetime Prediction of Short Fiber Reinforced Polymer Composites—A Review

Bogdanov,

Panin,

Kosmachev

2023

J. Compos. Sci.

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“…with high accuracy as discussed in Magino et al [17]. This formulation enables extending the one-dimensional definition for the dynamic stiffness (1) to a three-dimensional dynamic stiffness tensor.…”

Section: Introductionmentioning

confidence: 96%

“…For viscoelastic materials, different approaches exist to derive the macroscale behavior [5,9]. A convenient and computationally efficient method to predict the dynamic stiffness of a short-fiber reinforced structure is the approximate method introduced in Magino et al [17]. It is based on assigning effective dynamic properties to the constituents of the material and deriving the composite behavior from elastic computations.…”

Section: Introductionmentioning

confidence: 99%

Factors influencing the dynamic stiffness in short‐fiber reinforced polymers

Magino

Köbler

Andrä

et al. 2023

Proc Appl Math and Mech

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In short‐fiber reinforced polymers, fatigue damage is typically characterized by measuring the dynamic stiffness and its degradation under cyclic loading. Computational homogenization methods may be used to characterize the fatigue behavior of the composite via numerical predictions. Such an approach may reduce the experimental effort significantly. In the previous works, the authors proposed an elastic fatigue damage model for predicting the relative stiffness degradation of short‐fiber reinforced materials. However, the absolute value of the dynamic stiffness within the first cycle showed deviations from the expected elastic material behavior. Thus, the effect of viscoelastic polymer behavior as well as different microstructure descriptors on the dynamic stiffness is studied in the work at hand.

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On the effectiveness of deep material networks for the multi-scale virtual characterization of short fiber-reinforced thermoplastics under highly nonlinear load cases

Dey,

Welschinger,

Schneider

et al. 2024

Arch Appl Mech

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A key challenge for the virtual characterization of components manufactured using short fiber-reinforced thermoplastics (SFRTs) is the inherent anisotropy which stems from the manufacturing process. To address this, a multi-scale approach is necessary, leveraging deep material networks (DMNs) as a micromechanical surrogate, for a one-stop solution when simulating SFRTs under highly nonlinear long-term load cases like creep and fatigue. Therefore, we extend the a priori fiber orientation tensor interpolation for quasi-static loading (Liu et al. in Intelligent multi-scale simulation based on process-guided composite database. arXiv:2003.09491, 2020; Gajek et al. in Comput Methods Appl Mech Eng 384:113,952, 2021; Meyer et al. in Compos Part B Eng 110,380, 2022) using DMNs with a posteriori approach. We also use the trained DMN framework to simulate the stiffness degradation under fatigue loading with a linear fatigue-damage law for the matrix. We evaluate the effectiveness of the interpolation approach for a variety of load classes using a dedicated fully coupled plasticity and creep model for the polymer matrix. The proposed methodology is validated through comparison with composite experiments, revealing the limitations of the linear fatigue-damage law. Therefore, we introduce a new power-law fatigue-damage model for the matrix in the micro-scale, leveraging the quasi-model-free nature of the DMN, i.e., it models the microstructure independent of the material models attached to the constituents of the microstructure. The DMN framework is shown to effectively extend material models and inversely identify model parameters based on composite experiments for all possible orientation states and variety of material models.

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Accounting for viscoelastic effects in a multiscale fatigue model for the degradation of the dynamic stiffness of short-fiber reinforced thermoplastics

Cited by 7 publications

References 93 publications

Fatigue Damage Assessment and Lifetime Prediction of Short Fiber Reinforced Polymer Composites—A Review

Fatigue Damage Assessment and Lifetime Prediction of Short Fiber Reinforced Polymer Composites—A Review

Factors influencing the dynamic stiffness in short‐fiber reinforced polymers

On the effectiveness of deep material networks for the multi-scale virtual characterization of short fiber-reinforced thermoplastics under highly nonlinear load cases

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