Identification of Hill's anisotropic parameters for reinforced plastics based on numerical material test results

A parameter identification issue for Hill's orthotropic model to characterize plastic and creep properties of reinforced plastics is revisited on the premise of the practical use of the numerical material testing (NMT) in decoupled multiscale analyses based on homogenization theory. Specificall...
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Autor*in:	Koji YAMAMOTO [verfasserIn] Norio HIRAYAMA [verfasserIn] Kenjiro TERADA [verfasserIn]

Format:	E-Artikel
Sprache:	Japanisch

Erschienen:	2016

Schlagwörter:	decoupled multiscale analysis numerical material testing hill's anisotropic model optimization

Übergeordnetes Werk:	In: Nihon Kikai Gakkai ronbunshu - The Japan Society of Mechanical Engineers, 2022, 82(2016), 840, Seite 16-00056-16-00056
Übergeordnetes Werk:	volume:82 ; year:2016 ; number:840 ; pages:16-00056-16-00056

Links:	Link aufrufen Link aufrufen Link aufrufen Journal toc

DOI / URN:	10.1299/transjsme.16-00056

Katalog-ID:	DOAJ026608448

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520			\|a A parameter identification issue for Hill's orthotropic model to characterize plastic and creep properties of reinforced plastics is revisited on the premise of the practical use of the numerical material testing (NMT) in decoupled multiscale analyses based on homogenization theory. Specifically, the use of optimization methods is suggested to determine the Hill's constants that represent elastic limits followed by plastic flows in anisotropic plasticity and stress-relaxation in anisotropic creep. To examine the effectiveness of the present strategy, NMTs are conducted on three separate periodic microstructures (unit cels) to obtain the macroscopic stress-strain or time-creep-strain curves and the particle swarm optimization (PSO) algorithm is employed for parameter identification. In each of the unit cells, polyamide and epoxy resins, which are assumed to respectively exhibit plastic and creep deformations, are selected for matrix phases, while carbon is taken as a reinforcing material in unidirectional-fiber, plain-weave-fiber and particulate-dispersion reinforced plastics. During the course of the examination, we also discuss the implication of the ratios of orthotropic elastic constants in the determination of Hill's constants for the creep model in terms of the relaxation spectrums in the directions of material axes.
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language	Japanese
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callnumber-first	T - Technology
author	Koji YAMAMOTO
spellingShingle	Koji YAMAMOTO misc TJ1-1570 misc TA213-215 misc decoupled multiscale analysis misc numerical material testing misc hill's anisotropic model misc optimization misc Mechanical engineering and machinery misc Engineering machinery, tools, and implements Identification of Hill's anisotropic parameters for reinforced plastics based on numerical material test results
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topic_title	TJ1-1570 TA213-215 Identification of Hill's anisotropic parameters for reinforced plastics based on numerical material test results decoupled multiscale analysis numerical material testing hill's anisotropic model optimization
topic	misc TJ1-1570 misc TA213-215 misc decoupled multiscale analysis misc numerical material testing misc hill's anisotropic model misc optimization misc Mechanical engineering and machinery misc Engineering machinery, tools, and implements
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title	Identification of Hill's anisotropic parameters for reinforced plastics based on numerical material test results
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title_full	Identification of Hill's anisotropic parameters for reinforced plastics based on numerical material test results
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title_sort	identification of hill's anisotropic parameters for reinforced plastics based on numerical material test results
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title_auth	Identification of Hill's anisotropic parameters for reinforced plastics based on numerical material test results
abstract	A parameter identification issue for Hill's orthotropic model to characterize plastic and creep properties of reinforced plastics is revisited on the premise of the practical use of the numerical material testing (NMT) in decoupled multiscale analyses based on homogenization theory. Specifically, the use of optimization methods is suggested to determine the Hill's constants that represent elastic limits followed by plastic flows in anisotropic plasticity and stress-relaxation in anisotropic creep. To examine the effectiveness of the present strategy, NMTs are conducted on three separate periodic microstructures (unit cels) to obtain the macroscopic stress-strain or time-creep-strain curves and the particle swarm optimization (PSO) algorithm is employed for parameter identification. In each of the unit cells, polyamide and epoxy resins, which are assumed to respectively exhibit plastic and creep deformations, are selected for matrix phases, while carbon is taken as a reinforcing material in unidirectional-fiber, plain-weave-fiber and particulate-dispersion reinforced plastics. During the course of the examination, we also discuss the implication of the ratios of orthotropic elastic constants in the determination of Hill's constants for the creep model in terms of the relaxation spectrums in the directions of material axes.
abstractGer	A parameter identification issue for Hill's orthotropic model to characterize plastic and creep properties of reinforced plastics is revisited on the premise of the practical use of the numerical material testing (NMT) in decoupled multiscale analyses based on homogenization theory. Specifically, the use of optimization methods is suggested to determine the Hill's constants that represent elastic limits followed by plastic flows in anisotropic plasticity and stress-relaxation in anisotropic creep. To examine the effectiveness of the present strategy, NMTs are conducted on three separate periodic microstructures (unit cels) to obtain the macroscopic stress-strain or time-creep-strain curves and the particle swarm optimization (PSO) algorithm is employed for parameter identification. In each of the unit cells, polyamide and epoxy resins, which are assumed to respectively exhibit plastic and creep deformations, are selected for matrix phases, while carbon is taken as a reinforcing material in unidirectional-fiber, plain-weave-fiber and particulate-dispersion reinforced plastics. During the course of the examination, we also discuss the implication of the ratios of orthotropic elastic constants in the determination of Hill's constants for the creep model in terms of the relaxation spectrums in the directions of material axes.
abstract_unstemmed	A parameter identification issue for Hill's orthotropic model to characterize plastic and creep properties of reinforced plastics is revisited on the premise of the practical use of the numerical material testing (NMT) in decoupled multiscale analyses based on homogenization theory. Specifically, the use of optimization methods is suggested to determine the Hill's constants that represent elastic limits followed by plastic flows in anisotropic plasticity and stress-relaxation in anisotropic creep. To examine the effectiveness of the present strategy, NMTs are conducted on three separate periodic microstructures (unit cels) to obtain the macroscopic stress-strain or time-creep-strain curves and the particle swarm optimization (PSO) algorithm is employed for parameter identification. In each of the unit cells, polyamide and epoxy resins, which are assumed to respectively exhibit plastic and creep deformations, are selected for matrix phases, while carbon is taken as a reinforcing material in unidirectional-fiber, plain-weave-fiber and particulate-dispersion reinforced plastics. During the course of the examination, we also discuss the implication of the ratios of orthotropic elastic constants in the determination of Hill's constants for the creep model in terms of the relaxation spectrums in the directions of material axes.
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title_short	Identification of Hill's anisotropic parameters for reinforced plastics based on numerical material test results
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Identification of Hill's anisotropic parameters for reinforced plastics based on numerical material test results

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