Micromechanical Modeling of FRCs Containing Matrix Cracks and Partially Debonded Fibers

X. D. Wang; S. A. Meguid

Source: Journal of Engineering Materials and Technology:;1999:;volume( 121 ):;issue: 004::page 445

Author:

X. D. Wang

S. A. Meguid

DOI: 10.1115/1.2812400

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: This study is concerned with the treatment of the dynamic antiplane failure behavior of fiber reinforced composites involving matrix cracks and partially-debonded fibers. The matrix/fiber interphase was modeled as a thin interfacial layer with varying elastic modulus. The steady-state theoretical solution of this class of problems is formulated using a newly developed pseudo-incident wave method, thus reducing the original interaction problem into the solution of coupled single fiber/crack solutions. By using Fourier transform technique and solving the resulting singular integral equations, the dynamic stress intensity factor at the matrix crack was obtained analytically. Numerical examples were provided to show the effect of the location and material property of fibers, the size of debonded layer, and the frequency of the incident wave upon the dynamic stress intensity factors of the matrix crack.

keyword(s): Fibers , Modeling , Fracture (Materials) , Stress , Waves , Fiber reinforced composites , Elastic moduli , Failure , Fourier transforms , Integral equations , Steady state AND Materials properties ,

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Micromechanical Modeling of FRCs Containing Matrix Cracks and Partially Debonded Fibers

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contributor author	X. D. Wang
contributor author	S. A. Meguid
date accessioned	2017-05-08T23:59:45Z
date available	2017-05-08T23:59:45Z
date copyright	October, 1999
date issued	1999
identifier issn	0094-4289
identifier other	JEMTA8-27002#445_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/122202
description abstract	This study is concerned with the treatment of the dynamic antiplane failure behavior of fiber reinforced composites involving matrix cracks and partially-debonded fibers. The matrix/fiber interphase was modeled as a thin interfacial layer with varying elastic modulus. The steady-state theoretical solution of this class of problems is formulated using a newly developed pseudo-incident wave method, thus reducing the original interaction problem into the solution of coupled single fiber/crack solutions. By using Fourier transform technique and solving the resulting singular integral equations, the dynamic stress intensity factor at the matrix crack was obtained analytically. Numerical examples were provided to show the effect of the location and material property of fibers, the size of debonded layer, and the frequency of the incident wave upon the dynamic stress intensity factors of the matrix crack.
publisher	The American Society of Mechanical Engineers (ASME)
title	Micromechanical Modeling of FRCs Containing Matrix Cracks and Partially Debonded Fibers
type	Journal Paper
journal volume	121
journal issue	4
journal title	Journal of Engineering Materials and Technology
identifier doi	10.1115/1.2812400
journal fristpage	445
journal lastpage	452
identifier eissn	1528-8889
keywords	Fibers
keywords	Modeling
keywords	Fracture (Materials)
keywords	Stress
keywords	Waves
keywords	Fiber reinforced composites
keywords	Elastic moduli
keywords	Failure
keywords	Fourier transforms
keywords	Integral equations
keywords	Steady state AND Materials properties
tree	Journal of Engineering Materials and Technology:;1999:;volume( 121 ):;issue: 004
contenttype	Fulltext

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