A continuum damage model to predict the influence of ply waviness on stiffness and strength in ultra-thick unidirectional Fiber-reinforced Plastics

Andreas Altmann; Robin Taubert; Ulrich Mandel; Roland Hinterhoelzl; Klaus Drechsler

doi:10.1177/0021998315612536

A continuum damage model to predict the influence of ply waviness on stiffness and strength in ultra-thick unidirectional Fiber-reinforced Plastics

Andreas Altmann
, Robin Taubert
, Ulrich Mandel
, Roland Hinterhoelzl
, Klaus Drechsler

Chair of Carbon Composites

Technical University of Munich

Research output: Contribution to journal › Review article › peer-review

20 Scopus citations

Abstract

Ply waviness is a commonly observed manufacturing defect of ultra-thick composite materials essentially affecting stiffness, strength, and fatigue behavior of the composite. A specimen's geometry is designed to represent the failure mechanisms in thick wavy laminates, typically observed in spar caps of today's wind turbine blades. A material model is developed to simulate the phenomenological processes in wavy laminates to obtain a strength knock-down. Particular attention is taken on the nonlinear shear behavior and kink band formation. The presented model correlates well with results achieved by experiments. This paper shows a significantly higher influence of compressive compared with tensile loading on the mechanical material behavior of wavy laminates.

Original language	English
Pages (from-to)	2739-2755
Number of pages	17
Journal	Journal of Composite Materials
Volume	50
Issue number	20
DOIs	https://doi.org/10.1177/0021998315612536
State	Published - 1 Aug 2016

Keywords

Wavy composites
continuum damage model
effects of defects
matrix systems

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10.1177/0021998315612536

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title = "A continuum damage model to predict the influence of ply waviness on stiffness and strength in ultra-thick unidirectional Fiber-reinforced Plastics",

abstract = "Ply waviness is a commonly observed manufacturing defect of ultra-thick composite materials essentially affecting stiffness, strength, and fatigue behavior of the composite. A specimen's geometry is designed to represent the failure mechanisms in thick wavy laminates, typically observed in spar caps of today's wind turbine blades. A material model is developed to simulate the phenomenological processes in wavy laminates to obtain a strength knock-down. Particular attention is taken on the nonlinear shear behavior and kink band formation. The presented model correlates well with results achieved by experiments. This paper shows a significantly higher influence of compressive compared with tensile loading on the mechanical material behavior of wavy laminates.",

keywords = "Wavy composites, continuum damage model, effects of defects, matrix systems",

author = "Andreas Altmann and Robin Taubert and Ulrich Mandel and Roland Hinterhoelzl and Klaus Drechsler",

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AU - Altmann, Andreas

AU - Taubert, Robin

AU - Mandel, Ulrich

AU - Hinterhoelzl, Roland

AU - Drechsler, Klaus

N1 - Publisher Copyright: © SAGE Publications.

PY - 2016/8/1

Y1 - 2016/8/1

N2 - Ply waviness is a commonly observed manufacturing defect of ultra-thick composite materials essentially affecting stiffness, strength, and fatigue behavior of the composite. A specimen's geometry is designed to represent the failure mechanisms in thick wavy laminates, typically observed in spar caps of today's wind turbine blades. A material model is developed to simulate the phenomenological processes in wavy laminates to obtain a strength knock-down. Particular attention is taken on the nonlinear shear behavior and kink band formation. The presented model correlates well with results achieved by experiments. This paper shows a significantly higher influence of compressive compared with tensile loading on the mechanical material behavior of wavy laminates.

AB - Ply waviness is a commonly observed manufacturing defect of ultra-thick composite materials essentially affecting stiffness, strength, and fatigue behavior of the composite. A specimen's geometry is designed to represent the failure mechanisms in thick wavy laminates, typically observed in spar caps of today's wind turbine blades. A material model is developed to simulate the phenomenological processes in wavy laminates to obtain a strength knock-down. Particular attention is taken on the nonlinear shear behavior and kink band formation. The presented model correlates well with results achieved by experiments. This paper shows a significantly higher influence of compressive compared with tensile loading on the mechanical material behavior of wavy laminates.

KW - Wavy composites

KW - continuum damage model

KW - effects of defects

KW - matrix systems

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DO - 10.1177/0021998315612536

M3 - Review article

AN - SCOPUS:84978976703

SN - 0021-9983

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EP - 2755

JO - Journal of Composite Materials

JF - Journal of Composite Materials

IS - 20

ER -

A continuum damage model to predict the influence of ply waviness on stiffness and strength in ultra-thick unidirectional Fiber-reinforced Plastics

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Keywords

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