Micro-CT analysis of deviations in fiber orientation and composite stiffness near the microvascular channels embedded in glass-fiber reinforced composites

Baris Sabuncuoglu; Hamed Tanabi; Jeroen Soete; Stepan V. Lomov

doi:10.1016/j.compstruct.2020.111896

Micro-CT analysis of deviations in fiber orientation and composite stiffness near the microvascular channels embedded in glass-fiber reinforced composites

Baris Sabuncuoglu
, Hamed Tanabi
, Jeroen Soete
, Stepan V. Lomov

Division of Mechanics

Turk Hava Kurumu Universitesi
KU Leuven

Research output: Contribution to journal › Article › peer-review

22 Citations (Scopus)

Abstract

Microvascular channels, embedded in fiber-reinforced composites are introduced as an efficient tool for internal damage monitoring, self-healing, and thermal management applications. As an adverse effect, vascular channels cause a disturbance in the fibers around the channel region. In this study, first, the fiber orientation around the channel is evaluated using micro-CT images analyzed with VoxTex software. Variation in the stiffness around the channels is determined using micro-homogenization. The results revealed orientation disturbance in the out-of-plane direction with a maximum of about 6°. The micro-channel affected the nearby local stiffness as well, reducing it by up to 19%.

Original language	English
Article number	111896
Journal	Composite Structures
Volume	237
DOIs	https://doi.org/10.1016/j.compstruct.2020.111896
Publication status	Published - 1 Apr 2020

Keywords

Fiber orientation
Micro-CT analysis
Microstructure
Microvascular channels

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10.1016/j.compstruct.2020.111896

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title = "Micro-CT analysis of deviations in fiber orientation and composite stiffness near the microvascular channels embedded in glass-fiber reinforced composites",

abstract = "Microvascular channels, embedded in fiber-reinforced composites are introduced as an efficient tool for internal damage monitoring, self-healing, and thermal management applications. As an adverse effect, vascular channels cause a disturbance in the fibers around the channel region. In this study, first, the fiber orientation around the channel is evaluated using micro-CT images analyzed with VoxTex software. Variation in the stiffness around the channels is determined using micro-homogenization. The results revealed orientation disturbance in the out-of-plane direction with a maximum of about 6°. The micro-channel affected the nearby local stiffness as well, reducing it by up to 19\%.",

keywords = "Fiber orientation, Micro-CT analysis, Microstructure, Microvascular channels",

author = "Baris Sabuncuoglu and Hamed Tanabi and Jeroen Soete and Lomov, \{Stepan V.\}",

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AU - Sabuncuoglu, Baris

AU - Tanabi, Hamed

AU - Soete, Jeroen

AU - Lomov, Stepan V.

PY - 2020/4/1

Y1 - 2020/4/1

N2 - Microvascular channels, embedded in fiber-reinforced composites are introduced as an efficient tool for internal damage monitoring, self-healing, and thermal management applications. As an adverse effect, vascular channels cause a disturbance in the fibers around the channel region. In this study, first, the fiber orientation around the channel is evaluated using micro-CT images analyzed with VoxTex software. Variation in the stiffness around the channels is determined using micro-homogenization. The results revealed orientation disturbance in the out-of-plane direction with a maximum of about 6°. The micro-channel affected the nearby local stiffness as well, reducing it by up to 19%.

AB - Microvascular channels, embedded in fiber-reinforced composites are introduced as an efficient tool for internal damage monitoring, self-healing, and thermal management applications. As an adverse effect, vascular channels cause a disturbance in the fibers around the channel region. In this study, first, the fiber orientation around the channel is evaluated using micro-CT images analyzed with VoxTex software. Variation in the stiffness around the channels is determined using micro-homogenization. The results revealed orientation disturbance in the out-of-plane direction with a maximum of about 6°. The micro-channel affected the nearby local stiffness as well, reducing it by up to 19%.

KW - Fiber orientation

KW - Micro-CT analysis

KW - Microstructure

KW - Microvascular channels

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Micro-CT analysis of deviations in fiber orientation and composite stiffness near the microvascular channels embedded in glass-fiber reinforced composites

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Keywords

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