A refined modelling approach for plain-woven composites based on virtual fiber embedding technique with weaving process simulation

Rongqiao Wang; Xin Li; Xi Liu; Yu Liu; Dianyin Hu; Jinchao Pan; Xiaojie Zhang; Jier Wang; Jiaqiang Li

doi:10.1177/00219983261416101

A refined modelling approach for plain-woven composites based on virtual fiber embedding technique with weaving process simulation

Rongqiao Wang
, Xin Li
, Xi Liu^*
, Yu Liu
, Dianyin Hu^*
, Jinchao Pan
, Xiaojie Zhang
, Jier Wang
, Jiaqiang Li

^*Corresponding author for this work

Beijing Key Laboratory of Aero-Engine Structure and Strength
United Research Center of Mid-Small Aero-Engine
Beihang University
AECC Hunan Aviation Powerplant Research Institute
CAS - Beijing Institute of Control Engineering
Imperial College London

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

Abstract

A refined modelling approach was developed to capture the real fiber bundle morphology and microstructural characteristics of plain-woven SiC_f/SiC composites. Using the virtual fiber embedding (VFE) technique, a single-cell model was constructed, and an energy-weighted stiffness correction method for nonlinear conditions was proposed, reducing the stress calculation error due to stiffness redundancy from 23.85% to 9.22%. To account for fiber damage caused by fiber bundle morphology changes, simulations of the plain weaving and compaction processes were performed. By integrating microfiber material direction and fiber volume fraction data from these simulations, a refined single-cell model was established. Compared to idealized models, the VFE-based model, which accounts for the effects of the weaving process, reduces the fatigue life prediction error from 43.96% to 20.30%.

Original language	English
Journal	Journal of Composite Materials
DOIs	https://doi.org/10.1177/00219983261416101
State	Accepted/In press - 2026

Keywords

SiC/SiC composites
fatigue life prediction
stiffness correction
virtual fiber embedding
weaving process

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10.1177/00219983261416101

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title = "A refined modelling approach for plain-woven composites based on virtual fiber embedding technique with weaving process simulation",

abstract = "A refined modelling approach was developed to capture the real fiber bundle morphology and microstructural characteristics of plain-woven SiCf/SiC composites. Using the virtual fiber embedding (VFE) technique, a single-cell model was constructed, and an energy-weighted stiffness correction method for nonlinear conditions was proposed, reducing the stress calculation error due to stiffness redundancy from 23.85\% to 9.22\%. To account for fiber damage caused by fiber bundle morphology changes, simulations of the plain weaving and compaction processes were performed. By integrating microfiber material direction and fiber volume fraction data from these simulations, a refined single-cell model was established. Compared to idealized models, the VFE-based model, which accounts for the effects of the weaving process, reduces the fatigue life prediction error from 43.96\% to 20.30\%.",

keywords = "SiC/SiC composites, fatigue life prediction, stiffness correction, virtual fiber embedding, weaving process",

author = "Rongqiao Wang and Xin Li and Xi Liu and Yu Liu and Dianyin Hu and Jinchao Pan and Xiaojie Zhang and Jier Wang and Jiaqiang Li",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2026",

year = "2026",

doi = "10.1177/00219983261416101",

language = "英语",

journal = "Journal of Composite Materials",

issn = "0021-9983",

publisher = "SAGE Publications Ltd",

}

TY - JOUR

T1 - A refined modelling approach for plain-woven composites based on virtual fiber embedding technique with weaving process simulation

AU - Wang, Rongqiao

AU - Li, Xin

AU - Liu, Xi

AU - Liu, Yu

AU - Hu, Dianyin

AU - Pan, Jinchao

AU - Zhang, Xiaojie

AU - Wang, Jier

AU - Li, Jiaqiang

PY - 2026

Y1 - 2026

N2 - A refined modelling approach was developed to capture the real fiber bundle morphology and microstructural characteristics of plain-woven SiCf/SiC composites. Using the virtual fiber embedding (VFE) technique, a single-cell model was constructed, and an energy-weighted stiffness correction method for nonlinear conditions was proposed, reducing the stress calculation error due to stiffness redundancy from 23.85% to 9.22%. To account for fiber damage caused by fiber bundle morphology changes, simulations of the plain weaving and compaction processes were performed. By integrating microfiber material direction and fiber volume fraction data from these simulations, a refined single-cell model was established. Compared to idealized models, the VFE-based model, which accounts for the effects of the weaving process, reduces the fatigue life prediction error from 43.96% to 20.30%.

AB - A refined modelling approach was developed to capture the real fiber bundle morphology and microstructural characteristics of plain-woven SiCf/SiC composites. Using the virtual fiber embedding (VFE) technique, a single-cell model was constructed, and an energy-weighted stiffness correction method for nonlinear conditions was proposed, reducing the stress calculation error due to stiffness redundancy from 23.85% to 9.22%. To account for fiber damage caused by fiber bundle morphology changes, simulations of the plain weaving and compaction processes were performed. By integrating microfiber material direction and fiber volume fraction data from these simulations, a refined single-cell model was established. Compared to idealized models, the VFE-based model, which accounts for the effects of the weaving process, reduces the fatigue life prediction error from 43.96% to 20.30%.

KW - SiC/SiC composites

KW - fatigue life prediction

KW - stiffness correction

KW - virtual fiber embedding

KW - weaving process

UR - https://www.scopus.com/pages/publications/105029165674

U2 - 10.1177/00219983261416101

DO - 10.1177/00219983261416101

M3 - 文章

AN - SCOPUS:105029165674

SN - 0021-9983

JO - Journal of Composite Materials

JF - Journal of Composite Materials

ER -

A refined modelling approach for plain-woven composites based on virtual fiber embedding technique with weaving process simulation

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Keywords

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