Benchmark exercise on image-based permeability determination of engineering textiles: Microscale predictions

E. Syerko; T. Schmidt; D. May; C. Binetruy; S. G. Advani; S. Lomov; L. Silva; G. Broggi; B. Caglar; null More Authors

doi:10.1016/j.compositesa.2022.107397

Benchmark exercise on image-based permeability determination of engineering textiles: Microscale predictions

E. Syerko^*, T. Schmidt, D. May, C. Binetruy, S. G. Advani, S. Lomov, L. Silva, G. Broggi, B. Caglar, More Authors

^*Corresponding author for this work

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

Abstract

Permeability measurements of engineering textiles exhibit large variability as no standardization method currently exists; numerical permeability prediction is thus an attractive alternative. It has all advantages of virtual material characterization, including the possibility to study the impact of material variability and small-scale parameters. This paper presents the results of an international virtual permeability benchmark, which is a first contribution to permeability predictions for fibrous reinforcements based on real images. In this first stage, the focus was on the microscale computation of fiber bundle permeability. In total 16 participants provided 50 results using different numerical methods, boundary conditions, permeability identification techniques. The scatter of the predicted axial permeability after the elimination of inconsistent results was found to be smaller (14%) than that of the transverse permeability (∼24%). Dominant effects on the permeability were found to be the boundary conditions in tangential direction, number of sub-domains used in the renormalization approach, and the permeability identification technique.

Original language	English
Article number	107397
Number of pages	18
Journal	Composites Part A: Applied Science and Manufacturing
Volume	167
DOIs	https://doi.org/10.1016/j.compositesa.2022.107397
Publication status	Published - 2023
Externally published	Yes

Keywords

A. Fabrics/textiles
A. Tow
B. Permeability
C. Computational modelling
E. Resin flow

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10.1016/j.compositesa.2022.107397

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@article{7dcffd23c0a3417c977668b03b4c376b,

title = "Benchmark exercise on image-based permeability determination of engineering textiles: Microscale predictions",

abstract = "Permeability measurements of engineering textiles exhibit large variability as no standardization method currently exists; numerical permeability prediction is thus an attractive alternative. It has all advantages of virtual material characterization, including the possibility to study the impact of material variability and small-scale parameters. This paper presents the results of an international virtual permeability benchmark, which is a first contribution to permeability predictions for fibrous reinforcements based on real images. In this first stage, the focus was on the microscale computation of fiber bundle permeability. In total 16 participants provided 50 results using different numerical methods, boundary conditions, permeability identification techniques. The scatter of the predicted axial permeability after the elimination of inconsistent results was found to be smaller (14%) than that of the transverse permeability (∼24%). Dominant effects on the permeability were found to be the boundary conditions in tangential direction, number of sub-domains used in the renormalization approach, and the permeability identification technique.",

keywords = "A. Fabrics/textiles, A. Tow, B. Permeability, C. Computational modelling, E. Resin flow",

author = "E. Syerko and T. Schmidt and D. May and C. Binetruy and Advani, {S. G.} and S. Lomov and L. Silva and G. Broggi and B. Caglar and {More Authors}",

year = "2023",

doi = "10.1016/j.compositesa.2022.107397",

language = "English",

volume = "167",

journal = "Composites Part A: Applied Science and Manufacturing",

issn = "1359-835X",

publisher = "Elsevier",

}

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T1 - Benchmark exercise on image-based permeability determination of engineering textiles

T2 - Microscale predictions

AU - Syerko, E.

AU - Schmidt, T.

AU - May, D.

AU - Binetruy, C.

AU - Advani, S. G.

AU - Lomov, S.

AU - Silva, L.

AU - Broggi, G.

AU - Caglar, B.

AU - More Authors, null

PY - 2023

Y1 - 2023

N2 - Permeability measurements of engineering textiles exhibit large variability as no standardization method currently exists; numerical permeability prediction is thus an attractive alternative. It has all advantages of virtual material characterization, including the possibility to study the impact of material variability and small-scale parameters. This paper presents the results of an international virtual permeability benchmark, which is a first contribution to permeability predictions for fibrous reinforcements based on real images. In this first stage, the focus was on the microscale computation of fiber bundle permeability. In total 16 participants provided 50 results using different numerical methods, boundary conditions, permeability identification techniques. The scatter of the predicted axial permeability after the elimination of inconsistent results was found to be smaller (14%) than that of the transverse permeability (∼24%). Dominant effects on the permeability were found to be the boundary conditions in tangential direction, number of sub-domains used in the renormalization approach, and the permeability identification technique.

AB - Permeability measurements of engineering textiles exhibit large variability as no standardization method currently exists; numerical permeability prediction is thus an attractive alternative. It has all advantages of virtual material characterization, including the possibility to study the impact of material variability and small-scale parameters. This paper presents the results of an international virtual permeability benchmark, which is a first contribution to permeability predictions for fibrous reinforcements based on real images. In this first stage, the focus was on the microscale computation of fiber bundle permeability. In total 16 participants provided 50 results using different numerical methods, boundary conditions, permeability identification techniques. The scatter of the predicted axial permeability after the elimination of inconsistent results was found to be smaller (14%) than that of the transverse permeability (∼24%). Dominant effects on the permeability were found to be the boundary conditions in tangential direction, number of sub-domains used in the renormalization approach, and the permeability identification technique.

KW - A. Fabrics/textiles

KW - A. Tow

KW - B. Permeability

KW - C. Computational modelling

KW - E. Resin flow

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U2 - 10.1016/j.compositesa.2022.107397

DO - 10.1016/j.compositesa.2022.107397

M3 - Article

AN - SCOPUS:85146147537

SN - 1359-835X

VL - 167

JO - Composites Part A: Applied Science and Manufacturing

JF - Composites Part A: Applied Science and Manufacturing

M1 - 107397

ER -

Benchmark exercise on image-based permeability determination of engineering textiles: Microscale predictions

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Keywords

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