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Algorithm to determine orientation distribution function from microscopic images of fibrous networks: Validation with X-ray microtomography

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journal contribution
posted on 2022-09-07, 08:44 authored by Yasasween Hewavidana, Mehmet Balci, Andy GleadallAndy Gleadall, Behnam Pourdeyhimi, Vadim SilberschmidtVadim Silberschmidt, Emrah DemirciEmrah Demirci
Quantitative analysis of fibre orientation in a random fibrous network (RFN) is important to understand their microstructure, properties and performance. 2D fibre orientation distribution presents an in-plane fibre orientation without any information on fibre orientation in thickness direction. This research introduces a fully parametric algorithm for computing 3D fibre orientation as thickness is important for high-density or thick fibrous networks. The algorithm is tested for 3 major classes of nonwoven fabrics called low- (L), medium- (M) and high-density (H) ones. H fabric density is 6–8 times larger than the L fabric density. M fabric density (traditional intermediate fabric density) is 3–4 times larger than the L fabric density. Voxel models of experimental nonwoven webs were generated by an X-ray micro-CT (µCT) system and evaluated with the algorithm. Statistical results showed that a fraction of fibres orientated along the thickness direction increases as fibre density grows. To validate the accuracy of findings, deterministic voxelated virtual fibrous structures, created using mathematical functions were used. This novel algorithm is able to produce a 3D orientation distribution function (ODF) for any RFN including, models of nonwovens produced with various manufacturing parameters, experimentally verified and validated with X-ray µCT. Also, it can compute 2D ODFs of various types of RFNs to evaluate 2D behaviour of fibrous structures. The obtained results are useful for applications in many fields including finite element analysis, computational fluid dynamics, additive manufacturing, etc.

Funding

The Nonwovens Institute of North Carolina State University, Raleigh, NC [Grant no. 19-234, 2020]

Reicofil GmbH (Germany)

History

School

  • Mechanical, Electrical and Manufacturing Engineering

Published in

Micron

Volume

160

Issue

2022

Publisher

Elsevier

Version

  • AM (Accepted Manuscript)

Rights holder

© Elsevier

Publisher statement

This paper was accepted for publication in the journal Micron and the definitive published version is available at https://doi.org/10.1016/j.micron.2022.103321

Acceptance date

2022-06-23

Publication date

2022-06-27

Copyright date

2022

ISSN

0968-4328

eISSN

1878-4291

Language

  • en

Depositor

Dr Emrah Demirci. Deposit date: 6 September 2022

Article number

103321

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