Abstract
Hypothesis
Wicking flow in the wale direction of knit fabrics is slowed by capillary pressure minima during the transition at yarn contacts. The characteristic pore structure of yarns leads to an unfavorable free energy evolution and is the cause of these minima.
Experiments
Time-resolved synchrotron tomographic microscopy is employed to study the evolution of water configuration during wicking flow in interlacing yarns. Dynamic pore network modeling is used based on the obtained image data and distributions of delay times for pore intrusion. Good agreement is observed by comparison to the experimental data.
Findings
Yarn-to-yarn transition is found to coincide with slow water advance in a thin interface zone at the yarn contact. The pore spaces of the two yarns merge within this interface zone and provide a transition path. A deep capillary pressure minimum occurs while water passes through the center of the interface zone, effectively delaying the wicking flow. A pore network model considering pore intrusion delay times is expanded to include inter-yarn wicking and reproduce the observed wicking dynamics. Mehr anzeigen
Persistenter Link
https://doi.org/10.3929/ethz-b-000557742Publikationsstatus
publishedExterne Links
Zeitschrift / Serie
Journal of Colloid and Interface ScienceBand
Seiten / Artikelnummer
Verlag
ElsevierThema
Wicking; Capillarity; X-ray tomographic microscopy; Wetting; Contact interface; Porous mediumOrganisationseinheit
03806 - Carmeliet, Jan / Carmeliet, Jan