Comparison of Measured and Calculated Porosity Parameters of Woven Fabrics to Results Obtained with Image Analysis

Zupin, Živa; Štampfl, Veronika; Kočevar, Tanja Nuša; Gabrijelčič Tomc, Helena

doi:10.3390/ma17040783

Materials

2024

DOI: 10.3390/ma17040783

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Comparison of Measured and Calculated Porosity Parameters of Woven Fabrics to Results Obtained with Image Analysis

Živa Zupin,

Veronika Štampfl,

Tanja Nuša Kočevar

et al.

Abstract: Porosity, the measure of the open spaces within a fabric structure, is a decisive factor in the performance of textiles. It influences breathability, permeability to liquids or gases, and suitability for various industries such as apparel, medical, and technical textiles. This study compares classical porosity calculation methods with non-destructive image analysis for 24 woven fabric samples that differ in density and weave pattern. Factors such as fabric density, weave pattern, illumination conditions, magni… Show more

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Cited by 2 publications

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CO₂ Hydrate Formation Kinetics Using Aqueous MOF Ink-Soaked Water-Absorbing Materials

Pandey,

Mahant

2024

Energy Fuels

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Although numerous studies have focused on gas hydrates using water-adsorbent materials, there is a lack of a detailed understanding regarding the role of water-absorbing materials in hydrate formation. This study tested everyday-purpose water-absorbing hygroscopic materials such as textile fabrics, bamboo wipe fibers, and baby diaper foam for their role in CO 2 hydrate formation. These materials are highly hydrophilic, readily available commercially, and affordable and exhibit high water retention capabilities. The kinetics of CO 2 hydrate formation using these watersoaked hygroscopic materials are investigated using a rocking cell reactor under constant ramping and isothermal temperature programs. The study evaluated the influence of material wetness, the presence and concentration of metal−organic frameworks (MOFs) (HKUST-1, MIL-53(Al), and MOF-303) in water, and the temperature on the nucleation temperature, induction time, water-to-hydrate conversion, and total mmol of CO 2 per gram of material. Results indicated that above temperatures exceeding 1 °C, chenille fabrics, bamboo wipes, and polyether polyurethane foam (PPU) did not exhibit significant nucleation temperatures or trends. Conversely, at temperatures below 0 °C, only PPU-based CO 2 hydrate studies demonstrated rapid pressure drops, confirming high water-to-hydrate conversion. PPU materials soaked in water-based MOF ink showed induction times lower than those in water or SDS solution. Among the water-based MOF inks, MOF-303 ink exhibited the best stability, CO 2 induction times, and total CO 2 captured in hydrates. PPU material performance was due to embedded superabsorbing polymers (SAP) into nonwoven fabrics, which improved the contact area between liquid and gas compared to those studies where SAP was used in powdered form. Furthermore, PPU materials demonstrated high water retention, even after multiple cycles of formation and dissociation. Comparative benchmarks against other wet solid porous materials showed that PPU achieved a maximum CO 2 uptake in hydrates of approximately 32 mmol per gram of material at an initial starting pressure of 30 bar and when temperature reached <0 °C, representing competitive mmol CO 2 /gram with respect to other materials. The authors propose that PPU and similar highperformance hygroscopic materials embedded with SAP or similar water-absorbing materials could serve as the surface material of a moving bed. They proposed a conceptual layout for a novel moving bed reactor for continuous CO 2 capture and separation.

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CO₂ Hydrate Formation Kinetics Using Aqueous MOF Ink-Soaked Water-Absorbing Materials

Pandey,

Mahant

2024

Energy Fuels

View full text Add to dashboard Cite

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A New Method for Evaluating the Homogeneity within and between Weave Repeats in Plain Fabric Structures Using Computer Image Analysis

Owczarek

2024

Materials

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This article introduces a novel, rapid, and non-destructive method for assessing homogeneity within and between weave repeats in fabric structures, termed intra-repeat (IAR) and inter-repeat (IER) evaluation. The method focuses on structural parameters, including inter-thread pores (ITPs) and warp and weft pitches, using computer image analysis. Each parameter is assigned to a module in the repeat weave pattern, facilitating the sorting of modules in the IAR and IER fabric structure arrangement. The method was verified using artificial images and 30 real plain fabrics with varying degrees of warp grouping, employing the author’s proprietary software, MagFABRIC version 2.1The general measurable coefficients of intra- and inter-homogeneity were defined and related to the airflow measurements of these fabrics. Multiple regression models of airflow revealed strong dependencies, particularly for F = 10, with the size, shape, and position of ITPs and warp and weft pitches showing significant correlation. These findings underscore the importance of the new homogeneity parameters in textile structure analysis, including both IAR and IER woven fabric structure homogeneity parameters. The research aims to model specialized fabrics (e.g., barrier, filtration, composite fabrics) to address local changes in fabric structure affecting properties such as filtration efficiency, air permeability, and mechanical properties, especially in applications like composites or medical implants.

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Comparison of Measured and Calculated Porosity Parameters of Woven Fabrics to Results Obtained with Image Analysis

Cited by 2 publications

References 21 publications

CO₂ Hydrate Formation Kinetics Using Aqueous MOF Ink-Soaked Water-Absorbing Materials

CO₂ Hydrate Formation Kinetics Using Aqueous MOF Ink-Soaked Water-Absorbing Materials

A New Method for Evaluating the Homogeneity within and between Weave Repeats in Plain Fabric Structures Using Computer Image Analysis

Contact Info

Product

Resources

About

Comparison of Measured and Calculated Porosity Parameters of Woven Fabrics to Results Obtained with Image Analysis

Cited by 2 publications

References 21 publications

CO2 Hydrate Formation Kinetics Using Aqueous MOF Ink-Soaked Water-Absorbing Materials

CO2 Hydrate Formation Kinetics Using Aqueous MOF Ink-Soaked Water-Absorbing Materials

A New Method for Evaluating the Homogeneity within and between Weave Repeats in Plain Fabric Structures Using Computer Image Analysis

Contact Info

Product

Resources

About

CO₂ Hydrate Formation Kinetics Using Aqueous MOF Ink-Soaked Water-Absorbing Materials

CO₂ Hydrate Formation Kinetics Using Aqueous MOF Ink-Soaked Water-Absorbing Materials