Fluids transmission and thermal durability analysis of Miura-ori auxetic relief knits; the next generation wearable materials

[Display omitted] •Fluids transmission and heat retention evaluation of weft knitted auxetic fabrics.•Negative Poisson’s ratio characterization of knitted geometries.•Biaxial extension and thermal comfort correlations using statistical tools.•Durability analysis for wearing longevity. Knitted materi...

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Bibliographic Details
Published in:Thermal science and engineering progress 2023-08, Vol.43, p.101950, Article 101950
Main Authors: Abbas, Adeel, Umair, Muhammad, Hussain, Muzzamal, Jabbar, Madeha, Khan, Muhammad Imran, Hassan, Syeda Hafsa, Awais, Habib
Format: Article
Language:English
Subjects:
Auxetic materials
Durability analysis
Fluid transmissions
Heat retention
Microscopy
Size changing materials
Statistical analysis
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Summary:[Display omitted] •Fluids transmission and heat retention evaluation of weft knitted auxetic fabrics.•Negative Poisson’s ratio characterization of knitted geometries.•Biaxial extension and thermal comfort correlations using statistical tools.•Durability analysis for wearing longevity. Knitted materials with superior thermal comfort attributes and cheap production costs are primarily utilized in leisurewear. Auxetic materials having biaxial stretch capabilities increase the propensity of knitted auxetic fabrics for size-changing clothing applications, such as maternity wear and growing kids’ apparel, consequently supporting the sustainable development goal of responsible material consumption. Knitted auxetic fabrics based on Miura-ori fold geometries have been engineered with typically targeted clothing fibrous assemblies/yarns (polyester, cotton, and acrylic) and assortingdifferent knitting parameters. Diagonal relief and hybrid square relief patterns with variable structural knitted cell (SKC) size proved to be a solution towards size and shape-changing clothing materials. Fluid transmission, heat retention, and durability evaluations were undertaken to determine the efficacy towards wearability of such auxetic materials. Varying structural porosities and the number of folds per unit area created properties discrepancy, governing different Poisson’s ratios and thermal attributes. Engineered foldable geometries exhibited about 10% to 40% increase in fluids transmissions than control plain rib fabrics. Quadratic thermal resistance enhancements of above 100% were noticed for auxetic fabrics and increasing SKC size enhanced thermal insulation. Influence of studied input variables was found statistically significant; fluid transmission had a p-value 
ISSN:2451-9049
2451-9049
DOI:10.1016/j.tsep.2023.101950