FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4323928546> ?p ?o ?g. }

• W4323928546 endingPage "131273" @default.
• W4323928546 startingPage "131273" @default.
• W4323928546 abstract "Thermo-physiological comfort of human body is highly influenced by the moisture transmission behaviour of the fabric. For active sportswear, intimate apparels and inner layer of extreme cold weather clothing, moisture transport is very crucial. The liquid moisture transport of fabrics is analysed using standardised test methods like vertical wicking, absorbency test and moisture management through moisture management tester. These test methods use large reservoir of liquid in contrast to human sweating behaviour. The human skin generates sweats in the form of microdroplets through sweating glands. Hence, the standard test procedures employed to assess the fabric’s liquid moisture transport fail to capture preciously the sweat transport from human skin to the fabrics. Hence, in this work, the spreading behaviour of water microdroplets simulating human sweat through yarns which are the building block of fabrics and knitted fabrics that are widely used as sportswear or inner layer of extreme cold weather clothing are investigated. The purpose of this study is to understand how the microfluid move along the capillary channels in yarns (in the forms of network of yarns crossing over each other and fabric) by keeping yarn count and twist same for all yarns. A single micro drop representing accumulated sweat droplets and multiple drops showing continuous sweating through sweat glands were allowed to wick through the yarns made up of coarser and finer fibres to understand the role of fibre diameter on wicking kinetics. Results from the conventional wicking test were compared with microfluidic wicking. It is found that the initial wicking speed in coarser-fibres yarn is faster in comparison to finer-fibres yarn, but the final wicking height is longer in finer fibre yarn. Overall liquid spreading length found to be similar for both the yarns. Yarn to yarn liquid transfer at crossover junctions is faster with finer-fibre yarn compared to coarser-fibre yarn. Same trends are found in fabrics constructed with these yarns. The effect of yarn tortuosity on liquid spreading behaviour has also been studied. As the yarn path becomes torturous (straight yarn to fabric form) wicking length also decreases." @default.
• W4323928546 created "2023-03-12" @default.
• W4323928546 creator A5018757350 @default.
• W4323928546 creator A5018999435 @default.
• W4323928546 creator A5026473251 @default.
• W4323928546 creator A5045437064 @default.
• W4323928546 date "2023-05-01" @default.
• W4323928546 modified "2023-10-11" @default.
• W4323928546 title "Spreading of water microdroplets simulating human sweating in polyester yarns and fabrics" @default.
• W4323928546 cites W1971363623 @default.
• W4323928546 cites W1977924931 @default.
• W4323928546 cites W1988651633 @default.
• W4323928546 cites W2003437722 @default.
• W4323928546 cites W2014773258 @default.
• W4323928546 cites W2025126889 @default.
• W4323928546 cites W2027189750 @default.
• W4323928546 cites W2053540075 @default.
• W4323928546 cites W2065928337 @default.
• W4323928546 cites W2092758551 @default.
• W4323928546 cites W2120452133 @default.
• W4323928546 cites W2122311274 @default.
• W4323928546 cites W2138964785 @default.
• W4323928546 cites W2149313717 @default.
• W4323928546 cites W2161226746 @default.
• W4323928546 cites W2332902833 @default.
• W4323928546 cites W2735557231 @default.
• W4323928546 cites W3048088377 @default.
• W4323928546 cites W3122798774 @default.
• W4323928546 cites W3159439146 @default.
• W4323928546 cites W3164344460 @default.
• W4323928546 cites W4220776116 @default.
• W4323928546 cites W4229455386 @default.
• W4323928546 cites W4312217258 @default.
• W4323928546 doi "https://doi.org/10.1016/j.colsurfa.2023.131273" @default.
• W4323928546 hasPublicationYear "2023" @default.
• W4323928546 type Work @default.
• W4323928546 citedByCount "0" @default.
• W4323928546 crossrefType "journal-article" @default.
• W4323928546 hasAuthorship W4323928546A5018757350 @default.
• W4323928546 hasAuthorship W4323928546A5018999435 @default.
• W4323928546 hasAuthorship W4323928546A5026473251 @default.
• W4323928546 hasAuthorship W4323928546A5045437064 @default.
• W4323928546 hasConcept C119394753 @default.
• W4323928546 hasConcept C159985019 @default.
• W4323928546 hasConcept C176864760 @default.
• W4323928546 hasConcept C192562407 @default.
• W4323928546 hasConcept C196806460 @default.
• W4323928546 hasConcept C2778787235 @default.
• W4323928546 hasConceptScore W4323928546C119394753 @default.
• W4323928546 hasConceptScore W4323928546C159985019 @default.
• W4323928546 hasConceptScore W4323928546C176864760 @default.
• W4323928546 hasConceptScore W4323928546C192562407 @default.
• W4323928546 hasConceptScore W4323928546C196806460 @default.
• W4323928546 hasConceptScore W4323928546C2778787235 @default.
• W4323928546 hasFunder F4320321024 @default.
• W4323928546 hasLocation W43239285461 @default.
• W4323928546 hasOpenAccess W4323928546 @default.
• W4323928546 hasPrimaryLocation W43239285461 @default.
• W4323928546 hasRelatedWork W2089161636 @default.
• W4323928546 hasRelatedWork W2090695246 @default.
• W4323928546 hasRelatedWork W2109471562 @default.
• W4323928546 hasRelatedWork W2290619882 @default.
• W4323928546 hasRelatedWork W2352481835 @default.
• W4323928546 hasRelatedWork W2378508949 @default.
• W4323928546 hasRelatedWork W2381070915 @default.
• W4323928546 hasRelatedWork W2392493391 @default.
• W4323928546 hasRelatedWork W28089859 @default.
• W4323928546 hasRelatedWork W4200164335 @default.
• W4323928546 hasVolume "665" @default.
• W4323928546 isParatext "false" @default.
• W4323928546 isRetracted "false" @default.
• W4323928546 workType "article" @default.