Human wetness perception in relation to textile water absorption parameters under static skin contact

Skin wetness perception (WP) greatly affects thermal and sensorial discomfort in clothing and as such is of great interest to the clothing industry. Following neurophysiological studies of WP, this study looks at textile parameters affecting WP. Twenty-four fabrics varying in thickness, fiber type a...

Full description

Saved in:
Bibliographic Details
Published in:Textile research journal 2017-12, Vol.87 (20), p.2449-2463
Main Authors: Raccuglia, Margherita, Hodder, Simon, Havenith, George
Format: Article
Language:English
Subjects:
Absorption
Cooling
Correlation
Cotton
Fabrics
Females
Heat
Males
Materials research
Moisture absorption
Moisture content
Perception
Perceptions
Polyesters
Researchers
Skin
Skin temperature
Studies
Surface roughness
Textile research
Water absorption
Water content
Wool
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Skin wetness perception (WP) greatly affects thermal and sensorial discomfort in clothing and as such is of great interest to the clothing industry. Following neurophysiological studies of WP, this study looks at textile parameters affecting WP. Twenty-four fabrics varying in thickness, fiber type and absorption capacity were studied. Using 12 participants (males/females), the WP induced was studied in four wetness states: 1. Dry; 2. absolute (ABS), all having the same absolute water content of 2400 µL per sample (=0.24 µL mm−2); 3. 100REL, saturated with water to their individual absorption capacity; 4. 50REL, to 50% of the value in 3. As total absorption capacity was highly correlated (r = 0.99) to fabric thickness, conditions 3 and 4 were equivalent to having the same water content per volume of textile, i.e. 0.8 and 0.4 µL mm−3, respectively. Samples were applied to the upper back statically to minimize the contribution of surface roughness/friction. WP was highly correlated to drop in skin temperature induced by the wet fabric, and increased with application pressure of the fabric. No effect of fiber type was observed. In REL, with equal µL mm−3, WP showed a positive correlation to total fabric water-content-per-area (µL mm−2), and thus also to thickness, given the correlation between the latter two, with saturation above 1.5 µL mm−2. In ABS, on the other hand, with equal µL mm−2, and thus with relative water content (µL mm µL mm−3) inversely proportional to thickness, WP was also inversely proportional to thickness. Thus WP showed opposing responses depending on the wetting type, indicating that the methodology of manipulating water content should be selected in relation to the product end-use.
ISSN:0040-5175
1746-7748
DOI:10.1177/0040517516671127