Heat Transfer in Single-side Napped Fabrics During Compression
DOI:
10.3993/jfbi03201409
Journal of Fiber Bioengineering & Informatics, 7 (2014), pp. 103-116.
Published online: 2014-07
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@Article{JFBI-7-103,
author = {Sujian Zhang, Yi Li, Junyan Hu, Xiao Liao and Haotian Zhou},
title = {Heat Transfer in Single-side Napped Fabrics During Compression},
journal = {Journal of Fiber Bioengineering and Informatics},
year = {2014},
volume = {7},
number = {1},
pages = {103--116},
abstract = {This paper presents a systematic analysis of the changes in thickness and the differences in the heat flux
transfer for the two surfaces of selected single-side napped fabric, to explore the relationship between
their heat flux and thickness during compression. The results showed that heat flow in the un-napped
surface was greater than that in the napped surface when the fabric initially contacted the upper plate of
a Fabric Touch Tester (p ‹ 0.05); few differences of the heat flux between the un-napped and the napped
surfaces measured separately with each surface facing upwards for each fabric type were observed when
the pressure exceeded 0.6 Pa (p › 0.05); the heat flux was linearly correlated with thickness for both the
un-napped surface and napped surface when the pressure exceeded 0.6 Pa (correlation coefficient R² ›
0.9); the gradients of the regression equation of heat flux-thickness gradually increased from the initial
thickness point to the midpoint of the maximum pressure except for the first heat peak point of the
un-napped surface. In conclusion, heat flux was significantly affected by the surface characteristics of
the fabrics in the initial stages of compression but was then not affected by either the surface features or
the fabric structures at higher levels of compression pressure. The conclusion could be useful in product
development and in providing a guide for clothing wearing comfort.},
issn = {2617-8699},
doi = {https://doi.org/10.3993/jfbi03201409},
url = {http://global-sci.org/intro/article_detail/jfbi/4770.html}
}
TY - JOUR
T1 - Heat Transfer in Single-side Napped Fabrics During Compression
AU - Sujian Zhang, Yi Li, Junyan Hu, Xiao Liao & Haotian Zhou
JO - Journal of Fiber Bioengineering and Informatics
VL - 1
SP - 103
EP - 116
PY - 2014
DA - 2014/07
SN - 7
DO - http://doi.org/10.3993/jfbi03201409
UR - https://global-sci.org/intro/article_detail/jfbi/4770.html
KW - Thickness
KW - Heat Flux
KW - Napped Surface
KW - Surface Measurement
KW - First Heat Peak
KW - Standard Pressure
AB - This paper presents a systematic analysis of the changes in thickness and the differences in the heat flux
transfer for the two surfaces of selected single-side napped fabric, to explore the relationship between
their heat flux and thickness during compression. The results showed that heat flow in the un-napped
surface was greater than that in the napped surface when the fabric initially contacted the upper plate of
a Fabric Touch Tester (p ‹ 0.05); few differences of the heat flux between the un-napped and the napped
surfaces measured separately with each surface facing upwards for each fabric type were observed when
the pressure exceeded 0.6 Pa (p › 0.05); the heat flux was linearly correlated with thickness for both the
un-napped surface and napped surface when the pressure exceeded 0.6 Pa (correlation coefficient R² ›
0.9); the gradients of the regression equation of heat flux-thickness gradually increased from the initial
thickness point to the midpoint of the maximum pressure except for the first heat peak point of the
un-napped surface. In conclusion, heat flux was significantly affected by the surface characteristics of
the fabrics in the initial stages of compression but was then not affected by either the surface features or
the fabric structures at higher levels of compression pressure. The conclusion could be useful in product
development and in providing a guide for clothing wearing comfort.
Sujian Zhang, Yi Li, Junyan Hu, Xiao Liao and Haotian Zhou. (2014). Heat Transfer in Single-side Napped Fabrics During Compression.
Journal of Fiber Bioengineering and Informatics. 7 (1).
103-116.
doi:10.3993/jfbi03201409
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