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The Physical Properties and Warmth retaining of Bedspread Jacquard Fabrics Using Filling Batt Yarn  

Park, Myung-Soo (Dept. of Textile & Fashion Tech., Kyungil University)
Publication Information
Fashion & Textile Research Journal / v.9, no.4, 2007 , pp. 445-449 More about this Journal
Abstract
The results of warmth retaining, heat transfer and compressive elastic recovery of the five kinds of bedspread fabrics, which were produced from packing weft of 2700 denier and 3600 denier batt yarn treated with raw material of Polyester $150^D$/48 DTY, are as follows: 1) 3600 denier packing weft showed lover count in compressive elastic recovery than 2700d packing weft, so it took longer time to recover. 2) When packing weft of the same count is used, a sample of packing weft with higher density showed lower recovery. 3) It took 2700d packing weft 30min to get approximately 98% recovery in temperature $30^{\circ}C$. But, 3600d packing weft stayed under 98% recovery in the same temperature. Considering only the result of compressive elastic recovery, we should use 2700d packing weft. 4) The higher the density of packing weft is, the higher warmth retaining becomes. Although sharp increase appeared until 5min, equilibrium was kept without any increase after that time. 5) When 2700d packing weft was used, the maximum warmth retaining was approximately 60% and 64% in the conditions of density 12(thread/in) and 22(thread/in) respectively.
Keywords
warmth retaining; compressive elastic recovery; filling batt; bedspread;
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  • Reference
1 松尾達樹 (1967) '纖維工學(II)'. 12, 12
2 Shalev, I. and Barker, R.L. (1983) Analysis of heat transfer characteristics of fabrics in an open flame exposure. Text .Res.J., 52, 475
3 Song, S.J. and Sung S.K. (1993) Studies on the thermal insulation effect of bedding(III). J. Korean Soc. Clothing and Textiles, 17(2), 301-306
4 Horikawa, A., Watanabe, I., Sakabe, M. and Kobinata, E. (1981) Porosity distribution and effective heat conductivity of laminated porous materials. J. Text. Mach. Soc. of Jap., 34, 161
5 Naka, S., Kamata, Y. and Yoshino, J. (1974) Measurement of the axial thermal conductivity of fibers. Sen-I Gakkaishi, 30, T9   DOI
6 Naka, S. and Kamata, Y. (1973) Measurement of the thermal conductivity of fiber perpendicular to its axis. J. Text. Mach. Soc. of Jap., 26, 1   DOI
7 北川洋子 (1967) Journal of Home Economics, 18, 172
8 Song, S.J. and Sung S.K. (1992) Studies on the thermal insulation effect of bedding(I). J. Korean Soc. Clothing and Textiles, 16(3), 251-256
9 Nogai, T. and Ihara, M. (1981) Study on the effect of the free convection on the effective thermal conductivity of the unidirectionally oriented fiber assembly. J. Text. Mach. Soc. of Jap., 34, 153   DOI
10 Song, S.J. and Sung S.K. (1992) Studies on the thermal insulation effect of bedding(II). J. Korean Soc. Clothing and Textiles, 16(4), 349-355
11 Kawabata, S. (1986) Measurement of anisotropic thermal conductivity of single fiber. J. Text. Mach. Soc. of Jap., 39, T184   DOI
12 Fujimoto, T. and Seki, N. (1987) Effective thermal conductivity and role of radiative transfer in many kinds of clothing materials. J, Text. Mach. Soc. of Jap., 40, T13   DOI