Influence of air gap on thermal and moisture properties of permeable protective clothing

被引：0

作者：

Hu Z. ^{[1
]}

Zheng X. ^{[2
]}

Feng M. ^{[1
]}

Wang Y. ^{[1
]}

Liu L. ^{[1
]}

Ding S. ^{[2
]}

机构：

[1] School of Fashion, Beijing Institute of Fashion Technology, Beijing

[2] State Key Laboratory of NBC Protection for Civilian, Research Institute of Chemical Defense of Military Academic of Sciences, Beijing

来源：

Fangzhi Xuebao/Journal of Textile Research | 2019年 / 40卷 / 11期

关键词：

Clothing air gap; Clothing ease; Nuclear biological and chemical protective clothing; Thermal manikin; Thermal resistance; Vapor resistance;

D O I：

10.13475/j.fzxb.20181002707

中图分类号：

学科分类号：

摘要：

In order to find the suitable clothing ease to improve thermal and moisture comfort of permeable nuclear biological and chemical (NBC) protective clothing, the wearing experimental procedure was designed. 5 pieces of clothing were observed under a normal temperature and static condition. Thermal manikin and three-dimensional scanning technology were used in a climate chamber to explore the influence of air gap on thermal and vapor resistance of NBC protective clothing. The results showed that with the increase of the ease of NBC protective clothing, the volume of air gap under the garment changes similarly with the average thickness of the air gap, and the air gap has a significant impact on total thermal resistance and vapor resistance. The total thermal resistance of the clothing increases with the increase of the air gap, and when the air gap exceeds by a certain volume, the thermal resistance of the clothing starts to drop. The total vapor resistance increases with the increase of air gap under the clothing. Copyright No content may be reproduced or abridged without authorization.

引用

页码：145 / 150and160

共 11 条

[1] Gagge A.P., Burton A.C., Bazett H.C., A practical system of units for the description of the heat exchange of man with his environment, Science, 94, 2445, (1941)
[2] Il Y.K., Lee C., Li P., Et al., Investigation of air gaps entrapped in protective clothing systems, Fire & Materials, 26, 3, pp. 121-126, (2002)
[3] Wang Y., Zhang X., Li X., Et al., Geomagic-based characteristic extraction of air gap under clothing, Journal of Textile Research, 33, 11, pp. 102-106, (2012)
[4] Oliveira A.V., Gaspar A.R., Quintela D.A., Measurements of clothing insulation with a thermal manikin operating under the thermal comfort regulation mode: comparative analysis of the calculation methods, European Journal of Applied Physiology, 104, 4, pp. 679-688, (2008)
[5] Zhang W., Qian X., Shi Y., Et al., Relationship between static and dynamic thermal insulation of local or whole body and its model, Journal of Textile Research, 39, 7, pp. 111-113, (2018)
[6] Liu Y., Dai X., Measurement and calculation of clothing thermal resistance and evaporative resistance, China Personal Protective Equipment, 1, pp. 32-36, (2014)
[7] Lu Y., Wang F., Peng H., Et al., Effect of sweating set rate on clothing real evaporative resistance determined on a sweating thermal manikin in a socalled isothermal condition (T manikin=Ta=Tr), International Journal of Biometeorology, 60, 4, pp. 481-488, (2016)
[8] Huang J., Theoretical analysis of three methods for calculating thermal insulation of clothing from thermal manikin, Annals of Occupational Hygiene, 56, 6, pp. 728-735, (2012)
[9] Lee Y., Hong K., Hong S.A., 3D quantification of microclimate volume in layered clothing for the prediction of clothing insulation, Applied Ergonomics, 38, 3, pp. 349-355, (2007)
[10] Cui Z., Fan J., Wu Y., A comparative study on the effects of air gap wind and walking motion on the thermal properties of Arabian Thawbs and Chinese Cheongsams, Ergonomics, 59, 8, pp. 999-1008, (2015)

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