[1]柯 莹,周 文.个体降温服降温效应评价指标及方法[J].服装学报,2021,6(01):1-7.
 KE Ying,ZHOU Wen.Evaluation Indicators and Methods of Cooling Effects for Personal Cooling Clothing[J].Journal of Clothing Research,2021,6(01):1-7.
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个体降温服降温效应评价指标及方法()
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《服装学报》[ISSN:2096-1928/CN:32-1864/TS]

卷:
第6卷
期数:
2021年01期
页码:
1-7
栏目:
服装材料与技术
出版日期:
2021-02-28

文章信息/Info

Title:
Evaluation Indicators and Methods of Cooling Effects for Personal Cooling Clothing
作者:
柯 莹1; 2;  周 文3
1.江南大学 设计学院,江苏 无锡 214122; 2.江南大学 江苏省非物质文化遗产研究基地,江苏 无锡 214122; 3. 江南大学 纺织科学与工程学院,江苏 无锡 214122
Author(s):
KE Ying1; 2;  ZHOU Wen3
1. School of Design, Jiangnan University, Wuxi 214122, China; 2. Intangible Culture Heritage Research Base in Jiangsu Province,Jiangnan University, Wuxi 214122,China; 3. College of Textile Science and Engineering, Jiangnan University, Wuxi 214122, China
分类号:
TS 941.71
文献标志码:
A
摘要:
个体降温服对高温高湿环境下作业人员有隔热降温的保护作用,可使其免受热应激危害。为评定降温服降温效果的有效性与稳定性,需对其进行测评。通过对国内外降温服降温效果评价研究进行综述,从客观评价和主观评价两个方面,对降温服降温效果的物理、生理、心理3个指标进行探讨,归纳总结了高温高湿环境下个体降温服降温效果评价指标体系,为降温服降温效果综合评价提供依据。
Abstract:
Personal cooling clothing has the heat insulating and cooling effects for workers in high temperature and humidity environments,and can protect them from heat stress. In order to evaluate the effectiveness and stability of the cooling effects for cooling clothing,it needs to be evaluated. Through summarizing the research on the cooling effect evaluation of cooling clothes at home and abroad,the physical,physiological and psychological indicators of the cooling effects for cooling clothes were discussed from two aspects:objective evaluation and subjective evaluation.An evaluation indications system of cooling effects for personal cooling clothing inhigh temperature and humidity environments was summarized. It will provide a basis for the evaluation of the cooling effect for cooling clothing.

参考文献/References:

[1] GUO Y M, GASPARRINI A, ARMSTRONG B G, et al. Heat wave and mortality: a multicountry, multicommunity study[J]. Environmental Health Perspectives, 2017, 125(8): 1-11.
[2] 廖梦婷, 邹声华. 降温服综合性能的模糊评价[J]. 工业安全与环保, 2018,44(6): 75-78.
LIAO Mengting, ZOU Shenghua. Fuzzy evaluation of cooling garments comprehensive performance [J]. Industrial Safety and Dust Control, 2018,44(6): 75-78.(in Chinese)
[3] MOKHTARI Y M, SHEIKHZADEH M. Personal cooling garments: a review[J].The Journal of the Textile Institute,2014, 105(12):1231-1250.
[4] 李紫含, 王世杰, 徐伯乐,等. 热防护服降温效果评价体系研究[J]. 武汉理工大学学报(信息与管理工程版), 2018, 40(1):16-20.
LI Zihan,WANG Shijie,XU Bole, et al. Study on evaluation system of thermal protective clothing cooling effect[J]. Journal of Wuhan University of Technology(Information and Management Engineering), 2018, 40(1):16-20.(in Chinese)
[5] QIAN X. Prediction of clothing thermal insulation and moisture vapour resistance[D]. Hong Kong: Hong Kong Polytechnic University, 2005.
[6] 陆丽娅,张辉. 服装热湿舒适性评价指标及方法概述[J]. 纺织科技进展, 2014(4): 58- 61.
LU Liya,ZHANG Hui.Introduction for the evaluation indexes and methods of clothing thermal-wet comfort [J]. Progress in Textile Science and Technology, 2014(4):58- 61.(in Chinese)
[7] 陈益松,范金土,张渭源. 新型出汗假人“Walter”与“一步法”测量原理[J]. 东华大学学报(自然科学版), 2005, 31(3): 100-103.
CHEN Yisong,FAN Jintu,ZHANG Weiyuan.The novel perspiring manikin "Walter" and "one-step" measurement method[J]. Journal of Donghua University(Natural Science), 2005, 31(3): 100-103.(in Chinese)
[8] 张英, 胡琴, 李紫含,等. 热防护服降温效果评价指标与方法研究进展[J]. 工业安全与环保, 2018,44(3):46- 49.
ZHANG Ying,HU Qin,LI Zihan,et al.Research progress on evaluation indicators and methods of cooling effect for thermal protective clothing[J]. Industrial Safety and Environmental Protection,2018,44(3):46- 49.(in Chinese)
[9] 李璐娜, 陈磊, 梁永辉,等. 对相变降温服的相变材料充注量及摆放位置的研究[J].中国新技术新产品, 2019(8): 79-82.
LI Luna, CHEN Lei, LIANG Yonghui,et al. Study on the filling quantity and placement of phase change materials with phase change temperature-lowering clothing[J]. New Technologies and Products, 2019(8): 79-82.(in Chinese)
[10] GAO C S, KUKLANE K, HOLMER I. Cooling vests with phase change material packs: the effects of temperature gradient, mass and covering area[J]. Ergonomics, 2010, 53(5):716-723.
[11] CHINEVERE T D, CADARETTE B S, GOODMAN D A, et al. Efficacy of body ventilation system for reducing strain in warm and hot climates[J]. European Journal of Applied Physiology, 2008, 103(3): 307-314.
[12] VERNIEUW C R, STEPHENSON L A,KOLKA M A. Thermal comfort and sensation in men wearing a cooling system controlled by skin temperature[J]. Human Factors, 2007, 49(6): 1033-1044.
[13] LUY H,WEI F R, LAI D D, et al. A novel personal cooling system(PCS)incorporated with phase change materials(PCMs)and ventilation fans: an investigation on its cooling efficiency[J].Extreme Physiology and Medicime,2015,4(1):1-2.
[14] CHAN A P C,ZHANG Y,WANG F, et al. A field study of the effectiveness and practicality of a novel hybrid personal cooling vest worn during rest in Hong Kong construction industry[J]. Journal of Thermal Biology, 2017,70(7): 21-27.
[15] SPECKMAN K L, ALLAN A E, SAWKA M N, et al. A review: microclimate cooling of protective over garments in the heat [R]. Natick: United States Army Research Institute of Environmental Medicine, 1988.
[16] WEBBON B, MONTGOMERY L,MILLER L, et al. A comparison of three liquid-ventilation cooling garments during treadmill exercise [J]. Aviation, Space,and Environmental Medicine, 1981, 52(7):408- 415.
[17] BEIKO K. Evaluation of personal cooling systems explosive ordnance disposal suits [R]. Canada: Canadian Police Research Center, 1993.
[18] 张昭华. 防护服热湿舒适性的研究进展[J]. 中国个体防护装备, 2008(5): 22-26.
ZHANG Zhaohua.Research development of thermal and moisture comfort of protecties clothing[J]. China Personal Protection Equipment,2008(5): 22-26.(in Chinese)
[19] 李利娜, 钱晓明, 范金土. 冷却服的冷却性能测试与分析[J]. 天津工业大学学报, 2008,27(5):47-50.
LI Lina,QIAN Xiaoming,FAN Jintu.Test and analysis of cooling performance of cooling garments[J]. Journal of Tianjin Polytechnic University,2008,27(5):47-50.(in Chinese)
[20] International organization for standardization.Ergonomics of the thermal environment—analytical determination and interpretation of heat stress using the predicted heat strain model:ISO 7933—2018[S].Geneva:International organization for standardization,2018.
[21] MITCHELL D, WYNDHAM C H, ATKINS A R, et al. Direct measurement of the thermal responses of nude resting men in dry environments[J]. Pflügers Archiv,1968,303(4):324-343.
[22] BURTON A C. Human calorimetry.IL The average temperature of the tissue of the body[J]. Journal of Nutrition, 1935, 9(3):281-300.
[23] RAMANATHAN N L. A new weighting system for meansurface temperature of the humanbody[J]. Journal of Applied Physiology, 1964, 19(3):531-533.
[24] HARDY J D. The technic of measuring radiation and convection one figure[J]. The Journal of Nutrition, 1938, 15(5): 461- 475.
[25] WINSLOW C E A,HERRINGTON L P,et al. Anew method of partitional calorimetry[J]. American Journal of Physiology,1936,116(3): 641- 655.
[26] International Organization for Standardization.Ergonomics-evaluation of thermal strain by physiological measurements. International Organization for Standardization:ISO 9886—2004[S].Geneva:International Organization for Standardization,2004.
[27] MORAN D S,SHITZER A,PANDOLF K B. A physiological strain index to evaluate heat stress[J]. The American Journal of Physiology, 1998,275(1):129-134.
[28] 徐子龙. 偏热环境下人体热舒适研究[D]. 郑州:中原工学院, 2015.
[29] 张渭源. 服装舒适性与功能[M]. 北京:中国纺织出版社, 2005.
[30] 赵蒙蒙, 柯莹, 王发明,等. 通风服热舒适性研究现状与展望 [J]. 纺织学报, 2019, 40(3):183-188.
ZHAO Mengmeng,KE Ying,WANG Faming,et al. Research and development trend of ventilation clothing thermal comfort[J]. Journal of Textile Research,2019, 40(3):183-188.(in Chinese)
[31] JAN A J, STOLWI J K, HARDY J D. Control of body temperature[M]// Comprehensive Physiology. USA:John Wiley and Sons, Inc. 2011.
[32] DUSAN F, LOMAS K J, MARTIN S. A computer model of human thermoregulation for a wide range of environ-mental conditions: the passive system[J]. Journal of Applied Physiology, 1999, 87(5):1957-1972.
[33] HAVENITH G, FIALA D. Thermal indices and ther-mophysiological modeling for heat stress[J]. Com-prehensive Physiology, 2016(6):255-302.
[34] CHAUDHURI T, ZHAI D Q, SOH Y C, et al. Thermal comfort prediction using normalized skin temperature in a uniform built environment[J]. Energy and Buildings, 2018,159(15):426- 440.
[35] CHOI J H, YEOM D. Development of the data-driven thermal satisfaction prediction model as a function of human physiological responses in a built environment[J]. Building and Environment, 2019, 150(4):206-218.
[36] PSIKUTA A, KOELBLEN B, MERT E, et al. An integrated approach to develop, validate and operate thermo-physiological human simulator for the development of protective clothing[J]. Industrial Health, 2017, 55(6):500-512.
[37] SANTOS M S, OLIVEIRA D, CAMPOS J B L, et al. Numerical analysis of the flow and heat transfer in cylindrical clothing microclimates-Influence of the microclimate thickness ratio[J]. International Journal of Heat and Mass Transfer, 2018, 117(2):71-79.
[38] International Organization of Standards.Clothing-physiological effects-measurement of thermal insulation by means of a thermal manikin:ISO 15831—2004[S].Genva:International Organization of Standards,2004.
[39] American Society for Testing and Materials.Standard test method for measuring the thermal insulation of clothing using a heated manikin:ASTM Fl291—16[S]. West Conshohocken:American Society for Testing and Materials, 2016.
[40] International Organization for Standardization.Estimation of thermal insulation and water vapour resistance of a clothing ensemble:ISO 9920—2007[S].Geneva:International Organization for Standardization,2007.
[41] American Society for Testing and Materials.Standard test method for measuring the evaporative resistance of clothing using a sweating manikin:ASTM F 2370—2016[S]. West Conshohocken:American Society for Testing and Materials, 2016.
[42] American Society for Testing and Materials.Standard test method for measuring the heat removal rate of personal cooling systems using a sweating heated manikin:ASTM F 2371—2005[S].West Conshohocken:American Society for Testing and Materials, 2005.
[43] ZHAO M M, GAO C S, WANG F M, et al. A study on local cooling of garments with ventilation fans and openings placed at different torso sites[J]. International Journal of Industrial Ergonomics, 2013, 43(3):232-237.
[44] 韦帆汝, 王发明. 基于相变材料与微型通风风扇的新型个体混合冷却服在温热环境下的制冷效果研究[J]. 丝绸, 2016, 53(3):1-8.
WEI Fanru,WANG Faming.The cooling performance of a portable hybrid personal cooling system(PCS)based on phase change materials and micro-ventilation fans in a warm environment[J]. Journal of Silk, 2016, 53(3):1-8.(in Chinese)
[45] 马瑞鑫. 基于相变材料的石油行业防热降温装备研究[D].北京:中国石油大学,2018.
[46] YANG J, WANG F M, SONG G W, et al. Effects of clothing size and air ventilation rate on cooling performance of air ventilation clothing in a warm condition[J].Journal of Occupational Safety and Ergonomics,2020,29(4):316.
[47] BARTKOWIAK G,DABROWSKA A,MARSZALEK A. Assessment of an active liquid cooling garment intended for use in a hot environment[J]. Applied Ergonomics, 2017, 58(1):182-189.
[48] 郑晴, 王宏付, 柯莹,等. 相变降温矿工服的设计与评价[J]. 纺织学报, 2020,41(3):124-129.
ZHENG Qing,WANG Hongfu,KE Ying,et al. Design and evaluation of cooling clothing by phase change materials for miners[J]. Journal of Textile Research,2020, 41(3):124-129.(in Chinese)
[49] SONG W, WANG F. The hybrid personal cooling system(PCS)could effectively reduce the heat strain while exercising in a hot and moderate humid environment[J]. Ergonomics, 2015(8):1009-1018.
[50] SONG W, WANG F, WEI F. Hybrid cooling clothing to improve thermal comfort of office workers in a hot indoor environment[J]. Building and Environment, 2016, 100(2):92-101.
[51] WANG F, SONG W F. An investigation of thermophysiological responses of human while using four personal cooling strategies during heatwaves[J]. Journal of Thermal Biology, 2017, 70(5):37- 44.
[52] CHAN A P, ZHANG Y, WANG F, et al. A field study of the effectiveness and practicality of a novel hybrid personal cooling vest worn during rest in Hong Kong construction industry [J]. Journal of Thermal Biology, 2017, 70(7):21-27.
[53] CHAN A P, YANG Y, SONG W. Evaluating the usabi-lity of a commercial cooling vest in the Hong Kong industries [J]. International Journal of Occupational Safety and Ergonomics, 2018, 24(1):73-81.
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更新日期/Last Update: 2020-02-28