棉纱布被保暖性能的影响因素

doi:10.13475/j.fzxb.20220606401

纺织学报 ›› 2023, Vol. 44 ›› Issue (07): 79-85.doi: 10.13475/j.fzxb.20220606401

棉纱布被保暖性能的影响因素

张露杨¹, 宋海波², 孟晶¹, 殷兰君², 卢业虎¹()

1.苏州大学纺织与服装工程学院, 江苏苏州 215006
2.深圳全棉时代科技有限公司, 广东深圳 518110

收稿日期:2022-06-27 修回日期:2022-09-22 出版日期:2023-07-15 发布日期:2023-08-10
通讯作者: 卢业虎(1986—),男,教授,博士。主要研究方向为智能和防护服装。E-mail: yhlu@suda.edu.cn。
作者简介:张露杨(1998—),女,硕士生。主要研究方向为服装舒适性。
基金资助:
江苏省高等学校基础科学(自然科学)重大项目(21KJA540004);苏州市科技计划项目(SS202147);南通市科技计划项目(JC2021004)

Influencing factors for thermal insulating properties of cotton gauze quilts

ZHANG Luyang¹, SONG Haibo², MENG Jing¹, YIN Lanjun², LU Yehu¹()

1. College of Textile and Clothing Engineering, Soochow University, Suzhou, Jiangsu 215006, China
2. Shenzhen Purcotton Technology Co., Ltd., Shenzhen, Guangdong 518110, China

Received:2022-06-27 Revised:2022-09-22 Published:2023-07-15 Online:2023-08-10

摘要/Abstract

摘要：

为提高人体睡眠热舒适性,改善睡眠质量,对不同参数的棉纱布被进行系统的保暖性能研究。借助出汗热平板纱布织物实验与出汗暖体假人被子实验,探究了棉纱布织物透气性、面密度、层数及水洗处理等因素对纱布被织物热阻的影响规律,并建立纱布被织物热阻与被子热阻的相关关系。结果表明:纱布被织物的热阻与其面密度呈明显的正相关线性关系,热阻与透气率相关性较低;棉被与纱布被的面密度相当的情况下,棉被的保暖性能更好,纱布被的透气性更好;纱布被织物的热阻与层数之间呈线性关系,层数越多热阻值越大;水洗处理后棉纱布被织物的热阻增加;纱布被织物热阻与纱布被子热阻呈显著的相关关系,当纱布被织物的总热阻较小(小于1.8 clo)时,二者近似呈线性关系。本文研究结果可为开发高质量棉纱布被提供参考。

关键词: 棉纱布被, 棉被, 出汗热平板, 热阻, 保暖性能, 透气性

Abstract:

Objective Studies on thermal insulating properties of quilts have been carried out aiming to improve the thermal comfort and sleep quality. Previous studies mainly focused on quilts with filling materials, and few research focused on non-filling quilts such as gauze quilt. In order to provide more understanding on comfortable sleeping microclimate, a systematic investigation on thermal insulating properties of several gauze quilts with different parameters was conducted.

Method 41 samples in total were provided, including 22 unwashed cotton gauze quilt fabric samples, 4 washed cotton gauze quilt fabric samples, 3 spunlaced cotton wadding samples, 6 cotton gauze quilt samples. The influences of air permeability, surface density and number of layers on heat resistance of cotton gauze quilts were analyzed by sweating hot plate tests and thermal manikin tests. The correlation between heat resistance of fabric and quilt was also established.

Results It was found that the heat resistance of both cotton gauze quilt samples and cotton spunlaced wadding samples have significant positive linear relationships with surface density. The heat resistance rose with the increase of surface density. The growth rate of the spunlaced cotton wadding quilts (0.006 1) was higher than that of cotton gauze quilts (0.001 7). Heat resistance of cotton gauze quilt samples decreased with the increasing of air permeability, exhibiting a low correlation, but the influence on thermal insulation was obvious when the air permeability was below 1 000 mm/s. The heat resistance of the spunlaced cotton wadding quilt showed a significant negative linear relationship with its air permeability. In addition, the air permeability and surface density presented an exponentially negative correlation. The change rate was constantly decreasing when surface density was more than 450 g/m². Generally, the air permeability of each cotton gauze quilt was above 500 mm/s, higher than that of the spunlaced cotton wadding quilt. The surface fitting results (thermal insulation as dependent variable, air permeability and surface density as independent variables) revealed that heat resistance and air permeability exhibited a low correlation. The surface density demonstrated a significant influence on heat resistance, and the heat resistance of cotton gauze quilt exhibited a positive linear relationship with the number of cotton gauze fabric layers. The air permeability of cotton gauze quilt showed power function relationship with the number of fabric layers. The heat resistance of cotton gauze quilt was increased after washing, with the average increase of about 20%. After once machine washing in 20 ℃ water, the thickness and surface density of cotton gauze quilt was increased by 26.6% and 13.6% in average, respectively, whereas the air permeability was decreases by 8.7% in average. A significant non-linear relationship exists between the heat resistance of fabric samples and quilt samples (p<0.05), which can be approximately expressed by an exponential function. In particular, they show approximate a linear relationship when the heat resistance of fabric was less than 1.8 clo.

Conclusion The heat resistance of the cotton gauze quilts has a significant positive linear relationship with the surface density, exhibiting a negative and low correlated relationship with the air permeability. Therefore, surface density is more appropriate for the prediction of heat resistance value in engineering application. Under the same surface density, spunlaced cotton wadding quilt provides higher thermal insulating properties, while cotton gauze quilt provides bigger air permeability. The superimposition of cotton gauze fabric layers can produce thicker air gaps, resulting in higher thermal insulating property of cotton gauze quilt. Once machine washing has a positive effect on thermal insulating property of cotton gauze quilt by virtue of the increase of thickness and surface density after washing. Moreover, heat resistance of fabric samples can be adopted to predict the heat resistance of quilt, showing a significant non-linear correlation. These research findings can provide evidence for the design of cotton gauze quilts and usage guideline to achieve thermal comfort during sleeping.

Key words: cotton gauze quilt, spunlaced cotton wadding quilt, sweating hot plate, heat resistance, thermal insulating property, air permeability

中图分类号:

TS941.75

张露杨, 宋海波, 孟晶, 殷兰君, 卢业虎. 棉纱布被保暖性能的影响因素[J]. 纺织学报, 2023, 44(07): 79-85.

ZHANG Luyang, SONG Haibo, MENG Jing, YIN Lanjun, LU Yehu. Influencing factors for thermal insulating properties of cotton gauze quilts[J]. Journal of Textile Research, 2023, 44(07): 79-85.

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样品编号	样品结构	样品层数	样品厚度/mm	单层纱布参数
样品编号	样品结构	样品层数	样品厚度/mm	单层纱布位置	密度/ (根·(2.54 cm²)^-1)
G1	双层纱布	2	1.240		50×50
G2	4层纱布	4	2.378		66×80
G3	4层纱布(粗纱)		2.004		64×59
G4	4层蜂巢		1.888		60×60
G5	4层纱布(2个2层织物叠放)		1.159		50×50
G6	4层斜纹纱布		1.979	第1、4层第2、3层	42×42 42×21
G7	4层纱布(4个单层织物叠放)		0.941		30×30
G8	4层纱布(2个2层织物叠放)		1.246		60×60
G9	4层纱布(2个2层织物叠放)		1.086		80×65
G10	双层纱布+平纹皱布(2个2层织物叠放)		2.854		55×42
G11	6层纱布(2个3层织物叠放)	6	2.740		55×43
G12	6层纱布(2个3层织物叠放)		1.808		54×54
G13	6层提花纱布		2.273		28×33
G14	6层纱布		2.782		172×176
G15	6层加密纱布		3.297		210×230
G16	6层纱布		2.132		28×33
G17	6层纱布(6个单层织物叠放)		1.459		30×30
G18	8层纱布(2个4层织物叠放)		3.446	第1、4层第2、3层	42×41
G18	8层纱布(2个4层织物叠放)	8	3.446	第1、4层第2、3层	42×41
G19	8层一体纱布	8	3.895		180×174
G20	8层一体蜂巢		4.164		210×206
G21	10层纱布	10	6.371		232×232
G22	12层纱布	12	6.019		232×232

样品编号	样品质量/g	样品尺寸(长×宽)/m
C1	730	1.25×1.55
C2	1 300	1.50×2.00
C3	850	1.00×1.20

被子样品编号	层数	纱布被种类	单层纱布密度/ (根·(2.54 cm²)^-1)
Q1-a	4	4层斜纹纱布被	126×126
Q2-a	4	4层纱布夹棉被	100×100
Q3-a	6	6层纱布被	154×166
Q4-a	6	6层加密纱布被	210×210
Q5-a	8	8层印花纱布被	210×206
Q6-a	12	12层纱布被	232×232

样品编号	水洗处理前			水洗处理后
样品编号	透气率/(mm·s^-1)	厚度/mm	面密度/(g·m^-2)	透气率/(mm·s^-1)	厚度/mm	面密度/(g·m^-2)
G6	1 945.24	1.978	232.7	1 716.93	2.330	249.5
G13	2 046.27	2.273	252.4	1 908.29	3.052	279.6
G16	1 973.75	2.132	245.5	1 829.26	2.734	296.6
G21	969.63	5.789	532.0	880.99	7.302	614.8

棉纱布被保暖性能的影响因素

Influencing factors for thermal insulating properties of cotton gauze quilts

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