阻燃防水多功能涤纶篷布的制备及其性能

doi:10.13475/j.fzxb.20220502701

纺织学报 ›› 2023, Vol. 44 ›› Issue (06): 168-174.doi: 10.13475/j.fzxb.20220502701

阻燃防水多功能涤纶篷布的制备及其性能

杨海富¹, 罗丽娟², 师建军², 马晓光¹, 郑振荣¹()

1.天津工业大学纺织科学与工程学院, 天津 300380
2.航天材料及工艺研究所, 北京 100071

收稿日期:2022-05-09 修回日期:2023-03-21 出版日期:2023-06-15 发布日期:2023-07-20
通讯作者: 郑振荣
作者简介:杨海富(1997—),男,硕士生。主要研究方向为多功能织物开发。
基金资助:
国家自然科学基金项目(52003071);北京市科技新星计划(Z211100002121090)

Preparation of flame-retardant and waterproof multifunctional polyester tarpaulin

YANG Haifu¹, LUO Lijuan², SHI Jianjun², MA Xiaoguang¹, ZHENG Zhenrong¹()

1. School of Textile Science and Engineering, Tiangong University, Tianjin 300380, China
2. Institute of Aerospace Materials and Processes, Beijing 100071, China

Received:2022-05-09 Revised:2023-03-21 Published:2023-06-15 Online:2023-07-20
Contact: ZHENG Zhenrong

摘要/Abstract

摘要：

为提高篷布的阻燃、抗熔滴及防水性能,以涤纶帆布为基布,采用有机阻燃剂、无机阻燃剂和防水涂层胶对涤纶帆布进行阻燃整理及防水整理,制得多功能阻燃防水涤纶篷布。探究了TF-11氮磷阻燃剂质量浓度、十溴二苯醚和无机阻燃剂三氧化二锑的质量分数及质量比对阻燃性能的影响,测试了整理后篷布的续燃阴燃时间、损毁长度、静水压值及断裂强力,并借助热重分析仪、扫描电子显微镜分析了多功能篷布的阻燃抗熔滴性及表面形貌。结果表明:TF-11氮磷阻燃剂质量浓度为150 g/L,十溴二苯醚与三氧化二锑质量比为2∶1且占树脂总量的30%时,制备的篷布阻燃效果可达离火自熄程度,损毁长度缩短至5.5 cm,并且无熔滴现象,防水性能优异,静水压值为5.1 kPa,满足篷布对于阻燃和防水性能的要求。

关键词: 涂层整理, 阻燃整理, 防熔滴, 防水整理, 多功能篷布

Abstract:

Objective Tarpaulin textiles have a wide range of applications in military field, and multifunctional tarpaulin textiles have attracted extensive attentions of researchers. The main purpose of this study is to develop a type of tarpaulin with both flame-retardancy and waterproofness, which are contradictive to each other and are difficult to achieve. The tarpaulin prepared in this study is expected to be used for covering automobile, aircraft, tank and for field tent cloth.
Method The effect of the concentration of flame-retardant TF-11 and the method of dipping the flame retardant on the flame-retardant performance was investigated. In order to improve the flame-retardant and waterproof performance of canvas, DBDPO and Sb₂O₃ were added to PA-822 resin solution and coated on the polyester canvas based on the bromine antimony flame-retardant synergy theory. The flame-retardant and anti-melt-drip mechanism of the multifunctional tarpaulins was analyzed by testing the after-glow time, the after-flame time, the damage length, hydrostatic pressure resistance and breaking strength of the finished tarpaulins, and by testing the carbon residue of the original polyester canvas and the finished tarpaulins with the aid of TG and SEM.
Results The polyester canvas was dipped and rolled twice in 150 g/L of the nitrogen-phosphorus flame retardant TF-11, and after dipping and rolling the fabric had the after-glow time and the after-flame time of 0 s and a damage length of 7.5 cm(Tab. 1). TG analysis showed that the phosphoric acid produced by the flame retardant during combustion was a strong dehydrating agent, which promoted the charring of the polyester canvas and prevented the decomposition of the fabric. The fabric was coated after dipping and rolling with the nitrogen and phosphorus flame retardant TF-11. When the mass ratio of decabromodiphenyl ether (DBDPO) to antimony trioxide was 2∶1 and 30% of the total amount of polyacrylic resin PA-822, the after-glow time and the after-flame time of the coated fabric was 0 s. Compared with the unfinished polyester canvas, the damage length was shortened to 5.5 cm (Fig. 3), and there was no melt drip, and the tarp had a high flame-retardant performance. The SEM images of the residual carbon profile of the finished tarpaulin showed a significant increase in the charring of the coated fabric (Fig. 4) and a significant reduction in the length of damage. This may be due to the synergistic effect of the bromine and antimony added to the coating agent, which promote the charring of the fabric. The char layer inhibits the diffusion of combustible gases and the transfer of heat to achieve the flame-retardant effect, and the bromine and antimony produced the incombustible gas SbBr₃, which reduced the oxygen concentration. Compared with uncoated polyester canvas, the hydrostatic pressure resistance value of the coated polyester canvas increased from 0 to 5.1 kPa (Tab. 2), with excellent waterproof performance. Compared with commercially available tarpaulins, the warp and weft breaking strength of prepared tarpaulins was above 2 000 N (Tab. 4). The flame-retardant effect can reach the degree of self-extinguishing from fire, and the length of damage after burning was obviously reduced, with good waterproof ability.
Conclusion Using polyester canvas as the tarp base fabric, the flame-retardant properties of the polyester canvas were significantly improved by dipping and rolling with the nitrogen and phosphorus flame-retardant TF-11. In order to further improve the flame-retardant and waterproof performance of the polyester canvas, a moisture permeable polyacrylic resin containing bromine antimony flame-retardant was used to coat the fabric after dipping and rolling the nitrogen phosphorus flame-retardant, so that the tarp had good flame-retardant and waterproof performance at the same time, which better solves the contradiction problem between the flame-retardant and waterproof performance of polyester canvas. The multifunctional tarpaulin can reach the degree of self-extinguishing from fire, with hydrostatic performance, can resist the rainstorm soaking, meeting the tarpaulin standard for flame retardant and waterproof performance requirements. In addition to high flame-retardant and waterproof performances, tarpaulin in practical application should also have high strength and corrosion resistance, low weight and fastness to the sun, to cope with different environmental conditions. In protective textiles, the tarpaulin with flame-retardant and waterproof performance has a good prospect for development and application.

Key words: coating finishing, flame-retardant finishing, anti-dripping, waterproof finishing, multifunctional tarpaulin

中图分类号:

TS195.1

杨海富, 罗丽娟, 师建军, 马晓光, 郑振荣. 阻燃防水多功能涤纶篷布的制备及其性能[J]. 纺织学报, 2023, 44(06): 168-174.

YANG Haifu, LUO Lijuan, SHI Jianjun, MA Xiaoguang, ZHENG Zhenrong. Preparation of flame-retardant and waterproof multifunctional polyester tarpaulin[J]. Journal of Textile Research, 2023, 44(06): 168-174.

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浸轧方式	续燃时间/s	阴燃时间/s	损毁长度/cm	熔滴性
一浸一轧	0.8	0	8.0	轻微
二浸二轧	0	0	7.5	无

样品编号	续燃时间/s	损毁长度/cm	熔滴	静水压/ kPa	沾水等级/级	面密度/ (g·m^-2)
A	48	25.0	多	0	0	290
B	0	7.5	轻微	1.2	1	298
C	0	5.5	无	5.1	3	395
D	0	5.6	无	5.1	3	395

样品编号	起始热温度/℃	最大热质量损失速率峰对应温度/℃	最大质量损失速率/ (%·min^-1)	700 ℃ 时残炭量/%
A	405.3	428.4	18.84	17.23
B	380.5	418.5	13.05	19.78
C	340.1	371.6	9.80	16.43

样品	断裂强力/N		阻燃性能			防水性能		面密度/ (g·m^-2)
样品	经向	纬向	续燃时间/s	阴燃时间/s	损毁长度/cm	静水压/kPa	沾水等级/级	面密度/ (g·m^-2)
阻燃防水涤纶篷布	2 610	2 100	0	0	5.5	5.1	3	395
市售涤纶阻燃篷盖布	2 858	2 293	45	0	30.0	>35	1	280
市售BW571-Z锦丝涂层篷布	1 800	1 400	0	0	6.8	>35	2	230

阻燃防水多功能涤纶篷布的制备及其性能

Preparation of flame-retardant and waterproof multifunctional polyester tarpaulin

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