聚乳酸非织造布植酸/壳聚糖/硼酸一浴法阻燃整理

doi:10.13475/j.fzxb.20221102301

摘要/Abstract

摘要：

为实现聚乳酸非织造布的阻燃抗熔滴功能,以壳聚糖(CS)、植酸(PA)、无机硼酸(BA)为主要原料,采用一浴法对聚乳酸非织造布进行阻燃整理。借助傅里叶红外光谱仪、扫描电镜、X射线能谱仪和热重分析仪、垂直法织物燃烧性能测试仪等表征和评价了聚乳酸非织造布的化学结构、表面形貌及表面元素分布、热稳定性能和阻燃性能。结果表明:聚乳酸非织造布经一浴法处理后,续燃、阴燃时间均为0 s,无熔滴,损毁长度仅为 11.3 cm,极限氧指数为34.6%;壳聚糖、植酸、硼酸以及复合物共沉积覆盖在聚乳酸纤维上,且磷、硼、氮等元素质量分数分别达到5.26%、12.91%、4.26%;氮气气氛下,阻燃处理样起始分解温度降低了139.3 ℃,800 ℃时的残炭量达到14.57%;PA/CS/BA一浴法生物质阻燃体系提高了聚乳酸非织造布的阻燃抗熔滴效果和热稳定性,符合凝聚相阻燃机制。该生物质阻燃体系为聚乳酸纺织品提供了一种新的环保阻燃和抗熔滴的策略,具有较好的市场应用潜力。

关键词: 聚乳酸纤维, 非织造布, 植酸, 壳聚糖, 阻燃整理, 一浴法

Abstract:

Objective Polylactic acid (PLA) fiber is an eco-friendly thermoplastic degradable synthetic fiber, which has biocompatibility and easy biodegradability but poor flame retardancy and easy to produce droplets. Biomass flame retardant has the advantages of innocuity, harmless and easy biodegradation. In order to solve the problem of flame retardancy and droplet resistance of PLA fiber products, it is urgent to develop flame retardancy technology for PLA fiber biomass to improve its flame retardancy and droplet resistance.

Method The subject design uses biomass chitosan (CS), biomass phytic acid (PA), and inorganic boric acid (BA) as the main raw materials, and uses the one bath method to finish the polylactic acid nonwovens with flame retardancy and anti-dripping, so as to improve their flame retardancy and anti-dripping performance. FT-IR, SEM, EDS and TG were used to characterize the chemical structure, surface morphology, surface element distribution, and thermal stability of flame retardant polylactic acid nonwovens. The flammability of flame retardant polylactic acid nonwovens was evaluated by vertical flammability tester and limiting oxygen index tester.

Results After the one bath method treatment of polylactic acid nonwovens, many granular or flaky substances co-deposited on the surface of the polylactic acid fiber, and the fiber surface became rough(Fig. 3), indicating that chitosan, phytic acid, boric acid and composites co-deposited on the fiber. After the one bath method treatment of polylactic acid nonwovens, the continuous burning and smoldering time of the flame retardant treated samples are zero, only a small amount of melting shrinkage without dripping, the carbon length is only 11.3 cm, and the limiting oxygen index of the original sample is 21.0% increased to 34.6% of the treated samples(Fig. 2 and Tab. 1), which improves the flame retardant and anti-dripping effect of polylactic acid nonwovens. After the one bath method treatment of polylactic acid nonwovens, the flame retardant treated samples contain not only carbon and oxygen, but also phosphorus (5.26%), boron (12.91%), nitrogen (4.26%) (Fig. 3 and Tab. 2). The reactive P—OH and B—OH in phytic acid and boric acid may form a complex with the —NH₂ of chitosan(Fig. 4). It is beneficial to promote the catalytic dehydration of PLA fiber into carbon and improve its flame retardancy and anti-dripping performance. After the "one bath method" treatment of polylactic acid nonwovens, the thermal cracking of flame retardant-treated samples in a nitrogen atmosphere includes three processes: decomposition, thermal degradation, and carbonization. The initial decomposition temperature of flame retardant treated samples is 139.3 ℃ earlier (from 299.1 ℃ of the original sample to 159.8 ℃), and the carbon residue at 800 ℃ reaches 14.57% (Fig. 5 and Tab. 3).It is shown that the flame-retardant system is helpful to promote the catalytic dehydration of PLA fiber to form carbon, and the dense carbon layer has a blocking effect, which can inhibit the transfer of combustible gas and the diffusion of oxygen, and conforms to the condensed phase flame retardant mechanism (Fig. 6).

Conclusion Biomass chitosan (CS), biomass phytic acid (PA), and inorganic boric acid (BA) were used as the main raw materials to finish the polylactic acid nonwovens in a one bath method. The continuous burning time and smoldering time of the treated samples were zero, with no melt drops. The carbon length was only 11.3 cm, and the limiting oxygen index reached 34.6%. The thermal cracking in the nitrogen atmosphere was roughly divided into three stages: initial decomposition, thermal degradation, and carbonization. The carbon residue reached 14.57% at 800 ℃. The improvement of flame retardancy, droplet resistance, and thermal stability of PLA fiber conforms to the mechanism of condensed phase flame retardancy, and the influence of wearing properties (whiteness, breaking strength, etc.) is small. The one bath method flame retardant system of PA/CS/BA improves the flame retardancy, anti-dripping effect, and thermal stability of PLA nonwovens. It conforms to the flame retardant mechanism of the condensed phase. This flame-retardant system provides a new environment-friendly flameretardant and anti-droplet strategy for PLA fiber and has good market application potential.

Key words: polylactic acid fiber, nonwoven, phytic acid, chitosan, flame retardant finishing, one bath method

中图分类号:

TS195.6

张广知, 杨甫生, 方进, 杨顺. 聚乳酸非织造布植酸/壳聚糖/硼酸一浴法阻燃整理[J]. 纺织学报, 2023, 44(10): 120-126.

ZHANG Guangzhi, YANG Fusheng, FANG Jin, YANG Shun. One bath flame retardant finishing of polylactic acid nonwoven by phytic acid/chitosan/boric acid[J]. Journal of Textile Research, 2023, 44(10): 120-126.

图/表 9

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样品	阻燃指标					断裂强力/N	白度/%
样品	损毁长度/cm	续燃时间/s	阴燃时间/s	LOI值/%	熔滴情况	断裂强力/N	白度/%
原样	16.7	0	0	21.0	熔融,有熔滴	11.56	79.1
PA/CS阻燃处理样	14.1	0	0	30.2	收缩,无熔滴	9.58	71.5
PA/CS/BA阻燃处理样	11.3	0	0	34.6	收缩,无熔滴	9.49	72.1

样品	质量分数/%
样品	C	O	P	N	B
原样	74.03	25.97	0	0	0
PA/CS阻燃处理样	63.56	23.71	8.60	4.13	0
PA/CS/BA阻燃处理样	30.10	47.47	5.26	4.26	12.91

样品	T_-5%/ ℃	T_-50%/ ℃	R_max/ (%·℃^-1)	T_max/ ℃	800 ℃时的残炭量/%
原样	299.1	349.8	2.42	360.9	0
PA/CS阻燃处理样	163.1	365.1	1.58	365.9	14.57
PA/CS/BA阻燃处理样	159.8	361.6	1.49	370.2	14.57