聚酰胺原液着色母粒的制备及其性能

doi:10.13475/j.fzxb.20220702701

摘要/Abstract

摘要：

针对聚酰胺66(PA66)原液着色过程中炭黑在PA66基体中分散性差的问题,首先,将炭黑加入到含有一定质量分数的分散剂的水溶液中,采用超声波分散协同喷雾干燥技术制备了自分散炭黑(SPCB);随后将SPCB再分散于含有一定质量分数PA66盐的水溶液中,制备了PA66盐基炭黑分散体,并通过原位聚合法制备了PA66原液着色母粒;最后,通过熔融共混法制备了PA66膜。探究了分散剂结构和质量分数、炭黑质量分数、超声波处理功率和时间对PA66盐基炭黑分散体粒径、粒径分布及稳定性的影响,分析了SPCB质量分数与PA66膜性能的关系。结果表明:聚乙烯吡咯烷酮相对炭黑质量分数为15%,炭黑相对体系的质量分数为10%,超声波处理功率为1 260 W,时间为80 min时,制备的PA66盐基炭黑分散体粒径最小为184.1 nm,离心稳定性和放置稳定性均在90%以上;SPCB与PA66的相容性良好,在PA66基体中分布均匀,粒径约为200 nm,当其质量分数为0.2%时,制备的PA66膜的熔融温度为259.2 ℃,L^*值为26.82。

关键词: 原液着色, 自分散炭黑, 聚酰胺66, 聚乙烯吡咯烷酮, 喷雾干燥, 原位聚合

Abstract:

Objective The conventional dyeing of polyamide 66 (PA66) has the disadvantage of poor uniformity, color depth and color fastness, and also has other problems such as serious environmental pollution and high energy consumption. Dope dyeing refers to adding colorant during and after the polymerization process to produce colored fibers during fiber spinning. In order to meet the increasingly stringent environmental requirements, the dope dyeing technology has high practical value and good prospects for development. In this research, PA66 salt-based carbon black dispersion was prepared, which was further used as a colorant in dope dyeing of PA66.

Method Self-dispersible carbon black (SPCB) was prepared by combining ultrasonic dispersion with spray drying, which was then dispersed in PA66 salt solution to prepare PA66 salt-based carbon black dispersion, PA66 masterbatch was prepared by in situ polymerization method, and finally PA66 film was further prepared by melt blending method. The factors of PA66 salt-based carbon black dispersion were investigated by estimating its particle size and stability. The SPCB influence on the performance of PA66 film was analyzed.

Results Among the dispersants NNO, Tween 20, SMA and polyvinylpyrrolidone (PVP), it was found PVP is the best dispersant to prepare the PA66 salt-based carbon black dispersion with small particle size and good stability. The influence of mass fraction of carbon black, ultrasonic time and power on the dispersion process was investigated. The optimum preparation process was as follows. The mass fraction of PVP to carbon black was 15%, the mass fraction of carbon black to the system was 10%, the ultrasonic treatment power was 1 260 W, and the time was 80 min. The average particle size of the prepared PA66 salt-based carbon black dispersion was 184.1 nm, the centrifugal stability was 96.20%, and the placement stability was 91.85%. The spray-dried SPCB surface was successfully coated with PVP. Compared with the original carbon black, SPCB showed better self-dispersing properties with a narrow particle size distribution. The average particle size of SPCB was 202 nm, which was about 30 nm larger than that of the carbon black dispersion before spray drying. The pigment particles were evenly dispersed in the PA66 matrix with a particle size of about 200 nm. With the increase of SPCB mass fraction, the color change value of PA66 film gradually became smaller, the color tended to be saturated, and the uniformity was better. At SPCB mass fraction of 0.2%, the K/S value was 9.20, L^* value was 26.82, a^* value was -0.04, and b^* value was -0.55. However, the distribution of pigment particles in the matrix hindered the movement of macromolecular chains, which hindered the crystallization of PA66. The melt temperature of the prepared PA66 film was 259.2 ℃, the crystallization temperature was 230.8 ℃, and the crystallinity was 36.5%.

Conclusion Compared with conventional dyeing, dope dyeing enables PA66 to be prepared with better uniformity, color depth and color fastness, dope dyeing is also a cleaner and greener coloring technology. The most critical issue of dope dyeing is to improve the compatibility and dispersion of pigments in PA66 matrix. The pigments were modified by coating through ultrasonic dispersion and spray drying technique in combination, and PA66 masterbatches were prepared by in situ polymerization after mixing with PA66 salt solution. The results showed that no large particle agglomeration occurred in SPCB in PA66 matrix, and the particle size was 200 nm, which indicated that the experiment improved the compatibility and dispersion of pigments in PA66 matrix very well. The research results show that PA66 salt-based carbon black dispersion is a good colorant for dope dyeing of PA66.

Key words: dope dyeing, self-dispersible carbon black, polyamide 66, polyvinylpyrrolidone, spray drying, in situ polymerization

中图分类号:

TS193

李修田, 宋伟广, 张丽平, 杜长森, 付少海. 聚酰胺原液着色母粒的制备及其性能[J]. 纺织学报, 2023, 44(11): 45-51.

LI Xiutian, SONG Weiguang, ZHANG Liping, DU Changsen, FU Shaohai. Preparation and properties of masterbatch for polyamide dope dyeing[J]. Journal of Textile Research, 2023, 44(11): 45-51.

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分散剂	粒径/ nm	PDI	加入PA66盐
分散剂	粒径/ nm	PDI	粒径/nm	PDI	S_s/%	S_c/%
NNO	168.0	0.090	384.6	0.081	71.10	85.86
吐温20	160.9	0.069	196.9	0.147	71.76	48.15
SMA	154.2	0.096	793.9	0.121	93.69	94.34
PVP	173.3	0.134	184.1	0.143	96.20	91.85

PVP质量分数/%	粒径/nm	PDI	S_s/%	S_c/%
10	209.4	0.218	66.00	80.18
15	184.1	0.143	96.20	91.85
20	186.9	0.090	95.18	90.17
25	192.0	0.140	94.79	91.51

炭黑质量分数/%	粒径/nm	PDI	S_s/%	S_c/%
5	177.1	0.083	83.34	91.13
10	184.1	0.143	96.20	91.85
15	196.8	0.144	96.06	80.23
20	206.1	0.160	95.88	58.85

SPCB质量分数/%	K/S值	L^*	a^*	b^*	ΔE
0.2	9.20	26.82	-0.04	-0.55	0.00
0.4	9.85	26.03	-0.15	-0.71	0.81
0.6	10.03	25.65	-0.05	-0.03	0.78
0.8	10.40	25.41	-0.08	-0.64	0.66
1.0	10.49	25.22	-0.10	-0.43	0.23