全生物基聚呋喃二甲酸丙二醇酯及其纤维制备与性能

doi:10.13475/j.fzxb.20211200501

摘要/Abstract

摘要：

为促进生物基聚酯在纺织领域的应用,采取酯交换-熔融缩聚法,使用醋酸锌-钛酸四丁酯为组合催化剂,制备了全生物基聚呋喃二甲酸丙二醇酯(PTF)。借助红外光谱仪、核磁共振波谱仪、差示扫描量热仪、热重分析仪等表征了PTF的化学结构和热性能;通过二步法纺丝工艺制备了PTF纤维,并研究了不同牵伸倍数对纤维的力学性能影响。结果表明:成功合成的目标产物PTF的数均分子质量达到35 000 g/mol,玻璃化转变温度为60~62 ℃,熔点约为171 ℃,起始热分解温度高于370 ℃,具有良好的热稳定性;初生纤维牵伸至2.5倍时,PTF纤维的断裂伸长率为34.2%左右,断裂强度为0.48 cN/dtex。

关键词: 生物基材料, 聚呋喃二甲酸丙二醇酯, 合成工艺, 熔融纺丝, 酯交换-熔融缩聚法, 热性能

Abstract:

Objective Polyester industry is an important industry relating to the national economy and the people's livelihood. Most polyesters are prepared from petroleum and other fossil resources as raw materials. The combustion process of polyester will produce a large amount of carbon dioxide and sulfur dioxide, which not only pollute the environment, but also lead to global warming, climate change and other serious problems. In order to further implement the sustainable development and the promote China's ″double carbon″ strategic goal, it is urgent to minimise the dependence on fossil energy. In 2004, the US Department of Energy released 12 platform compounds derived from biomass that can be converted into high value-added biobased materials. Among them, the chemical structure of 2,5-furanedicarboxylic acid (FDCA) is similar to petroleum based terephthalic acid (PTA), which can be used as an ideal biobased substitute for PTA. With the maturity of the synthesis and purification technology of FDCA, furan based polyester has attracted attention in various fields, becoming a key research direction of biobased high molecular materials. This research focus is on the study of furan based homopolymers and copolymers.

Method In this research, the use conditions of zinc acetate tetrabutyl titanate composite catalyst were optimized using 1,3-PDO and DMFD as raw materials. The full biological PTF with high molecular weight was synthesized by transesterification melt polycondensation. The chemical structure and thermal properties of the PTF were characterized by infrared spectroscopy, nuclear magnetic resonance hydrogen spectroscopy, differential scanning calorimetry and thermogravimetry, the biobased PTF fibers were prepared by two-step spinning process(UDY-DT), and the influences of different drafting ratios on the mechanical properties of the fibers were studied.

Results In the process of adjusting the reaction process, it was found that only zinc acetate was added in the esterification stage, and tetrabutyl titanate was added in the polycondensation stage. The alcohol ester ratio was increased to 2.6, which would synchronously reduce the transesterification reaction time (Tab. 1). The analysis of the chemical structure of the product showed that the target product PTF (Figs.3 and 4) was successfully synthesized, and the number average molecular weight of the prepared product reached 3.25 × 10⁴ g/mol, the PDI was controlled below 3 (Tab. 4), and the chip color was light yellow. It is believed that the optimal use conditions of the combined catalyst were found. The glass transition temperature of the synthesized product was 60-62 ℃, the melting point was about 171 ℃, and the initial thermal decomposition temperature was higher than 370 ℃ (Tab.5). With the primary fiber drawn to 2.5 times, the elongation at break of PTF fiber was about 34.2%, and the breaking strength was 0.48 cN/dtex (Tab. 6).

Conclusion The whole biological PTF fiber was successfully prepared by UDY-DT two-step method. After 2.5 times of drafting, the elongation at break of the fiber was 34%, and the breaking strength was 0.48 cN/dtex. Owing to wide molecular weight distribution of PTF, relatively low breaking strength of prepared PEF fiber, and yellow color of polymer and fiber, further optimization and improvement of synthesis and spinning process are required in future research work.

Key words: fully biobased material, polytrimethylene furandicarboxylate, synthesis process, melt spinning, transesterification melt polycondensation, thermal performance

中图分类号:

TQ323.4

赫爽, 孙莉娜, 胡红梅, 朱瑞淑, 俞建勇, 王学利. 全生物基聚呋喃二甲酸丙二醇酯及其纤维制备与性能[J]. 纺织学报, 2023, 44(05): 63-69.

HE Shuang, SUN Li'na, HU Hongmei, ZHU Ruishu, YU Jianyong, WANG Xueli. Synthesis and fiber fabrication of fully biobased polytrimethylene furandicarboxylate[J]. Journal of Textile Research, 2023, 44(05): 63-69.

图/表 12

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样品编号	醇酯比	酯交换阶段		缩聚阶段
样品编号	醇酯比	催化剂	反应过程	催化剂	反应过程
1^#	2.2	醋酸锌、 Ti(OBu)₄	分别在125 ℃反应1 h,150 ℃反应2 h,160 ℃反应2 h,170 ℃反应0.5 h,175 ℃反应0.5 h		分别在220 ℃反应2.5 h,230 ℃反应3 h,235 ℃反应0.5 h
2^#	2.2	醋酸锌	分别在125 ℃反应1 h,150 ℃反应2 h,160 ℃反应2 h,170 ℃反应2 h,175 ℃反应1 h	Ti(OBu)₄	分别在220 ℃反应2 h,230 ℃反应3 h,235 ℃反应0.5 h
3^#	2.6	醋酸锌	分别在125 ℃反应1 h,150 ℃反应2 h,160 ℃反应1 h,170 ℃反应1 h,175 ℃反应0.5 h	Ti(OBu)₄	分别在220 ℃反应2 h,230 ℃反应2 h,235 ℃反应1.5 h
4^#	2.6	醋酸锌	分别在125 ℃反应1 h,150 ℃反应2 h,160 ℃反应1 h,170 ℃反应2.5 h,175 ℃反应1 h	Ti(OBu)₄	分别在220 ℃反应2 h,230 ℃反应2 h,235 ℃反应3 h

纺丝组件		温度/℃	纺丝组件	速度/(m·min^-1)
螺杆区域	Ⅰ	240	导盘1	600
	Ⅱ	260	导盘2	650
	Ⅲ	260	导盘4	670
计量泵/管道/箱体		260	卷绕机	650

牵伸倍数	牵伸部件	速度/(m·min^-1)	温度/℃
1.5	GR1	333	50
	GR2	500	100
	导盘4	520
	卷绕机	500
2.0	GR1	250	50
	GR2	500	100
	导盘4	520
	卷绕机	500
2.5	GR1	200	50
	GR2	500	100
	导盘4	520
	卷绕机	500

样品编号	特性黏数[η]/ (dL·g^-1)	M_n/ (g·mol^-1)	PDI值
1^#	0.86	34 500	4.16
2^#	0.62	29 500	2.72
3^#	0.78	32 500	2.91
4^#	0.88	35 700	2.99

样品编号	T_g/℃	T_m/℃	T_5%/℃	T_max/℃	T_end/℃	残炭量/%
1^#	62	171	377	420	396	7.15
2^#	60		377	419	396	4.54
3^#	62		381	419	392	6.95
4^#	61		378	421	396	6.55