纺织学报 ›› 2023, Vol. 44 ›› Issue (08): 18-25.doi: 10.13475/j.fzxb.20211201601

• 纤维材料 • 上一篇    下一篇

棉秆皮微晶纤维素/改性壳聚糖吸附纤维制备与性能

邵彦峥, 孙将皓, 魏春艳(), 吕丽华   

  1. 大连工业大学 纺织与材料工程学院, 辽宁 大连 116034
  • 收稿日期:2021-12-08 修回日期:2022-11-18 出版日期:2023-08-15 发布日期:2023-09-21
  • 通讯作者: 魏春艳(1965—),女,教授,硕士。主要研究方向为功能纤维与纺织品。E-mail:weicy@dlpu.edu.cn
  • 作者简介:邵彦峥(1996—),女,硕士生。主要研究方向为纺织品结构与功能材料。
  • 基金资助:
    辽宁省自然科学基金指导计划项目(2019-ZD-0295)

Preparation and properties of adsorption fiber made from cotton stalk bark microcrystalline cellulose/modified chitosan

SHAO Yanzheng, SUN Jianghao, WEI Chunyan(), LÜ Lihua   

  1. School of Textile and Material Engineering, Dalian Polytechnic University, Dalian, Liaoning 116034, China
  • Received:2021-12-08 Revised:2022-11-18 Published:2023-08-15 Online:2023-09-21

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摘要:

为提高壳聚糖(CS)对阴离子染料刚果红的吸附性能,以尿素溶剂法低温溶解棉秆皮微晶纤维素(MCC)作为纺丝基体,以改性壳聚糖为分散吸附材料,经湿法纺丝和冷冻干燥制备棉秆皮微晶纤维素/改性壳聚糖(MCC/DCS)吸附纤维。通过正交试验方法优化壳聚糖改性工艺,利用单因素方法优化纺丝工艺,并对DSC粉末的化学结构、MCC/DCS吸附纤维形貌结构及其对刚果红染料吸附性能等进行测试与表征。结果表明:壳聚糖改性较优工艺为醋酸用量55 mL,2,5-二硫二脲用量0.6 g,壳聚糖用量1.0 g,甲醛用量8 mL;MCC/DCS纤维制备的较佳工艺为DCS添加量1.5 g, 纺丝凝固时间1 h时,MCC/DCS吸附纤维的吸附效果和力学性能均较好;当刚果红染液质量浓度为250 mg/L时,MCC/DCS纤维对刚果红染料达到最大吸附量,为96.03 mg/g。

关键词: 改性壳聚糖, 棉秆皮微晶纤维素, 吸附材料, 刚果红, 吸附动力学

Abstract:

Objective The pollution of dye wastewater to the environment seriously harms people's health and is also an important factor restricting the development of textile enterprises. The adsorption method is a promising one for dye wastewater treatment. Natural polymeric cellulose and chitosan are widely used as adsorption materials for wastewater treatment because of the advantages in large capacity for storage, good adsorption, non-toxicity and easy degradation. In this research, an cotton stalk microcrystalline cellulose/chitosan(MCC/CS) adsorption fiber was prepared for the adsorption of Congo Red.

Method Firstly, modified chitosan (DCS) was prepared by surface modification to CS with formaldehyde as crosslinking agent and 2,5-disulfide diurea as modifier, to improve their adsorption of Congo Red. The modified chitosan process was optimized by the orthogonal test method. Urea solvent method was used to dissolve MCC at low temperature as spinning matrix, DCS was added as insoluble dispersion adsorption material, composite fiber was prepared by wet spinning and freeze-drying, and the spinning process was optimized by the single factor method. Finally, the chemical structure of DCS was analyzed, the morphology and dye adsorption properties of MCC/DCS adsorbed fibers were tested and characterized.

Results The modification of CS was carried out successfully, where the new C=S characteristic absorption peaks at 1 209 cm-1appear and the absorption peak of -NH2 (2,5-dithiourea, DB) disappeared at 1 640 cm-1 in DCS infrared spectrum. The combination of conditions obtained by orthogonal test for preparation of DCS was optimized, where acetic acid dosage was 55 mL, DB dosage was 0.60 g, CS dosage was 1.0 g, and formaldehyde dosage was 8 mL. The modified chitosan increased the contents of N and S elements, and the changes were obvious. The pore size of the MCC/DCS was larger than the MCC adsorbent fibers, and the modification CS was more beneficial to the adsorption of Congo Red by adsorbent fibers. The fracture strength of MCC/DCS adsorption fiber decreased gradually with the increase of the amount of DCS in the fiber, while the linear density increased gradually because DCS is insoluble in alkaline solution. With the addition of DCS, the viscosity of the spinning solution decreased gradually. When the concentration of dye solution was 60 mg/L, the adsorption capacity of unmodified CS for Congo Red was 13.85 mg/g, and the DCS under optimal conditions was 17.63 mg/g, the adsorption capacity of DCS was increased by 27.29% compared with CS. At the same dye solution concentration, the adsorption capacity of MCC/DCS fiber was 49.55 mg/g, which was 47.82% higher than that of MCC/CS fiber 33.52 mg/g. The analysis of the influencing factors of adsorption performance showed that the adsorption capacity of MCC/DCS adsorption fiber for Congo Red decreased gradually with the increase of adsorption temperature. The adsorption capacity was increased with the adsorption time of MCC/DCS fiber and the change of the initial concentration of dye solution, and the adsorption equilibrium was reached when the concentration of dye solution was 250 mg/L. Ho kinetic model was suitable to simulate the adsorption process of DCS adsorption fibers. The adsorption thermodynamic analysis showed that the Langmuir model was suitable to simulate the adsorption process of DCS adsorbed fibers.

Conclusion CS was successfully modified with formaldehyde as crosslinking agent and 2, 5-dithiourea as modifier. The modification process of CS was optimized by orthogonal test, and the optimum process was obtained. The MCC was dissolved by urea dissolution system at low temperature as a spinning matrix, coated with DCS powder prepared by the optimized process. Adsorption experiment test results are as follows: when the concentration of dye solution was 60 mg/L, the average removal rate of MCC/DCS fiber Congo Red was 82.58%, and the average removal rate of MCC/CS fiber for Congo Red was 55.87%. The removal rate of MCC/DCS fiber was 47.82% higher than that of MCC/CS fiber, and the expected effect was achieved.

Key words: modified chitosan, cotton stalk bark microcrystalline cellulose, adsorption material, Congo Red, adsorption kinetics

中图分类号: 

  • TS102.2

表1

正交试验因素水平表"

水平 A
醋酸用量/mL		 B
DB用量/g		 C
壳聚糖用量/g		 D
甲醛用量/mL
1 50 0.50 0.6 6
2 55 0.55 0.8 7
3 60 0.60 1.0 8

表2

正交试验设计和结果"

序号 A B C D 吸附量/(mg·g-1)
1 1 1 1 1 5.25
2 1 2 2 2 6.44
3 1 3 3 3 10.00
4 2 1 2 3 12.94
5 2 2 3 1 17.50
6 2 3 1 2 8.56
7 3 1 3 2 11.88
8 3 2 1 3 10.00
9 3 3 2 1 9.63
K1 21.69 30.07 23.81 32.38 较优水平
K2 39.00 33.94 29.01 26.88 A2B3C3D3
K3 31.51 28.19 39.38 32.94
Rj 17.31 5.75 15.57 6.06

图1

壳聚糖改性机制"

图2

CS和DCS的傅里叶红外光谱图"

表3

壳聚糖和改性壳聚糖的元素分布质量百分比"

样品名称 C N O S
壳聚糖 50.54 9.24 40.04 0.18
改性壳聚糖 45.42 16.97 27.81 9.80

图3

CS和DCS的表面元素分布图"

图4

DCS用量对纤维断裂强度和线密度、吸附量的影响"

图5

凝固时间与断裂强度和线密度、吸附量的关系"

图6

MCC纤维和MCC/DCS吸附纤维的扫描电镜照片(×5 000)"

图7

吸附温度与MCC/DCS纤维对刚果红吸附量的关系"

图8

pH值与MCC/DCS纤维对刚果红吸附量的关系"

图9

刚果红染液初始质量浓度对MCC/DCS纤维吸附量的影响"

表4

吸附动力学拟合参数"

准一级动力学 准二级动力学 粒子内扩散动力学
K1 qe K2 qe a b
0.021 5 39.165 0.069 4.427 9.095 -9.628

图10

动力学模型模拟结果"

表5

吸附热力学拟合参数"

Langmuir热力学模型 Freundlich热力学模型
qm KL n KF
100 0.109 1.733 13.015

图11

热力学模型模拟结果"

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