Journal of Textile Research ›› 2020, Vol. 41 ›› Issue (07): 101-108.doi: 10.13475/j.fzxb.20190600208

• Dyeing and Finishing & Chemicals • Previous Articles     Next Articles

Dyeing kinetics of reactive dye on cotton yarn in Pickering emulsion system

DING Yongsheng1,2, DAI Yamin1,2, ZHONG Yi1,2(), XU Hong3, MAO Zhiping1,4, ZHANG Linping1,2, CHEN Zhize1,2   

  1. 1. Key Laboratory of Science and Technology of Eco-Textile, Ministry of Education, Donghua University, Shanghai 201620, China
    2. College of Chemistry, Chemical Engineering and Biotechnology, Donghua University, Shanghai 201620, China
    3. Lutai Textile Co., Ltd., Zibo, Shandong 255000, China
    4. Innovation Center for Textile Science and Technology, Donghua University, Shanghai 201620, China
  • Received:2019-06-03 Revised:2020-01-15 Online:2020-07-15 Published:2020-07-24
  • Contact: ZHONG Yi E-mail:zhongyi@dhu.edu.cn

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Abstract:

In order to explore the dyeing mechanism of reactive dye on cotton yarn in SiO2 emulsion (Pickering emulsion)system, Reactive Red M-3BF was used to explore the kinetics for cotton dyeing. The dyeing performance of the dye in Pickering emulsion system and the traditional aqueous system were compared, before the data of cotton yarn dyed in Pickering emulsion system was fitted, and the kinetic parameters were calculated and compared with the traditional aqueous system. The results show that the dye utilization of Reactive Red M-3BF in the Pickering emulsion system are higher than that in the traditional aqueous bath dyeing system and the washing fastness is equivalent under the same dye dosages, and the dyeing of reactive Red M-3BF on cotton fibers in both systems conforms to the quasi-second-order kinetic adsorption model equation. The equilibrium adsorption capacity of dye in Pickering emulsion system is higher than that of traditional aqueous system, and the adsorption activation energy is smaller, the half-dyeing time is shortened. Sodium sulfate can increase the equilibrium adsorption capacity and speed up the dyeing rate.

Key words: reactive dye, Pickering emulsion system, cotton yarn, dyeing, silica emulsion

CLC Number: 

  • TS193.5

Fig.1

Dyeing process. (a) Pickering emulsion system;(b) Traditional aqueous system"

Fig.2

Dye utilization of Reactive Red M-3BF in different systems with different dye dosages"

Fig.3

Kinetic curves of Reactive Red M-3BF dyeing cotton yarn in different systems at different temperatures"

Fig.4

Fitting curves of quasi-first-order kinetics of adsorption of Reactive Red M-3BF dyeing on cotton fiber in different systems. (a) Pickering emulsion system; (b) Traditional aqueous system"

Tab.1

Correlation coefficient of quasi-first-order kinetics of Reactive Red M-3BF adsorption on cotton fiber in different systems"

染色体系 温度/℃ R2
皮克林乳液体系 40 0.865 16
60 0.604 27
80 0.671 02
传统水浴体系 40 0.953 10
60 0.898 17
80 0.971 79

Fig.5

Fitting curves of quasi-second-order kinetics of adsorption of Reactive Red M-3BF dyeing on cotton fiber in different systems. (a) Pickering emulsion system;(b) Traditional aqueous system"

Tab.2

Quasi-second-order kinetic parameters of Reactive Red M-3BF adsorption on cotton fiber in different systems"

染色
体系		 温度/
 qe,exp/
(mg·g-1)		 准二级动力学参数
k2/
(g·mg-1·min-1)		 qe,cal/
(mg·g-1)		 R2
皮克
林乳液
体系		 40 17.99 0.115 18.14 0.999 94
60 17.90 0.164 18.01 0.999 97
80 17.76 0.243 17.83 0.999 98
传统
水浴体系		 40 13.05 0.043 13.39 0.999 63
60 12.10 0.071 12.38 0.999 64
80 10.44 0.147 10.58 0.999 91

Fig.6

Fitting curves in different systems"

Tab.3

Half-dyeing time of Reactive Red M-3BF dyeing cotton yarns in different systems"

染色体系 温度/℃ 半染时间t1/2/min
皮克林
体系乳液		 40 0.48
60 0.34
80 0.23
传统
水浴体系		 40 1.78
60 1.16
80 0.65

Fig.7

Kinetic curves of Reactive Red M-3BF dyeing cotton yarn in different systems and different temperatures at different salt dosages"

Tab.4

Quasi-second-order kinetic parameters of Reactive Red M-3BF adsorption on cotton fiber in different systems at different salt dosages"

染色
体系		 Na2SO4
质量
浓度		 R2 qe,exp k2 qe,cal t1/2
皮克林
乳液体系		 40 1.000 00 19.23 0.260 19.29 0.20
60 0.999 99 19.36 0.289 19.41 0.18
80 0.999 99 19.57 0.409 19.60 0.12
传统
水浴体系		 40 0.999 51 9.80 0.068 13.39 1.50
60 0.999 64 12.10 0.071 12.38 1.16
80 0.999 88 13.37 0.076 10.58 0.98

Tab.5

Diffusion coefficients of Reactive Red M-3BF at different temperatures in different systems"

染色体系 温度/℃ D×1016/(m2·s-1)
皮克林
乳液体系		 40 3.475
60 4.782
80 6.419
传统
水浴体系		 40 2.546
60 4.081
80 5.775
[1] 宋心远. 纺织品生态染色和染色新技术[J]. 染料与染色, 2003(2):80-82.
SONG Xinyuan. New technology of textile ecological dyeing[J]. Dyes & Dyeing, 2003(2):80-82.
[2] 韩莹莹, 孙丽静, 钟毅, 等. 活性染料Pickering乳液非均相浸渍染色[J]. 纺织学报, 2017,38(11):79-83.
HAN Yingying, SUN Lijing, ZHONG Yi, et al. Heterogeneous exhausting dyeing of cotton fabrics with reactive dye in Pickering emulsion[J]. Journal of Textile Research, 2017,38(11):79-83.
[3] 宋心远, 沈煜如. 生态纺织品染整工程概述:三[J]. 印染, 1999(11):45-48.
SONG Xinyuan, SHEN Yuru. Overview of ecological textile dyeing and finishing engineering: III[J]. China Dyeing & Finishing, 1999(11):45-48.
[4] 张永金, 张波兰, 宋心远. 非水染色研究进展[J]. 印染, 2003(S1):34-35.
ZHANG Yongjin, ZHANG Bolan, SONG Xinyuan. Progress in non-aqueous dyeing research[J]. China Dyeing & Finishing, 2003(S1):34-35.
[5] 张庆富, 杨文芳. 超临界CO2的应用技术及发展现状[J]. 毛纺科技, 2011,39(8):48-54.
ZHANG Qingfu, YANG Wenfang. Development and application of supercritical CO2[J]. Wool Textile Journal, 2011,39(8):48-54.
[6] 何源, 邢建伟, 徐成书. 纺织纤维超临界二氧化碳染色研究进展[J]. 印染, 2013,39(10):51-54.
HE Yuan, XING Jianwei, XU Chengshu. Progress in supercritical carbon dioxide dyeing of textiles[J]. China Dyeing & Finishing, 2013,39(10):51-54.
[7] 李艳玲, 董永春, 易世雄, 等. 反胶束技术在染整加工中的应用进展[J]. 印染, 2014,40(11):48-53.
LI Yanling, DONG Yongchun, YI Shixiong, et al. Progress on reversed micelle technology in wet processing of textiles[J]. China Dyeing & Finishing, 2014,40(11):48-53.
[8] 周君, 乔秀颖, 孙康. Pickering乳液的制备和应用研究进展[J]. 化学通报, 2012,75(2):99-105.
ZHOU Jun, QIAO Xiuying, SUN Kang. Advance in the investigations of the preparation and application of Pickering emulsion[J]. Chemistry, 2012,75(2):99-105.
[9] 孙丽静, 张莹莹, 钟毅, 等. 苯甲醚介质活性染料皮克林乳液染色[J]. 印染, 2018(7):1-5.
SUN Lijing, ZHANG Yingying, ZHONG Yi, et al. Pickering emulsion dyeing of cotton fabrics with reactive dyes in anisole medium[J]. China Dyeing & Finishing, 2018(7):1-5.
[10] 金咸穰. 染整工艺实验 [M]. 北京: 中国纺织出版社, 1987: 1-20.
JIN Xianyu. Dyeing and finishing process exper-iment [M]. Beijing: China Textile & Apparel Press, 1987: 1-20.
[11] 张莹莹, 钟毅, 张凯, 等. 纯棉筒子纱皮克林乳液染色[J]. 印染, 2018,44(15):1-6.
ZHANG Yingying, ZHONG Yi, ZHANG Kai, et al. Pickering emulsion dyeing process of cotton cheese yarn[J]. China Dyeing & Finishing, 2018,44(15):1-6.
[12] 赵涛. 染整工艺与原理 [M]. 北京: 中国纺织出版社, 2009: 1-10.
ZHAO Tao. Dyeing and finishing process and prin-ciple [M]. Beijing: China Textile & Apparel Press, 2009: 1-10.
[13] SUN Qingye, YANG Linzhang. The adsorption of basic dyes from aqueous solution on modified peat-resin particle[J]. Water Research, 2003,37(7):1535-1544.
pmid: 12600381
[14] 缪华丽, 李永强, 付承臣, 等. 棉织物的活性染料/D5悬浮体系染色动力学研究[J]. 纺织学报, 2013,34(5):76-81.
MIAO Huali, LI Yongqiang, FU Chengchen, et al. Dyeing kinetics study of reactive dye on cotton in dye / D5 suspending system[J]. Journal of Textile Research, 2013,34(5):76-81.
[15] 张鸿志, 王祥荣. Outlast空调纤维活性染料染色动力学研究[J]. 印染助剂, 2016,33(6):19-22.
ZHANG Hongzhi, WANG Xiangrong. Dyeing kinetics of Outlast air conditioning fiber with reactive dyes[J]. Textile Auxiliaries, 2016,33(6):19-22.
[16] 赵海凤, 汪澜, 林俊雄. 超声波对棉织物活性染料染色的作用机制[J]. 纺织学报, 2009,30(3):62-66.
ZHAO Haifeng, WANG Lan, LIN Junxiong. Mechanism of ultrasonic dyeing on cotton fabric with reactive dye[J]. Journal of Textile Research, 2009,30(3):62-66.
[17] 蔡金芳, 陈维国, 崔志华, 等. 双亚芴基醌式噻吩染料对棉织物的染色性能[J]. 纺织学报, 2018,39(10):81-85.
CAI Jinfang, CHEN Weiguo, CUI Zhihua, et al. Dyeing properties of difluorenylidene quinoidal thiophene dye on cotton fabric[J]. Journal of Textile Research, 2018,39(10):81-85.
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