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过程工程学报 ›› 2020, Vol. 20 ›› Issue (12): 1448-1454.DOI: 10.12034/j.issn.1009-606X.219369

• 过程与工艺 • 上一篇    下一篇

煤与高岭石表面性质对凝聚过程的影响机制

王茜茜, 黄 元, 孙 月, 石梦云, 牛安然, 林 喆*   

  1. 中国矿业大学化工学院,江苏 徐州 221116
  • 收稿日期:2019-12-11 修回日期:2020-03-08 出版日期:2020-12-22 发布日期:2020-12-22
  • 通讯作者: 林喆 z.lin@cumt.edu.cn
  • 基金资助:
    Magnéli相亚氧化钛的可控制备、微结构与性能基础研究

Influence mechanism of surface properties of coal and kaolinite on coagulation process

Xixi WANG, Yuan HUANG, Yue SUN, Mengyun SHI, Anran NIU, Zhe LIN*   

  1. School of Chemical Engineering and Technology, China University of Mining and Technology, Xuzhou, Jiangsu 221116, China
  • Received:2019-12-11 Revised:2020-03-08 Online:2020-12-22 Published:2020-12-22

摘要: 煤泥水中含大量高岭石等黏土矿物,为其絮凝沉降带来较大的困难。为明确矿物性质对凝聚过程的影响机制,在应用扩展的DLVO理论计算煤和高岭石颗粒间作用力的基础上,采用聚焦光束反射测量仪监测了CaCl2用量为4.50 mmol/L时20 g/L的煤和高岭石的悬浮液在60, 100和150 r/min的搅拌转速下的凝聚过程。结果表明,颗粒间的静电作用力在颗粒表面间距2?200 nm范围内起主导作用,高岭石的电负性较大,在凝聚过程中更难发生靠近和碰撞;较高的转速可为颗粒提供较大的动量,有利于提高碰撞频率,缩短完成凝聚所需时间,实验条件下,煤和高岭石的凝聚时间分别由74和123 s缩短至47和89 s。疏水性作用力在颗粒表面间距小于2 nm的范围内起主导作用,决定了颗粒的黏附效率;煤因强疏水性,在碰撞后更易黏附,且能抵抗更高的流体剪切作用,可由19.32 μm凝聚形成100 μm的大凝聚体,而高岭石则因其亲水性难以得到较大粒度的凝聚体,均小于30 μm。

关键词: 煤, 高岭石, 凝聚, XDLVO, 聚焦光束反射测量仪

Abstract: Coal slime water contains a large amount of clay minerals such as kaolinite, which brings great difficulties for flocculation and sedimentation. In order to clarify the influence mechanism of these mineral properties on the coagulation process, the interaction between the particles of coal or kaolinite were calculated by the extended DLVO theory, and the coagulation process of 20 g/L coal and kaolinite suspension with a CaCl2 dosage of 4.5 mmol/L was monitored by a focused beam reflectometer at the stirring speeds of 60, 100 and 150 r/min. The results showed that the electrostatic interaction played a dominant role in the range of 2?200 nm for particle surface distance. The kaolinite particles had larger electronegativity, so it was more difficult to approach to and collide to each other during the coagulation process. The higher rotation speed increased the momentum of particles and was beneficial to increase the collision frequency and shorten the time required to complete the coagulation. Under the experimental conditions, the coagulation times of coal and kaolinite were shortened from 74 and 123 s to 47 and 89 s, respectively. The hydrophobic force played a leading role in the range of particle spacing less than 2 nm, which determined the adhesion efficiency of the particles. With strong hydrophobic surface, coal particles were easier to adhere to each other after collision, and can resist higher fluid shearing action. As the result, coal particles can agglomerate to form large agglomerates of 100 μm from its initial size of 19.32 μm, while kaolinite was difficult to obtain agglomerates larger than 30 μm due to their hydrophilicity.

Key words: coal, kaolinite, coagulation, XDLVO, focused beam reflectance measurement