Fe3O4-PAC 复合药剂强化煤炭与高岭土沉降特性差异的规律研究

doi:10. 11799/ ce202512027

摘要/Abstract

摘要：

选择性絮凝浮选、选选择性油团聚浮选、选择性絮凝—重力分选—浮选等技术是解决难选煤泥提质难的新思路，其关键在于扩大微细黏土矿物与煤炭颗粒絮体的粒径差异。选取对高岭土和煤炭颗粒具有一定选择性的聚合氯化铝（PAC）为研究对象，对比了溶胶凝胶法和溶剂热法制得的Fe₃O₄-PAC复合药剂形貌特征，及其对高岭土和煤炭颗粒的絮凝效果，进而研究了Fe₃O₄和PAC质量配比下复合药剂对煤与高岭土沉降特性差异的影响规律。结果表明：PAC对高岭土絮凝具有一定选择性，在高岭土溶液浓度为3%时絮体沉降速度最快。溶剂热法制得的Fe3O4颗粒粒径均一，且粒径小于共沉淀法制得的Fe₃O₄颗粒；沉淀法和溶剂热法均能制备出Fe₃O₄-PAC复合药剂，在试验浓度范围内对煤炭和高岭土依然具有选择性，但药剂用量增加，且采用溶剂热法制备的复合药剂在高岭土絮体沉降速度和溶液上清液透光度上表现更优；Fe₃O₄-PAC复合药剂制备过程中，随着Fe₃O₄占比增高，复合药剂表面负载的Fe₃O₄颗粒增多，复合药剂中含铁量越多，对高岭土的絮凝作用越明显，高岭土絮体沉降速度加快，但出现明显分界面所需药剂浓度也增多。

关键词: Fe₃O₄ -PAC, 煤泥水, 高岭土, 沉降特性差异, 絮凝

Abstract:

Selective flocculation flotation, selective oil agglomeration flotation, selective flocculation - gravity separation - flotation and other technologies are new ideas for solving refractory coal slime. The key lies in expanding the particle size difference between fine clay minerals and coal particles. The paper selects polyaluminum chloride (PAC), which has certain selectivity for kaolin and coal particles, as the research object. It explores the morphological characteristics of the Fe3O4 - PAC composite agent prepared by the sol - gel method and the solvothermal method, as well as its selective flocculation effects on kaolin and coal particles. Furthermore, it studies the influence law of the mass ratio of Fe3O4 and PAC in the composite agent on the difference in sedimentation characteristics between coal and kaolinite. The results show that PAC has selectivity for the flocculation of kaolin, and the best effect is achieved when its concentration is 3%. In the preparation of Fe3O4 particles, the solvothermal method is superior to the coprecipitation method. The Fe3O4 particles prepared by the solvothermal method are uniformly spherical with a small particle size. Both the precipitation method and the solvothermal method can prepare the Fe3O4 - PAC composite agent, and the one prepared by the solvothermal method performs better in terms of floc sedimentation rate and the transmittance of the supernatant of the solution. With the increase of the proportion of Fe3O4 in the composite agent, the sedimentation rate of kaolin flocs accelerates, but the amount of the agent required to form an obvious interface also increases.

中图分类号:

TD94

原　峰, 叶贵川, 董宪姝, 郭睿凤, 樊玉萍, 张晋榜, 方文杰. Fe₃O₄-PAC 复合药剂强化煤炭与高岭土沉降特性差异的规律研究[J]. 煤炭工程, 2025, 57(12): 210-217.

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Fe₃O₄-PAC 复合药剂强化煤炭与高岭土沉降特性差异的规律研究

Study on the pattern of difference in sedimentation characteristics between coal and kaolinite enhanced by Fe₃O₄-PAC composite agent

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