工程纳米材料颗粒物气溶胶制备方法研究进展

doi:10.6040/j.issn.1672-3961.0.2022.009

Abstract

Abstract:

With the development of nanotechnology and biochemistry, higher requirements were put forward for the particle size and manufacturing process of micro particles. Aerosol, as a common engineering nano material particle, was widely used in all walks of life. The research progress of common aerosol preparation methods, which starts from the aerosol preparation methods and systematically based on a large number of relevant literatures, the applicable scenarios of different aerosol preparation methods, the application requirements were summarized of different aerosol preparation methods were defined, the advantages and disadvantages of were compared and analyzed different aerosol preparation methods. On this basis, the optimization and improvement of various methods by domestic and foreign scholars in different periods were further ummarized, and the experimental and research results of domestic and foreign scholars were deeply analyzed, and the application of supercritical fluid technology in aerosol preparation was analyzed and prospected.

Key words: engineering nano materials, aerosol, aerosol preparation, supercritical fluid technology, high voltage electrostatic atomization

CLC Number:

X513

Hui HU, Ningye TANG, Siyu WANG, Haisen WANG. Research progress on preparation methods of engineering nano material particle aerosol[J].Journal of Shandong University(Engineering Science), 2022, 52(4): 1-11.

Figures/Tables 13

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Table 1

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方法	粒径	应用范围	优点	缺点
流化床法	纳米级	固体、液体、气体	应用范围广, 操作简单	粒径大小难以控制且不均匀
雾化法	纳米级	少部分能够溶解于液体的材料	制备工艺高	材料要求高, 应用范围小
凝集法	纳米级	容易发生物理化学反应的固体材料	制备工艺高	材料要求高, 发生器结构复杂, 操作繁琐
高压静电雾化	纳米级	液体和少部分能够溶解于液体的材料	胶粒径小, 分布均匀	质量浓度低, 不能长时间制备
超临界流体雾化	纳米级	液体	粒径分布均匀、制造过程便捷、适用范围广	对试验装置要求较高

Research progress on preparation methods of engineering nano material particle aerosol

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