An experimental study on size distribution and zeta potential of bulk cavitation nanobubbles 被引量：15

An experimental study on size distribution and zeta potential of bulk cavitation nanobubbles

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摘要 Nanobubble flotation technology is an important research topic in the field of fine mineral particle separation.The basic characteristics of nanobubbles,including their size,concentration,surface zeta potential,and stability have a significant impact on the nanobubble flotation performance.In this paper,bulk nanobubbles generated based on the principle of hydrodynamic cavitation were investigated to determine the effects of different parameters(e.g.,surfactant(frother)dosage,air flow,air pressure,liquid flow rate,and solution pH value)on their size distribution and zeta potential,as measured using a nanoparticle analyzer.The results demonstrated that the nanobubble size decreased with increasing pH value,surfactant concentration,and cavitation-tube liquid flow rate but increased with increasing air pressure and increasing air flow rate.The magnitude of the negative surface charge of the nanobubbles was positively correlated with the pH value,and a certain relationship was observed between the zeta potential of the nanobubbles and their size.The structural parameters of the cavitation tube also strongly affected the characteristics of the nanobubbles.The results of this study offer certain guidance for optimizing the nanobubble flotation technology. Nanobubble flotation technology is an important research topic in the field of fine mineral particle separation. The basic characteristics of nanobubbles, including their size, concentration, surface zeta potential, and stability have a significant impact on the nanobubble flotation performance. In this paper, bulk nanobubbles generated based on the principle of hydrodynamic cavitation were investigated to determine the effects of different parameters(e.g., surfactant(frother) dosage, air flow, air pressure, liquid flow rate, and solution pH value) on their size distribution and zeta potential, as measured using a nanoparticle analyzer. The results demonstrated that the nanobubble size decreased with increasing pH value,surfactant concentration, and cavitation-tube liquid flow rate but increased with increasing air pressure and increasing air flow rate. The magnitude of the negative surface charge of the nanobubbles was positively correlated with the pH value, and a certain relationship was observed between the zeta potential of the nanobubbles and their size. The structural parameters of the cavitation tube also strongly affected the characteristics of the nanobubbles. The results of this study offer certain guidance for optimizing the nanobubble flotation technology.

作者 Xu-yu Zhang Qian-shuai Wang Zhong-xian Wu Dong-ping Tao

机构地区 School of Mining Engineering School of Resources and Environmental Engineering

出处《International Journal of Minerals,Metallurgy and Materials》 SCIE EI CAS CSCD 2020年第2期152-161,共10页 矿物冶金与材料学报（英文版）

关键词 NANOBUBBLE hydrodynamic cavitation zeta potential size distribution nanobubble hydrodynamic cavitation zeta potential size distribution

分类号 TB383.1 [一般工业技术—材料科学与工程]

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International Journal of Minerals,Metallurgy and Materials

2020年第2期

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