RATES OF CAPTURE OF SMALL PARTICLES IN FLOTATION.

被引:0
|
作者
Anfruns, J.F.
Kitchener, J.A.
机构
来源
Transactions of the Institution of Mining and Metallurgy, Section C: Mineral Processing and Extractive Metallurgy | 1977年 / 86卷
关键词
QUARTZ;
D O I
暂无
中图分类号
学科分类号
摘要
The absolute rate of flotation was determined by a new experimental technique that depends on allowing single bubbles to rise through a very dilute suspension of particles. Measurements were made of the rate of capture of particles 10 - 50 mu m in diameter by bubbles 0. 5 - 1. 0 mm in diameter. The particles comprised narrow-range fractions of quartz or spherical glass micro-beads, all previously rendered strongly hydrophobic by surface methylation. It was concluded that angularity or roughness of quartz particles ensures easy rupture of the wetting film, even when the barrier is strengthened by addition of low concentrations of surfactant or when the contact angle is reduced from 87 degree to 30 degree .
引用
收藏
相关论文
共 50 条
  • [21] USE OF CHEMICAL REAGENTS IN FLOTATION.
    Klimpel, Richard R.
    Chemical Engineering (New York), 1984, 91 (18): : 75 - 79
  • [22] RATE LIMITATIONS IN FROTH FLOTATION.
    Meyer, W.C.
    Klimpel, R.R.
    Transactions of the American Institute of Mining, Metallurgical, and Petroleum Engineers, Society, 1983, 274 : 1852 - 1858
  • [23] Some notes on the carbon flotation.
    Wolf, K
    JOURNAL FUR PRAKTISCHE CHEMIE-LEIPZIG, 1922, 105 (1/6): : 39 - 49
  • [24] Effect of capillary pressure in nanobubbles on their adhesion to particles under foam flotation. Part 3
    Melik-Gaikazyan, V. I.
    Emel'yanova, N. P.
    Dolzhenkov, D. V.
    RUSSIAN JOURNAL OF NON-FERROUS METALS, 2014, 55 (04) : 309 - 317
  • [25] Experimental determination of particles capture efficiency in flotation
    Sarrot, V.
    Huang, Z.
    Legendre, D.
    Guiraud, P.
    CHEMICAL ENGINEERING SCIENCE, 2007, 62 (24) : 7359 - 7369
  • [26] USE OF OZONE IN IRON ORE FLOTATION.
    Iwasaki, I.
    Malicsi, A.S.
    Transactions of the American Institute of Mining, Metallurgical, and Petroleum Engineers, Society, 1985, 278 : 104 - 105
  • [27] ALTERNATIVE CONTROL STRATEGIES FOR COAL FLOTATION.
    Herbst, J.A.
    Bascur, O.A.
    Minerals and Metallurgical Processing, 1985, 2 (01): : 1 - 9
  • [28] Column flotation. The South African experience
    Franzidis, J.-P.
    Harris, M.C.
    O'Connor, C.T.
    Evaluation and Optimization of Metallurgical Performance, 1991, : 259 - 291
  • [29] STRUCTURE AND PROPERTY OF ORGANIC DEPRESSANT IN FLOTATION.
    Wang Dianzuo
    Bai Shibin
    Yu Se Chin Shu/Nonferrous Metals, 1983, 35 (02): : 47 - 54
  • [30] Separation of Molybdenum and Tungsten by Ionic Flotation.
    Skrylev, L.D.
    Pavlenko, S.N.
    Sazonova, V.F.
    Izvestiya Vysshikh Uchebnykh Zavedenij. Tsvetnaya Metallurgiya, 1986, (01): : 28 - 32
12345