Flooding Characteristics of Hydrofoil Impeller in a Two- and Three-phase Stirred Tank 被引量：2

Flooding Characteristics of Hydrofoil Impeller in a Two- and Three-phase Stirred Tank

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摘要 The flooding characteristics of hydrofoil impeller were systematically investigated in a two-and three-phase 383 mm i.d. stirred tank operated on air, water and spherical glass beads. The volumetric solid concen-tration Cs was varied from 0 to 25%. And the superficial gas velocity Ug was at the range of 0-0.096 m·s-1. A fast and objective method for identifying flooding point NF is developed based on the statistical analysis of the pressure fluctuation signals. It is found, the effect of solid concentration on the flooding point NF depends on the gas velocity. At the lower gas velocity (Ug = 0.010 m·s-1), the solid concentration has only a minor effect. However, it displays a very significant effect on the flooding point NF at the medium and high gas velocity. The flooding point NF linearly increases with the gas velocity Ug, at lower solid concentration (Cs = 0, 10%). When Cs = 20%, the behavior of NF versus Ug becomes more complex. The correlations of the flooding characteristics in the slurry stirred tank are proposed by considering the solid concentration effect. The flooding characteristics of hydrofoil impeller were systematically investigated in a two-and three-phase 383 mm i.d. stirred tank operated on air, water and spherical glass beads. The volumetric solid concen-tration Cs was varied from 0 to 25%. And the superficial gas velocity Ug was at the range of 0-0.096 m·s-1. A fast and objective method for identifying flooding point NF is developed based on the statistical analysis of the pressure fluctuation signals. It is found, the effect of solid concentration on the flooding point NF depends on the gas velocity. At the lower gas velocity （Ug = 0.010 m·s^-1）, the solid concentration has only a minor effect. However, it displays a very significant effect on the flooding point NF at the medium and high gas velocity. The flooding point NF linearly increases with the gas velocity Ug, at lower solid concentration （Cs = 0, 10%）. When Cs = 20%, the behavior of NF versus Ug becomes more complex. The correlations of the flooding characteristics in the slurry stirred tank are proposed by considering the solid concentration effect.

作者蔡清白戴干策

机构地区 State Key Laboratory of Chemical Engineering

出处《Chinese Journal of Chemical Engineering》 SCIE EI CAS CSCD 2010年第3期355-361,共7页 中国化学工程学报（英文版）

关键词 flooding point NF flooding/loading transition hydrofoil impeller power spectra analysis 搅拌槽三相叶轮固体浓度翼形特征洪水特性压力波动信号

分类号 TQ051.72 [化学工程] TM343.2 [电气工程—电机]

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