摘要
通过量纲分析和实验测量,对于垂直、局部均匀的湍流稀态液一固流中,大颗粒的相对速度,建立了无量纲参数表达式.用分析和实验相结合的方法,确定了表达式中无量纲参数的幂次及有关系数.实验中用激光多普勒分相测量技术,分别测出流体和颗粒的时均速度结果表明,大颗粒相对速度强烈依赖于流体雷诺数,当流体雷诺数较高时,其幂次渐近于1.5。
A dimensionless formula for estimating the time-mean velocity differences between fluid and large particles has been given. The Particles are suspended in a homogeneous turbulent liquid flow. and their sizes are larger than the size of the micro-eddy of the turbulent liquid flow.A comparison between the orders of the accelerations of the eddy and the gravity shows that in a flow with considerable high Reynolds number, the dynamic force of eddy is dominant and the influence of the gravity to the motion of the particles can be ignored, on the other hand, in a flow with sufficiently low Reynolds number, the gravity is dominant and the influence of the dynamic force of eddy to the motion of the particles can be ignored. By combining these two situations,it is possible to predict theoretically the general form of the dimensionless relationship between the relative Reynolds number of the large particles and the other four dimensionless numbers.In addition to the dimensional analysis, experimental measurements are provided, the coefficient and the powers of the dimensionless numbers in the formula have been determined and examined by the results of the measurements. The experiments are carried out in a pipe water flow with suspended particles, for different set of the experiments, the densities and sizes of the particles are different. Measurements of two-phase velocities in the pipe center have been made by using two phase velocity separation technique of LDV. It is shown that the relative velocity depends on the relative size of the particle to the liquid flow with a power of 1.25, and strongly depends on the Reynolds number of the fluid flow with a power approaching to 1.5 for rather high fluid flow Reynolds numbers.
出处
《力学学报》
EI
CSCD
北大核心
1999年第1期29-37,共9页
Chinese Journal of Theoretical and Applied Mechanics
基金
国家自然科学基金
关键词
液-固流
湍流
相对速度
颗粒
激光多普勒测速
liquid-solid flow, relative velocity, velocity difference turbulence, laser Dopplervelocimetry
