We have developed a new experimental technique to measure the Lagrangian velocity of tracer particles in a turbulent flow, based on ultrasonic Doppler tracking. This method yields a direct access to the velocity of a single particule at a turbulent Reynolds number R{sub}λ = 1200. Its dynamics is analyzed with two decades of time resolution, below the Lagrangian correlation time. We observe that the Lagrangian velocity spectrum has a Lorentz form E{sup}L(ω) = u{sub}(rms){sup}2 T{sub}L/(1 + (T{sub}Lω){sup}2), in agreement with a Kolmogorov-like scaling in the inertial range. The probability density function (PDF) of the velocity time increments displays a change of shape from quasi-Gaussian a integral time scale to stretched exponential tails at the smallest time increments. This intermittency, when measured from relative scaling exponents of structure functions, is more pronounced than in the Eulerian framework.
展开▼
机译:基于超声多普勒跟踪,我们开发了一种新的实验技术来测量湍流中示踪剂颗粒的拉格朗日速度。该方法在湍流雷诺数R {Sub}λ= 1200处直接进入单个分粒的速度。通过低于拉格朗日相关时间,通过两十年来分析其动力学。我们观察到拉格朗日速度谱具有Lorentz形式E {sup} L(ω)= u {sub}(rms){sup} 2 t {sub} l /(1 +(t {sub}lω){sup} 2),与惯性范围内的Kolmogorov样缩放相一致。速度时间增量的概率密度函数(PDF)显示从准高斯的形状的变化,以便以最小的时间增量拉伸指数尾部。当从结构函数的相对缩放指数测量时,这种间歇性比在欧拉架上更加明显。
展开▼
