沿管扩散气溶胶的一些流动相关特性的演变

IF 3.9 3区 环境科学与生态学 Q2 ENGINEERING, CHEMICAL
M. Alonso
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引用次数: 0

摘要

本文是关于浸没在层流流体中的布朗气溶胶粒子行为的系列论文之三。粒子径向位置(RPD)、粒子停留时间(RTD)和粒子平均轴向速度(MAVD)的分布沿管的演变是通过粒子轨迹的蒙特卡罗(MC)模拟确定的。RPD 和粒子穿透力也是通过可忽略粒子轴向扩散的平流扩散方程(ADE)数值求解确定的。这两种方法得出的结果显示出相当好的一致性,这证明我们有信心使用 MC 技术来确定 MAVD 和 RTD 等其他粒子特性,因为这些特性的相应微分方程尚不清楚。气溶胶的流动相关特性(如穿透力和停留时间)主要由其 MAVD 决定。MAVD与RPD密切相关;RPD的变化方式使存活颗粒倾向于聚集在靠近管轴线的地方,而远离管壁。当流体的局部速度取决于空间位置时,颗粒的平均轴向速度会随着气溶胶流向管的下游而增加,尽管颗粒上没有外力作用,但其值可能比流体的平均速度大得多。这一违背直觉的事实的直接后果是,即使颗粒扩散系数的值适中,气溶胶在管道中的平均停留时间也会比流体的平均停留时间小得多,小于 0.65 倍。气溶胶平均停留时间的这个渐近值可以通过 ADE 结合本文提出的一个简单估算模型来预测。如果管内流体速度恒定(匀速或塞流),则颗粒的平均轴向速度在任何地方都等于流体速度,颗粒和流体在管内停留的时间相同。流体速度曲线偏离均匀性的程度越大,颗粒和流体之间的平均轴向速度和平均停留时间的差值就越大。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evolution of some flow-related properties of diffusive aerosols along a tube

This is the third of a series of papers dealing with the behavior of Brownian aerosol particles immersed in a laminar fluid flow. The evolution along the tube of the distributions of particle radial positions (RPD), particle residence time (RTD), and particle mean axial velocity (MAVD) were determined by Monte Carlo (MC) simulation of particles trajectories. The RPD and particle penetration was also determined by numerical solution of the advection-diffusion equation (ADE) with negligible particle axial diffusion. The fairly good agreement shown between the results obtained by these two methods justifies our confidence on the use of the MC technique to determine other particle properties, as MAVD and RTD, for which the corresponding differential equation is yet unknown. Flow-related properties of the aerosol, such as penetration and residence time, are mainly determined by its MAVD. The MAVD is intimately related to the RPD; the latter evolves in such a manner that the surviving particles tend to accumulate nearer the tube axis and farther from the wall. When the fluid local velocity depends on the spatial location, the mean particle axial velocity increases as the aerosol flows downstream the tube, and its value can be considerably larger than the mean fluid velocity, in spite that no external force is acting on the particle. A direct consequence of this counterintuitive fact is that the mean aerosol residence time in the tube can be much smaller, by a factor of ∼0.65, than that of the fluid for even moderate values of the particle diffusion coefficient. This asymptotic value of the aerosol mean residence time can be predicted using the ADE in conjunction with a simple estimation model proposed here. If the fluid velocity is constant within the tube (uniform or plug flow), the mean particle axial velocity is everywhere equal to the fluid velocity, and particles and fluid spend the same time to traverse the tube. The larger the departure of the fluid velocity profile from uniformity, the larger the difference of mean axial velocity and mean residence time between particles and fluid.

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来源期刊
Journal of Aerosol Science
Journal of Aerosol Science 环境科学-工程:化工
CiteScore
8.80
自引率
8.90%
发文量
127
审稿时长
35 days
期刊介绍: Founded in 1970, the Journal of Aerosol Science considers itself the prime vehicle for the publication of original work as well as reviews related to fundamental and applied aerosol research, as well as aerosol instrumentation. Its content is directed at scientists working in engineering disciplines, as well as physics, chemistry, and environmental sciences. The editors welcome submissions of papers describing recent experimental, numerical, and theoretical research related to the following topics: 1. Fundamental Aerosol Science. 2. Applied Aerosol Science. 3. Instrumentation & Measurement Methods.
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