Deposition of aerosol particles and characteristics of turbulent flow inside wavy pipe using Eulerian-Lagrangian approach

IF 3.8 3区 工程技术 Q3 ENERGY & FUELS
Farzana Akter, Sumon Saha
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引用次数: 0

Abstract

This paper demonstrates a numerical simulation study to understand particle deposition phenomena in wavy pipe configurations comprehensively. The research investigates the intricate dynamics of particle deposition within wavy pipes by utilizing the RNG k-ε turbulence model with enhanced wall treatment for fluid flow simulation and employing a Lagrangian particle tracking model. The finite volume approach is adopted to solve the mathematical model of the current problem. The rate of aerosol particle deposition within a wavy pipe under turbulent flow conditions is systematically explored by varying the size of particles (1 ≤ dp (μm) ≤ 30), Reynolds numbers (5000 ≤ Re ≤ 10,000), and other parameters like wave frequency (3 ≤ f ≤ 7), wave amplitude (5 ≤ a (mm) ≤ 15), and diameter of the pipe (10 ≤ D (mm) ≤ 30). The findings reveal significant correlations between these parameters and deposition efficiency, shedding light on the complex interplay between geometric factors and flow characteristics within the wavy pipe configurations. Notably, larger pipe diameters and higher wave amplitudes are found to enhance deposition rates, while the optimal wave frequencies exist at intermediate values. Additionally, alterations in flow velocity exhibit an inverse relationship with deposition efficiency.

Abstract Image

利用欧拉-拉格朗日方法分析气溶胶颗粒的沉积和波浪形管道内湍流的特征
本文展示了一项数值模拟研究,旨在全面了解波浪形管道构型中的颗粒沉积现象。研究利用增强壁面处理的 RNG k-ε 湍流模型进行流体流动模拟,并采用拉格朗日粒子跟踪模型,研究了波浪形管道内粒子沉积的复杂动力学过程。采用有限体积法求解当前问题的数学模型。通过改变颗粒尺寸(1≤dp(μm)≤30)、雷诺数(5000≤Re≤10000)以及波频(3≤f≤7)、波幅(5≤a(mm)≤15)和管道直径(10≤D(mm)≤30)等参数,系统地探讨了湍流条件下气溶胶颗粒在波浪形管道内的沉积速率。研究结果揭示了这些参数与沉积效率之间的重要关联,揭示了波浪形管道配置中几何因素与流动特性之间复杂的相互作用。值得注意的是,较大的管道直径和较高的波幅可提高沉积率,而最佳波频存在于中间值。此外,流速的变化与沉积效率呈反比关系。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.80
自引率
9.30%
发文量
408
审稿时长
49 days
期刊介绍: Chemical Engineering and Processing: Process Intensification is intended for practicing researchers in industry and academia, working in the field of Process Engineering and related to the subject of Process Intensification.Articles published in the Journal demonstrate how novel discoveries, developments and theories in the field of Process Engineering and in particular Process Intensification may be used for analysis and design of innovative equipment and processing methods with substantially improved sustainability, efficiency and environmental performance.
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