Effect Of Power-Law Fluids Flow Structures On Germicides Disinfection Through Taylor-Couette Configuration

IF 1.8 3区工程技术 Q3 ENGINEERING, MECHANICAL

Journal of Fluids Engineering-Transactions of the Asme Pub Date : 2023-10-21 DOI:10.1115/1.4063851

Feriel Hasballaoui, Samir Khali, Rachid Nebbali, Abderrahmane Zidane

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引用次数: 0

Abstract

Abstract Fluid disinfection involving ultraviolet rays (UV) is a promising method due to its easy implementation and low cost compared to other methods. In the present work, fluid disinfection in a Taylor-Couette configuration operating with power-law fluids with different absorbance coefficients,and fluence rates were simulated using the Lattice Boltzmann Method. The effects of operating parameters such as Taylor and axial Reynolds numbers, power-law index behavior, and fluence rate were analyzed. Results show that the required UV dose decreases for an increase in absorbance coefficient, while it grows for increasing power-law indexes. For T a = 120 and Re = 3, the disinfection reaches 82.3% for pseudo-plastic fluids and is complete for dilatant fluids. Considering different absorbance coefficients, it was observed that a = 0.4 leads to complete disinfection regardless of the fluid. For a = 0.5, fluid disinfection is complete for the dilatant fluid only. A value of 0.6 leads to partial disinfection (~90%) for all fluids.

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幂律流体流动结构对Taylor-Couette构型杀菌消毒的影响

摘要与其他方法相比，采用紫外线(UV)进行液体消毒具有操作简单、成本低等优点，是一种很有前途的方法。在本工作中，使用格子玻尔兹曼方法模拟了具有不同吸光度系数和通量率的幂律流体在Taylor-Couette配置中的流体消毒。分析了泰勒雷诺数、轴向雷诺数、幂律折射率行为和流量等操作参数的影响。结果表明，随着吸光度系数的增加，所需紫外线剂量减小，而随着幂律指数的增加，所需紫外线剂量增大。当t_a = 120, Re = 3时，拟塑性流体消毒效果达到82.3%，膨胀流体消毒效果完全。考虑不同吸光度系数，无论采用何种液体，a = 0.4均可达到完全消毒。当a = 0.5时，仅对膨胀液消毒完成。值为0.6导致所有液体部分消毒(~90%)。

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

Journal of Fluids Engineering-Transactions of the Asme 工程技术-工程：机械

CiteScore

4.60

自引率

10.00%

发文量

165

审稿时长

5.0 months

期刊介绍： Multiphase flows; Pumps; Aerodynamics; Boundary layers; Bubbly flows; Cavitation; Compressible flows; Convective heat/mass transfer as it is affected by fluid flow; Duct and pipe flows; Free shear layers; Flows in biological systems; Fluid-structure interaction; Fluid transients and wave motion; Jets; Naval hydrodynamics; Sprays; Stability and transition; Turbulence wakes microfluidics and other fundamental/applied fluid mechanical phenomena and processes