The Role of Particle Inertia and Thermal Inertia in Heat Transfer in a Non-Isothermal Particle-Laden Turbulent Flow

IF 1.8 Q3 MECHANICS Fluids Pub Date : 2024-01-19 DOI:10.3390/fluids9010029
Hamid Reza Zandi Pour, Michele Iovieno
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Abstract

We present an analysis of the effect of particle inertia and thermal inertia on the heat transfer in a turbulent shearless flow, where an inhomogeneous passive temperature field is advected along with inertial point particles by a homogeneous isotropic velocity field. Eulerian–Lagrangian direct numerical simulations are carried out in both one- and two-way coupling regimes and analyzed through single-point statistics. The role of particle inertia and thermal inertia is discussed by introducing a new decomposition of particle second-order moments in terms of correlations involving Lagrangian acceleration and time derivative of particles. We present how particle relaxation times mediate the level of particle velocity–temperature correlation, which gives particle contribution to the overall heat transfer. For each thermal Stokes number, a critical Stokes number is individuated. The effect of particle feedback on the attenuation or enhancement of fluid temperature variance is presented. We show that particle feedback enhances fluid temperature variance for Stokes numbers less than one and damps is for larger than one Stokes number, regardless of the thermal Stokes number, even if this effect is amplified by an increasing thermal inertia.
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粒子惯性和热惯性在非等温粒子湍流传热中的作用
我们分析了粒子惯性和热惯性对无剪切力湍流中传热的影响,在该湍流中,非均质被动温度场与惯性点粒子一起被均质各向同性速度场平流。在单向和双向耦合状态下进行了欧拉-拉格朗日直接数值模拟,并通过单点统计进行了分析。通过引入涉及拉格朗日加速度和粒子时间导数的相关性的粒子二阶矩的新分解,讨论了粒子惯性和热惯性的作用。我们介绍了粒子弛豫时间如何介导粒子速度-温度相关性水平,从而得出粒子对整体热传递的贡献。对于每种热斯托克斯数,都有一个临界斯托克斯数。本文介绍了粒子反馈对衰减或增强流体温度变化的影响。我们表明,无论热斯托克斯数如何,当斯托克斯数小于 1 时,粒子反馈会增强流体温度变化,而当斯托克斯数大于 1 时,粒子反馈则会减弱流体温度变化,即使这种效应会因热惰性的增加而放大。
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来源期刊
Fluids
Fluids Engineering-Mechanical Engineering
CiteScore
3.40
自引率
10.50%
发文量
326
审稿时长
12 weeks
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