A Nusselt number correlation for a superhydrophobic solid sphere encapsulated in a perfect plastron

IF 1.4 4区工程技术 Q2 ENGINEERING, MULTIDISCIPLINARY

Journal of Engineering Mathematics Pub Date : 2024-06-22 DOI:10.1007/s10665-024-10377-9

Zavier Berti, M. R. Flynn

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Abstract

Surface-attached air bubbles are known to provide lubricating (i.e., drag reducing) benefits but their contribution to inhibiting heat transfer is not as well understood. The present theoretical study considers Stokes flow around a solid sphere and uses matched asymptotic expansions to estimate the degree of thermal insulation offered by an encapsulating air layer of uniform thickness. Key to our analysis is to derive an expression for the Nusselt number in terms of the air layer thickness and the Péclet number, \(\text{ Pe}_w\), of the surrounding liquid, here assumed to be water. This latter parameter, which characterizes advective to diffusive heat transport, is assumed to be small such that our zeroth- and first-order solutions are, respectively, proportional to \(\text{ Pe}_w^0\) and \(\text{ Pe}_w^1\). Although small \(\text{ Pe}_w\) favors small free stream velocities, forced convection will dominate over natural convection only if the free stream velocity (and/or the solid sphere radius) exceeds a certain threshold. This requirement constrains the solution space; on the other hand, it is straightforward to generalize our analysis so that it considers fluid pairs other than water and air.

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封装在完美质体中的超疏水性固体球体的努塞尔特数相关性

众所周知，表面附着的气泡具有润滑（即减少阻力）的作用，但它们对抑制热传递的作用却不甚了解。本理论研究考虑了固体球体周围的斯托克斯流，并使用匹配的渐近展开来估算厚度均匀的封装空气层所提供的隔热程度。我们分析的关键是根据空气层厚度和周围液体（此处假定为水）的佩克莱特数（\(\text{ Pe}_w\) ）推导出努塞尔特数的表达式。后一个参数表征了从平流到扩散的热传输，我们假设它很小，这样我们的零阶和一阶求解分别与 \(\text{ Pe}_w^0\) 和 \(\text{ Pe}_w^1\) 成比例。虽然小的 \(\text{ Pe}_w\) 有利于小的自由流速度，但只有当自由流速度（和/或实心球半径）超过某个临界值时，强制对流才会比自然对流占优势。这一要求限制了求解空间；另一方面，将我们的分析推广到考虑水和空气以外的流体对也很简单。

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 Engineering Mathematics 工程技术-工程：综合

CiteScore

2.10

自引率

7.70%

发文量

审稿时长

6 months

期刊介绍： The aim of this journal is to promote the application of mathematics to problems from engineering and the applied sciences. It also aims to emphasize the intrinsic unity, through mathematics, of the fundamental problems of applied and engineering science. The scope of the journal includes the following: • Mathematics: Ordinary and partial differential equations, Integral equations, Asymptotics, Variational and functional−analytic methods, Numerical analysis, Computational methods. • Applied Fields: Continuum mechanics, Stability theory, Wave propagation, Diffusion, Heat and mass transfer, Free−boundary problems; Fluid mechanics: Aero− and hydrodynamics, Boundary layers, Shock waves, Fluid machinery, Fluid−structure interactions, Convection, Combustion, Acoustics, Multi−phase flows, Transition and turbulence, Creeping flow, Rheology, Porous−media flows, Ocean engineering, Atmospheric engineering, Non-Newtonian flows, Ship hydrodynamics; Solid mechanics: Elasticity, Classical mechanics, Nonlinear mechanics, Vibrations, Plates and shells, Fracture mechanics; Biomedical engineering, Geophysical engineering, Reaction−diffusion problems; and related areas. The Journal also publishes occasional invited ''Perspectives'' articles by distinguished researchers reviewing and bringing their authoritative overview to recent developments in topics of current interest in their area of expertise. Authors wishing to suggest topics for such articles should contact the Editors-in-Chief directly. Prospective authors are encouraged to consult recent issues of the journal in order to judge whether or not their manuscript is consistent with the style and content of published papers.