Superhydrophobicity Can Enhance Convective Heat Transfer in Pressure-Driven Pipe Flow

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The quarterly journal of mechanics and applied mathematics Pub Date : 2022-11-17 DOI:10.1093/qjmam/hbac016

Henry Rodriguez-Broadbent, Darren G Crowdy

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Abstract

Summary Theoretical evidence is given that it is possible for superhydrophobicity to enhance steady laminar convective heat transfer in pressure-driven flow along a circular pipe or tube with constant heat flux. Superhydrophobicity here refers to the presence of adiabatic no-shear zones in an otherwise solid no-slip boundary. Adding such adiabatic no-shear zones reduces not only hydrodynamic friction, leading to greater fluid volume fluxes for a given pressure gradient, but also reduces the solid surface area through which heat enters the fluid. This leads to a delicate trade-off between competing mechanisms so that the net effect on convective heat transfer along the pipe, as typically measured by a Nusselt number, is not obvious. Existing evidence in the literature suggests that superhydrophobicity always decreases the Nusselt number, and therefore compromises the net heat transfer. In this theoretical study, we confirm this to be generally true but, significantly, we identify a situation where the opposite occurs and the Nusselt number increases thereby enhancing convective heat transfer along the pipe.

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超疏水性可以增强压力驱动管道流动中的对流换热

从理论上证明了超疏水性可以增强沿恒定热流密度的圆形管道或管的压力驱动流动中的稳定层流对流换热。这里的超疏水性是指在固体无滑移边界中存在绝热无剪切带。添加这样的绝热无剪切区不仅减少了流体动力摩擦，导致给定压力梯度下更大的流体体积通量，而且还减少了热量进入流体的固体表面积。这导致了竞争机制之间的微妙权衡，因此，通常用努塞尔数测量的沿管道对流换热的净效应并不明显。现有的文献证据表明，超疏水性总是降低努塞尔数，从而损害净换热。在本理论研究中，我们证实这是普遍正确的，但重要的是，我们确定了相反情况发生的情况，努塞尔数增加，从而增强了沿管道的对流换热。

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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The quarterly journal of mechanics and applied mathematics

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