Abstract

It is well established that the dropwise condensation (DWC) mode can lead up to significant enhancement in heat transfer coefficients as compared to the filmwise mode (FWC). Typically, hydrophobic surfaces are expected to promote DWC, while hydrophilic ones induce FWC. To this end, superhydrophobic surfaces, where a combination of low surface energy and surface texturing is used to enhance the hydrophobicity, have recently been proposed as a promising approach to promote dropwise condensation. An attractive feature of using superhydrophobic surfaces is to facilitate easy roll-off of the droplets as they form during condensation, thus leading to a significant improvement in the heat transfer associated with the condensation process.High droplet mobility can be obtained acting on the surface chemistry, decreasing the surface energy, and on the surface structure, obtaining a micro- or nano- superficial roughness. The first part of this paper will present a literature review of the most relevant works about DWC on superhydrophobic nanotextured substrates, with particular attention on the fabrication processes. In the second part, experimental data about DWC on superhydrophobic nanotextured samples will be analyzed. Particular attention will be paid to the effect of vapour velocity on the heat transfer. Results clearly highlight the excellent potential of nanostructured surfaces for application in flow condensation applications. However, they highlight the need to perform flow condensation experiments at realistic high temperature and saturation conditions in order to evaluate the efficacy of superhydrophobic surfaces for practically relevant pure vapor condensation applications.

Highlights

  • Vapor condensation is an important phenomenon in nature with direct applications to many fields ranging from the chemical to the power industries

  • It is well established that the dropwise condensation (DWC) mode can lead up to several hundred percent enhancement in heat transfer coefficients as compared to filmwise condensation (FWC), as firstly underlined by Schmidt et al [1], who recognized that during DWC heat transfer coefficients are 5 – 7 times higher than those obtained with filmwise mode, and more recently by Rose [2]

  • Heat transfer coefficient behaves differently with velocity and subcooling: it seems to depend strongly on vapor velocity, while the influence of the subcooling degree is not significant. This highlights the positive influence of vapor flux on the performance of nanostructured superhydrophobic surfaces

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Summary

Introduction

Vapor condensation is an important phenomenon in nature with direct applications to many fields ranging from the chemical to the power industries. Enhancing thermal transport during condensation is a subject which has received a lot of interest in the literature, being at the center of numerous scientific investigations. It is well established that the dropwise condensation (DWC) mode can lead up to several hundred percent enhancement in heat transfer coefficients as compared to filmwise condensation (FWC), as firstly underlined by Schmidt et al [1], who recognized that during DWC heat transfer coefficients are 5 – 7 times higher than those obtained with filmwise mode, and more recently by Rose [2]. Published under licence by IOP Publishing Ltd doi:10.1088/1742-6596/501/1/012028 mechanism responsible for heat transfer increase in dropwise condensation over filmwise one is related to droplets mobility. The sweeping and renewal mechanism present in the droplet growth process during DWC directly leads to an augment of both heat and mass transfer coefficients. The absence of a liquid layer adjacent to the wall avoids the introduction of an additional thermal resistance which adversely affects the thermal and mass transport

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