Theoretical Modeling of CHF for Near-Saturated Pool Boiling and Flow Boiling from Short Heaters Using the Interfacial Lift-Off Criterion

Convective Flow Boiling Pub Date : 1995-12-31 DOI:10.1201/9780367812089-29

I. Mudawar, J. Galloway, C. O. Gersey

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Abstract

Pool boiling and flow boiling were examined for near-saturated bulk conditions in order to determine the critical heat flux (CHF) trigger mechanism for each. Photographic studies of the wall region revealed features common to both situations. At fluxes below CHF, the vapor coalesces into a wavy layer which permits wetting only in wetting fronts, the portions of the liquid-vapor interface which contact the wall as a result of the interfacial waviness. Close examination of the interfacial features revealed the waves are generated from the lower edge of the heater in pool boiling and the heater`s upstream region in flow boiling. Wavelengths follow predictions based upon the Kelvin-Helmholtz instability criterion. Critical heat flux in both cases occurs when the pressure force exerted upon the interface due to interfacial curvature, which tends to preserve interfacial contact with the wall prior to CHF, is overcome by the momentum of vapor at the site of the first wetting front, causing the interface to lift away from the wall. It is shown this interfacial lift-off criterion facilitates accurate theoretical modeling of CHF in pool boiling and in flow boiling in both straight and curved channels.

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近饱和池沸腾和短加热器流动沸腾CHF的界面升离准则理论建模

研究了近饱和体积条件下的池沸腾和流动沸腾，以确定两者的临界热流密度触发机制。墙壁区域的摄影研究揭示了这两种情况的共同特征。在低于CHF的通量下，蒸汽凝聚成一个波浪形层，只允许在润湿前沿润湿，即由于界面波浪形而与壁面接触的液-汽界面部分。对界面特征的仔细研究表明，波浪产生于池沸腾时加热器的下缘和流沸腾时加热器的上游区域。波长遵循基于开尔文-亥姆霍兹不稳定性准则的预测。在这两种情况下，当由于界面曲率而施加在界面上的压力力在CHF之前倾向于保持界面与壁面的接触，被第一个润湿锋位置的蒸汽动量所克服，导致界面从壁面上升时，就会出现临界热流密度。结果表明，该界面升离准则有助于对直管和弯曲管中池沸腾和流动沸腾的CHF进行精确的理论建模。

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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Convective Flow Boiling

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