Experimental measurements and CFD results of liquid film thickness in vertical downward air–water annular flow

Q4 Engineering
Y. Rivera, J. Muñoz-Cobo, A. Escrivá, C. Berna, Y. Cordova
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引用次数: 1

Abstract

Annular gas–liquid flows have been extensively studied over the years. However, the nonlinear behavior of the interface is still currently the subject of study by multiple researchers worldwide. The appearance of a liquid layer on the wall and its turbulent behavior support the heat exchange of multiple systems in the industrial field. Research in this area allows the optimization of these instal-lations as well as the analysis of possible safety problems if the liquid film disappears. This study first shows some of the most important findings obtained in the GEPELON experimental facility (GEneración de PElícula ONdulatoria or Wavy Film Generator). The facility was built in order to analyze the behavior of the liquid film in annular downward air–water flow. The experimental range of the inlet conditions is 800–8000 for the Re L and 0–110,000 for the Re g . Measurements for the mean film thickness show a fairly good agreement with the empirical correlations and the measurements of other authors. One of the most demanded applications of this type of measurements is the validation of computational dynamics or CFD codes. Therefore, the experiment has been modeled using Ansys CFX software, and the simulation results have been compared with the experimental ones. This article outlines some of the reasons why two-phase flow simulations are currently challenging and how the codes are able to overcome them. Simulation predictions are fairly close to the experimental measurements, and the mean film thickness evolution when changing the boundary conditions also shows a good agreement. annular
垂直向下气-水环流液膜厚度的实验测量与CFD结果
多年来,人们对环空气液流动进行了广泛的研究。然而,界面的非线性行为目前仍是世界范围内众多研究者研究的课题。壁面液体层的出现及其湍流行为支持了工业领域中多个系统的热交换。该领域的研究可以优化这些装置,并分析如果液膜消失可能出现的安全问题。这项研究首先展示了在GEPELON实验设备(GEneración de PElícula波纹膜发生器)中获得的一些最重要的发现。为了分析液膜在空气-水环形向下流动中的行为,建立了该装置。进口条件的实验范围为Re L为800-8000,Re g为0 - 11万。平均膜厚的测量结果与经验相关性和其他作者的测量结果相当吻合。这类测量最需要的应用之一是计算动力学或CFD代码的验证。因此,利用Ansys CFX软件对实验进行建模,并将仿真结果与实验结果进行对比。本文概述了两相流模拟目前具有挑战性的一些原因以及代码如何能够克服它们。模拟结果与实验结果相当接近,边界条件变化时的平均膜厚演变也表现出较好的一致性。环形
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
CiteScore
1.10
自引率
0.00%
发文量
24
审稿时长
33 weeks
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