Modeling of Interfacial Area Transport in Two-Phase Flows | BenthamScience

Advances in Multiphase Flow and Heat Transfer

Volume: 4

Indexed in: Chemical Abstracts, EBSCO, Ulrich's Periodicals Directory

Multiphase flow and heat transfer have found a wide range of applications in several engineering and science fields such as mechanical engineering, chemical and petrochemical engineering, nuclear ...
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Modeling of Interfacial Area Transport in Two-Phase Flows

Pp. 3-27 (25)

Yang Liu, Takashi Hibiki and Mamoru Ishii

Abstract

The interfacial area concentration is an important parameter to characterize the interfacial transport of mass, momentum and energy. The dynamic modeling approach of interfacial area, namely, the Interfacial Area Transport Equation (IATE) is thus indispensable for an accurate prediction of twophase flows using the two-fluid model. This article reviews the theoretical development of the IATE from two aspects: formulation of the transport equation and modeling of the closures. The first approach to arrive at the IATE is based on the statistical description of a large number of particles using the Boltzmann transport equation. This approach is straightforward to obtain the macroscopic equation of the interfacial area concentration. However, for flows with continuous interface such as annular flow, one has to resort to the second approach, the local instantaneous formulation to derive the macroscopic transport equation. The source and sink terms in the IATE are required to close the problem and they are divided into volume change term, phase change term and particle interaction term. Details on formulating IATE using both approaches and modeling of the closures are discussed.

Keywords:

Multiphase flow, two-fluid model, interfacial area concentration, interfacial area transport equation, bubble interaction mechanism.

Affiliation:

School of Nuclear Engineering, Purdue University, West Lafayette, Indiana, 47907, USA