Open Access

ARTICLE

Numerical Simulation of Elongated Bubbles and Liquid Films in Horizontal Slug Flow

Xiaojian You¹, Zhen Sun¹, Lei Zhang¹, Weikun Qian¹, Cong Wang¹, Weigang Pang¹, Hongming Li¹, Yingshuang Cui¹, Chen Chen¹, Yue Wang¹, Xiao Wu^2,*

1 Zhuangxi Oil Production Plant, Shengli Oilfield Company, SINOPEC, Dongying, China
2 Shandong Institute of Petroleum and Chemical Technology, Dongying, China

* Corresponding Author: Xiao Wu. Email:

(This article belongs to the Special Issue: Theoretical Foundations and Applications of Multiphase Flow in Pipeline Engineering)

Fluid Dynamics & Materials Processing 2026, 22(5), 3 https://doi.org/10.32604/fdmp.2026.081350

Received 28 February 2026; Accepted 28 April 2026; Issue published 27 May 2026

Abstract

Slug flow poses significant dynamic challenges in multiphase pipeline transport, particularly in complex offshore and Floating Liquefied Natural Gas systems, where conventional one- and two-dimensional models fail to capture the intricate three-dimensional interfacial topologies and transient liquid-film dynamics. To overcome this limitation, the present study develops a three-dimensional transient numerical model based on the coupled level-set and volume-of-fluid (CLSVOF) method within a large eddy simulation (LES) framework, and validates it against high-frequency measurements obtained from a double parallel conductance probe experimental platform. The proposed model successfully resolves phase velocity slip and interfacial morphological evolution, predicting the translational velocity and length of elongated bubbles with a relative error of 2.5% to 6.0%. Local hydrodynamic analysis reveals that a high-speed gas wedge induces rapid liquid displacement and localized stagnation, generating high-frequency pressure surges at the liquid-film front that act as primary drivers of transient mechanical stress. In contrast, increasing the superficial liquid velocity leads to thickening of the underlying liquid film, which provides an effective hydrodynamic buffer that attenuates the trailing-edge hydraulic jump. This damping mechanism suppresses chaotic interfacial fragmentation and promotes a transition toward stable, continuous stratified aeration.

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Keywords

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