Multiphase flow model developed for simulating gas hydrate transport in horizontal pipe

doi:10.1007/s10483-016-2127-6

Abstract

Abstract:

The hydrate formation or dissociation in deep subsea flow lines is a challenging problem in oil and gas transport systems. The study of multiphase flows is complex while necessary due to the phase changes (i.e., liquid, solid, and gas) that occur with increasing the temperature and decreasing the pressure. A one-dimensional multiphase flow model coupled with a transient hydrate kinetic model is developed to study the characteristics of the multiphase flows for the hydrates formed by the phase changes in the pipes. The multiphase flow model is derived from a multi-fluid model, while has been widely used in modelling multiphase flows. The heat convection between the fluid and the ambient through the pipe wall is considered in the energy balance equation. The developed multiphase flow model is used to simulate the procedure of the hydrate transport. The results show that the formation of the hydrates can cause hold-up oscillations of water and gas.

Key words: phase change, hydrate, slug flow, multiphase flow

2010 MSC Number:

76F25

Shuai TANG, Caixi LIU, Yuhong DONG. Multiphase flow model developed for simulating gas hydrate transport in horizontal pipe. Applied Mathematics and Mechanics (English Edition), 2016, 37(9): 1193-1202.

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