Planar dynamics of inclined curved flexible riser carrying slug liquid–gas flows

• Published in: Journal of fluids and structures Vol. 94; p. 102911
• Main Authors: Ma, Bowen, Srinil, Narakorn
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.04.2020
• Subjects: Catenary riser; Flow-induced vibration; Inclined pipe; Multiphase flow; Slug liquid–gas flow; Catenary riser; Flow-induced vibration; Multiphase flow; Slug liquid–gas flow; Inclined pipe
• ISSN: 0889-9746; 1095-8622
• DOI: 10.1016/j.jfluidstructs.2020.102911

Flexible risers transporting hydrocarbon liquid–gas flows may be subject to internal dynamic fluctuations of multiphase densities, velocities and pressure changes. Previous studies have mostly focused on single-phase flows in oscillating pipes or multiphase flows in static pipes whereas understanding of multiphase flow effects on oscillating pipes with variable curvatures is still lacking. The present study aims to numerically investigate fundamental planar dynamics of a long flexible catenary riser carrying slug liquid–gas flows and to analyse the mechanical effects of slug flow characteristics including the slug unit length, translational velocity and fluctuation frequencies leading to resonances. A two-dimensional continuum model, describing the coupled horizontal and vertical motions of an inclined flexible/extensible curved riser subject to the space–time varying fluid weights, flow centrifugal momenta and Coriolis effects, is presented. Steady slug flows are considered and modelled by accounting for the mass–momentum balances of liquid–gas phases within an idealized slug unit cell comprising the slug liquid (containing small gas bubbles) and elongated gas bubble (interfacing with the liquid film) parts. A nonlinear hydrodynamic film profile is described, depending on the pipe diameter, inclination, liquid–gas phase properties, superficial velocities and empirical correlations. These enable the approximation of phase fractions, local velocities and pressure variations which are employed as the time-varying, distributed parameters leading to the slug flow-induced vibration (SIV) of catenary riser. Several key SIV features are numerically investigated, highlighting the slug flow-induced transient drifts due to the travelling masses, amplified mean displacements due to the combined slug weights and flow momenta, extensibility or tension changes due to a reconfiguration of pipe equilibrium, oscillation amplitudes and resonant frequencies. Single- and multi-modal patterns of riser dynamic profiles are determined, enabling the evaluation of associated bending/axial stresses. Parametric studies reveal the individual effect of the slug unit length and the translational velocity on SIV response regardless of the slug characteristic frequency being a function of these two parameters. This key observation is practically useful for the identification of critical maximum response. •Planar dynamics of inclined curved flexible riser carrying slug liquid–gas flows are investigated.•Mechanistic slug flow model is applied to identify liquid–gas flow features within a slug unit cell.•Slug flow-induced vibration is subject to fluctuations of phase fractions, velocities and pressure.•Effects of slug unit length, translational velocity and characteristic frequency are investigated.•Transient and steady-state responses highlight fundamental coupling mechanism of mean drift and oscillation components.