Numerical simulation of pig motion in gas and liquid pipelines using the Flux-Corrected Transport method

Numerical simulation of pig motion in gas and liquid pipelines using the Flux-Corrected Transport method

The transportation of fluids in long pipelines occurs very often in the oil and gas industries. To keep high efficiency and productivity in pipeline operations, a device called pig is routinely passed throughout the pipeline for the purpose of cleaning, inspection, sealing, corrosion evaluation, amo...

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Bibliographic Details
Published in:Journal of petroleum science & engineering Vol. 189; p. 106970
Main Authors: Patricio, Rodrigo Augusto Camara, Baptista, Renan Martins, Rachid, Felipe Bastos de Freitas, Bodstein, Gustavo C.R.
Format: Journal Article
Language:English
Published: Elsevier B.V 01-06-2020
Subjects:
Flux-corrected transport method
Gas pipeline
Liquid pipeline
Numerical simulation
Petroleum engineering
Pig motion
Pig motion
Liquid pipeline
Numerical simulation
Gas pipeline
Flux-corrected transport method
Petroleum engineering
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Summary:The transportation of fluids in long pipelines occurs very often in the oil and gas industries. To keep high efficiency and productivity in pipeline operations, a device called pig is routinely passed throughout the pipeline for the purpose of cleaning, inspection, sealing, corrosion evaluation, among others, despite the uncertainties and risks associated with its passage inside a long duct. For these reasons, it is important to use numerical simulations to follow the motion of a pig inside a pipeline and estimate the pig travelling time. This paper presents a one-dimensional mechanical model, along with a numerical scheme, to obtain approximate solutions for the pig movement and for the transient one-phase flow inside the pipeline, which are physically and mathematically connected. In this model the pig is treated as a moving singular boundary and its mathematical model reduces to an initial-boundary-value problem. This system of equations is coupled to a boundary value problem for the transient fluid flow inside the duct. Since the pig is modeled as a moving surface, the pipeline is divided in two sections, one upstream and one downstream of the pig, and these two separate fluid flows are coupled with the pig motion system. The mathematical domain is discretized within the finite-volume framework and is solved using the Flux-Corrected Transport (FCT) method, which is second-order in space, as our results attest. We present simulations for the pig velocity history and for the distributions of flow pressure and velocity along the pipe in air and water single-phase flows. The results show physically consistent results for no-hole and one-hole pigs, for a rapid transient valve closure problem and in a direct comparison with a commercial software. •A general-purpose pig model is proposed for numerical simulations in liquid and gas pipelines.•Hydrodynamic and mechanical friction forces acting on the pig are properly accounted for from the physical viewpoint.•Different forms of bypass flow rates are included that properly represent real pig features.•A numerical strategy based on the FCT method is proposed to solve the coupled pig and fluid motion.•Numerical simulations are presented in liquid and gas flow for pigs with and without holes in the pig body.•The results obtained are capable to describe the correct physical behavior of the pig motion with excellent agreement with OLGA.
ISSN:0920-4105
1873-4715
DOI:10.1016/j.petrol.2020.106970