Investigation of Back Pressure Effects on Transient Gas Flow Through Porous Media via Laboratory Experiments and Numerical Simulation

When developing a transient numerical reservoir simulator, it is important to consider the back pressure effects that waves propagating from one end of the porous medium will have on the temporal distribution of pore fluid pressure within the medium itself. Such waves can be triggered by changing bo...

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Published in:Volume 5: Materials Technology; Petroleum Technology
Main Authors: Liu, Xiaolei, Limpasurat, Akkharachai, Falcone, Gioia, Teodoriu, Catalin
Format: Conference Object
Language:unknown
Published: 2014
Subjects:
Arctic
Online Access:http://eprints.gla.ac.uk/169669/
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spelling ftuglasgow:oai:eprints.gla.ac.uk:169669 2023-05-15T14:27:10+02:00 Investigation of Back Pressure Effects on Transient Gas Flow Through Porous Media via Laboratory Experiments and Numerical Simulation Liu, Xiaolei Limpasurat, Akkharachai Falcone, Gioia Teodoriu, Catalin 2014 http://eprints.gla.ac.uk/169669/ unknown Liu, X. <http://eprints.gla.ac.uk/view/author/49704.html> , Limpasurat, A., Falcone, G. <http://eprints.gla.ac.uk/view/author/46939.html> and Teodoriu, C. (2014) Investigation of Back Pressure Effects on Transient Gas Flow Through Porous Media via Laboratory Experiments and Numerical Simulation. In: ASME 2014 33rd International Conference on Ocean, Offshore and Arctic Engineering, San Francisco, CA., 8-13 June 2014, V005T11A030. ISBN 9780791845455 (doi:10.1115/OMAE2014-24648 <http://dx.doi.org/10.1115/OMAE2014-24648>) Conference Proceedings PeerReviewed 2014 ftuglasgow https://doi.org/10.1115/OMAE2014-24648 2021-09-30T22:15:57Z When developing a transient numerical reservoir simulator, it is important to consider the back pressure effects that waves propagating from one end of the porous medium will have on the temporal distribution of pore fluid pressure within the medium itself. Such waves can be triggered by changing boundary conditions at the interface between reservoir and wellbore. An example is given by the transient reservoir response following pressure fluctuations at the wellbore boundary for gas wells suffering from liquid loading. Laboratory experiments were performed using a modified Hassler cell to mimic the effect of varying downhole pressure on gas flow in the near-wellbore region of a reservoir. Gauges were attached along a sandstone core to monitor the pressure profile. The results of the experiments are shown in this paper. A numerical code for modelling transient flow in the near-wellbore region was run to mimic the experiments. The comparisons of simulations and laboratory test results are presented here, for the initial and final steady-state flowing conditions, and where the inlet pressure was maintained constant while initiating a transient pressure build up at the core outlet. The concept of the U-shaped pressure profile along the near-wellbore region of a reservoir under transient flow conditions, originally proposed by Zhang et al. [1], was experimentally and numerically reproduced for single-phase gas flow. This is due to a combination of inertia and compressibility effects, leading to the reservoir response not being instantaneous. The results suggest that, in two phase gas-liquid conditions, liquid re-injection could occur during liquid loading in gas wells. From the experimental results, the U-shaped curves were more obvious and of longer duration in the case of greater outlet pressure. The transition from the initial to the final steady state condition occurred rapidly in all the cases shown here, with the U-shaped pressure profile appearing only over a relatively short time (at the small scale and low pressures tested in this study). Conference Object Arctic University of Glasgow: Enlighten - Publications Volume 5: Materials Technology; Petroleum Technology
institution Open Polar
collection University of Glasgow: Enlighten - Publications
op_collection_id ftuglasgow
language unknown
description When developing a transient numerical reservoir simulator, it is important to consider the back pressure effects that waves propagating from one end of the porous medium will have on the temporal distribution of pore fluid pressure within the medium itself. Such waves can be triggered by changing boundary conditions at the interface between reservoir and wellbore. An example is given by the transient reservoir response following pressure fluctuations at the wellbore boundary for gas wells suffering from liquid loading. Laboratory experiments were performed using a modified Hassler cell to mimic the effect of varying downhole pressure on gas flow in the near-wellbore region of a reservoir. Gauges were attached along a sandstone core to monitor the pressure profile. The results of the experiments are shown in this paper. A numerical code for modelling transient flow in the near-wellbore region was run to mimic the experiments. The comparisons of simulations and laboratory test results are presented here, for the initial and final steady-state flowing conditions, and where the inlet pressure was maintained constant while initiating a transient pressure build up at the core outlet. The concept of the U-shaped pressure profile along the near-wellbore region of a reservoir under transient flow conditions, originally proposed by Zhang et al. [1], was experimentally and numerically reproduced for single-phase gas flow. This is due to a combination of inertia and compressibility effects, leading to the reservoir response not being instantaneous. The results suggest that, in two phase gas-liquid conditions, liquid re-injection could occur during liquid loading in gas wells. From the experimental results, the U-shaped curves were more obvious and of longer duration in the case of greater outlet pressure. The transition from the initial to the final steady state condition occurred rapidly in all the cases shown here, with the U-shaped pressure profile appearing only over a relatively short time (at the small scale and low pressures tested in this study).
format Conference Object
author Liu, Xiaolei
Limpasurat, Akkharachai
Falcone, Gioia
Teodoriu, Catalin
spellingShingle Liu, Xiaolei
Limpasurat, Akkharachai
Falcone, Gioia
Teodoriu, Catalin
Investigation of Back Pressure Effects on Transient Gas Flow Through Porous Media via Laboratory Experiments and Numerical Simulation
author_facet Liu, Xiaolei
Limpasurat, Akkharachai
Falcone, Gioia
Teodoriu, Catalin
author_sort Liu, Xiaolei
title Investigation of Back Pressure Effects on Transient Gas Flow Through Porous Media via Laboratory Experiments and Numerical Simulation
title_short Investigation of Back Pressure Effects on Transient Gas Flow Through Porous Media via Laboratory Experiments and Numerical Simulation
title_full Investigation of Back Pressure Effects on Transient Gas Flow Through Porous Media via Laboratory Experiments and Numerical Simulation
title_fullStr Investigation of Back Pressure Effects on Transient Gas Flow Through Porous Media via Laboratory Experiments and Numerical Simulation
title_full_unstemmed Investigation of Back Pressure Effects on Transient Gas Flow Through Porous Media via Laboratory Experiments and Numerical Simulation
title_sort investigation of back pressure effects on transient gas flow through porous media via laboratory experiments and numerical simulation
publishDate 2014
url http://eprints.gla.ac.uk/169669/
genre Arctic
genre_facet Arctic
op_relation Liu, X. <http://eprints.gla.ac.uk/view/author/49704.html> , Limpasurat, A., Falcone, G. <http://eprints.gla.ac.uk/view/author/46939.html> and Teodoriu, C. (2014) Investigation of Back Pressure Effects on Transient Gas Flow Through Porous Media via Laboratory Experiments and Numerical Simulation. In: ASME 2014 33rd International Conference on Ocean, Offshore and Arctic Engineering, San Francisco, CA., 8-13 June 2014, V005T11A030. ISBN 9780791845455 (doi:10.1115/OMAE2014-24648 <http://dx.doi.org/10.1115/OMAE2014-24648>)
op_doi https://doi.org/10.1115/OMAE2014-24648
container_title Volume 5: Materials Technology; Petroleum Technology
_version_ 1766300767005704192

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