Experimental study on an alternative oil stimulation technique for tight gas reservoirs based on dynamic shock waves generated by Pulsed Arc Electrohydraulic Discharges

Experimental study on an alternative oil stimulation technique for tight gas reservoirs based on dynamic shock waves generated by Pulsed Arc Electrohydraulic Discharges

This article deals with the development of a technique to stimulate low-permeability reservoirs, a potential alternative to hydraulic fracturing. The practical objective is to increase the intrinsic permeability of rocks around the oil well by dynamic shock waves. Laboratory experiments were carried...

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Veröffentlicht in:Journal of petroleum science & engineering 2012-06, Vol.88-89, p.67-74
Hauptverfasser: Chen, Wen, Maurel, Olivier, Reess, Thierry, De Ferron, Antoine Silvestre, La Borderie, Christian, Pijaudier-Cabot, Gilles, Rey-Bethbeder, Franck, Jacques, Antoine
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Sprache:eng
Schlagworte:
Chemical Physics
concrete
Cylinders
Damage
Dynamics
Evolution
fracture
microstructure
Natural gas
Permeability
Physics
sandstone
Shock waves
Thresholds
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container_end_page 74
container_issue
container_start_page 67
container_title Journal of petroleum science & engineering
container_volume 88-89
creator Chen, Wen
Maurel, Olivier
Reess, Thierry
De Ferron, Antoine Silvestre
La Borderie, Christian
Pijaudier-Cabot, Gilles
Rey-Bethbeder, Franck
Jacques, Antoine
description This article deals with the development of a technique to stimulate low-permeability reservoirs, a potential alternative to hydraulic fracturing. The practical objective is to increase the intrinsic permeability of rocks around the oil well by dynamic shock waves. Laboratory experiments were carried out on small hollow cylinder specimens under different confinements, which mimic in situ conditions. Shock waves are generated in water by Pulsed Arc Electrohydraulic Discharges (PAED), which then propagate in water and into the specimens. The specimen is damaged by the pressure waves and its permeability increases with the evolution of damage. Specimens were tested mechanically under three stress levels, corresponding to different depths underground. Then the overall permeability to gas of the specimens was measured and correlated to the electrical energy involved into the PAED. For each stress level, the threshold of energy was observed. From the threshold, the increase of permeability is linear. The thresholds of injected electrical energy increase with confinement level. The effect of repeated shocks on permeability is also considered. Tomography X ray scans have been used to analyze the evolution of the microstructure of representative specimens qualitatively. A good correlation is observed between the X-ray tomography results and the permeability. The evolution of cracking and damage due to dynamic mechanical loads are correlated with the intrinsic permeability of the material and with its microstructure. ► Development of a technique to increase the permeability of rock with dynamic loads. ► Tests with single shock exhibit increases of permeability by two orders of magnitude. ► Permeability increases with the number of shocks with moderate energy. ► X-ray tomography correlates macro-cracking with the increase of permeability.
doi_str_mv 10.1016/j.petrol.2012.01.009
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source ScienceDirect Journals (5 years ago - present)
subjects Chemical Physics
concrete
Cylinders
Damage
Dynamics
Evolution
fracture
microstructure
Natural gas
Permeability
Physics
sandstone
Shock waves
Thresholds
title Experimental study on an alternative oil stimulation technique for tight gas reservoirs based on dynamic shock waves generated by Pulsed Arc Electrohydraulic Discharges
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