Mechanistic Study for the Applicability of CO₂-EOR in Unconventional Liquids Rich Reservoirs

Abstract

In shale oil reservoirs, Improved Oil Recovery (IOR) methods are relatively considered as new concepts compared with in conventional oil reservoirs. Different IOR techniques have been investigated by using lab experiments, numerical simulation studies, and limited pilot tests. Unconventional IOR methods include injecting CO₂, surfactant, natural gas, and water. However, CO₂ injection is the most investigated option due to different reasons. CO₂ has lower miscibility pressure with shale oils, and has special properties in its supercritical conditions, and CO₂ injection also solves greenhouse problems. In this paper, numerical simulation methods of compositional models were incorporated with LS-LR-DK (logarithmically spaced, locally refined, and dual permeability) reservoir models and Local Grids Refinement (LGR) of hydraulic fractures conditions to investigate the feasibility of CO₂ injection in shale oil reservoirs. Different mechanisms for CO₂ interactions with organic surface, shale brine, and shale oil were implemented in different scenarios of numerical models. Molecular diffusion mechanisms, adsorption effects, and aqueous solubility effects were simulated in this study. In addition, linear elastic models and stress-dependent correlations were used to consider geomechanics coupling effects on production and injection processes of CO₂-EOR in shale oil reservoirs. Some of the results for this simulation study were validated by matching the performance of some CO₂ fields' pilots performed in Bakken formation, in North Dakota and Montana portions. This study extremely found that some of the CO₂-EOR pilot tests have a match with the typical simulated diagnostic plots which have CO₂ molecular-diffusion rate that is significantly low. Furthermore, this research indicated that CO₂ molecular diffusion mechanism has a clearly positive effect on CO₂-EOR in huff-n-puff protocol; however, this mechanism has a relatively negative effect on continuous flooding mode of CO₂-EOR. Both of dissolution and adsorption mechanisms have a negative effect on CO₂ performance in terms of enhancing oil recovery in unconventional formations. Geomechanics coupling has a clear effect on CO₂-EOR performance, and different geomechanics models have a different validity in these shale plays. Stress dependent correlations give the best match with CO₂-EOR pilots in Bakken formation while linear elastic models would give the best match in Eagle Ford formation. This study explains the effects of different nano and macro mechanisms on the performance of CO₂-EOR in unconventional reservoirs since these plays are much complex and very different from conventional formations. Also, general guidelines have been provided in this study to enhance success of CO₂-EOR in these types of reservoirs.

Meeting Name

SPE Improved Oil Recovery Conference 2018 (2018: Apr. 14-18, Tulsa, OK)

Department(s)

Geosciences and Geological and Petroleum Engineering

Keywords and Phrases

Carbon dioxide; Diffusion in liquids; Diffusion in solids; Enhanced recovery; Geomechanics; Mechanical permeability; Numerical methods; Numerical models; Oil shale; Oil well flooding; Petroleum reservoirs; Road construction; Shale; Shale oil; Solubility, Adsorption mechanism; Compositional models; Improved oil recovery; Linear elastic model; Numerical simulation method; Numerical simulation studies; Supercritical condition; Unconventional reservoirs, Petroleum reservoir engineering

Document Type

Article - Conference proceedings

Document Version

Citation

File Type

text

Language(s)

English

Rights

© 2018 Society of Petroleum Engineers (SPE), All rights reserved.

Publication Date

01 Apr 2018

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