Reservoir simulation and optimization of CO₂ huff-and-puff operations in the Bakken Shale

Reservoir simulation and optimization of CO₂ huff-and-puff operations in the Bakken Shale

A numerical reservoir model was created to optimize CO₂ Huff-and-Puff operations in the Bakken Shale. Huff-and-Puff is an enhanced oil recovery treatment in which a well alternates between injection, soaking, and production. Injecting CO₂ into the formation and allowing it to “soak” re-pressurizes t...

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Bibliographic Details
Main Author: Sanchez Rivera, Daniel
Format: Others
Language:en
Published: 2014
Subjects:
Huff-and-puff
Bakken
EOR
Enhanced oil recovery
CO₂
Gas injection
Reservoir simulation
Numerical methods
Mortar coupling
Online Access:http://hdl.handle.net/2152/26461
id ndltd-UTEXAS-oai-repositories.lib.utexas.edu-2152-26461
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spelling ndltd-UTEXAS-oai-repositories.lib.utexas.edu-2152-264612015-09-20T17:26:49ZReservoir simulation and optimization of CO₂ huff-and-puff operations in the Bakken ShaleSanchez Rivera, DanielHuff-and-puffBakkenEOREnhanced oil recoveryCO₂Gas injectionReservoir simulationNumerical methodsMortar couplingA numerical reservoir model was created to optimize CO₂ Huff-and-Puff operations in the Bakken Shale. Huff-and-Puff is an enhanced oil recovery treatment in which a well alternates between injection, soaking, and production. Injecting CO₂ into the formation and allowing it to “soak” re-pressurizes the reservoir and improves oil mobility, boosting production from the well. A compositional reservoir simulator was used to study the various design components of the Huff-and-Puff process in order to identify the parameters with the largest impact on recovery and understand the reservoir’s response to cyclical CO₂ injection. It was found that starting Huff-and-Puff too early in the life of the well diminishes its effectiveness, and that shorter soaking periods are preferable over longer waiting times. Huff-and-Puff works best in reservoirs with highly-conductive natural fracture networks, which allow CO₂ to migrate deep into the formation and mix with the reservoir fluids. The discretization of the computational domain has a large impact on the simulation results, with coarser gridding corresponding to larger projected recoveries. Doubling the number of hydraulic fractures per stage results in considerably greater CO₂ injection requirements without proportionally larger incremental recovery factors. Incremental recovery from CO₂ Huff-and-Puff appears to be insufficient to make the process commercially feasible under current economic conditions. However, re-injecting mixtures of CO₂ and produced hydrocarbon gases was proven to be technically and economically viable, which could significantly improve profit margins of Huff-and-Puff operations. A substantial portion of this project involved studying alternative numerical methods for modeling hydraulically-fractured reservoir models. A domain decomposition technique known as mortar coupling was used to model the reservoir system as two individually-solved subdomains: fracture and matrix. A mortar-based numerical reservoir simulator was developed and its results compared to a tradition full-domain finite difference model for the Cinco-Ley et al. (1978) finite-conductivity vertical fracture problem. Despite some numerical issues, mortar coupling closely matched Cinco-Ley et al.'s (1978) solution and has potential applications in complex problems where decoupling the fracture-matrix system might be advantageous.text2014-10-10T17:44:55Z2014-082014-09-10August 20142014-10-10T17:44:55ZThesisapplication/pdfhttp://hdl.handle.net/2152/26461en
collection NDLTD
language en
format Others
sources NDLTD
topic Huff-and-puff
Bakken
EOR
Enhanced oil recovery
CO₂
Gas injection
Reservoir simulation
Numerical methods
Mortar coupling
spellingShingle Huff-and-puff
Bakken
EOR
Enhanced oil recovery
CO₂
Gas injection
Reservoir simulation
Numerical methods
Mortar coupling
Sanchez Rivera, Daniel
Reservoir simulation and optimization of CO₂ huff-and-puff operations in the Bakken Shale
description A numerical reservoir model was created to optimize CO₂ Huff-and-Puff operations in the Bakken Shale. Huff-and-Puff is an enhanced oil recovery treatment in which a well alternates between injection, soaking, and production. Injecting CO₂ into the formation and allowing it to “soak” re-pressurizes the reservoir and improves oil mobility, boosting production from the well. A compositional reservoir simulator was used to study the various design components of the Huff-and-Puff process in order to identify the parameters with the largest impact on recovery and understand the reservoir’s response to cyclical CO₂ injection. It was found that starting Huff-and-Puff too early in the life of the well diminishes its effectiveness, and that shorter soaking periods are preferable over longer waiting times. Huff-and-Puff works best in reservoirs with highly-conductive natural fracture networks, which allow CO₂ to migrate deep into the formation and mix with the reservoir fluids. The discretization of the computational domain has a large impact on the simulation results, with coarser gridding corresponding to larger projected recoveries. Doubling the number of hydraulic fractures per stage results in considerably greater CO₂ injection requirements without proportionally larger incremental recovery factors. Incremental recovery from CO₂ Huff-and-Puff appears to be insufficient to make the process commercially feasible under current economic conditions. However, re-injecting mixtures of CO₂ and produced hydrocarbon gases was proven to be technically and economically viable, which could significantly improve profit margins of Huff-and-Puff operations. A substantial portion of this project involved studying alternative numerical methods for modeling hydraulically-fractured reservoir models. A domain decomposition technique known as mortar coupling was used to model the reservoir system as two individually-solved subdomains: fracture and matrix. A mortar-based numerical reservoir simulator was developed and its results compared to a tradition full-domain finite difference model for the Cinco-Ley et al. (1978) finite-conductivity vertical fracture problem. Despite some numerical issues, mortar coupling closely matched Cinco-Ley et al.'s (1978) solution and has potential applications in complex problems where decoupling the fracture-matrix system might be advantageous. === text
author Sanchez Rivera, Daniel
author_facet Sanchez Rivera, Daniel
author_sort Sanchez Rivera, Daniel
title Reservoir simulation and optimization of CO₂ huff-and-puff operations in the Bakken Shale
title_short Reservoir simulation and optimization of CO₂ huff-and-puff operations in the Bakken Shale
title_full Reservoir simulation and optimization of CO₂ huff-and-puff operations in the Bakken Shale
title_fullStr Reservoir simulation and optimization of CO₂ huff-and-puff operations in the Bakken Shale
title_full_unstemmed Reservoir simulation and optimization of CO₂ huff-and-puff operations in the Bakken Shale
title_sort reservoir simulation and optimization of co₂ huff-and-puff operations in the bakken shale
publishDate 2014
url http://hdl.handle.net/2152/26461
work_keys_str_mv AT sanchezriveradaniel reservoirsimulationandoptimizationofco2huffandpuffoperationsinthebakkenshale
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