Optimization of CO2 Huff-n-Puff in Unconventional Reservoirs with a Focus on Pore Confinement Effects, Fluid Types, and Completion Parameters

The cyclic injection of CO2, referred to as the huff-n-puff (HnP) method, is an attractive option to improve oil recovery from unconventional reservoirs. This study evaluates the optimization of the CO2 HnP method and provides insight into the aspects of CO2 sequestration for unconventional reservoirs. Furthermore, this study also examines the impact of nanopore confinement, fluid composition, injection solvent, diffusivity parameters, and fracture properties on the long-term recovery factor. The results from over 500 independent simulations showed that the optimal recovery is obtained for the puff-to-huff ratio of around 2.73 with a soak period of fewer than 2.7 days. After numerous HnP cycles, an optimized CO2 HnP process resulted in about 970-to-1067-ton CO2 storage per fracture and over 32% recovery, compared to 22% recovery for natural depletion over the 30 years. The optimized CO2 HnP process also showed higher effectiveness compared to the N2 HnP scenario. Additionally, for reservoirs with significant pore confinement (pore size ≤ 10 nm), the oil recovery improved by over 3% compared to the unconfined bulk phase properties. We also observed over 300% improvement in recovery factor for a fluid with a significant fraction of light hydrocarbons (C1–C6), compared to just a 50% improvement in recovery for a fluid with a substantial fraction of heavy hydrocarbons (C7+). Finally, the results also showed that fracture properties are much more important for CO2 HnP than natural depletion. This study provides critical insights to optimize and improve CO2 HnP operations for different fluid phases and fracture properties encountered in unconventional reservoirs.

[1]  X. Li,et al.  CO2 huff-n-puff process to enhance heavy oil recovery and CO2 storage: An integration study , 2022, Energy.

[2]  A. Khanal,et al.  The current techno-economic, environmental, policy status and perspectives of sustainable aviation fuel (SAF) , 2022, Fuel.

[3]  R. Junin,et al.  Huff-n-Puff Technology for Enhanced Oil Recovery in Shale/Tight Oil Reservoirs: Progress, Gaps, and Perspectives , 2021, Energy & Fuels.

[4]  Yushu Wu,et al.  Nanopore Confinement Effect on the Phase Behavior of CO2/Hydrocarbons in Tight Oil Reservoirs considering Capillary Pressure, Fluid-Wall Interaction, and Molecule Adsorption , 2021, Geofluids.

[5]  A. Trindade,et al.  Optimal Drawdown for Woodford and Mayes in the Anadarko Basin Using Data Analytics , 2021 .

[6]  Xiaoli Li,et al.  Modified Peng-Robinson equation of state for CO2/hydrocarbon systems within nanopores , 2020 .

[7]  A. Trindade,et al.  Optimizing initial oil production of horizontal Wolfcamp wells utilizing data analytics , 2020, Journal of Petroleum Exploration and Production Technology.

[8]  B. Moradi,et al.  Evaluation of nanopore confinement during CO2 huff and puff process in liquid-rich shale formations , 2020, Computational Geosciences.

[9]  K. Lee,et al.  Investigation of asphaltene-derived formation damage and nano-confinement on the performance of CO2 huff-n-puff in shale oil reservoirs , 2019, Journal of Petroleum Science and Engineering.

[10]  Haitao Wang,et al.  A comparative study of CO2 and N2 huff-n-puff EOR performance in shale oil production , 2019, Journal of Petroleum Science and Engineering.

[11]  R. Weijermars,et al.  Visualization of drained rock volume (DRV) in hydraulically fractured reservoirs with and without natural fractures using complex analysis methods (CAMs) , 2019, Petroleum Science.

[12]  Y. Zhang,et al.  Compositional Simulation of CO2 Huff ’n’ Puff in Eagle Ford Tight Oil Reservoirs With CO2 Molecular Diffusion, Nanopore Confinement, and Complex Natural Fractures , 2019, SPE Reservoir Evaluation & Engineering.

[13]  J. Sheng,et al.  Experimental and Numerical Study on CO2 Sweep Volume during CO2 Huff-n-Puff Enhanced Oil Recovery Process in Shale Oil Reservoirs , 2019, Energy & Fuels.

[14]  Feng Xu,et al.  Compositional simulation of CO2 Huff-n-Puff process in Middle Bakken tight oil reservoirs with hydraulic fractures , 2019, Fuel.

[15]  R. Weijermars,et al.  Pressure depletion and drained rock volume near hydraulically fractured parent and child wells , 2019, Journal of Petroleum Science and Engineering.

[16]  Tao Wan,et al.  The use of numerical simulation to investigate the enhanced Eagle Ford shale gas condensate well recovery using cyclic CO2 injection method with nano-pore effect , 2018, Fuel.

[17]  J. Sheng,et al.  Further Investigation of Effects of Injection Pressure and Imbibition Water on CO2 Huff-n-Puff Performance in Liquid-Rich Shale Reservoirs , 2018 .

[18]  Catalin Teodoriu,et al.  A review on the effect of confinement on phase behavior in tight formations , 2018 .

[19]  James A. Sorensen,et al.  Advancing CO2 enhanced oil recovery and storage in unconventional oil play—Experimental studies on Bakken shales , 2017 .

[20]  Yu-Shu Wu,et al.  Advances in improved/enhanced oil recovery technologies for tight and shale reservoirs , 2017 .

[21]  Chengyao Song,et al.  Experimental and numerical evaluation of CO2 huff-n-puff processes in Bakken formation , 2017 .

[22]  Michael Nikolaou,et al.  New forecasting method for liquid rich shale gas condensate reservoirs with data driven approach using principal component analysis , 2017 .

[23]  Kamy Sepehrnoori,et al.  Investigation of nanopore confinement on fluid flow in tight reservoirs , 2017 .

[24]  J. Wilcox,et al.  CO2 Storage and Flow Capacity Measurements on Idealized Shales from Dynamic Breakthrough Experiments , 2017 .

[25]  Tadesse Weldu Teklu,et al.  Nanopore Compositional Modeling in Unconventional Shale Reservoirs , 2016 .

[26]  G. Moridis,et al.  Effect of Confinement on Pressure/Volume/Temperature Properties of Hydrocarbons in Shale Reservoirs , 2016 .

[27]  Zhangxin Chen,et al.  Phase Equilibria of Confined Fluids in Nanopores of Tight and Shale Rocks Considering the Effect of Capillary Pressure and Adsorption Film , 2016 .

[28]  Kamy Sepehrnoori,et al.  CO2 injection for enhanced oil recovery in Bakken tight oil reservoirs , 2015 .

[29]  Tadesse Weldu Teklu,et al.  Enhanced Oil Recovery in Liquid-Rich Shale Reservoirs: Laboratory to Field , 2015 .

[30]  Derek Elsworth,et al.  Geomechanics of CO2 enhanced shale gas recovery , 2015 .

[31]  S. Dworkin,et al.  Origin of organic matter in the Eagle Ford Formation , 2015 .

[32]  Matthew T. Balhoff,et al.  Effect of Reservoir Heterogeneity on Primary Recovery and CO2 Huff 'n' Puff Recovery in Shale-Oil Reservoirs , 2014 .

[33]  Ramona M. Graves,et al.  Phase Behavior and Minimum Miscibility Pressure in Nanopores , 2014 .

[34]  Mohamed Y. Soliman,et al.  An Experimental Study of Cyclic CO2 Injection to Improve Shale Oil Recovery , 2014 .

[35]  Faye Liu,et al.  Assessing the feasibility of CO2 storage in the New Albany Shale (Devonian–Mississippian) with potential enhanced gas recovery using reservoir simulation , 2013 .

[36]  Dake Wu,et al.  A MODIFIED PENG-ROBINSON EQUATION OF STATE , 1997 .

[37]  H. Cinco-Ley,et al.  Transient Pressure Analysis for Fractured Wells , 1981 .