Abstract
In this study, a systematical technique has been developed to experimentally and numerically evaluate the displacement efficiency in heavy oil reservoirs with enzyme under different conditions. First, dynamic interfacial tensions (IFTs) between enzyme solution and heavy oil are measured with a pendant-drop tensiometer, while effects of pressure, temperature, enzyme concentration, and contact time of enzyme and heavy oil on equilibrium IFT were systematically examined and analyzed. After waterflooding, enzyme flooding was carried out in sandpacks to evaluate its potential to enhance heavy oil recovery at high water-cut stage. Numerical simulation was then performed to identify the underlying mechanisms accounting for the enzyme flooding performance. Subsequently, a total of 18 scenarios were designed to simulate and examine effects of the injection modes and temperature on oil recovery. Except for pressure, temperature, enzyme concentration, and contact time are found to impose a great impact on the equilibrium IFTs, i.e., a high temperature, a high enzyme concentration, and a long contact time reduce the equilibrium IFTs. All three enzyme flooding tests with different enzyme concentrations show the superior recovery performance in comparison to that of pure waterflooding. In addition to the IFT reduction, modification of relative permeability curves is found to be the main reason responsible for further mobilizing the residual heavy oil. A large slug size of enzyme solution usually leads to a high recovery factor, although its incremental oil production is gradually decreased. In addition, temperature is found to have a great effect on the recovery factor of enzyme flooding likely owing to reduction of both oil viscosity and IFT.
Issue Section:
Petroleum Engineering
References
1.
Feng
, Q.
, Ma
, X.
, Zhou
, L.
, Shao
, D.
, Wang
, X.
, and Qin
, B.
, 2009
, “EOR Pilot Tests With Modified Enzyme-Dagang Oilfield China
,” SPE Reser. Eval. Eng.
, 12
(1
), pp. 79
–88
. 10.2118/107128-PA2.
Jain
, T.
, and Sharma
, A.
, 2012
, “New Frontiers in EOR Methodologies by Application of Enzymes
,” Presented at the SPE EOR Conference at Oil and Gas West Asia
, Muscat, Oman
, Apr. 16–18
, Paper No. SPE-154690-MS
.3.
Jabbar
, M.
, Azrak
, O.
, Berthier
, M.
, Blondeau
, C.
, and Al-Amrie
, O.
, 2015
, “Application of Enzyme EOR in a Mature UAE Offshore Carbonate Oil Field
,” Presented at the SPE Abu Dhabi International Petroleum Exhibition and Conference
, Abu Dhabi, UAE
, Nov. 9–12
, Paper No. SPE-177688-MS.4.
Harris
, R. E.
, and Mckay
, I. D.
, 1998
, “New Applications for Enzymes in Oil and Gas Production
,” Presented at the SPE European Petroleum Conference
, Hague, The Netherlands
, Oct. 20–22
, Paper No. SPE-50621-MS
.5.
Khusainova
, A.
, Shapiro
, A. A.
, Stenby
, E. H.
, and Woodley
, J. M.
, 2012
, “Wettability Improvement With Enzymes: Application to Enhanced Oil Recovery Under Conditions of the North Sea Reservoirs
,” Proceedings of the 33rd IEA EOR Symposium
, Regina, SK
, Aug. 26–30
, Paper No. SPE-50621-MS.
6.
Haastrup
, B.
, 2014
, “Enzyme Penetration Tests on Carbonaceous Rocks for Application to Enhanced Oil Recovery
,” Presented at the SPE Annual Technical Conference and Exhibition
, Amsterdam, The Netherlands
, Oct. 27–29
, Paper No. SPE-173461-MS
.7.
Khusainova
, A.
, 2016
, “Enhanced Oil Recovery With Application of Enzymes
,” Ph.D. dissertation
, Technical University of Denmark
, Kongens Lyngby, Denmark
.8.
Morgan
, A.
, Akanji
, L.
, Udoh
, T.
, Mohammed
, S.
, Nkrumah
, W. A.
, and Sarkodie-Kyeremeh
, J.
, 2020
, “Experimental Determination of Protein Enzyme Bio-Surfactant Properties for Enhanced Oil Recovery
,” Presented at the SPE Nigeria Annual International Conference and Exhibition
, Lagos, Nigeria
, Aug. 11–13
, Paper No. SPE-203599-MS
.9.
Nasiri
, H.
, 2011
, “Enzymes for Enhanced Oil Recovery (EOR)
,” Ph.D. dissertation
, University of Bergen
, Bergen, Norway
.10.
Rahayyem
, M.
, Mostaghimi
, P.
, Alzahid
, Y. A.
, Halim
, A.
, Evangelista
, L.
, and Armstrong
, R. T.
, 2019
, “Enzyme Enhanced Oil Recovery EEOR: A Microfluidics Approach. Society of Petroleum Engineers
,” Presented at the SPE Middle East Oil and Gas Show and Conference
, Manama, Bahrain
, Mar. 18–21
, Paper No. SPE-195116-MS
.11.
Morgan
, A.
, Akanji
, L.
, Udoh
, T.
, Mohammed
, S.
, Anumah
, P.
, and Kyeremeh
, S. J.
, 2020
, “Fractional Flow Behaviour and Transport Mechanisms During Low Salinity and Protein Enzyme Bio-Surfactant EOR Flooding
,” Presented at the SPE Nigeria Annual International Conference and Exhibition
, Lagos, Nigeria
, Aug. 11–13
, Paper No. SPE-203600-MS
.12.
Moon
, T.
, 2008
, “Using Enzymes to Enhance Oil Recovery
,” http://jumpstartenergyservices.com/pdf/19_Jumpstart-EEOR-pdf.pdf13.
Liu
, H.
, and Zhang
, Z.
, 2011
, “Biology Enzyme EOR for Low Permeability Reservoir
,” Presented at the SPE Enhanced Oil Recovery Conference
, Kuala Lumpur, Malaysia
, July 19–21
, Paper No. SPE-144281-MS
.14.
Ayodele
, O. R.
, Nasr
, T. N.
, Ivory
, J. J.
, Beaulieu
, G.
, and Heck
, G.
, 2010
, “Testing and History Matching of ES-SAGD (Using Hexane)
,” Presented at the SPE Western Regional Meeting
, Anaheim, CA
, May 27–29
, Paper SPE-134002-MS
.15.
Das
, S.
, 2005
, “Improving the Performance of SAGD
,” Presented at the SPE International Thermal Operations and Heavy Oil Symposium
, Calgary, AB, Canada
, Nov. 1–3
, Paper No. SPE-97921-MS
.16.
Taborda
, E. A.
, Franco
, C. A.
, Ruiz
, M. A.
, Alvarado
, V.
, and Cortés
, F. B.
, 2017
, “Experimental and Theoretical Study of Viscosity Reduction in Heavy Crude Oils by Addition of Nanoparticles
,” Energy Fuels
, 31
(2
), pp. 1329
–1338
. 10.1021/acs.energyfuels.6b0268617.
Yi
, S.
, Babadagli
, T.
, and Andy Li
, H.
, 2018
, “Use of Nickel Nanoparticles for Promoting Aquathermolysis Reaction During Cyclic Steam Stimulation
,” SPE J.
, 23
(1
), pp. 145
–156
. 10.2118/186102-PA18.
Meng
, X.
, and Yang
, D.
, 2019
, “Critical Review of Stabilized Nanaoparticle Transport in Porous Media
,” ASME J. Energy Resour. Technol.
, 141
(7
), p. 070801
. 10.1115/1.404192919.
Li
, S.
, Li
, B.
, Zhang
, Q.
, Li
, Z.
, and Yang
, D.
, 2018
, “Effect of CO2 on Heavy Oil Recovery and Physical Properties in Huff-n-Puff Processes Under Reservoir Conditions
,” ASME J. Energy Resour. Technol.
, 140
(7
), p. 072907
. 10.1115/1.403932520.
Lee
, J.
, Babadagli
, T.
, and Ozum
, B.
, 2018
, “Microemulsion Flooding of Heavy Oil Using Biodiesel Under Cold Conditions
,” Presented at the SPE International Heavy Oil Conference and Exhibition
, Kuwait City, Kuwait
, Dec. 10–12
, Paper SPE-193642-MS
.21.
Mohebbifar
, M.
, Ghazanfari
, M. H.
, and Vossoughi
, M.
, 2015
, “Experimental Investigation of Nano-Biomaterial Applications for Heavy Oil Recovery in Shaly Porous Models: A Pore-Level Study
,” ASME J. Energy Resour. Technol.
, 137
(1
), p. 014501
. 10.1115/1.402827022.
Wang
, Y.
, Kantzas
, A.
, Li
, B.
, Li
, Z.
, Wang
, Q.
, and Zhao
, M.
, 2008
, “New Agent for Formation–Damage Mitigation in Heavy-Oil Reservoir: Mechanism and Application
,” Presented at the SPE International Symposium and Exhibition on Formation Damage Control
, Lafayette, LA
, Feb. 13–15
, Paper SPE-112355-MS
.23.
Chen
, Z.
, and Yang
, D.
, 2021
, “Predicting Viscosities of Heavy Oils and Solvent-Heavy Oil Mixtures Using Artificial Neural Networks
,” ASME J. Energy Resour. Technol.
, 143
(11
), p. 113001
. 10.1115/1.404960324.
Shi
, Y.
, and Yang
, D.
, 2017
, “Experimental and Theoretical Quantification of Nonequilibrium Phase Behaviour and Physical Properties of Foamy Oil Under Reservoir Conditions
,” ASME J. Energy Resour. Technol.
, 139
(6
), p. 062902
. 10.1115/1.403696025.
Yang
, D.
, Tontiwachwuthikul
, P.
, and Gu
, Y.
, 2005
, “Interfacial Tensions of the Crude Oil + Reservoir Brine + CO2 Systems at Pressures Up to 31 MPa and Temperatures of 27 °C and 58 °C
,” J. Chem. Eng. Data
, 50
(4
), pp. 1242
–1249
. 10.1021/je050022726.
Yang
, D.
, and Gu
, Y.
, 2008
, “Determination of Diffusion Coefficients and Interface Mass-Transfer Coefficients of the Crude Oil-CO2 System by Analysis of the Dynamic and Equilibrium Interfacial Tensions
,” Ind. Eng. Chem. Res.
, 47
(15
), pp. 5447
–5455
. 10.1021/ie800053d27.
Li
, H.
, Yang
, D.
, and Tontiwachwuthikul
, P.
, 2012
, “Experimental and Theoretical Determination of Equilibrium Interfacial Tension for the Solvents-CO2-Heavy Oil Systems
,” Energy Fuels
, 26
(3
), pp. 1776
–1786
. 10.1021/ef201860f28.
Zheng
, S.
, and Yang
, D.
, 2013
, “Pressure Maintenance and Improving Oil Recovery by Means of Immiscible Water-Alternating-CO2 Processes in Thin Heavy-Oil Reservoirs
,” SPE Reser. Eval. Eng.
, 16
(1
), pp. 60
–71
. 10.2118/157719-PA29.
Ding
, Y.
, Zheng
, S.
, Meng
, X.
, and Yang
, D.
, 2019
, “Low Salinity Hot Water Injection With Addition of Nanoparticles for Enhancing Heavy Oil Recovery
,” ASME J. Energy Resour. Technol.
, 141
(7
), p. 072904
. 10.1115/1.404223830.
Pallas
, N. R.
, and Harrison
, Y.
, 1990
, “An Automated Drop Shape Apparatus and the Surface Tension of Pure Water
,” Colloids Surf.
, 43
(2
), pp. 169
–194
. 10.1016/0166-6622(90)80287-E31.
Karnanda
, W.
, Benzagouta
, M. S.
, Abdulrahman AlQuraishi
, A.
, and Amro
, M. M.
, 2013
, “Effect of Temperature, Pressure, Salinity, and Surfactant Concentration on IFT for Surfactant Flooding Optimization
,” Arabian J. Geosci.
, 6
(9
), pp. 3535
–3544
. 10.1007/s12517-012-0605-732.
Lagzi
, I.
, Meszaros
, R.
, Gelybo
, G.
, and Leelossy
, A.
, 2013
, Atmospheric Chemistry
, Eotvos Lorand University
, Hungary
.33.
Deniel
, R. M.
, and Danson
, M. J.
, 2013
, “Temperature and Catalytic Activity of Enzyme: A Fresh Understanding
,” FEBS Lett.
, 587
(17
), pp. 2738
–2743
. 10.1016/j.febslet.2013.06.02734.
Copeland
, R. A.
, 2000
, Enzyme: A Practical Instruction to Structure, Mechanism and Data Analysis
, Wilye-VCH
, New York
.35.
Fulcher
, R. A.
, Ertekin
, T.
, and Stahl
, C. D.
, 1985
, “Effect of Capillary Number and Its Constituents on Two-Phase Relative Permeability Curves
,” J. Pet. Technol.
, 37
(2
), pp. 249
–260
. 10.2118/12170-PA36.
Harbert
, L. W.
, 1983
, “Low Interfacial Tension Relative Permeability
,” Presented at the SPE Annual Technical Conference and Exhibition
, San Francisco, CA
, Oct. 5–8
, Paper SPE-12171-MS
.37.
Jahanbakhsh
, A.
, Sohrabi
, M.
, Fatemi
, S. M.
, and Shahverdi
, H.
, 2016
, “A Comparative Study of the Effect of Gas/Oil IFT Variation on Two- and Three-Phase Relative Permeability and the Performance of WAG Injection at Laboratory Scale
,” Presented at the SPE Improved Oil Recovery Conference
, Tulsa, OK
, Apr. 11–13
, Paper SPE-179571-MS
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