Register      Login
The APPEA Journal The APPEA Journal Society
Journal of Australian Energy Producers
Shopping Cart: ( empty )
You are here: Home > Journals > AJ > AJ18125 | return to Australian Energy Producers Journal
RESEARCH ARTICLE (Non peer reviewed)
Contents Vol 59 (Conference Proceedings)

Subsurface engineering of CCUS in Australia (case studies)

Mohammad B. Bagheri A B and Matthias Raab A
+ Author Affiliations
- Author Affiliations

A CO2CRC limited, 11–15 Argyle Place South, Carlton, Vic. 3053, Australia.

B Corresponding author. Email: Mohammad.bagheri@co2crc.com.au

The APPEA Journal 59(2) 762-766 https://doi.org/10.1071/AJ18125
Accepted: 16 April 2019   Published: 17 June 2019

Abstract

Carbon capture utilisation and storage (CCUS) is a rapidly emerging field in the Australian oil and gas industry to address carbon emissions while securing reliable energy. Although there are similarities with many aspects of the oil and gas industry, subsurface CO2 storage has some unique geology and geophysics, and reservoir engineering considerations, for which we have developed specific workflows. This paper explores the challenges and risks that a reservoir engineer might face during a field-scale CO2 injection project, and how to address them. We first explain some of the main concepts of reservoir engineering in CCUS and their synergy with oil and gas projects, followed by the required inputs for subsurface studies. We will subsequently discuss the importance of uncertainty analysis and how to de-risk a CCUS project from the subsurface point of view. Finally, two different case studies will be presented, showing how the CCUS industry should use reservoir engineering analysis, dynamic modelling and uncertainty analysis results, based on our experience in the Otway Basin. The first case study provides a summary of CO2CRC storage research injection results and how we used the dynamic models to history match the results and understand CO2 plume behaviour in the reservoir. The second case study shows how we used uncertainty analysis to improve confidence on the CO2 plume behaviour and to address regulatory requirements. An innovative workflow was developed for this purpose in CO2CRC to understand the influence of each uncertainty parameter on the objective functions and generate probabilistic results.

Keywords: dynamic modelling, reservoir engineering, uncertainty analysis.

Dr Mohammad Bagheri holds a PhD in Petroleum Engineering from the Sharif University of Technology in Tehran. For the past 15 years he has worked as a Reservoir Engineer in the oil and gas industry in the Middle East, North Sea and Australia. He is now working as subsurface manager with CO2CRC Ltd in Melbourne.

Dr Matthias Raab is an experienced manager with international credentials in successful, high profile and complex projects in industry and academia. He has 23 years of experience in commercial and R&D environments with major sector clients. At CO2CRC Ltd, Dr Raab manages large project portfolios with teams of up to 70 people and annual budgets of up to $20M. As COO, Dr Raab has strategic and operational responsibility for CO2CRC’s research facilities, research programs and the delivery of major research and infrastructure projects. Dr Raab manages a group of Senior Program, Project and Operations Managers and provides leadership to CO2CRC’s strategic planning and implements new strategic initiatives. Dr Raab’s overall portfolio includes the $45M research program in Carbon Capture and Geological Carbon Storage, the CO2CRC Otway Field Facility, the Stage 3 Expansion of the Otway Project and the $51.6M infrastructure grant awarded to CO2CRC under the Education Investment Fund. In previous roles, Dr Raab managed Australia’s largest 2D marine seismic survey in Bass Strait, led the Victorian CCS initiative exploring for industrial-scale CO2 storage in the Gippsland Basin and was a Project Manager building and documenting the border between the Kingdom of Saudi Arabia and the Republic of Yemen.

References

Akkurt, R., Kersey, D. G., and Zainalabedin, K. A. (2006). Challenges for everyday-NMR: an operator’s perspective. Society of Petroleum Engineers. 10.2118/102247-MS10.2118/102247-MS

Bachu, S. (2013). Drainage and imbibition CO2/brine relative permeability curves at in situ conditions for sandstone formations in Western Canada. Energy Procedia 37, 4428–4436.
Drainage and imbibition CO2/brine relative permeability curves at in situ conditions for sandstone formations in Western Canada.Crossref | GoogleScholarGoogle Scholar |

Bachu, S., Bonijoly, D., Bradshaw, J., Burruss, R., Holloway, S., Christensen, N. P., and Mathiassen, O. M. (2007). CO2 storage capacity estimation: methodology and gaps. International Journal of Greenhouse Gas Control 1, 430–443.
CO2 storage capacity estimation: methodology and gaps.Crossref | GoogleScholarGoogle Scholar |

Bemer, J., and Lombard, J. M. (2010). From injectivity to integrity studies of CO2 geological storage. Chemical alteration effects on carbonates petrophysical and geomechanical properties. Oil & Gas Science and Technology 65, 445–459.
From injectivity to integrity studies of CO2 geological storage. Chemical alteration effects on carbonates petrophysical and geomechanical properties.Crossref | GoogleScholarGoogle Scholar |

Dentz, M., and Tartakovsky, D. (2009). Abrupt-interface solution for carbon dioxide injection into porous media. Transport in Porous Media 79, 15–27.
Abrupt-interface solution for carbon dioxide injection into porous media.Crossref | GoogleScholarGoogle Scholar |

IPCC (2005). IPCC Special Report on Carbon Dioxide Capture and Storage. Prepared by Working Group III of the Intergovernmental Panel on Climate Change (Eds. B. Metz, O. Davidson, H. C. de Coninck, M. Loos, and L. A. Meyer.). (Cambridge University Press: Cambridge, UK and New York, NY, USA.)

GCCSI (2018). The global status of CCS. Available at https://www.globalccsinstitute.com/resources/global-status-report/ [verified 9 May 2019]

Jenkins, C., Bagheri, M., Baraclough, P., Dance, T., Ennis-King, J., Freifield, B., Glubokovskikh, S., Gunning, J., LaForce, T., Marshall, S., Paraschivoiu, E., Paterson, L., Pevzner, R., Tenthorey, E., Watson, M.: (2018). Fit for purpose monitoring - a progress report on the CO2CRC Otway Stage 3 project, GHGT-14, 21–25 October 2018, Melbourne, Australia.

Menhali, A., Reynolds, C., Lai, P., Niu, B., Nicholls, N., Crawshaw, J., and Krevor, S. (2014). Advanced reservoir characterization for CO2 storage. International Petroleum Technology Conference, Doha, Qatar, 20–22 January 2014.

Nordbotten, J. M., and Celia, M. A. (2006). Similarity solutions for fluid injection into confined aquifers. Journal of Fluid Mechanics 561, 307–327.
Similarity solutions for fluid injection into confined aquifers.Crossref | GoogleScholarGoogle Scholar |

Papanastasiou, P., Papamichos, E., and Atkinson, C. (2016). Hydraulic fracturing in CO2 geological storage. American Rock Mechanics Association.

Samuelson, J., and Spiers, C. J. (2012). Fault friction and slip stability not affected by CO2 storage: Evidence from short-term laboratory experiments on North Sea reservoir sandstones and caprocks. International Journal of Greenhouse Gas Control 11, S78–S90.
Fault friction and slip stability not affected by CO2 storage: Evidence from short-term laboratory experiments on North Sea reservoir sandstones and caprocks.Crossref | GoogleScholarGoogle Scholar |

Sarris, E., Gravanis, E., and Papanastasiou, P. (2014). Investigation of self-similar interface evolution in carbon dioxide sequestration in saline aquifers. Transport in Porous Media 103, 341–359.
Investigation of self-similar interface evolution in carbon dioxide sequestration in saline aquifers.Crossref | GoogleScholarGoogle Scholar |

Schulze-riegert, R., Bagheri, M., Krosche, M., Kueck, N., and Ma, D. (2011). Multiple-objective optimization applied to well path design under geological uncertainty. Society of Petroleum Engineers.10.2118/141712-MS10.2118/141712-MS

Stewart, G., Jaafar, M. D., and Du, K. F. (1989). Improved methods for the modeling and conduct of vertical interference tests across a tight zone. Society of Petroleum Engineers.10.2118/19798-MS10.2118/19798-MS

Vallin, V., Pereira, J. M., Fabbri, A., and Wong, H. (2013). Numerical modelling of the hydro-chemo-mechanical behaviour of geomaterials in the context of CO2 injection. International Journal for Numerical and Analytical Methods in Geomechanics 37, 3052–3069.
Numerical modelling of the hydro-chemo-mechanical behaviour of geomaterials in the context of CO2 injection.Crossref | GoogleScholarGoogle Scholar |

Watson, M., Bagheri, M., Pevzner, R., Dance, T., Gurevich, B., Ennis-King, J., Glubokovskikh, S., Uroservic, M., LaForce, T., Tenthorey, E., Paterson, L., Cinar, Y., Freifeld, B., Singh, R., and Raab, M. (2018). The Otway Stage 2C Project – End to end CO2 storage in a saline formation, comprising characterisation, injection and monitoring, 14th International Conference on Greenhouse Gas Control Technologies, GHGT-14, 21–25 October 2018, Melbourne, Australia.

Wojtacki, K., Lewandowska, J., Gouze, Ph., and Lipkowski, A. (2015). Numerical computations of rock dissolution and geomechanical effects for CO2 geological storage. International Journal for Numerical and Analytical Methods in Geomechanics 39, 482–506.
Numerical computations of rock dissolution and geomechanical effects for CO2 geological storage.Crossref | GoogleScholarGoogle Scholar |