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RESEARCH ARTICLE
Contents Vol 59 (Papers)

Impact of in-seam drilling performance on coal seam gas production and remaining gas distribution

Fengde Zhou A B , Glen Fernandes A , Joao Luft A , Kai Ma A , Mahmoud Oraby A , Mariano Ospina Guevara A , Dan Kuznetsov A , Brad Pinder A and Sean Keogh A
+ Author Affiliations
- Author Affiliations

A Arrow Energy Pty Ltd, Brisbane, Qld 4072, Australia.

B Corresponding author. Email: fengde.zhou@arrowenergy.com.au

The APPEA Journal 59(1) 328-342 https://doi.org/10.1071/AJ18049
Submitted: 14 December 2018  Accepted: 22 February 2019   Published: 17 June 2019

Abstract

Drilling horizontal wells in low permeability coal seams is a key technology to increase the drainage area of a well, and hence, decrease costs. It’s unavoidable that some parts of the horizontal section will be drilled outside the targeted coal seam due to unforeseen subsurface conditions, such as sub-seismic faulting, seam rolls, basic geosteering tools, drilling practices and limited experiences. Therefore, understanding the impact of horizontal in-seam drilling performance on coal seam gas (CSG) production and remaining gas distribution is an important consideration in drilling and field development plans. This study presents a new workflow to investigate the impact of horizontal in-seam performance on CSG production and gas distribution for coal seams with different porosity, permeability, permeability anisotropy, initial gas content (GC), initial gas saturation and the ratio of in-coal length to in-seam length (RIIL). First, a box model with an area of 2 km × 0.3 km × 6 m was used for conceptual simulations. Reduction indexes of the cumulative gas production at the end of 10 years of simulations were compared. Then, a current Chevron well consisting of a vertical well and two lateral wells, was selected as a case study in which the impact of outside coal drilling on history matching and remaining gas distribution were analysed. Results show that the RIIL plays an increasing role for cases with decreasing permeability or initial gas saturation, while it plays a very similar role for cases with varied porosity, permeability anisotropy and GC. The size and location of outside coal drilling will affect the CSG production and remaining gas distribution.

Keywords: Chevron well, horizontal well, in-coal length, in-seam length, reservoir simulation.

Fengde Zhou is a Senior Geologist at the Arrow Energy Pty Ltd. Before joining Arrow, he was a Research Fellow at the University of Queensland and University of New South Wales and an associate professor at the China University of Geosciences. Fengde received his PhD in Petroleum Engineering from China University of Geosciences in 2009. He is a Professional Member of the SPE and an Editorial Board Member of the Journal ofPetroleum Science and Engineering. He was awarded as a Top Reviewer by the Journal of PetroleumScience and Engineering in 2012. He is interested in reservoir characterisation for conventional and unconventional oil and gas reservoirs.

Glen Fernandes is a Reservoir Engineer at Arrow Energy Pty Ltd and has over 7 Years of experience in unconventional gas reservoirs, ranging from exploration, well testing, forecasting, dynamic modelling, and field development planning to operations. Glen has received his Msc in Oil and Gas Engineering from the University of Western Australia, Perth, in 2011 and his Bsc in Mechanical Engineering from Visvesvaraya Technological University, Belgaum, India in 2009. Key areas of interest are: Dynamic Modelling, Well testing, Data analytics, Production Forecasting, Field development planning and production optimisation.

Joao Luft is a Senior Geologist at the Arrow Energy Pty Ltd. In 2005, he received a PhD in Earth Sciences from Federal University of Rio Grande do Sul (Brazil) in a project of geologic correlation between Brazil and Africa (Namibia). In Australia, Joao has more than 13 years' experience working initially as exploration and well site geologist for coal and coal seam gas industry in Queensland and Victoria. Key contributions include projects at Gippsland Basin (CSG), Surat, Nagoorin and Bowen Basins where he worked as consulting geologist. In the last 8 years, Joao Luft has been involved in Arrow's Moranbah Gas Project of the Bowen Basin as production and development geologist aiming to further extend this field production. Key areas of interest are: structural geology, geochemistry, static modelling, coal properties, geomechanics, and optimal lateral well placement into coal reservoirs.

Kai Ma is a Reservoir Engineer at Arrow Energy Ltd and has 2 years of experience in unconventional resources. Before joining Arrow Energy Ltd,Kai Mahas worked as a Reservoir Engineer for conventional projects in South Sudan, Chad and Mozambique for 6 years. She received her Msc fromthe Petroleum University of China (Beijing) in 2011.

Mahmoud Oraby is a Principal Petrophysicist at Arrow Energy Pty Ltd. Mahmoud holds a BSc in Petroleum and Mining Engineering and has global experience in both E&P and Service companies. He has global experience in high profile projects and has worked for reputed market leaders in Egypt, Middle East, US, Asia, New Zealand and Australia . Mahmoud has robust skills in sensor physics, core analysis, data processing and interpretation/integration, with maximum efficient utilisation in field development process and field studies in support of static or dynamic modelling and reservoir surveillance activities.

Mariano Ospina is a Senior Production Technologist at Arrow Energy Pty Ltd and has over 5 years of experience in unconventional gas reservoirs. In prior the 6 years Mariano worked in conventional assets as a Production Technologist for an offshore greenfield in New Zealand, onshore brown fields in Austria and as a Completions Engineers in Austria. Mariano received MSc accreditation in Petroleum Engineering from Heriot Watt University, Edinburgh, Scotland in 2007 and his BSc is in Mechanical Engineering from Universidad de America, Bogotá, Colombia in 2003.

Dan Kuznetsov is a principal reservoir engineer at Arrow Energy. His current work focuses on the appraisal and development of coal seam gas fields. Previously, Dan worked on various conventional hydrocarbon projects with major E&P and service companies. He has a special interest in reservoir simulation and production forecasting.Dan holds a MSc degree in physics from Lomonosov Moscow State University and a PhD in physics and mathematics from the Russian Academy of Sciences.

Brad Pinder received his Batchelor of Applied Science with Honours degree in Geoscience for the Queensland University of Technology in 2001. Since then he has been involved in CSG exploration and development in a variety of eastern Australian basins in a number of roles. Brad is currently the Geology Discipline Lead for Arrow Energy.

Sean Keogh is employed by Arrow Energy Pty Ltd as Geology and Petrophysics Manager, and also as Subsurface Manager for the company's Bowen Basin assets. Sean has worked in unconventional reservoirs for over 15 years', with experience across assets in all stages of development, exploration, and appraisal. Sean graduated with a BSc (Geology) from the Queensland University of Technology (QUT) in 1991.

References

Adesina, F. A., Churchill, A., and Olugbenga, F. (2011). Modeling productivity index for long horizontal well. Journal of Energy Resources Technology 133, 033101.
Modeling productivity index for long horizontal well.Crossref | GoogleScholarGoogle Scholar |

Al-Arouri, K. R., McKirdy, D. M., and Boreham, C. J. (1998). Oil-source correlations as a tool in identifying the petroleum systems of the southern Taroom Trough, Australia. Organic Geochemistry 29, 713–734.
Oil-source correlations as a tool in identifying the petroleum systems of the southern Taroom Trough, Australia.Crossref | GoogleScholarGoogle Scholar |

Aminzadeh, F., and Dasgupta, S. N. (2013). Geophysics in Drilling. Developments in Petroleum Science 60, 223–246.
Geophysics in Drilling.Crossref | GoogleScholarGoogle Scholar |

Baker, J. C., and de Caritat, P. (1992). Post-depositional history of the Permian Sequence in the Denison Trough, eastern Australia. AAPG Bulletin 76, 1224–1249.

Baker, J. C., Fielding, C. R., De Caritat, P., and Wilkinson, M. M. (1993). Permian evaluation of sandstone composition in a complex back-arc extensional to foreland basin; the Bowen Basin, eastern Australia. Journal of Sedimentary Research 63, 881–893.

Bond, A., Zhu, D., Kamdom, R., and Hill, A.D. (2006). The effect of well trajectory on horizontal well performance. In ‘International Oil & Gas Conference and Exhibition in China, Beijing, China, 5–7 December.’ (Society of Petroleum Engineers) 10.2118/104183-MS.

Burkett, M. A. (2003). Application of horizontal drilling in low-permeability reservoirs. In ‘AAPG Southwest Section Meeting, Ruidoso, New Mexico, 6–8 June 2002.’ pp. 139–146. (APPG: Tulsa, OK).

Calvert, S. E. E. (2002). Log interpretation in horizontal wells. Ph.D. thesis, University of Leicester, Leicester, UK.

Exon, N. F. (1976). Geology of the Surat Basin, Queensland. Geol. Geophys. Bull. 166, 160–184.

Faiz, M., Saghafi, A., Sherwood, N., and Wang, I. (2007). The influence of petrological properties and burial history on coal seam methane reservoir characterisation, Sydney Basin, Australia. International Journal of Coal Geology 70, 193–208.
The influence of petrological properties and burial history on coal seam methane reservoir characterisation, Sydney Basin, Australia.Crossref | GoogleScholarGoogle Scholar |

Fielding, C. R., Falkner, A. J., and Scott, S. G. (1993). Fluvial response to foreland basin overfilling; the Late Permian Rangal Coal Measures in the Bowen Basin, Queensland, Australia. Sedimentary Geology 85, 475–497.
Fluvial response to foreland basin overfilling; the Late Permian Rangal Coal Measures in the Bowen Basin, Queensland, Australia.Crossref | GoogleScholarGoogle Scholar |

Fielding, C. R., Stephens, C. J., and Holcombe, R. J. 1997. Permian stratigraphy and palaeogeography of the eastern Bowen Basin, Gogango Overfolded Zone and Strathmuir Synclinorium in the Rockhampton–Mackay region, central Queensland. In ‘Tectonics and Metallogenesis of the New England Orogen: Geological Socity of Australia Special Publication 19’ (Eds. P.M. Ashley and P.G. Flood), pp. 80–95. (Geological Society of Australia: Hornsby, NSW).

Fu, X., Qin, Y., Wang, G. X. G., and Victor, R. (2009). Evaluation of gas content of coalbed methane reservoirs with the aid of geophysical logging technology. Fuel 88, 2269–2277.
Evaluation of gas content of coalbed methane reservoirs with the aid of geophysical logging technology.Crossref | GoogleScholarGoogle Scholar |

Hammod, D. R. 1990. Modelling the geological structure of the Bowen Basin, present and future. In ‘Bowen Basin Symposium 1990: proceedings: incorporating GSA (QLD Division) Field Conference: Mackay, Qld’ ( Ed. J.W. Beeston) pp. 7–9. (Geological Society of Australia: Brisbane, QLD) .

Hemza, P., Sivek, M., and Jirásek, J. (2009). Factors influencing the methane content of coal beds of the Czech part of the Upper Silesian Coal Basin, Czech Republic. International Journal of Coal Geology 79, 29–39.
Factors influencing the methane content of coal beds of the Czech part of the Upper Silesian Coal Basin, Czech Republic.Crossref | GoogleScholarGoogle Scholar |

Karacan, C. Ö. (2013). Integration of vertical and in-seam horizontal well production analyses with stochastic geostatistical algorithms to estimate pre-mining methane drainage efficiency from coal seams: Blue Creek seam, Alabama. International Journal of Coal Geology 114, 96–113.
Integration of vertical and in-seam horizontal well production analyses with stochastic geostatistical algorithms to estimate pre-mining methane drainage efficiency from coal seams: Blue Creek seam, Alabama.Crossref | GoogleScholarGoogle Scholar | 26435557PubMed |

Karacan, C. Ö., Diamond, W. P., and Schatzel, S. J. (2007). Numerical analysis of the influence of in-seam horizontal methane drainage boreholes on longwall face emission rates. International Journal of Coal Geology 72, 15–32.
Numerical analysis of the influence of in-seam horizontal methane drainage boreholes on longwall face emission rates.Crossref | GoogleScholarGoogle Scholar |

Keim, S. A., Luxbacher, K. D., and Karmis, M. A. (2011). Numerical study on optimization of multilateral horizontal wellbore patterns for coalbed methane production in Southern Shanxi Province, China. International Journal of Coal Geology 86, 306–317.
Numerical study on optimization of multilateral horizontal wellbore patterns for coalbed methane production in Southern Shanxi Province, China.Crossref | GoogleScholarGoogle Scholar |

Korsch, R. J. 2004. A Permian-Triassic retroforeland thrust system – The New England orogen and adjacent sedimentary basins, eastern Australia. In ‘Thrust tectonics and hydrocarbon system AAPG Memoir 82.’ (Ed. K. R. McClay), pp. 515–537. (AAPG: Tulsa, OK)

Laubach, S. E., Marrett, R. A., Olson, J. E., and Scott, A. R. (1998). Characteristics and origins of coal cleat: a review. International Journal of Coal Geology 35, 175–207.
Characteristics and origins of coal cleat: a review.Crossref | GoogleScholarGoogle Scholar |

Lee, W.J. 1982. ‘Well Testing’. (Society of Petroleum Engineers: Dallas, TX)

Mallett, C. W., Pattison, C., McLennan, T., Balfe, P., and Sullivan, D. 1995. Bowen Basin. In,’Geology of Australian Coal Basins, Special Publication No. 1’. (Eds. C.R. Ward, H.J. Harrington, C.W. Mallett and J.W. Beeston) pp. 299–339 (Geological Society of Australia, Coal Geology Group: Hornsby, NSW).

Michaelsen, P., Henderson, R. A., Crosdale, P. J., and Mikkelsen, S. O. (2000). Facies Architecture and Depositional Dynamics of the Upper Permian Rangal Coal Measures, Bowen Basin, Australia. Journal of Sedimentary Research 70, 879–895.
Facies Architecture and Depositional Dynamics of the Upper Permian Rangal Coal Measures, Bowen Basin, Australia.Crossref | GoogleScholarGoogle Scholar |

Murray, C. G., Scheibner, E., and Walker, R. N. (1989). Regional geological interpretation of a digital coloured residual Bouguer gravity image of eastern Australia with a wavelength cut-off of 250 km. Australian Journal of Earth Sciences 36, 423–449. 10.1080/08120098908729498.

Mutalik, P. N., and Magness, W. D. (2006). Production data analysis of horizontal CBM wells in Arkoma Basin. In ‘SPE Annual Conference and Exhibition, San Antonio, 24–27 September 2006’. (Society of Petroleum Engineers). org/10.2118/103206-MS.

O’Brien, P. E. 1984. Bowen Basin beneath Surat Basin, In ‘Permian Coals of eastern Australia. Bureau of Mineral Resources Bulletin 231’. (Ed. H.J. Harrington). pp. 93–105. (Bureau of Mineral Resources: Canberra, ACT).

Ranney, L. (1939). The First Horizontal Well. The Petroleum Engineer 11, 25--30.

Schlumberger 2007. Eclipse Blackoil Reservoir Simulation. Training and Exercise Guide. Available at http://civil.gisland.org/wp-content/uploads/ECLIPSE-blackoil2007.pdf [verified 2 October 2018]

Shi, Z., Zhao, Y., Qi, H., Liu, J., and Hu, Z. (2011). Research and application of drilling technology of extended-reach horizontally-intersected well used to extract coalbed methane. Procedia Earth and Planetary Science 3, 446–454.
Research and application of drilling technology of extended-reach horizontally-intersected well used to extract coalbed methane.Crossref | GoogleScholarGoogle Scholar |

Singh, S. K. 2013. Examining the technology of CBM multiple-lateral horizontal well. Available at https://businessdocbox.com/Green_Solutions/70394866-Examining-the-technology-of-cbm-multiple-lateral-horizontal-well.html [verified 28 September 2018]

Thwaites, N., and Suh, A. (2014). Use of near bit azimuthal Gamma Ray and inclination tool improves geosteering in CBM Wells, Airth Field, Scotland. In ‘SPE/EAGE European Unconventional Resources Conference and Exhibition, Vienna, Austria, 25–27 February 2014.’ (Society of Petroleum Engineers) 10.2118/167700-MS

Totterdell, J., Barker, A. T., Wells, A. T., and Hoffmann, K. L. 1995. Basin phases and sequence stratigraphy of the Bowen Basin. In ‘Proceedings of the Bowen Basin Symposium. Geological Society of Australia, Queensland Division’. (Eds. I.W., J.W. Beeston, and L.H. Hamilton, L.H). pp. 247–256. (Geological Society of Australia: Mackay, Qld).

Towler, B., Firouzi, M., Underschultz, J., Rifkin, W., Garnett, A., Schultz, H., Esterle, J., Tyson, S., and Witt, K. (2016). An overview of the coal seam gas developments in Queensland. Journal of Natural Gas Science and Engineering 31, 249–271.
An overview of the coal seam gas developments in Queensland.Crossref | GoogleScholarGoogle Scholar |

Uysal, I. T., Golding, S. D., and Thiede, D. S. (2001). KeAr and RbeSr dating of authigenic illiteesmectite in Late Permian coal measures, Queensland, Australia: implication for thermal history. Chemical Geology 171, 195–211.
KeAr and RbeSr dating of authigenic illiteesmectite in Late Permian coal measures, Queensland, Australia: implication for thermal history.Crossref | GoogleScholarGoogle Scholar |

Wheeler, A. J., Billings, T., Rennie, A., Lee, R., Little, R., Huiszoon, C., and Boonen, P. 2012. The introduction of an at-bit natural Gamma ray imaging tool reduces risk associated with real-time geosteering decisions in coalbed methane horizontal wells. In ‘SPWLA 53rd Annual Logging Symposium, Cartagena, 16–20 June 2012’. SPWLA-2012-167 (SPWLA).

Yang, Y., Cui, S., Ni, Y., Zhang, G., Li, L., and Meng, Z. (2016). Key technology for treating slack coal blockage in CBM recovery: A case study from multi-lateral horizontal wells in the Qinshui Basin. Natural Gas Industry B 3, 66–70.
Key technology for treating slack coal blockage in CBM recovery: A case study from multi-lateral horizontal wells in the Qinshui Basin.Crossref | GoogleScholarGoogle Scholar |

Zhang, Y., Yang, Y., Shao, G., Chen, L., Wei, N., and Zhang, L. (2017). Problems in development of high-rank CBM horizontal wells in the Fanzhuang-Zhengzhuang Block in the Qinshui Basin and countermeasures. Natural Gas Industry B 4, 423–431.
Problems in development of high-rank CBM horizontal wells in the Fanzhuang-Zhengzhuang Block in the Qinshui Basin and countermeasures.Crossref | GoogleScholarGoogle Scholar |

Zhao, Y., Shi, Z., Hao, S., Liu, J., Yang, Z., and Wang, S. (2014). Well completion technology using screen pipe for horizontally-intersected well in soft coal seam. Procedia Engineering 73, 311–317.
Well completion technology using screen pipe for horizontally-intersected well in soft coal seam.Crossref | GoogleScholarGoogle Scholar |

Zhou, F. (2012). History matching and production prediction of a horizontal coalbed methane well. Journal of Petroleum Science Engineering 96–97, 22–36.
History matching and production prediction of a horizontal coalbed methane well.Crossref | GoogleScholarGoogle Scholar |

Zhou, F., Yao, G., and Tyson, S. (2015). Impact of geological modelling processes on spatial coalbed methane resource estimation. International Journal of Coal Geology 146, 14–27.
Impact of geological modelling processes on spatial coalbed methane resource estimation.Crossref | GoogleScholarGoogle Scholar |