The Role of Inertinite Characteristics and Coal Porosity of Seam A-1 of Muara Enim Formation in West Merapi, Lahat, South Sumatera, Indonesia
DOI:
https://doi.org/10.25299/jgeet.2022.7.2.8986Keywords:
inertinite, porosity, mineral matter, permeability, fluid flow, vitrinite reflectanceAbstract
Coal contains a complex network of nano-, meso-, and a macro-pore can store fluids and allow fluids to flow through it. Nanoporosity in coal is primarily a result of molecules that have aromatic molecular structures and have been preserved in coal. Most adsorbate compounds, including gases, are stored here. The study area is located in South Sumatera, West Merapi Area, Lahat Regency. Geologically, the area in South Sumatra Basin belongs to the Middle-Late Miocene Muara Enim Formation. Using the ply-by-ply method, coal samples were taken directly from Seam-A in the coal mine walls outcrop, based on macroscopically determinable lithotype information. During laboratory analyses, coal is microscopically analyzed to determine the amount of porosity, permeability, and vitrinite reflectance. The purpose of this study is to investigate the change in composition and characteristics of inertinite macerals when the porosity value is varied.. Vitrinite content is between 91.00-92.80 %; liptinite 0.90-3.40%; inertinite 3.70-4.80%; mineral matter 0.7%-1.8%. Withh a vitrinite reflectance average of 0.34-0.36%, the variation in composition is an indication of changes in plant communities or coal facies. It is generally classified as sub-bituminous coal (ASTM). Porosity value of seam A upper is 1.9% and seam A lower 1.51%, permeability value seam A upper is 70.1 mD and seam A lower 27.1%. Composition of mineral matter in seam A upper is 0.8% and seam A lower 1.7%. The increasing number of inertinite pore is followed by lower porosity value. The inertinite maceral is predominantly aromatic with a high level of cross-linking, and exhibits a high level of aromatization and condensation. They have the highest carbon and the lowest oxygen hydrogen content. A coal maceral's porosity is composed of void spaces, such as open cell lumens preserved in semifusinite and sclerotinite. The porosity of cleats is the percentage of volume in relation to volume of coal, and the porosity of permeability. In coal, semifusinite has extensive interconnected pores that can form significant conduits for fluid flow.
Downloads
References
-1986., A. S.-A. (1986) ‘Coal Maceral Analysis. Published by The Standart Association of Australian Standart House’.
A. J. Barber, M. J. Crow, J. S. (1974) Sumatra, Geological Society Special Publication.
Bemmelen, R. W. V. A. N. (1969) ‘The Netherlands Company , Amsterdam THE ALPINE LC’OP OF THE TETHYS ZONE’, 8, Pp. 107–113.
Bustin, R. M. and Clarkson, C. R., 1998 (1999) ‘Geological controls on coalbed methane reservoir capacity and gas content:Int. J. Coal Geol., 1998, 38, (1–2), 3–26)’,
Fuel and Energy Abstracts, 40(6), p. 385.
Darman, H., Sidi, H.F., 2000 (2000) ‘An Outline Of The Geology Of Indonesia. Ikatan Ahli Geologi Indonesia’.
Diessel, C. F. K. et al. (1992) No Title.
Ginger, D. and Fielding, K. (2011) ‘The Petroleum Systems and Future Potential of the South Sumatra Basin’, 1(August 2005).
Harpalani, S., Chen, G., 1995. (1995) ‘Influence of gas production induced volumetric strain on permeability of coal. Geotech. Geol. Eng. 15, 303-325’.
Harpalani, S., Schraufnagel, R.A., 1990. (1990) ‘Shrinkage of coal matrix with release of gas and its impact on permeability of coal. Fuel 69. 551-556.’
Hodot, B.B., 1966 (1996) ‘Outburst of coal and coalbed gas. China Industry Press, Beijing, p.318’.
Isabel, S.-R. (2012) ‘Organic Petrology: An Overview’, Petrology - New Perspectives and Applications.
Koesoemadinata, R. P. (2002) ‘Outline of Tertiary Coal Basins of Indonesia. Sedimentology Newsletter. Number 17/I/2002. Published by The Indonesian Sedimentologist Forum, the sedimentology commission of the Indonesian Association of Geologist’.
Laubach, S. E. (1998) ‘Characteristics and origins of coal cleat : A review’.
Mazumder, S. et al. (2006) ‘Application of X-ray computed tomography for analyzing cleat spacing and cleat aperture in coal samples’, 68, pp. 205–222.
Pone, J. D. N., Halleck, P. M. and Mathews, J. P. (2009) ‘Energy Procedia Methane and Carbon Dioxide Sorption and Transport Rates in Coal at In-situ Conditions’, Energy Procedia, 1(1), pp. 3121–3128.
Rahmad, Kusumayudha, S. B. et al. (2018) ‘The Role of Coal Facies to Adsorption of Methane Gas: Case Study on Warukin and Tanjung Formation Binuang Area, South Kalimantan Province’.
Rahmad, B., Raharjo, S. and Rahmanda, H. A. (2020) ‘Underground Coal Gasification in the North Muara Tiga Besar Utara Area , East Merapi District , Lahat Regency , South Sumatera’, (April 2019), pp. 1–10.
Zhang, S. et al. (2014) ‘Journal of Natural Gas Science and Engineering Determining fractal dimensions of coal pores by FHH model : Problems and effects’, Journal of Natural Gas Science and Engineering, 21, pp. 929–939.
Downloads
Published
Issue
Section
License
Copyright @2019. This is an open-access article distributed under the terms of the Creative Commons Attribution-ShareAlike 4.0 International License which permits unrestricted use, distribution, and reproduction in any medium. Copyrights of all materials published in JGEET are freely available without charge to users or / institution. Users are allowed to read, download, copy, distribute, search, or link to full-text articles in this journal without asking by giving appropriate credit, provide a link to the license, and indicate if changes were made. All of the remix, transform, or build upon the material must distribute the contributions under the same license as the original.
