Analisis Mineral Matter dan Kualitas Batubara Blok Batulaki Kecamatan Satui, Kabupaten Tanah Bumbu, Provinsi Kalimantan Selatan
DOI:
https://doi.org/10.33536/jg.v9i03.1496Keywords:
Batulaki, kaolint, proximate, rank, sub-bituminousAbstract
Coal samples from Batulaki Block, Satui District, Tanah Bumbu Regency, South Kalimantan Province have been investigated on order to find out their mineralogical composition and quality. Mineral matter analyses were conducted using microscopic and X-ray diffractometry (XRD), whereas for coal quality analyses consist of proximate, total sulfur and calorific value. Results of mineral matters analysis show the coal samples dominated by kaolinite (Kln) which was followed by pyrite (Py), quartz (Qz), calcite (Cal) and goethite (Gt). The results of proximate, total sulfur, and calorific value analyses exhibit that coal quality of Batulaki block includes in high moisture, low ash, high volatile matter, medium fixed carbon and low sulphur. The average of calorific value is about 5516.94 cal/g indicating that coal rank of the Batulaki Block is classified as sub-bituminous coal.
Downloads
References
American Standard and Testing Materials. 1979. ASTM D 3177-02: Test Methods for Total Sulfur in the Analysis Sample of Coal and Coke. ASTM Book of Standards; ASTM: West Conshohocken, PA, Vol. 05.06.
Avicenna, F. M., Sufriadin, Budiman, A. A., Widodo, S. 2019. Analisis Mineralogi Dan Kualitas Batubara Desa Kadingeh Kecamatan Baraka, Kabupaten Enrekang, Sulawesi Selatan. Jurnal Geomine, Vol. 7, No. 2: 114-123.
Chou, C.L., 2012, Sulfur in Coals: A Review of Geochemistry and Origins: Intl. Journal of Coal Geology, vol. 100, p. 1-13.
Elliot, M.A dan YOHE, G.R. 1981. The Coal Industry and Coal Research and Development in Prospective Kentucky Geological Survey, University of Kentucky.
Firth, B, D, L., 1998. Trace Element in Coal Preparation. CSIRO Division of Coal and Energy Technology. Vol 19, pp. 297-317.
Flores, R. M. 2014. Coal and Coalbed Gas: Fuel in the future. Waltham USA.
Gluskoter, H., 1975. Mineral Matter and Trace Elements in Coal. Environ Earth Sci, Vol 10, pp. 01-41.
Lazaro, B.B., 2015, Halloysite and Kaolinite: Two Clay Minerals with Geological and Technological importance, Rev. Real Academia de Ciencias, Zaragoza, vol. 70, p. 7- 38.
Loye, H. 2013. X-ray Difraction How It Works. University of South Carolina. South Caroline, USA
Rao, D., Subba, V., and Gouricharan, T. 2016. Coal Processing and Utilization. CRC Press, Taylor & Francis Group. London. p 160, 162, 171.
Sanwani, E., Ibrahim, A., Sule D., dan Handayani, I. 1998. Pencucian. Batubara, Ciloto: Diklat Pencucian Batubara, p. II-36-II-41, V-1- V-7.
Sukandarrumidi. 1995. Batubara dan Gambut. Universitas Gajah Mada: Yogyakarta.
Swaine, D.J. 1990. Trace elements in coal. Butterworth, London.
Taylor, G.H., TeichmuellerM., Davis A., Diessel, C, F. K., Littje, R., and Robert, P. 1998. Organic petrologi. Gebrueder Borntraeger, Berlin, Stuttgart, 704 p.
Ward, C.R., 1986. Review of mineral matter in coal. Aust. Coal Geol., 87–110.
Ward, C.R., 2016. Analisis, origin, and significance of mineral matter in coal: An updated review, Intl. Journal of Coal Geology, vol. 165, pp. 1 – 27.
Warren, E., 1969. X-Ray Diffraction, Addittion Wesley Pub: Messachussets.
Xiuyi, T., 2009, Mineral Matter in Coal: Encyclopedia of Life Support Systems (EOLSS), Coal, Oil Shale, Natural Bitumen, Heavy Oil and Peat, vol.1., p. 1-10.
Downloads
Published
Issue
Section
License
Copyright (c) 2024 Jurnal Geomine
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
3.png)
1.png)
.png)
.png)
.png)
.png)
