Abstract
Coal gasification with CO2 has emerged as a cleaner and more efficient way for the production of energy, and it offers the advantages of CO2 mitigation policies through simultaneous CO2 sequestration. In the present investigation, a feasibility study on the gasification of three low-quality, high-sulphur coals from the north-eastern region (NER) of India in a CO2 atmosphere using thermogravimetric analysis (TGA-DTA) has been made in order to have a better understanding of the physical and chemical characteristics in the process of gasification of coal. Model-free kinetics was applied to determine the activation energies (E) and pre-exponential factors (A) of the CO2 gasification process of the coals. Multivariate non-linear regression analyses were performed to find out the formal mechanisms, kinetic model, and the corresponding kinetic triplets. The results revealed that coal gasification with CO2 mainly occurs in the temperature range of 800∘–1400∘C and a maximum of at around 1100∘C. The reaction mechanisms responsible for CO2 gasification of the coals were observed to be of the ‘nth order with autocatalysis (CnB)’ and ‘nth order (Fn) mechanism’. The activation energy of the CO2 gasification was found to be in the range 129.07–146.81 kJ mol−1.
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References
Ahmed M 1996 Petrology of Oligocene coal, Makum coalfield, Assam, northeast India; Int. J. Coal Geol. 30 319–325.
ASTM 2011a Test Method for Moisture in the Analysis Sample of Coal and Coke; ASTM International, West Conshohocken, PA.
ASTM 2011b Annual book of ASTM standards. Test Method for Ash in the Analysis Sample of Coal and Coke; ASTM International, West Conshohocken, PA.
ASTM 2011c Test Method for Volatile Matter in the Analysis Sample of Coal and Coke; ASTM International, West Conshohocken, PA.
ASTM D3176-15 2015 West Conshohocken PA. http://www.astm.org.
ASTM D5016-08e1 2015 West Conshohocken PA. http://www.astm.org.
Aranda G, Grootjes A J, van der Meijden C M, van der Drift A, Gupta D F, Sonde R R, Poojari S and Mitra C B 2016 Conversion of high-ash coal under steam and CO2 gasification conditions; Fuel Process. Technol. 141 (1) 16–30.
Baruah B P and Khare P 2007 Desulphurization of oxidized Indian coals with solvent extraction and alkali treatment; Energy and Fuels 21 2156–2164.
Behera P 2007 Volatile displacement of Meghalaya coals – A pointer to explore low sulphur coals; J. Earth Syst. Sci. 116 137–142.
Budrugeac P 2013 Thermokinetic study of the thermo-oxidative degradation of a composite epoxy resin material; Rev. Roum. Chim. 58 (4–5) 371–379.
Das T, Saikia B K and Baruah B P 2015 Formation of carbon nano-balls and carbon nano-tubes from northeast Indian Tertiary coal: Value added products from low-quality coal; Gondwana Res. 31 295–304.
Ergun S 1956 Kinetics of the reaction of carbon with carbon dioxide; J. Phys. Chem. 60 (4) 480–485.
Gomes M L I, Osorio E and Vilela A C F 2006 Thermal analysis evaluation of the reactivity of the mixture for injection in the blast furnace; Mat. Res. 9 (1) 91–95, doi:10.1590/S1516-14392006000100017.
Himus W G 1954 Fuel testing laboratory methods in fuel technology; A text book; University Press, Aberdeen, Great Britain.
Huo W, Zhou Z, Chen X, Dai Z and Yu G 2014 Study on CO2 gasification reactivity and physical characteristics of biomass, petroleum coke and coal chars; Bioresource Technol. 159 143–149.
Irfan M F, Usman M R and Kusakabe K 2011 Coal gasification in CO2 atmosphere and its kinetics since 1984: A brief review; Energy 36 12–40.
ISO/CD 18894 2006 Coke-determination of coke reactivity index (CRI) and coke strength after reaction (CSR).
Iyengar M S, Guha S and Beri M L 1960 The nature of sulphur groupings in abnormal coals; Fuel 39 235–243.
Jeffery G H, Bassett J, Mendham J and Denny R C 1989 Vogel’s textbook of quantitative inorganic chemistry; 5th edn.
Jing X, Wang Z, Zhang Q, Yu Z, Li C, Huang J and Fang Y 2013 Evaluation of CO2 gasification reactivity of different coal rank chars by physico-chemical properties; Energy and Fuels 27 7287–7293.
Kim Y T, Seo D and Hwang J 2011 Study of the effect of coal type and particle size on char–CO2 gasification via gas analysis; Energy and Fuels 25 (11) 5044–5055.
Kuznetsov P N, Kolesnikova S M and Kuznetsova L I 2013 Steam gasification of different brown coals catalysed by the naturally occurring calcium species; Int. J. Clean Coal Energ. 2 1–11.
Lahijani P, Zainal Z A and Mohamed A R 2012 Catalytic effect of iron species on CO2 gasification reactivity of oil palm shell char; Thermochim. Acta 546 24–31.
Machado J G M S, Osorio E and Vilela A C F 2010 Reactivity of Brazillian coal and blends aiming to their injection into blast furnaces; Mat. Res. 13 (3) 287–292.
Mishra A, Gautam S and Sharma T 2014 Effect of char structure on coal gasification; J. Basic Appl. Eng. Res. 1 1–3.
Ng K W, MacPhee J A, Giroux L and Todoschuk T 2011 Reactivity of bio-coke with CO2; Fuel Process. Technol. 92 801–804.
Saha S, Sahu G, Sharma B K and Sharma T 2012 Variation of CO2 gasification reactivity in gravity separated coal samples; J. Mines, Metals & Fuels 60 7–8.
Saha S, Sahu G, Dutta S, Chavan P, Sinha A K, Sharma B K and Sharma T 2013 Studies on CO2 gasification reactivity of high ash Indian coal; IJETAE 3 29–33.
Sahu H B 2013 Implementing clean coal technology through gasification and liquefaction – the Indian perspective; Int. J. Chem. Tech. Res. 5 824–830.
Saikia B K, Goswamee R L, Baruah B P and Baruah R K 2009 Occurrence of some hazardous metals in Indian coals; Coke Chem. USSR 52 54–59.
Saikia B K, Dutta A, Saikia L, Ahmed S and Baruah B P 2014a Ultrasonic assisted cleaning of high-sulphur Indian coals in water and mixed alkali; Fuel Process. Technol. 123 107–113.
Saikia B K, Ward C R, Oliveira M L S, Hower J C, Baruah B P, Braga M and Silva L F 2014b Geochemistry and nano-mineralogy of two medium-sulphur northeast Indian coals; Int. J. Coal Geol. 121 26–34.
Sawettaporn S, Bunyakiat K and Kitiyanan B 2009 CO2 gasification of Thai coal chars: Kinetics and reactivity studies; Korean J. Chem. Eng. 26 (4) 1009–1015.
Sbirrazzuoli N, Vincent L, Mija A and Guigo N 2009 Integral differential and advance isoconversional methods. Complex mechanism and isothermal predicted conversion-time curves; Chemomet. Intell. Lab. Syst. 96 219–226.
Sharma A, Saikia B K and Baruah B P 2012 Maceral contents of Tertiary Indian coals and their relationship with calorific values; IJIRD 1 (7) 196–203.
Sinag A, Sinek K, Tekes A T, Misirlioglu Z, Canel M and Wang L 2003 Study on CO2 gasification reactivity of chars obtained from Soma–Isikar Lignite (Turkey) at various coking temperature; Chem. Eng. Process. 42 1027–1103.
Skodras G 2013 Catalysis and compensation effect of K 2 CO 3 in low-rank coal-CO2 gasification; Cent. Eur. J. Chem. 11 (7) 1187–1200.
Stach E, Mackowsky M T, Teichmuller M, Taylor G H, Chandra D, Teichmuller R (eds) 1982 Stach Text book of Coal Petrology; Borntniger, Stuttgart.
Takayuki T, Hashimot K and Silveston P L 1985 Reactivities of 34 coals under steam gasification; Fuel 64 1438–1442.
Veraa M J and Bell A T 1978 Effect of alkali metal catalysts on gasification of coal char; Fuel 57 194–200.
Wei H, Zhijie Z, Chen X, Dai Z and Yu G 2014 Study on CO2 gasification reactivity and physical characteristics of biomass, petroleum coke and coal chars; Bioresource Technol. 159 143–149.
Yuan S, Chen X L, Li J and Wang F C 2011 CO2 gasification kinetics of biomass char derived from high-temperature rapid pyrolysis; Energy and Fuels 25 (5) 2314–2321.
Zhou L, Zhang G, Schurz M, Steffen K and Meyer B 2016 Kinetic study on CO2 gasification of brown coal and biomass chars: Reaction order; Fuel 173 (1) 311–319.
Zhang L X, Huang J J, Fang Y T and Wang Y 2006 Gasification reactivity and kinetics of typical Chinese anthracite chars with steam and CO2; Energy and Fuels 20 (3) 1201–1210.
Zhigang Li, Zhang X, Sugai Y, Wang J and Sasaki K 2013 Measurements of gasification characteristics of coal and char in CO2-rich gas flow by TG-DTA; J. Combustion, Article ID 985687 1–15, doi:10.1155/2013/985687.
Zhou Z, Hu Q, Liu X, Yu G and Wang F 2012 Effect of iron species and calcium hydroxide on high-sulphur petroleum coke CO2 gasification; Energy and Fuels 26 1489–1495.
Acknowledgements
The authors express their thanks to the Director of CSIR-NEIST, Jorhat, for his continuous encouragement. The authors are grateful to CSIR, New Delhi (MLP-6000-WP-III) and Department of Information Technology, Govt. of India (GAP-0261) for financial support. The suggestions received from Dr B P Baruah are thankfully acknowledged. Special thanks are given to all the staff of Coal Chemistry Pilot Plant (CSIR-NEIST) for their assistance during the study. The authors appreciate the esteemed reviewers for their constructive comments to improve the paper.
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Das, T., Saikia, A., Mahanta, B. et al. Thermogravimetric and model-free kinetic studies on CO2 gasification of low-quality, high-sulphur Indian coals. J Earth Syst Sci 125, 1365–1377 (2016). https://doi.org/10.1007/s12040-016-0743-5
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DOI: https://doi.org/10.1007/s12040-016-0743-5