Investigation on activation technology of self-heating decarbonization of coal gangue by a sintering process

Sheng-hu Lu; Jian Pan; De-qing Zhu; Zheng-qi Guo; Si-wei Li; Yue Shi; Wu-ju Zhang

doi:10.1007/s11771-023-5299-3

Journal of Central South University ›› 2023, Vol. 30 ›› Issue (4) : 1158 -1167. DOI: 10.1007/s11771-023-5299-3

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Investigation on activation technology of self-heating decarbonization of coal gangue by a sintering process

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Abstract

Coal gangue is a solid waste discharged in coal mining and dressing process. Large-scale decarbonization and activation treatment are key steps toward massive and efficient utilization of coal gangue. In this paper, a new process for the preparation of a cement admixture from coal gangue by effectively utilizing its calorific value was developed. The mineral composition, crystal structure, and microstructure of the sintered products obtained under different sintering conditions were investigated using XRD, FTIR, SEM and mechanical property analysis to reveal the activation mechanism of coal gangue. The blended cement containing 30% activated coal gangue prepared by adding 3% coal and no return fine exhibited the best mechanical properties. Furthermore, the mechanical properties of the cement containing 30% activated coal gangue prepared without coal and return fine were adequate, reaching a productivity of 0.96 t/(m²·h). The results show that the thermal activation of exhaust sintering can greatly improve the cementitious activity of coal gangue. Finally, the applied technology is promising for industrial application.

Keywords

coal gangue / activity / sintering process / self-heating / productivity index

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Sheng-hu Lu, Jian Pan, De-qing Zhu, Zheng-qi Guo, Si-wei Li, Yue Shi, Wu-ju Zhang. Investigation on activation technology of self-heating decarbonization of coal gangue by a sintering process. Journal of Central South University, 2023, 30(4): 1158-1167 DOI:10.1007/s11771-023-5299-3

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References

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[1]	WangB, MaY-n, LeeX-q, et al. . Environmental-friendly coal gangue-biochar composites reclaiming phosphate from water as a slow-release fertilizer [J]. Science of the Total Environment, 2021, 758: 143664

[2]	LiJ-y, WangJ-man. Comprehensive utilization and environmental risks of coal gangue: A review [J]. Journal of Cleaner Production, 2019, 239117946

[3]	WuR-d, DaiS-b, JianS-w, et al. . Utilization of solid waste high-volume calcium coal gangue in autoclaved aerated concrete: Physico-mechanical properties, hydration products and economic costs [J]. Journal of Cleaner Production, 2021, 278123416

[4]	LIN Xi-qiang, WANG Dong-min, FENG Jian-hua, et al. Influence of activated coal gangue to shrinkage of highperformance concrete [J]. Concrete, 2013(7): 56–58, 61. (in Chinese)

[5]	XU Chen-yang, FAN Xing-wang, ZHANG Liang, et al. Activated coal gangue used as concrete mineral mixture—Strength performance of concrete [J]. Ready - Mixed Concrete, 2010(4): 35–43. (in Chinese)

[6]	WangA-g, LiuP, SunD-s, et al. . Research progress in activity evaluation method of calcined coal gangue powder material [J]. Materials Review, 2018, 32(11): 1903-1909(in Chinese)

[7]	LiuH-b, LiuZ-l. Recycling utilization patterns of coal mining waste in China [J]. Resources, Conservation and Recycling, 2010, 54(12): 1331-1340

[8]	LiF, LiX-j, HouL, et al. . A long-term study on the soil reconstruction process of reclaimed land by coal gangue filling [J]. CATENA, 2020, 195104874

[9]	CaoZ, CaoY-d, DongH-j, et al. . Effect of calcination condition on the microstructure and pozzolanic activity of calcined coal gangue [J]. International Journal of Mineral Processing, 2016, 14623-28

[10]	YanK-z, GuoY-x, FangL, et al. . Decomposition and phase transformation mechanism of kaolinite calcined with sodium carbonate [J]. Applied Clay Science, 2017, 147: 90-96

[11]	BaudetG, PerrotelV, SeronA, et al. . Two dimensions comminution of kaolinite clay particles [J]. Powder Technology, 1999, 105(1–3): 125-134

[12]	LiC, WanJ-h, SunH-h, et al. . Investigation on the activation of coal gangue by a new compound method [J]. Journal of Hazardous Materials, 2010, 179(1–3): 515-520

[13]	de la VillaR V, GarcíaR, Martínez-RamírezS, et al. . Effects of calcination temperature and the addition of ZnO on coal waste activation: A mineralogical and morphological evolution [J]. Applied Clay Science, 2017, 150: 1-9

[14]	KuhnertN. Microwave-assisted reactions in organic synthesis: Are there any nonthermal microwave effects? [J]. Angewandte Chemie (International Ed in English), 2002, 41(11): 1863-1866

[15]	GuanX, ChenJ-x, ZhuM-y, et al. . Performance of microwave-activated coal gangue powder as auxiliary cementitious material [J]. Journal of Materials Research and Technology, 2021, 14: 2799-2811

[16]	OoiT C, ThompsonD, AndersonD R, et al. . The effect of charcoal combustion on iron-ore sintering performance and emission of persistent organic pollutants [J]. Combustion and Flame, 2011, 158(5): 979-987

[17]	LuL-m, AdamM, KilburnM, et al. . Substitution of charcoal for coke breeze in iron ore sintering [J]. ISIJ International, 2013, 53(9): 1607-1616

[18]	LuS-h, PanJ, LiS-w, et al. . Preparation of sinter with low reduction degradation index for COREX reduction in a high proportion [J]. Journal of Iron and Steel Research International, 2023, 30(4): 635-649

[19]	ZhuD-q, ShiB-j, PanJ, et al. . Effect of pre-briquetting on the granulation of sinter mixture containing high proportion of specularite concentrate [J]. Powder Technology, 2018, 331: 250-257

[20]	DawsonP R. Recent developments in iron ore sintering. III, Granulation and strand feeding [J]. Ironmaking and Steelmaking, 1993, 20(2): 144-149

[21]	GermanR MSintering theory and practice [M], 1996, New York, Wiley

[22]	YangW, ChoiS, ChoiE S, et al. . Combustion characteristics in an iron ore sintering bed—Evaluation of fuel substitution [J]. Combustion and Flame, 2006, 145(3): 447-463

[23]	ZhaoJ P, LooC E, DukinoR D. Modelling fuel combustion in iron ore sintering [J]. Combustion and Flame, 2015, 162(4): 1019-1034

[24]	PtáčekP, KubátováD, HavlicaJ, et al. . Isothermal kinetic analysis of the thermal decomposition of kaolinite: The thermogravimetric study [J]. Thermochimica Acta, 2010, 501(1–2): 24-29

[25]	PalomoA, GlasserF. Chemically-bonded cementitious materials based on metakaolin [J]. British Ceramic Transactions and Journal, 1992, 91: 107-112

[26]	KakaliG, PerrakiT, TsivilisS, et al. . Thermal treatment of Kaolin: The effect of mineralogy on the pozzolanic activity [J]. Applied Clay Science, 2001, 20(1–2): 73-80

[27]	ShvarzmanA, KovlerK, GraderG S, et al. . The effect of dehydroxylation/amorphization degree on pozzolanic activity of kaolinite [J]. Cement and Concrete Research, 2003, 33(3): 405-416

[28]	BrindleyG W, NakahiraM. A new concept of the transformation sequence of kaolinite to mullite [J]. Nature, 1958, 181(4619): 1333-1334

[29]	GaoQ-y, ZhangZ-q. Study on the structural change in the calcination process of kaolinite and its pozzolanic activity [J]. Journal of the Chinese Ceramic Society, 1989, 17(6): 541-548(in Chinese)

[30]	MingH. Modification of kaolinite by controlled hydrothermal deuteration—A DRIFT spectroscopic study [J]. Clay Minerals, 2004, 39(3): 349-362

[31]	ZhangJ-x, SunH-h, SunY-m, et al. . Correlation between ²⁹Si polymerization and cementitious activity of coal gangue [J]. Journal of Zhejiang University—Science A, 2009, 10(9): 1334-1340