The mechanism and products for co-thermal extraction of biomass and low-rank coal with NMP

Jun Zhao; Hai-bin Zuo; Jing-song Wang; Qing-guo Xue

doi:10.1007/s12613-019-1872-z

International Journal of Minerals, Metallurgy, and Materials ›› 2019, Vol. 26 ›› Issue (12) : 1512 -1522. DOI: 10.1007/s12613-019-1872-z

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The mechanism and products for co-thermal extraction of biomass and low-rank coal with NMP

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Abstract

The high-value utilization of low-rank coal would allow for expanding energy sources, improving energy efficiencies, and alleviating environmental issues. In order to use low-rank coal effectively, the hypercoals (HPCs) were co-extracted from two types of low-rank coal and biomass via N-methyl-2-purrolidinone (NMP) under mild conditions. The structures of the HPCs and residues were characterized by proximate and ultimate analysis, Raman spectra, and Fourier transform infrared (FT-IR) spectra. The carbon structure changes within the raw coals and HPCs were discussed. The individual thermal dissolution of Xibu (XB) coal, Guandi (GD) coal, and the biomass demonstrated that the biomass provided the lowest thermal dissolution yield Y ₁ and the highest thermal soluble yield Y ₂ at 280°C, and the ash content of three HPCs decreased as the extraction temperature rose. Co-thermal extractions in NMP at various coal/biomass mass ratios were performed, demonstrating a positive synergic effect for Y ₂ in the whole coal/biomass mass ratios. The maximum value of Y ₂ was 52.25wt% for XB coal obtained with a XB coal/biomass of 50wt% biomass. The maximum value of Y ₂ was 50.77wt% for GD coal obtained with a GD coal/biomass of 1:4. The difference for the optimal coal/biomass mass ratios between XB and GD coals could be attributed to the different co-extraction mechanisms for this two type coals.

Keywords

low-rank coal / biomass / co-thermal extraction / NMP / hypercoal

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Jun Zhao, Hai-bin Zuo, Jing-song Wang, Qing-guo Xue. The mechanism and products for co-thermal extraction of biomass and low-rank coal with NMP. International Journal of Minerals, Metallurgy, and Materials, 2019, 26(12): 1512-1522 DOI:10.1007/s12613-019-1872-z

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References

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[1]	Liu ZY, Shi SD, Li YW. Coal liquefaction technologies— Development in China and challenges in chemical reaction engineering. Chem. Eng. Sci., 2010, 65, 12.

[2]	B. Dudley, BP Statistical Review of World Energy, BP Brazil, London, UK [2019-6-11]. https://www.bp.com/content/dam/bp/business-sites/en/global/corporate/pdfs/news-and-insights/speeches/bp-stats-review-2019-bob-dudley-speech.pdf

[3]	Ariyama T, Sato M. Optimization of ironmaking process for reducing CO₂ emissions in the integrated steel works. ISIJ Int., 2006, 46, 1736.

[4]	Shui HF, Zhao W, Shan C, Shui T, Pan C, Wang Z, Lei Z, Ren S, Kang S. Caking and coking properties of the thermal dissolution soluble fraction of a fat coal. Fuel Process. Technol., 2014, 118, 64.

[5]	Okuyama N, Komatsu N, Shigehisa T, Kaneko T, Tsuruya S. Hyper-coal process to produce the ash-free coal. Fuel Process. Technol., 2004, 85, 947.

[6]	Mochizuki Y, Sugawara K. Removal of organic sulfur from hydrocarbon resources using ionic liquids. Energy Fuels, 2008, 22, 3303.

[7]	Ran H, Li JH. Current situation and development of agricultural waste resources and biomass energy utilization in rural areas. Energy Conserv. Environ. Prot., 2019 75

[8]	Zha XY. A review of biomass energy utilization technology. Gansu Agric., 2014 30

[9]	Wei ZS, Niu HJY, Ji YF. Simultaneous removal of SO₂ and NOx by microwave with potassium permanganate over zeolite. Fuel Process. Technol., 2009, 90, 324.

[10]	Cao Y, Casenas B, Pan WP. Investigation of chemical looping combustion by solid fuels. 2. Redox reaction kinetics and product characterization with coal, biomass, and solid waste as solid fuels and CuO as an oxygen carrier. Energy Fuels, 2006, 20, 1845.

[11]	Shui HF, Hui Z, Jiang QQ, Zhou H, Pan CX, Wang ZC, Lei ZP, Ren SB, Kang SG. Co-thermal dissolution of Shenmu–Fugu subbituminous coal and sawdust. Fuel Process. Technol., 2015, 131, 87.

[12]	Shui HF, Ma XQ, Yang L, Shui T, Pan CX, Wang ZC, Lei ZP, Ren SB, Kang SG, Xu CC. Thermolysis of biomass-related model compounds and its promotion on the thermal dissolution of coal. J. Energy Inst., 2017, 90, 418.

[13]	Hua Z, Jiang QQ, Pan CX, Shui HF, Lei ZP, Wang ZC. Co-thermal dissolution property of Shenfu coal and rice straw. J. Fuel Chem. Technol., 2014, 42, 1.

[14]	Cordero T, Rodrı́guez-Mirasol J, Pastrana J, Rodrı́guez JJ. Improved solid fuels from co-pyrolysis of a high-sulphur content coal and different lignocellulosic wastes. Fuel, 2004, 83, 1585.

[15]	Kim S D, Woo KJ, Jeong SK, Rhim YJ, Lee SH. Production of low ash coal by thermal extraction with N-methyl-2-pyrrolidinone. Korean J. Chem. Eng., 2008, 25, 758.

[16]	Shui HF, Zhou Y, Li HP, Wang Z, Lei ZC, Ren SB, Pan CX, Wang WW. Thermal dissolution of Shenfu coal in different solvents. Fuel, 2013, 108, 385.

[17]	Li CQ, Ashida S, Iino M, Takanohashi T. Coal dissolution by heat treatments in N-methyl-2-pyrrolidinone, 1,4,5,8,9,10-hexahydroanthracene, and their mixed solvents: A large synergistic effect of the mixed solvents. Energy Fuels, 2000, 14, 190.

[18]	Shui HF. Effect of coal extracted with NMP on its aggregation. Fuel, 2005, 84, 939.

[19]	Ishizuka T, Takanohashi T, Ito O, Iino M. Effects of additives and oxygen on extraction yield with CS2-NMP mixed solvent for argonne premium coal samples. Fuel, 1993, 72, 579.

[20]	Yoshida T, Takanohashi T, Sakanishi K, Saito I, Fujita M, Mashimo K. The effect of extraction condition on ‘HyperCoal’ production (1)—under room-temperature filtration. Fuel, 2002, 81, 1463.

[21]	Pan JN, Lv MM, Bai HL, Hou QL, Li M, Wang ZZ. Effects of metamorphism and deformation on the coal macromolecular structure by laser Raman spectroscopy. Energy Fuels, 2017, 31, 1136.

[22]	Wu D, Chen BY, Sun RY, Liu GJ. Thermal behavior and Raman spectral characteristics of step-heating perhydrous coal: Implications for thermal maturity process. J. Anal. Appl. Pyrolysis, 2017, 128, 143.

[23]	Zickler GA, Smarsly B, Gierlinger N, Peterlik H, Paris O. A reconsideration of the relationship between the crystallite size L _a of carbons determined by X-ray diffraction and Raman spectroscopy. Carbon, 2006, 44, 3239.

[24]	Xu T, Ning XJ, Wang GW, Laing W, Zhang JL, Li YJ, Wang HY, Jiang CH. Combustion characteristics and kinetic analysis of co-combustion between bag dust and pulverized coal. Int. J. Miner. Metall. Mater., 2018, 25, 1412.