Study on structure and combustion performance of Daliuta coal pyrolysis char by Raman spectroscopy

被引：0

作者：

Xu Y.-M. ^{[1
]}

Pan Z.-Y. ^{[1
]}

Hu H.-Q. ^{[2
]}

机构：

[1] College of Environment, Zhejiang University of Technology, Hangzhou

[2] State Key Laboratory of Fine Chemicals, Institute of Coal Chemical Engineering, School of Chemical Engineering, Dalian University of Technology, Dalian

来源：

Ranliao Huaxue Xuebao/Journal of Fuel Chemistry and Technology | 2021年 / 49卷 / 11期

关键词：

Combustion reactivity; Low-rank coal; Macerals; Pyrolysis; Raman spectroscopy;

D O I：

10.19906/j.cnki.JFCT.2021059

中图分类号：

学科分类号：

摘要：

In this study, the structure and combustion performance of pyrolysis chars from Daliuta raw coal, vitrinite-rich sample, inertinite-rich sample and demineralized coal sample were studied by Raman spectroscopy. The results showed that under the same pyrolysis conditions, compared with the pyrolysis char from Daliuta raw coal sample, the pyrolysis char from the demineralized coal sample has more large aromatic ring systems (≥ 6 rings), higher ignition temperature and much low combustion performance. The combustion performance of pyrolysis char from inertinite-rich sample is lower than that from vitrinite-rich sample, and the burnout capacity of pyrolysis char from inertinite-rich sample is far lower than that from vitrinite-rich sample. The ignition temperature (ti), the combustion reactivity index (tindex) and the wavenumber of D band (WD) in the Raman spectrum of Daliuta coal char has a good correlation; the correlation coefficients R2 obtained by the quadratic curve fitting are 0.9159 and 0.7133, respectively. There is no obvious correlation between burn-out temperature and WD of Daliuta coal char, indicating that the carbon structure of Daliuta coal char has a significant impact on the ignition temperature and combustion reactivity index of the char, but is no regular effect on the burn-out ability of the char. © 2021, Science Press. All right reserved.

引用

页码：1656 / 1666

页数：10

共 41 条

[1] ZHU J L, JIN L J, LUO Y W, HU H Q, XIONG Y K, WEI B Y, WANG D C., Fast co-pyrolysis of a massive naomaohu coal and cedar mixture using rapid infrared heating, Energy Convers Manage, 205, (2020)
[2] REDDY B R, SHRAVANI B, DAS B, DASH P S, VINU R., Microwave-assisted and analytical pyrolysis of coking and non-coking coals: Comparison of tar and char compositions, J Anal Appl Pyrolysis, 142, (2019)
[3] YAN J C, LIU M X, FENG Z H, BAI Z Q, SHUI H F, LI Z K, LEI Z P, WANG Z C, REN S B, KANG S G, YAN H L., Study on the pyrolysis kinetics of low-medium rank coals with distributed activation energy model, Fuel, 261, (2020)
[4] ZHAO Y P, HU H Q, JIN L J, HE X F, WU B., Pyrolysis behavior of vitrinite and inertinite from Chinese pingshuo coal by TG-MS and in a fixed bed reactor, Fuel Process Technol, 92, 4, pp. 780-786, (2011)
[5] ROBERTS M J, EVERSON R C, NEOMAGUS H W J P, OKOLO G N, VAN NIEKERK D, MATHEWS J P., The characterisation of slow-heated inertinite- and vitrinite-rich coals from the South African coalfields, Fuel, 158, pp. 591-601, (2015)
[6] SUN Q L, LI W, CHEN H K, LI B Q., The variation of structural characteristics of macerals during pyrolysis, Fuel, 82, 6, pp. 669-676, (2003)
[7] WANG Y, SERRANO S, SANTIAGO-AVILES J J., Raman characterization of carbon nanofibers prepared using electrospinning, Synth Met, 138, 3, pp. 423-427, (2003)
[8] CHEN H, GOLDER M R, WANG F, JASTI R, SWAN A K., Raman spectroscopy of carbon nanohoops[J], Carbon, 67, pp. 203-213, (2014)
[9] SADEZKY A, MUCKENHUBER H, GROTHE H, NIESSNER R, POSCHL U., Raman microspectroscopy of soot and related carbonaceous materials: Spectral analysis and structural information, Carbon, 43, 8, pp. 1731-1742, (2005)
[10] XU Jun, A study of the coal/char structures and combustion reactivity using Raman spectroscopy, (2017)

← 1 2 3 4 5 →