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J.B. Howard (1981)
Chemistry of Coal Utilization
(2014)
Understanding the stability of pyrolysis tar from biomass in a view point of free radical, Bioresour
Inves - tigating secondary pyrolysis reactions of coal tar via mass spectrometry techniques
Produc - tion of chemicals by cracking pyrolytic tar from Loy Yang coal over iron oxide catalysts in a steam atmosphere , Fuel Process
J. Leblanc, J. Quanci, M. Castaldi (2017)
Investigating Secondary Pyrolysis Reactions of Coal Tar via Mass Spectrometry TechniquesEnergy & Fuels, 31
M. Siskin, T. Aczel (1983)
Pyrolysis studies on the structure of ethers and phenols in coalFuel, 62
S. Niksa (2017)
A reaction mechanism for tar decomposition at moderate temperatures with any coal typeFuel, 193
Li Han, Rong Zhang, J. Bi (2009)
Experimental investigation of high-temperature coal tar upgrading in supercritical waterFuel Processing Technology, 90
Yao Song, J. Xiang, Song Hu, D. Quyn, Yijun Zhao, Xun Hu, Yi Wang, Chun-Zhu Li (2015)
Importance of the aromatic structures in volatiles to the in-situ destruction of nascent tar during the volatile–char interactionsFuel Processing Technology, 132
(2009)
Experimental investigation of high - temperature coal tar upgrading in supercritical water , Fuel Process
B. Ignasiak, M. Gawlak (1977)
Polymeric structure of coal. 1. Role of ether bonds in constitution of high-rank vitriniteFuel, 56
(1977)
Polymeric structure of coal
Junfei Wu, Qingya Liu, Renxing Wang, Wenjing He, Lei Shi, Xiaojin Guo, Zezhou Chen, Leiming Ji, Zhenyu Liu (2017)
Coke formation during thermal reaction of tar from pyrolysis of a subbituminous coalFuel Processing Technology, 155
Coke formation during thermal reaction of tar from pyrolysis of a subbi - tuminous coal , Fuel Process
W. Hesp, P. Waters (1970)
Thermal cracking of tars and volatile matter from coal carbonization. [500 to 1000/sup 0/C]
Wenjing He, Qingya Liu, Lei Shi, Zhenyu Liu, D. Ci, C. Lievens, Xiaofen Guo, Muxin Liu (2014)
Understanding the stability of pyrolysis tars from biomass in a view point of free radicals.Bioresource technology, 156
(1981)
Fundamentals of coal pyrolysis and hydropyrolysis, in Chemistry of Coal Utilization
Jieguang Wang, Xuesong Lu, Jianzhong Yao, Weigang Lin, L. Cui (2005)
Experimental Study of Coal Topping Process in a Downer ReactorIndustrial & Engineering Chemistry Research, 44
Lei Zhiping, Lei Zhiping, Kai Zhang, Zhiquan Hu, Hao Zhang, H. Shui, S. Ren, Zhicai Wang, Shigang Kang, C. Pan (2016)
Effect of ionic liquid 1-butyl-3-methyl-imidazolium dihydrogen phosphate pretreatment on pyrolysis of Shengli ligniteFuel Processing Technology, 147
Wenjing He, Zhenyu Liu, Qingya Liu, D. Ci, C. Lievens, Xiaofen Guo (2014)
Behaviors of radical fragments in tar generated from pyrolysis of 4 coalsFuel, 134
W.R. Hesp, P.L. Waters (1970)
Thermal cracking of tars and volatile matter from coal carbonizationInd. Eng. Chem. Prod. Res. Dev, 9
J. Edwards, Kym Schluter, R. Tyler (1986)
Upgrading of flash pyrolysis tars to synthetic crude oil: 1. First stage hydrotreatment using a disposable catalystFuel, 64
N. Sonoyama, K. Nobuta, T. Kimura (2017)
Production of chemicals by cracking pyrolytic tar from Loy Yang coal over iron oxide catalysts in a steam atmosphereFuel Process. Technol, 92
Lunjing Yan, Yonghui Bai, Ruifang Zhao, Fan Li, Xie Kechang (2015)
Correlation between coal structure and release of the two organic compounds during pyrolysisFuel, 145
Nozomu Sonoyama, Kazunari Nobuta, T. Kimura, S. Hosokai, J. Hayashi, T. Tago, T. Masuda (2011)
Production of chemicals by cracking pyrolytic tar from Loy Yang coal over iron oxide catalysts in aFuel and Energy Abstracts
Lei Zhiping, Zhiquan Hu, Hao Zhang, Lina Han, H. Shui, S. Ren, Zhicai Wang, Shigang Kang, C. Pan (2016)
Pyrolysis of lignite following low temperature ionic liquid pretreatmentFuel, 166
Naokatsu Kannari, Yuya Oyama, T. Takarada (2017)
Catalytic decomposition of tar derived from biomass pyrolysis using Ni-loaded chicken dropping catalystsInternational Journal of Hydrogen Energy, 42
ISSN 1068-364X, Coke and Chemistry, 2018, Vol. 61, No. 10, pp. 384–391. © Allerton Press, Inc., 2018. CHEMISTRY a, a a, b, a Wenhao Yu *, Kai Zhang , Zhiping Lei **, Hengfu Shui , a a a a Shibiao Ren , Zhicai Wang , Shigang Kang , and Chunxiu Pan School of Chemistry & Chemical Engineering, Anhui Key Laboratory of Coal Clean Conversion & Utilization, Anhui University of Technology, Ma’anshan, 243002, Anhui Province, PR China Key Laboratory Breeding Base of Coal Science and Technology Co-founded by Shanxi Province and the Ministry of Science and Technology, Taiyuan University of Technology, @Taiyuan, China *e-mail: 18855583762@163.com **e-mail: zplei@ahut.edu.cn Received April 14, 2018; Accepted June 7, 2018 Abstract⎯ Coal tar from lignite pyrolysis is prone to react during the transportation, heating and upgrading processing, which significantly affects the yield and quality of coal tar. From the view of industry, it is of sig- nificance to study the coal tar reactivity during heating. In this paper, the effects of reaction temperature and retention time on reaction of tar were studied. It is found that the inf luence of the heating temperature on the tar reaction is more significant than the heating time. With
Coke and Chemistry – Springer Journals
Published: Feb 11, 2019
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