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Experimental study of the physicochemical structure and moisture readsorption characteristics of Zhaotong lignite after hydrothermal and thermal upgrading.

Authors :
Feng, Xiaofei
Zhang, Cheng
Tan, Peng
Zhang, Xiaopei
Fang, Qingyan
Chen, Gang
Source :
Fuel. Dec2016, Vol. 185, p112-121. 10p.
Publication Year :
2016

Abstract

Hydrothermal and thermal upgrading techniques are promising coal drying methods that enable the utilization of low rank coals. In this study, Zhaotong (ZT) lignite from the Yunnan province of China was hydrothermally upgraded at 150–300 °C and thermally upgraded at 200–500 °C; then, the correlation between the changes in the physical and chemical structures and the moisture readsorption characteristics were investigated. The maturity of lignite was improved by the upgrading treatment. The main hydrophilic oxygen-containing groups, including hydroxyl and carboxyl, were effectively removed as the upgrading temperature increased. In addition, the removal of hydroxyl groups was more remarkable during hydrothermal upgrading. Irreversible changes occurred in the pore structure of the treated lignites; the specific surface area and total pore volume first increased and then decreased with hydrothermal upgrading, whereas the specific surface area and total pore volume continually increased with thermal upgrading as the temperature increased. In addition, the gel-like structure of the lignite experienced violent shrinkages and collapses. The moisture readsorption performance was effectively inhibited under the synergy effects of the physicochemical structure such that the moisture readsorption ratio ( MRR ) and moisture holding capacity (MHC) decreased continuously with the increasing upgrading temperature. An MHC model built through multiple linear regressions proved suitable to describe the moisture readsorption of the upgraded lignites. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
00162361
Volume :
185
Database :
Academic Search Index
Journal :
Fuel
Publication Type :
Academic Journal
Accession number :
117736103
Full Text :
https://doi.org/10.1016/j.fuel.2016.07.101