Insights into pyrolysis product characteristics and carbon structure evolution of bituminous coal under high-temperature thermal shock

•Pyrolysis of bituminous coal under high-temperature thermal shock is studied.•Relationship between pyrolytic gas product and particle morphology was analyzed.•Carbon matrix purification is a successive process linear with temperature rise.•Graphitization of coal carbon structure was found to exist...

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Bibliographic Details
Published in:Fuel (Guildford) 2024-09, Vol.371, Article 132096
Main Authors: Zhang, Haigang, Shen, Zhongjie, Zeng, Rubin, Liang, Qinfeng, Liu, Haifeng
Format: Article
Language:English
Subjects:
Carbon nanostructure
Carbonization
High-temperature pyrolysis
Product distribution
Thermal shock
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Summary:•Pyrolysis of bituminous coal under high-temperature thermal shock is studied.•Relationship between pyrolytic gas product and particle morphology was analyzed.•Carbon matrix purification is a successive process linear with temperature rise.•Graphitization of coal carbon structure was found to exist an abrupt temperature. The current investigation aims to reveal the pyrolysis characteristics and particle microstructure evolution of bituminous coal under the high-temperature thermal shock. In the experimental temperatures, the purification of carbon matrix in the coal char is a successive process linear on temperature. In contrast, the graphitization process of carbon structure existed a transition temperature (1600 ℃). Specifically, the range of 1000–1500 ℃ is critical for the transformation of amorphous carbon to disordered graphite, but the growth of graphite microcrystals was minimally affected. While the range of 1600–1900 ℃ is critical for the formation of the graphite-like carbon structure. It is characterized by the release of defective structures such as oxygen-containing functional groups, and a significant increase in crystal size. Although beneficial for the subsequent study of carbon materials, the ordered graphite transformation led to the deactivation of char. The pyrolysis behavior study under thermal shock insight into the thermal behavior of coal char in high-temperature furnaces, as well as a new idea for the clean utilization of coal resources.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2024.132096