Effect of temperature on Lu’an bituminous char structure evolution in pyrolysis and combustion
Received date: 06 Sep 2019
Accepted date: 30 Jan 2020
Published date: 15 Mar 2021
Copyright
In the process of pyrolysis and combustion of coal particles, coal structure evolution will be affected by the ash behavior, which will further affect the char reactivity, especially in the ash melting temperature zone. Lu’an bituminous char and ash samples were prepared at the N2 and air atmospheres respectively across ash melting temperature. A scanning electron microscope (SEM) was used to observe the morphology of char and ash. The specific surface area (SSA) analyzer and thermogravimetric analyzer were respectively adopted to obtain the pore structure characteristics of the coal chars and combustion parameters. Besides, an X-ray diffractometer (XRD) was applied to investigate the graphitization degree of coal chars prepared at different pyrolysis temperatures. The SEM results indicated that the number density and physical dimension of ash spheres exuded from the char particles both gradually increased with the increasing temperature, thus the coalescence of ash spheres could be observed obviously above 1100°C. Some flocculent materials appeared on the surface of the char particles at 1300°C, and it could be speculated that β-Si3N4 was generated in the pyrolysis process under N2. The SSA of the chars decreased with the increasing pyrolysis temperature. Inside the char particles, the micropore area and its proportion in the SSA also declined as the pyrolysis temperature increased. Furthermore, the constantly increasing pyrolysis temperature also caused the reactivity of char decrease, which is consistent with the results obtained by XRD. The higher combustion temperature resulted in the lower porosity and more fragments of the ash.
Key words: bituminous char; pyrolysis; ash; structure evolution; reactivity
Yandi ZHANG , Yinhe LIU , Xiaoli DUAN , Yao ZHOU , Xiaoqian LIU , Shijin XU . Effect of temperature on Lu’an bituminous char structure evolution in pyrolysis and combustion[J]. Frontiers in Energy, 2021 , 15(1) : 14 -25 . DOI: 10.1007/s11708-020-0805-x
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