The correlation between coal char structure and reactivity at rapid heating condition in TGA and heating stage microscope

•Reactivity of in-situ chars was investigated by rapid heating TGA and heating stage microscope.•The combined index by Raman and XRD is established for char gasification reactivity at the rapid heating rate.•The gasification rate of in-situ chars in HTSM was higher than that in rapid heating TGA. Th...

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Bibliographic Details
Published in:Fuel (Guildford) 2020-01, Vol.260, p.116318, Article 116318
Main Authors: Liu, Mengjie, Bai, Jin, Kong, Lingxue, Bai, Zongqing, He, Chong, Li, Wen
Format: Article
Language:English
Subjects:
Body weight loss
Carbon dioxide
Coal
Gasification
Gasification reactivity
Heating rate
Heating stage microscope
In-situ chars
Parameters
Particle interactions
Pyrolysis
Rapid heating TGA
Reactivity
Structure parameter
Temperature
Weight loss
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Summary:•Reactivity of in-situ chars was investigated by rapid heating TGA and heating stage microscope.•The combined index by Raman and XRD is established for char gasification reactivity at the rapid heating rate.•The gasification rate of in-situ chars in HTSM was higher than that in rapid heating TGA. The coal pyrolysis and char gasification process have been widely studied in TGA at a low heating rate, which is far lower than the heating rate when coal particle enters into the boiler and gasifier. In this work, the isothermal CO2 gasification reactivity of in-situ coal chars was performed in rapid heating TGA and a heating stage microscope. The char structure parameters determined by XRD and Raman were combined to describe the char reactivity at the same temperature. Results showed that maximum weight loss rate (DTGmax) of raw coal evidently increased and the corresponding maximum rate temperature raised with the increasing of heating rate during pyrolysis. Nonetheless, the heating rate had slightly effect on gasification reactivity of in-situ char samples when it exceeded 50 K/min. Considering the physical meaning and universality of the coal char structure and gasification reactivity fitting, the XRD and Raman structural parameters were combined to describe the gasification reactivity. The new method for coal char reactivity under rapid heating rate is established, Rs=0.174+43.14d002,aLc,a+3.58ID3×ID4IG2. Furthermore, a visually heating stage microscope was also applied for determining the in-situ char reactivity through image analyzing. The gasification process of in-situ coal char particles fits the shrinking particle pattern at the original and midterm stages. However, the shrinking particle pattern changed into the shrinking core pattern at high carbon conversion. Moreover, the CO inhibition effect and inter-particle interaction account for the difference of gasification reactivity by rapid heating TGA and heating stage microscope.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2019.116318