Synergistic effects from fast co-pyrolysis of lignin with low-rank coal: On-line analysis of products distribution and fractal analysis on co-pyrolysis char

Synergistic effects from fast co-pyrolysis of lignin with low-rank coal: On-line analysis of products distribution and fractal analysis on co-pyrolysis char

Synergistic effects from fast co-pyrolysis of low-rank coal with lignin via on-line mass spectrometry were explored. Iso-conversional method was used to obtain frequency factor and activation energy of main gaseous products. The morphology evolution of both individual and co-pyrolysis char was analy...

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Bibliographic Details
Published in:Journal of the Energy Institute Vol. 97; pp. 152 - 160
Main Authors: Fan, Yingjie, Yang, Bolun, Zhang, Bo, Wu, Zhiqiang, Sun, Zongyu, Shang, Jianxuan
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-08-2021
Subjects:
Co-pyrolysis
Fractal theory
Kinetic analysis
Lignin
Low-rank coal
Synergistic effects
Synergistic effects
Lignin
Fractal theory
Kinetic analysis
Co-pyrolysis
Low-rank coal
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Summary:Synergistic effects from fast co-pyrolysis of low-rank coal with lignin via on-line mass spectrometry were explored. Iso-conversional method was used to obtain frequency factor and activation energy of main gaseous products. The morphology evolution of both individual and co-pyrolysis char was analyzed via fractal theory quantificationally. The results indicated that various synergistic effects were found from the distribution and composition of products. CO and CO2 were the main content of the gaseous products, and the content of CO from lignin increased with the temperature. Lignin promoted the generation of tar and inhibited the formation of gaseous products during fast co-pyrolysis, which reflected different synergistic effects, respectively. Positive synergistic effects were observed from the component proportion of CH4 as the temperature increasing higher than 600 °C. Kinetic analysis indicated that activation energy for H2 from lignin and low-rank coal was 32.21 and 59.90 kJ/mol, and higher temperature would be beneficial for H2 formation. Fractal analysis indicated that lignin promoted the surface morphology of co-pyrolysis char to become more complicated, with the fractal dimension of individual char less than those of co-pyrolysis char. •Synergistic effects from fast co-pyrolysis of low-rank coal with lignin were explored.•The product distribution and change rules during the co-pyrolysis process were studied.•Kinetic parameters about gaseous products were obtained via the iso-conventional method.•Fractal analysis was applied to describe the morphology evolution of co-pyrolysis char.
ISSN:1743-9671
DOI:10.1016/j.joei.2021.04.009