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Analysis of tar and pyrolysis gas from low-rank coal pyrolysis assisted by apple branch
Low-rank coal (LRC) pyrolysis assisted by biomass can realize the clean and efficient conversion utilization of LRC. The gas and tar characteristics obtained from co-pyrolysis of apple branch (AB) and LRC at different stages were studied with TG-FTIR and Py-GC/MS. It was found that the co-pyrolysis process could be divided into four stages, and the weight loss rate of AB+LRC was 24.03% in the second stage (194.60–404.63 °C), lower than the calculated value. However, the third stage (404.63–594.33 °C) weight loss rate was 13.33%, higher than the calculated value. The content of volatile products increased during co-pyrolysis, resulting in a higher total weight loss rate than the calculated value. There was a synergistic effect between AB and LRC. Aromatic hydrocarbon release intensity in co-pyrolysis products was significantly enhanced in the second and third stages, and it was stronger than that of pyrolysis alone; in contrast, the release intensity of gaseous products was weaker than that of pyrolysis alone. In co-pyrolysis tar, the content of monocyclic and bicyclic aromatic hydrocarbons was increased. The C<10 component was 86.48%, higher than the calculated value of 12.68%. The proportion of aromatic hydrocarbons and phenols increased significantly compared with the calculated value.
Analysis of tar and pyrolysis gas from low-rank coal pyrolysis assisted by apple branch
Low-rank coal (LRC) pyrolysis assisted by biomass can realize the clean and efficient conversion utilization of LRC. The gas and tar characteristics obtained from co-pyrolysis of apple branch (AB) and LRC at different stages were studied with TG-FTIR and Py-GC/MS. It was found that the co-pyrolysis process could be divided into four stages, and the weight loss rate of AB+LRC was 24.03% in the second stage (194.60–404.63 °C), lower than the calculated value. However, the third stage (404.63–594.33 °C) weight loss rate was 13.33%, higher than the calculated value. The content of volatile products increased during co-pyrolysis, resulting in a higher total weight loss rate than the calculated value. There was a synergistic effect between AB and LRC. Aromatic hydrocarbon release intensity in co-pyrolysis products was significantly enhanced in the second and third stages, and it was stronger than that of pyrolysis alone; in contrast, the release intensity of gaseous products was weaker than that of pyrolysis alone. In co-pyrolysis tar, the content of monocyclic and bicyclic aromatic hydrocarbons was increased. The C<10 component was 86.48%, higher than the calculated value of 12.68%. The proportion of aromatic hydrocarbons and phenols increased significantly compared with the calculated value.
Analysis of tar and pyrolysis gas from low-rank coal pyrolysis assisted by apple branch
Yin, Ning (author) / Song, Yonghui (author) / Wu, Lei (author) / Dong, Ping (author) / Wang, Chaofan (author) / Zhou, Jun (author) / Zhang, Xinwei (author)
2023-07-01
9 pages
Article (Journal)
Electronic Resource
English
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