Study on the preparation and physicochemical property evolution of waste wood chips/bituminous coal-based composite fuel

IF 3.4 4区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Journal of the Indian Chemical Society Pub Date : 2025-09-17 DOI:10.1016/j.jics.2025.102125

Xinhang Yang , Jiachen Man , Zhijun He

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Abstract

In response to the "carbon peak and carbon neutrality" demands of the steel industry, this study employs the co-micro carbonization of waste wood chips and bituminous coal to prepare carbon-based composite fuels. By regulating the mixing ratios (from 9:1 to 5:5) and carbonization temperatures (300–500 °C), the pyrolysis behavior, combustion characteristics, and physicochemical evolution are systematically analyzed. The results indicate that mixing waste wood chips with bituminous coal significantly improves the pyrolysis synergy. When the proportion of bituminous coal increases to 60 %, the activation energy of rapid pyrolysis decreases from 130.07 kJ mol⁻¹ to 46.94 kJ mol⁻¹. The solid yield increases from 28.81 % to 45.47 % as the proportion of bituminous coal increases, but when the carbonization temperature rises to 500 °C, the yield decreases to 41.03 % due to intensified volatile release. Carbonization at 500 °C promotes the formation of a porous structure in the composite fuel and enhances the condensation degree of the aromatic carbon network. The Raman spectroscopy I_D/I_G value increases to 2.793, indicating that the increase in defect sites is beneficial for the combustion reaction.

Abstract Image

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废木屑/烟煤基复合燃料的制备及理化性质演变研究

针对钢铁行业“碳峰值与碳中和”的需求，本研究采用废木屑与烟煤共微碳化制备碳基复合燃料。通过调节混合比（9:1 ~ 5:5）和炭化温度（300 ~ 500℃），系统分析了热解行为、燃烧特性和理化演化。结果表明，废木屑与烟煤混合可显著提高热解协同效应。当烟煤添加量增加到60%时，快速热解活化能从130.07 kJ mol−1降低到46.94 kJ mol−1。随着烟煤添加量的增加，固体收率由28.81%提高到45.47%，但当炭化温度升至500℃时，由于挥发份释放加剧，固体收率降至41.03%。500℃炭化促进了复合燃料中多孔结构的形成，提高了芳香碳网的缩聚程度。拉曼光谱ID/IG值增加到2.793，表明缺陷位的增加有利于燃烧反应。

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来源期刊

Journal of the Indian Chemical Society 化学-化学综合

CiteScore

3.50

自引率

7.70%

发文量

492

审稿时长

3-8 weeks

期刊介绍： The Journal of the Indian Chemical Society publishes original, fundamental, theorical, experimental research work of highest quality in all areas of chemistry, biochemistry, medicinal chemistry, electrochemistry, agrochemistry, chemical engineering and technology, food chemistry, environmental chemistry, etc.