---------------------------------------------------------------------------------------------------------------------------------
(I)研究概述
----------------------------------------------------------------------------------------------------------------
(II)研究重点
----------------------------------------------------------------------------------------------------------------
(III)代表性成果
[1] Hydrothermal co-carbonization of industrial biowastes with lignite toward modified hydrochar production: Synergistic effects and structural characteristics. Journal of Environmental Chemical Engineering, 2022, 10(3): 107540.
[2] Pyrolysis of hydrothermally pretreated biowastes: The controllability on the formation of NOx precursors. Chemical Engineering Journal. 2020, 393: 124727.
[3] Insights into the evolution of chemical structures in lignocellulose and non-lignocellulose biowastes during hydrothermal carbonization (HTC). Fuel. 2019, 236: 960-974.
[4] A review on evolution of nitrogen-containing species during selective pyrolysis of waste wood-based panels. Fuel. 2019, 253: 1214-1228.
[5] Formation and regulatory mechanisms of N-containing gaseous pollutants during stage-pyrolysis of agricultural biowastes. Journal of Cleaner Production. 2019, 236: 117706.
[6] Insights into the evolution of fuel-N to NOx precursors during pyrolysis of N-rich nonlignocellulosic biomass. Applied Energy, 2018, 219: 20-33.
[1] 一种利用废弃人造板制备富N活性炭材料的方法. 发明专利, ZL2019100063516, 2020.04.27.
[2] 一种高氮生物质废弃物作为燃料利用的提质脱氮改性方法. 发明专利, ZL2017110376414, 2020.04.03.
[3] 一种可实现生物质燃气炉内高效净化的装置及方法. 发明专利. ZL2014107998714, 2017.06.20.
[4] 一种生物质燃气高效混合燃烧装置及其混合燃烧方法. 发明专利. ZL2014102760771, 2016.06.01.
[5] 一种轻工有机固废分级热转化制备低氮高值燃气的方法. 发明专利, ZL2019100521552, 2019.01.21.