Nitrogen conversion during the rapid pyrolysis of raw/torrefied wheat straw

•The N content of samples increased with the torrefaction temperature.•Part of N-A was converted to N-5, N-6, and N-Q through torrefaction.•The conversion of fuel-N was effected by atmosphere during torrefaction.•Less NH3 + HCN were generated during torrefied WS pyrolysis compared with WS.•WS torref...

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Bibliographic Details
Published in:Fuel (Guildford) 2020-01, Vol.259, p.116227, Article 116227
Main Authors: Gao, Pan, Guo, Dezhong, Liang, Chao, Liu, Gongyi, Yang, Shaoxia
Format: Article
Language:English
Subjects:
Ammonia
Atmosphere
Carbon dioxide
Conversion
Drying
Functional groups
Nitrogen
Nitrogen conversion
Nitrogen functionalities
Nuclear fuels
Pyridines
Pyrolysis
Straw
Temperature
Torrefaction
Torrefaction atmosphere
Wheat
Wheat straw
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Summary:•The N content of samples increased with the torrefaction temperature.•Part of N-A was converted to N-5, N-6, and N-Q through torrefaction.•The conversion of fuel-N was effected by atmosphere during torrefaction.•Less NH3 + HCN were generated during torrefied WS pyrolysis compared with WS.•WS torrefied in CO2 and O2 can promote the conversion of fuel-N to harmless N2. Nitrogen functionalities play an important role on the conversion of fuel-N during pyrolysis of raw and torrefied biomass while the influences haven’t been clarified yet. The conversion of fuel-N during the rapid pyrolysis of wheat straw (WS) and different torrefied WS was investigated using a fixed-bed reactor at 600–1000 °C and the change of fuel characteristics and nitrogen-containing functional groups in samples were analyzed by TG and XPS. Results showed that the N content of samples increased gradually with torrefaction temperature. The main N functionality of WS was amide-N (N-A), while part of the N-A was converted to pyrrole-N (N-5), pyridine-N (N-6), and quaternary-N (N-Q) during torrefaction. CO2 and O2 can inhibit the transformation of N-A to N-5 and promote the transformation of N-A to N-6. During WS pyrolysis, NH3 was the main NOx precursors at 600–700 °C, while HCN became the main nitrogen-containing gas species at 800–1000 °C and the conversion of (NH3 + HCN)-N was 18.15%–32.0%. After torrefaction, the conversion of NH3-N decreased in varying degrees, especially at low pyrolysis temperature (600–700 °C). The conversion of HCN-N increased with temperature during torrefied WS pyrolysis which was similar to that of WS, but the conversion decreased greatly at 800–1000 °C. Torrefaction atmosphere has a substantial effect on the conversion of fuel-N. In particular, WS torrefied in CO2 of O2 atmosphere can promote the conversion of fuel-N to harmless N2 during pyrolysis.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2019.116227