生物质富氮热解研究：温度的影响。

Investigation on biomass nitrogen-enriched pyrolysis: Influence of temperature.

机构信息

State Key Laboratory of Coal Combustion, School of Power and Energy Engineering, Huazhong University of Science and Technology, 430074 Wuhan, China.

出版信息

Bioresour Technol. 2018 Feb;249:247-253. doi: 10.1016/j.biortech.2017.10.022. Epub 2017 Oct 7.

DOI:10.1016/j.biortech.2017.10.022

PMID:29049983

Abstract

Biomass (bamboo waste) nitrogen-enriched pyrolysis was carried out in a fixed bed with NH atmosphere at 400-800 °C, and formation mechanism of N-containing species was explored in depth. Results showed that N-enriched pyrolysis greatly increased bio-oil and gas yields. H yield increased sharply to 130 mL/g (32.93 vol%) and became the main composition at higher temperature, while CH and CO yields deceased, and the lower heating value of gas reached ∼14 MJ/Nm. For bio-oil, the content of phenols (main compositions) and N-containing species increased significantly, and the maximums reached 61.33% and 11.47%, respectively. While that of acetic acid (disappeared), O-containing species (aldehydes/ketones/furans/esters) and aromatics decreased largely accordingly. For biochar, Nitrogen content increased, and it contained abundant pyridininc-N, pyrrolic-N, quaternary-N, and pyridone-N-oxide. Possible reaction pathways of biomass N-enriched pyrolysis was proposed based on products evolution. In conclusion, biomass N-enriched pyrolysis could obtain high-valued N-containing chemical species and functional biochar.

摘要

在固定床中，以 NH3 气氛在 400-800°C 下进行生物质（竹废料）富氮热解，深入探讨了含氮物种的形成机制。结果表明，富氮热解大大提高了生物油和气体的产率。H 产率急剧增加到 130 mL/g（32.93 vol%），并在较高温度下成为主要成分，而 CH 和 CO 的产率降低，气体的低热值达到约 14 MJ/Nm。对于生物油，酚类（主要成分）和含氮物种的含量显著增加，最大值分别达到 61.33%和 11.47%。而乙酸（消失）、含 O 物种（醛/酮/呋喃/酯）和芳烃则相应大量减少。对于生物炭，氮含量增加，含有丰富的吡啶-N、吡咯-N、季氮和吡啶酮-N-氧化物。根据产物演变提出了生物质富氮热解的可能反应途径。总之，生物质富氮热解可以获得高价值的含氮化学物质和功能性生物炭。

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生物质富氮热解研究：温度的影响。

Investigation on biomass nitrogen-enriched pyrolysis: Influence of temperature.

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