Microwave-assisted low-temperature biomass pyrolysis: from mechanistic insights to pilot scale

Microwave-assisted pyrolysis is suitable for biomass valorization with the advantages of temperature reduction and energy saving. However, the lack of deep insight into low-temperature behaviors and scale-up demonstration restrict the possibility of industrial applications. The laboratory studies fo...

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Veröffentlicht in:	Green chemistry : an international journal and green chemistry resource : GC 2021-02, Vol.23 (2), p.821-827
Hauptverfasser:	Luo, Hu, Zhang, Yanfei, Zhu, He, Zhao, Xinpeng, Zhu, Lijun, Liu, Wang, Sun, Mengya, Miao, Gai, Li, Shenggang, Kong, Lingzhao
Format:	Artikel
Sprache:	eng
Schlagworte:	Activation energy Augers Biomass Biomass energy production Dielectric loss Economic analysis Energy conservation Green chemistry Industrial applications Low temperature Pyrolysis Reduction
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container_title	Green chemistry : an international journal and green chemistry resource : GC
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creator	Luo, Hu Zhang, Yanfei Zhu, He Zhao, Xinpeng Zhu, Lijun Liu, Wang Sun, Mengya Miao, Gai Li, Shenggang Kong, Lingzhao
description	Microwave-assisted pyrolysis is suitable for biomass valorization with the advantages of temperature reduction and energy saving. However, the lack of deep insight into low-temperature behaviors and scale-up demonstration restrict the possibility of industrial applications. The laboratory studies found that the temperature range of rice straw pyrolysis with microwave heating was shifted to 250-300 °C, and the activation energy was about 40-150 kJ mol −1 reduced compared with conventional pyrolysis. The positive promotion of inter-link for the dielectric loss factor of biomass, instantaneous hotspots, temperature and activation energy reduction were revealed. Based on the findings, an original 80 kg h −1 pilot-scale microwave-assisted pyrolysis Auger reactor was designed and continuously operated at 200-300 °C with a 72% net energy ratio. The energy and economic analysis indicated that the small-scale microwave-assisted pyrolysis is suitable for the mobile decentralized biomass conversion system. Similar to how Ne zha grows, microwave-assisted pyrolysis of biomass at low temperature firmly moves from a fundamental laboratory to a pilot scale.
doi_str_mv	10.1039/d0gc03348k
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However, the lack of deep insight into low-temperature behaviors and scale-up demonstration restrict the possibility of industrial applications. The laboratory studies found that the temperature range of rice straw pyrolysis with microwave heating was shifted to 250-300 °C, and the activation energy was about 40-150 kJ mol −1 reduced compared with conventional pyrolysis. The positive promotion of inter-link for the dielectric loss factor of biomass, instantaneous hotspots, temperature and activation energy reduction were revealed. Based on the findings, an original 80 kg h −1 pilot-scale microwave-assisted pyrolysis Auger reactor was designed and continuously operated at 200-300 °C with a 72% net energy ratio. The energy and economic analysis indicated that the small-scale microwave-assisted pyrolysis is suitable for the mobile decentralized biomass conversion system. 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source	Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects	Activation energy Augers Biomass Biomass energy production Dielectric loss Economic analysis Energy conservation Green chemistry Industrial applications Low temperature Pyrolysis Reduction
title	Microwave-assisted low-temperature biomass pyrolysis: from mechanistic insights to pilot scale
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