生物质热化学转化提质及其催化剂研究进展

doi:10.11949/0438-1157.20200191

化工学报 ›› 2020, Vol. 71 ›› Issue (8): 3416-3427.DOI: 10.11949/0438-1157.20200191

生物质热化学转化提质及其催化剂研究进展

仉利^1,²(),姚宗路²,赵立欣^1,²(),李志合¹,易维明¹,付鹏¹,袁超³

^1.山东理工大学农业工程与食品科学学院，山东淄博 255000
^2.中国农业科学院农业环境与可持续发展研究所，北京 100081
^3.齐鲁工业大学食品科学与工程学院，山东济南 250000

收稿日期:2020-02-27 修回日期:2020-03-26 出版日期:2020-08-05 发布日期:2020-08-05
通讯作者: 赵立欣
作者简介:仉利（1988—），女，博士研究生，zlqiang214@126.com
基金资助:
现代农业产业技术体系专项资助项目(CARS-02-31);中国农业科学院科技创新工程协同创新任务(CAAS-XTCX2016011-01)

Research progress on thermochemical conversion of biomass to enhance quality and catalyst

Li ZHANG^1,²(),Zonglu YAO²,Lixin ZHAO^1,²(),Zhihe LI¹,Weiming YI¹,Peng FU¹,Chao YUAN³

^1.School of Agricultural Engineering and Food Science, Shandong University of Technology, Zibo 255000, Shandong, China
^2.Institute of Environment and Sustainable Development in Agriculture, Chinese Academy of Agricultural Sciences, Beijing 100081, China
^3.School of Food Science and Engineering, Qilu University of Technology, Jinan 250000, Shandong, China

Received:2020-02-27 Revised:2020-03-26 Online:2020-08-05 Published:2020-08-05
Contact: Lixin ZHAO

摘要/Abstract

摘要：

生物质通过热化学转化制备高品质生物油和高附加值精细化工品是未来工业发展的重要方向，是解决能源短缺、实现碳的闭路循环的有效方式，如何提升生物质热化学转化品质和效率是目前学术界和工业界关注的热点。本文介绍了不同技术路径下的生物质热化学转化研究进展，重点阐述了催化热解、水热催化、化学链转化三种方式的反应机理及其催化剂类型，讨论了生物质热化学转化提质策略。最后，针对生物质热化学转化目前尚存在的问题提出建议，期望为生物质高值化利用提供参考和借鉴。

关键词: 生物质, 热化学转化, 提质, 催化剂, 催化热解, 水热催化, 化学链转化

Abstract:

The preparation of high-quality bio-oils and high-value-added fine chemicals through thermochemical conversion of biomass is an important direction for future industrial development. It is an effective way to solve energy shortages and achieve closed-loop carbon. How to improve the quality and efficiency of biomass thermochemical conversion is a hot spot in academia and industry. This paper reviews the research progress of biomass thermochemical conversion under different technical paths and focus on the reaction mechanism and catalyst types of catalytic pyrolysis, hydrothermal catalysis and chemical-looping conversion. The strategy of improving quality in biomass thermochemical conversion is discussed. Finally, some suggestions of biomass thermochemical conversion are put forward, which is expected to provide reference for the high value utilization of biomass.

Key words: biomass, thermochemistry conversion, enhance quality, catalyst, catalytic pyrolysis, hydrothermal catalysis, chemical-looping conversion

中图分类号:

TK 6

仉利, 姚宗路, 赵立欣, 李志合, 易维明, 付鹏, 袁超. 生物质热化学转化提质及其催化剂研究进展[J]. 化工学报, 2020, 71(8): 3416-3427.

Li ZHANG, Zonglu YAO, Lixin ZHAO, Zhihe LI, Weiming YI, Peng FU, Chao YUAN. Research progress on thermochemical conversion of biomass to enhance quality and catalyst[J]. CIESC Journal, 2020, 71(8): 3416-3427.

图/表 8

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转化路径	转化条件	转化产物	产物利用价值	转化特点	文献
燃烧	富氧、着火点	能量、CO₂、H₂O等	热力、电力等	能源利用率低，环境污染大	[15,16]
催化热解	缺氧或少氧高温（300~1500℃）	热解气、生物油、生物炭	热力、电力、活性炭、燃气、液体燃料、化学品等	设备要求低，转化效率高，技术成熟	[17,18]
水热催化	缺氧或少氧高压（5~25 MPa）高温（200~600℃）	热解气、生物油、生物炭	热力、电力、活性炭、燃气、液体燃料、化学品等	（1）水作为溶剂或催化反应介质，绿色环保无污染；（2）水热催化传质传热速率较快，反应迅速，节约能量；（3）生物质原材料无须脱水，经定向反应后产物收率较高	[19,20]
化学链转化	高温（700~1000℃）氧载体	能量、CO₂、H₂O、合成气等	热力、电力、干冰、燃气等	（1）燃料反应器中产物为CO₂和水蒸气，可通过冷凝实现CO₂内分离；（2）空气反应器中温度较低避免了NO_x的生成，降低了环境污染；（3）分步转化过程实现了能量梯级利用，提高了能量的利用率	[21,22]

转化路径	转化条件	转化产物	产物利用价值	转化特点	文献
燃烧	富氧、着火点	能量、CO₂、H₂O等	热力、电力等	能源利用率低，环境污染大	[15,16]
催化热解	缺氧或少氧高温（300~1500℃）	热解气、生物油、生物炭	热力、电力、活性炭、燃气、液体燃料、化学品等	设备要求低，转化效率高，技术成熟	[17,18]
水热催化	缺氧或少氧高压（5~25 MPa）高温（200~600℃）	热解气、生物油、生物炭	热力、电力、活性炭、燃气、液体燃料、化学品等	（1）水作为溶剂或催化反应介质，绿色环保无污染；（2）水热催化传质传热速率较快，反应迅速，节约能量；（3）生物质原材料无须脱水，经定向反应后产物收率较高	[19,20]
化学链转化	高温（700~1000℃）氧载体	能量、CO₂、H₂O、合成气等	热力、电力、干冰、燃气等	（1）燃料反应器中产物为CO₂和水蒸气，可通过冷凝实现CO₂内分离；（2）空气反应器中温度较低避免了NO_x的生成，降低了环境污染；（3）分步转化过程实现了能量梯级利用，提高了能量的利用率	[21,22]

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生物质热化学转化提质及其催化剂研究进展

Research progress on thermochemical conversion of biomass to enhance quality and catalyst

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