Development of biomass power generation technology at home and abroad

doi:10.3969/j.issn.1674-1951.2021.03.011

Abstract

Abstract:

Biomass energy is a renewable and clean energy,which is of great significance for energy conservation and emission reduction.Biomass power generation can not only achieve carbon neutralization,but also replace some coal power after achieving carbon peak in China,which has become an important force in peak shaving of power grid.The combustion characteristics of biomass were analyzed,and the applications of pure biomass combustion for power generation,co-firing of biomass and coal for power generation,and biomass gasification coupled with coal in China and abroad were introduced respectively.It is pointed out that the capacity,efficiency and availability of pure biomass combustion units are insufficient,and the ash deposition and chlorine corrosion are prone to occur.The biomass and coal co-combustion technology can make use of the existing large-capacity power generating units with a little additional investment,and bring in high flexibility and improvement on biomass utilization efficiency.It is an economical and feasible power generation scheme at this stage,since it can avoid a series of problems caused by pure combustion.But the construction and operation of biomass and coal co-firing power generation projects will be difficult without policy support on electricity price.

Key words: biomass energy, pure combustion, co-combustion, co-firing of coal and biomass for power generation, circulating fluidized bed, carbon peak, carbon neutrality, zero carbon, ultra-low pollutants emission

CLC Number:

TK6:TM619

ZHANG Dongwang, FAN Haodong, ZHAO Bing, WANG Jialin, GONG Taiyi, ZHANG Man, LI Shiyuan, YANG Hairui, LYU Junfu. Development of biomass power generation technology at home and abroad[J]. Huadian Technology, 2021, 43(3): 70-75.

Figures/Tables 3

References 26

[1]	舟丹 . 可再生能源已成全球能源投资热点领域[J]. 中外能源, 2015,20(3):98.
	ZHOU Dan . Technologies for recovering low-temperature heat in delayed coking units[J]. Sino-Global Energy, 2015,20(3):98.
[2]	BACH Q V, TRINH T N, TRAN K Q , et al. Pyrolysis characteristics and kinetics of biomass torrefied in various atmospheres[J]. Energy Conversion and Management, 2017,141:72-78.
[3]	石元春 . 我国生物质能源发展综述[J]. 智慧电力, 2017,45(7):1-5,42.
	SHI Yuanchun . Overview of biomass energy development in China[J]. Smart Power, 2017,45(7):1-5,42.
[4]	田冬莲, 张辉, 高海洋 . 国外推广应用车用生物燃料的政策措施分析[J]. 客车技术与研究, 2009,32(2):58-61.
	TIAN Donglian, ZHANG Hui, GAO Haiyang . Analysis on the policy measures of promoting the application of vehicle biofuels abroad[J]. Bus Technology and Research, 2009,32(2):58-61.
[5]	于雄飞 . 带你全面了解生物质发电[J]. 绿色中国, 2018(4):44-47.
	YU Xiongfei . Bring you comprehensively understand biomass power generation[J]. Green China, 2018(4):44-47.
[6]	高荫榆, 雷占兰, 郭磊 , 等. 生物质能转化利用技术及其研究进展[J]. 江西科学, 2006,24(6):529-533,544.
	GAO Yinyu, LEI Zhanlan, GUO Lei , et al. The conversion and utilization technology of biomass energy and its research progress[J]. Jiangxi Science, 2006,24(6):529-533,544.
[7]	骆仲泱, 陈晨, 余春江 . 生物质直燃发电锅炉受热面沉积和高温腐蚀研究进展[J]. 燃烧科学与技术, 2014,20(3):189-198.
	LUO Zhongyang, CHEN Chen, YU Chunjiang . Review of deposition and high-temperature corrosion in biomass-fired boilers[J]. Journal of Combustion Science and Technology, 2014,20(3):189-198.
[8]	白贤祥, 张玉刚 . 生活垃圾焚烧厂余热锅炉水冷壁高温腐蚀治理研究[J]. 环境卫生工程, 2018,26(3):68-70,74.
	BAI Xianxiang, ZHANG Yugang . Research on treatment of water-wall high temperature corrosion of waste heat boiler in municipal solid waste incinerator[J]. Environmental Sanitation Engineering, 2018,26(3):68-70,74.
[9]	WANG H, HARB J N . Modeling of ash deposition in large-scale combustion facilities burning pulverized coal[J]. Progress in Energy and Combustion Science, 1997,23(3):267-282.
[10]	KLEINHANS U, WIELAND C, FRANDSEN F J , et al. Ash formation and deposition in coal and biomass fired combustion systems:Progress and challenges in the field of ash particle sticking and rebound behavior[J]. Progress in Energy and Combustion Science, 2018,68:65-168.
[11]	朱德辉 . 天门再生能源环保热电厂工程可行性研究[D]. 上海:同济大学, 2005.
[12]	罗永忠 . 秸秆发电商品化前景分析[J]. 中国能源, 2005(3):43-45.
	LUO Yongzhong . Commercial market analysis of straw fired technology in China[J]. Energy of China, 2005(3):43-45.
[13]	董玉平, 郭飞强, 董磊 , 等. 生物质热解气化技术[J]. 中国工程科学, 2011,13(2):44-49.
	DONG Yuping, GUO Feiqiang, DONG Lei , et al. Study on trend of biomass gasification[J]. Engineering Science, 2011,13(2):44-49.
[14]	郑美灵 . 生物质发电项目商业化可行性及政策支持研究[D]. 杭州:杭州电子科技大学, 2013.
[15]	姬爱华 . 生物质直燃发电特点及问题分析[J]. 科技风, 2012(8):56.
	JI Aihua . Characteristics and problem analysis of biomass direct combustion power generation[J]. Technology Wind, 2012(8):56.
[16]	姜士宏, 胡文平 . 燃煤耦合生物质发电需上网电价政策支持[N]. 中国能源报, 2018-07-30(17).
[17]	毛健雄 . 燃煤耦合生物质发电[J]. 分布式能源, 2017,2(5):47-54.
	MAO Jianxiong . Co-firing biomass with coal for power generation[J]. Distributed Energy, 2017,2(5):47-54.
[18]	JUNGINGER M, KOPPEJAN J, GOH C S . Sustainable bioenergy deployment in east and south east asia:notes on recent trends[J]. Sustainability Science, 2019,15(3):1-5. doi: 10.1007/s11625-019-00772-y
[19]	Alholmens:the world's largest biofuelled plant[EB/OL].( 2002 -01-01)[2021-01-06].https://www.modernpowersystems.com/features/featurealholmens-the-world-s-largest-biofuelled-plant-part-1/.
[20]	国家能源局, 环境保护部. 关于开展燃煤耦合生物质发电技改试点工作的通知[Z].国能发电力[2017]75号.
[21]	周国忠 . 生物质掺烧发电存在问题及探讨[J]. 科技视界, 2017(9):242-243.
	ZHOU Guozhong . Discuss on the problems of biomass co-firing power generation technology[J]. Science & Technology Vision, 2017(9):242-243.
[22]	高太振 . 污泥在大型燃煤电厂中干化掺烧处理的应用[J]. 企业技术开发, 2013,32(4):42-43.
	GAO Taizhen . Sludge drying and blending application in large coal-fired power plant[J]. Technological Development of Enterprise, 2013,32(4):42-43.
[23]	陈大元, 王志超, 李宇航 , 等. 燃煤机组耦合污泥发电技术[J]. 热力发电, 2019,48(4):15-20.
	CHEN Dayuan, WANG Zhichao, LI Yuhang , et al. Sludge-coupled power generation technology in coal-fired power plant[J]. Thermal Power Generation, 2019,48(4):15-20.
[24]	韩全顺, 谭兴 . 300 MW循环流化床锅炉生物质燃料混烧影响分析[J]. 铁法科技, 2018(2):45-47.
	HAN Quanshun, TAN Xing . Influence of biomass fuel co-combustion on 300 MW circulating fluidized bed boiler[J]. Tiefa Keji, 2018(2):45-47.
[25]	毛健雄 . 燃煤耦合生物质发电超超临界机组较大幅度减排CO₂的可行之路[C]// 第十一届超超临界机组技术交流会论文集. 合肥, 2017: 1-38.
[26]	马喜涛 . 大唐长山厂燃煤耦合生物质气化发电技术改造示范项目顺利通过168小时试运行[EB/OL].( 2019- 12- 23)[2020-12-18].http://news.bjx.com.cn/html/20191223/1030581.shtml .