基本信息
姓名:蒋滨繁
系所:热科学与能源工程系
职称:副教授
邮箱:jiangbinfan@ustb.edu.cn
教育及工作经历
2011.09~2015.06 北京科技大学 本科/学士
2015.09~2020.06 北京科技大学 研究生/博士
2018.11~2019.05 伯明翰大学(英国) 研究生/联合培养
2020.07~2022.06 北京科技大学 博士后/讲师
2022.07~2023.06 北京科技大学 特聘副教授
2023.07至今 北京科技大学 副教授
2015.09~2020.06 北京科技大学 研究生/博士
2018.11~2019.05 伯明翰大学(英国) 研究生/联合培养
2020.07~2022.06 北京科技大学 博士后/讲师
2022.07~2023.06 北京科技大学 特聘副教授
2023.07至今 北京科技大学 副教授
研究领域
能/质协同利用与工业节能降碳
1. 流程工业能-碳解耦:工业生产全流程碳素流追踪与碳排放评价
2. 工业过程CO2减排:与工业煅烧/熔炼/加热过程耦合的CO2循环富集与资源化回收
3. 系统能效/碳效提升:典型热工装备能源结构优化、能效提升与余热回收
1. 流程工业能-碳解耦:工业生产全流程碳素流追踪与碳排放评价
2. 工业过程CO2减排:与工业煅烧/熔炼/加热过程耦合的CO2循环富集与资源化回收
3. 系统能效/碳效提升:典型热工装备能源结构优化、能效提升与余热回收
研究生培养
硕士培养:每年招收硕士研究生2~3人.
基本要求:热爱生活、敬畏科研,对自我有要求、对未来有追求
能力要求:具有动力工程及工程热物理等相关学科专业知识,有逻辑思维,擅长数学和英语等
欢迎有志于从事工业节能降碳、能/质循环利用与低碳新工艺、热化学储能与余热回收、多孔介质热/质协同传递等领域基础和应用研究的同学申报,课题组提供开放的学术氛围与多元化国际交流机会(包括国际学术会议和出国访学等),欢迎你的加入!
基本要求:热爱生活、敬畏科研,对自我有要求、对未来有追求
能力要求:具有动力工程及工程热物理等相关学科专业知识,有逻辑思维,擅长数学和英语等
欢迎有志于从事工业节能降碳、能/质循环利用与低碳新工艺、热化学储能与余热回收、多孔介质热/质协同传递等领域基础和应用研究的同学申报,课题组提供开放的学术氛围与多元化国际交流机会(包括国际学术会议和出国访学等),欢迎你的加入!
开设课程
本科生课程:
1. 《热工过程及设备》(专业核心课,48学时)
2. 《热工学》(专业必修课,32学时)
1. 《热工过程及设备》(专业核心课,48学时)
2. 《热工学》(专业必修课,32学时)
学术/社会兼职
1. Energy Storage and Saving青年编委、SDEWES学术委员
2. J. Clean. Prod., Applied Energy, Energy Conversion and Management等期刊审稿人
2. J. Clean. Prod., Applied Energy, Energy Conversion and Management等期刊审稿人
代表性论文及著作
代表性论文及著作:
[1] Jiang Binfan, Xia Dehong. Toward carbon neutrality in China: A national wide carbon flow tracing and the CO2 emission control strategies for CO2-intensive industries. Science of the Total Environment, 2023, 879:163009. (SCI 一区)
[2] Jiang Binfan, Liu Yifei, Xia Dehong. Heat transfer enhancement of moving bed indirect heat exchanger through directional granule migration in 3-D shell enclosure. Chemical Engineering and Processing - Process Intensification, 2022, 181, 109178.
[3] Jiang Binfan, Zhoufang, Qu Hengyu, Xia Dehong. Industrial waste heat recovery: A helix-weaved convection-radiation converter for heat transfer enhancement in gas heat exchanger. Chemical Engineering and Processing - Process Intensification, 2022, 173:108853. (SCI)
[4] Jiang Binfan, Xia Dehong, Liu Xiangjun. Theoretical analysis for bacteria participating in atmospheric nucleation. Atmospheric Research, 2021, 250(2):105400. (SCI Top)
[5] Jiang Binfan, Xia Dehong. Ammonia control represents the key for PM 2.5 elimination: insights for global air pollution control interconnected from PM 2.5 events in China. Clean Technologies and Environmental Policy, 2021, 23(1). (SCI)
[6] Jiang Binfan, Xia Dehong, Zhang Huili, et al. Effective waste heat recovery from industrial high-temperature granules: A moving bed indirect heat exchanger with embedded agitation. Energy, 2020,118346. (SCI Top)
[7] 蒋滨繁,夏德宏,安苛苛,等. 基于CO2循环的低碳高效白云石煅烧新工艺. 化工学报. 2020, 71, 3699-3709. (EI 卓越期刊)
[8] Jiang Binfan, Xie Yulei, Xia Dehong, Liu Xiangjun, Effect of the molecular structure of volatile organic compounds on atmospheric nucleation: A modeling study based on gas kinetic theory and graph theory, Atmospheric Environment, 2019, 213: 215-222. (SCI Top)
[9] Jiang Binfan, Xia Dehong, et al., Theoretical heat conduction equation based on micro particle vibration fundamental. International Journal of Thermal Sciences, 2019, 140:521-529. (SCI Top)
[10] Jiang Binfan, Xie Yulei, Xia Dehong, Liu Xiangjun, A potential source for PM2.5: Analysis of fine particle generation mechanism in Wet Flue Gas Desulfurization System by modeling drying and breakage of slurry droplet. Environmental Pollution, 2019, 246: 249-256. (SCI Top)
[11] Jiang Binfan, Xia Dehong, et al., An environment-friendly process for limestone calcination with CO2 looping and recovery. Journal of Cleaner Production, 2019, 240: 188147. (SCI Top)
[12] Jiang Binfan, Xia Dehong, et al., Efficient waste heat recovery system for high-temperature solid particles based on heat transfer enhancement. Applied Thermal Engineering, 2019, 155: 166-174. (SCI Top)
[13] Jiang Binfan, Wen Yu, Li Zhiyong, Liu Xiangjun, Xia Dehong, Theoretical Analysis on the Removal of Cyclic Volatile Organic Compounds by Non-thermal Plasma. Water Air & Soil Pollution, 2018, 229(2):35. (SCI)
[14] Jiang Binfan, Xia Dehong, et al., A multicomponent kinetic model established for investigation on atmospheric new particle formation mechanism in H2SO4-HNO3-NH3-VOC system. Science of the Total Environment, 2017, 616-617. (SCI Top)
[15] Jiang Binfan, Xia Dehong. Role identification of NH3 in atmospheric secondary new particle formation in haze occurrence of China. Atmospheric Environment, 2017, 163:107-117. (SCI Top)
[16] Jiang Binfan, Xia Dehong, et al. Heat transfer enhanced by helix-weaved convection-radiation converter in gas side of heat exchanger, in 6th IWHT, Harbin, China, 2021. (国际会议)
[17] Jiang Binfan, Modeling analysis of PM2.5 Formation in Complex Air Pollution in China (SDEWES2019.0277), in: 15th SDEWES, Dubrovnik, Croatia, 2019. (国际会议)
[18] Jiang Binfan, Xiao Linshu, et al., An efficient waste heat reclamation system for solid particles producing from rotary kiln, in: 14th Conference on Sustainable Development of Energy, Water and Environment Systems (SDEWES), Palermo, Italy, 2018. (国际会议,分会场主席)
[19] Jiang Binfan, Xia Dehong. Key Factor Identification for PM2.5 Formation in China: The Role of NH3 in Atmospheric New Particle Formation, in: 5th International Conference on Environment and Renewable Energy, Vienna, Austria, 2018. (国际会议)
[20] Jiang Binfan, Xia Dehong. A potential source for PM2.5 in China, in 5th International Workshop on Heat/Mass Transfer Advances for Energy Conservation and Pollution Control (IWHT), Novosibirsk, Russia, 2019. (国际会议)
[1] Jiang Binfan, Xia Dehong. Toward carbon neutrality in China: A national wide carbon flow tracing and the CO2 emission control strategies for CO2-intensive industries. Science of the Total Environment, 2023, 879:163009. (SCI 一区)
[2] Jiang Binfan, Liu Yifei, Xia Dehong. Heat transfer enhancement of moving bed indirect heat exchanger through directional granule migration in 3-D shell enclosure. Chemical Engineering and Processing - Process Intensification, 2022, 181, 109178.
[3] Jiang Binfan, Zhoufang, Qu Hengyu, Xia Dehong. Industrial waste heat recovery: A helix-weaved convection-radiation converter for heat transfer enhancement in gas heat exchanger. Chemical Engineering and Processing - Process Intensification, 2022, 173:108853. (SCI)
[4] Jiang Binfan, Xia Dehong, Liu Xiangjun. Theoretical analysis for bacteria participating in atmospheric nucleation. Atmospheric Research, 2021, 250(2):105400. (SCI Top)
[5] Jiang Binfan, Xia Dehong. Ammonia control represents the key for PM 2.5 elimination: insights for global air pollution control interconnected from PM 2.5 events in China. Clean Technologies and Environmental Policy, 2021, 23(1). (SCI)
[6] Jiang Binfan, Xia Dehong, Zhang Huili, et al. Effective waste heat recovery from industrial high-temperature granules: A moving bed indirect heat exchanger with embedded agitation. Energy, 2020,118346. (SCI Top)
[7] 蒋滨繁,夏德宏,安苛苛,等. 基于CO2循环的低碳高效白云石煅烧新工艺. 化工学报. 2020, 71, 3699-3709. (EI 卓越期刊)
[8] Jiang Binfan, Xie Yulei, Xia Dehong, Liu Xiangjun, Effect of the molecular structure of volatile organic compounds on atmospheric nucleation: A modeling study based on gas kinetic theory and graph theory, Atmospheric Environment, 2019, 213: 215-222. (SCI Top)
[9] Jiang Binfan, Xia Dehong, et al., Theoretical heat conduction equation based on micro particle vibration fundamental. International Journal of Thermal Sciences, 2019, 140:521-529. (SCI Top)
[10] Jiang Binfan, Xie Yulei, Xia Dehong, Liu Xiangjun, A potential source for PM2.5: Analysis of fine particle generation mechanism in Wet Flue Gas Desulfurization System by modeling drying and breakage of slurry droplet. Environmental Pollution, 2019, 246: 249-256. (SCI Top)
[11] Jiang Binfan, Xia Dehong, et al., An environment-friendly process for limestone calcination with CO2 looping and recovery. Journal of Cleaner Production, 2019, 240: 188147. (SCI Top)
[12] Jiang Binfan, Xia Dehong, et al., Efficient waste heat recovery system for high-temperature solid particles based on heat transfer enhancement. Applied Thermal Engineering, 2019, 155: 166-174. (SCI Top)
[13] Jiang Binfan, Wen Yu, Li Zhiyong, Liu Xiangjun, Xia Dehong, Theoretical Analysis on the Removal of Cyclic Volatile Organic Compounds by Non-thermal Plasma. Water Air & Soil Pollution, 2018, 229(2):35. (SCI)
[14] Jiang Binfan, Xia Dehong, et al., A multicomponent kinetic model established for investigation on atmospheric new particle formation mechanism in H2SO4-HNO3-NH3-VOC system. Science of the Total Environment, 2017, 616-617. (SCI Top)
[15] Jiang Binfan, Xia Dehong. Role identification of NH3 in atmospheric secondary new particle formation in haze occurrence of China. Atmospheric Environment, 2017, 163:107-117. (SCI Top)
[16] Jiang Binfan, Xia Dehong, et al. Heat transfer enhanced by helix-weaved convection-radiation converter in gas side of heat exchanger, in 6th IWHT, Harbin, China, 2021. (国际会议)
[17] Jiang Binfan, Modeling analysis of PM2.5 Formation in Complex Air Pollution in China (SDEWES2019.0277), in: 15th SDEWES, Dubrovnik, Croatia, 2019. (国际会议)
[18] Jiang Binfan, Xiao Linshu, et al., An efficient waste heat reclamation system for solid particles producing from rotary kiln, in: 14th Conference on Sustainable Development of Energy, Water and Environment Systems (SDEWES), Palermo, Italy, 2018. (国际会议,分会场主席)
[19] Jiang Binfan, Xia Dehong. Key Factor Identification for PM2.5 Formation in China: The Role of NH3 in Atmospheric New Particle Formation, in: 5th International Conference on Environment and Renewable Energy, Vienna, Austria, 2018. (国际会议)
[20] Jiang Binfan, Xia Dehong. A potential source for PM2.5 in China, in 5th International Workshop on Heat/Mass Transfer Advances for Energy Conservation and Pollution Control (IWHT), Novosibirsk, Russia, 2019. (国际会议)
专利
[1] 蒋滨繁,敖雯青,夏德宏,张培昆,一种产物气循环煅烧石灰石与二氧化碳资源化回收工艺(授权号:CN110451822A)
[2] 蒋滨繁,郭浩,曲恒宇,刘向军,夏德宏,一种针对宽粒径散料的自然分级和均衡布料方法及装置(授权号:CN107442412A)
[3] 夏德宏,曲恒宇,刘向军,蒋滨繁,一种对高温含尘烟气的除尘换热一体化处理装置及方法(授权号:CN106731330A)
[4] 蒋滨繁 ,夏德宏,刘向军,张惠黎,一种基于颗粒掺混的高温固体散料间接传热强化方法(申请号:201911194940.8)
[5] 蒋滨繁 ,夏德宏,敖雯青,张培昆,针对竖窑高温均匀煅烧的内外环交变式加热装置及方法(申请号:201911193317.0)
[2] 蒋滨繁,郭浩,曲恒宇,刘向军,夏德宏,一种针对宽粒径散料的自然分级和均衡布料方法及装置(授权号:CN107442412A)
[3] 夏德宏,曲恒宇,刘向军,蒋滨繁,一种对高温含尘烟气的除尘换热一体化处理装置及方法(授权号:CN106731330A)
[4] 蒋滨繁 ,夏德宏,刘向军,张惠黎,一种基于颗粒掺混的高温固体散料间接传热强化方法(申请号:201911194940.8)
[5] 蒋滨繁 ,夏德宏,敖雯青,张培昆,针对竖窑高温均匀煅烧的内外环交变式加热装置及方法(申请号:201911193317.0)
代表性科研项目
Ø 2021至今:主持国家自然科学基金青年项目“内势-外场耦合驱动下气相污染物多元成核瞬态热-质作用机制”
Ø 2021 ~2022:主持中国博士后科学基金面上资助项目“复合污染物积聚及 VOC/NOx光化学释O3耦合驱动的大气二次PM2.5爆发机制”
Ø 2021~2022:主持中国博士后科学基金特别资助(站中)项目“分子间多作用势驱动的气相污染物多元成核过程热-质耦合瞬态传递动力学研究”
Ø 2020~2023:主持广东省基础与应用基础研究区域联合基金青年项目“复合污染大气中VOC/NOx光化学释O3及其与PM2.5耦合作用”
Ø 2021~2023:主持校企合作项目“天然气蓄热式烟气回流低氮燃烧器开发”
Ø 2021~2022:主持校企合作项目“小颗粒油页岩干馏提油工艺可行性研究”
Ø 2018~2021:参与国家重点研发计划项目“冶金、化工炉窑及系统节能减排关键技术”
Ø 2017~2020:参与国家重点研发计划课题“固体散料余热高效蓄存与分级提取工艺”
Ø 2016~2019:参与国家重点研发计划课题“三维蜂巢蓄换体烟气余热回收净化一体化技术”
Ø 2016~2018:参与国家标准编制《蓄热式轧钢加热炉能效限定值及能效等级》
Ø 2021 ~2022:主持中国博士后科学基金面上资助项目“复合污染物积聚及 VOC/NOx光化学释O3耦合驱动的大气二次PM2.5爆发机制”
Ø 2021~2022:主持中国博士后科学基金特别资助(站中)项目“分子间多作用势驱动的气相污染物多元成核过程热-质耦合瞬态传递动力学研究”
Ø 2020~2023:主持广东省基础与应用基础研究区域联合基金青年项目“复合污染大气中VOC/NOx光化学释O3及其与PM2.5耦合作用”
Ø 2021~2023:主持校企合作项目“天然气蓄热式烟气回流低氮燃烧器开发”
Ø 2021~2022:主持校企合作项目“小颗粒油页岩干馏提油工艺可行性研究”
Ø 2018~2021:参与国家重点研发计划项目“冶金、化工炉窑及系统节能减排关键技术”
Ø 2017~2020:参与国家重点研发计划课题“固体散料余热高效蓄存与分级提取工艺”
Ø 2016~2019:参与国家重点研发计划课题“三维蜂巢蓄换体烟气余热回收净化一体化技术”
Ø 2016~2018:参与国家标准编制《蓄热式轧钢加热炉能效限定值及能效等级》