唐春丽,博士,硕士研究生导师,讲师
Email: tangchunli219@163.com
教育背景
2010.09-2017.12 西安交通大学 动力工程及工程热物理 工学博士
2006.09-2010.06 重庆大学 热能与动力工程 工学学士
工作经历
2018.2~2022.2:西安交通大学,核科学与技术博士后,人居环境与建筑工程学院助理教授
2022.9~今:西安石油大学,讲师
主讲本科生课程《粉体工程》《工程流体力学》《区域能源论》,辅讲研究生课程《多相流理论》
研究方向
高碱低灰熔点燃料高效清洁利用理论与技术
采油炼化系统中多相流动及传热传质理论与相关技术
石化工业中二氧化碳捕集分离技术及设备开发防护
科研项目
[1]陕西省自然科学基金青年项目,熔融矿物质和还原气氛对旋风燃烧煤氮转化的耦合影响机制研究,2021~2022,主持
[2]中国博士后科学基金面上项目,高温强还原气氛下生物质与煤旋风混烧NOx生成机理研究,2019~2020,主持
[3]北明天时能源科技有限公司,基于典型房间室温的整栋建筑供热效果模拟及评价,2021,主持
[4]哈尔滨锅炉厂预热器有限责任公司,空气预热器性能计算程序扩展开发,2019,主持
[5]济南山源环保科技有限公司,锅炉冷凝式换热器热力计算软件开发,2019,主持
[6]国家重点研发计划子课题,液态排渣工艺条件下高碱煤渣膜形成机制研究,2018~2021,主要负责人
[7]国家重点研发计划,液态排渣旋风燃烧器低NOx燃烧控制技术研究,2018~2021,主要负责人
[8]武锅能源科技有限公司,高温超细废渣旋风膜态燃烧锅炉方案研发设计,2018,主要负责人
[9]武锅能源科技有限公司,超细废渣旋风膜态燃烧锅炉冷热态数值模拟研究,2018,主要负责人
[10]华东电力设计院,新型高中低压回热系统技术分析与计算,2014,主要完成人
[11]东方锅炉股份有限公司,烟气余热回收装置的改造方法及其软件开发,2014,主要完成人
学术成果
SCI论文
[1]C. Tang, X. Gao, Y. Shao, et al., Investigation on the rotary regenerative adsorption wheel in a new strategy for CO2 enrichment in greenhouse, Applied Thermal Engineering, 2022, 205, 118043
[2]C. Tang, T. Zhu, L. Wang, et al. Effects of ash parameters and fluxing agent on slag layer behavior in cyclone, Fuel, 2019, 253:1140-1148.
[3]C. Tang, L. Wang, X. Zhu, et al. Investigation on a new lignite pre-drying power generation system combined with a front air heater, Drying Technology, 2020, 38(12), 1584-1596
[4]C. Tang, L. Deng and D. Che. Numerical Simulation on Slag Flow and Heat Transfer Characteristics of Cyclone Barrel for a Cyclone Fired Boiler. Numerical Heat Transfer, Part A: Applications. 2017, 71(10):1052-1065.
[5]C. Tang, W. Jin, L. Wang, et al., Numerical simulation of a novel regenerative heat exchanger with combined sensible–latent heat storage matrix, Numerical Heat Transfer, Part A: Applications, (2021), 80(11), 579-596
[6]C. Tang, T. Zhu, L. Y. Hu, et al, Numerical Investigation of the Effects of Swirl-Vane Angle and Particle Size on Combustion and Flow Characteristics in a Vertical Cyclone Barrel, Journal of Energy Engineering, 2020, 146(4), 04020029
[7]C. Tang, L. Deng, X. Zhu, and D. Che. Comparative Study of Three Modes of Flue Gas Treatment for Power Plants. Journal of Energy Engineering, 2017, 143(6), 04017068
[8]C. Tang, T. Zhu, L. Wang, et al., NOx Formation Characteristics for Co-combustion of Rice Husk and Coal at High Temperature, Journal of Energy Engineering, 2022, 148(1), 04021065
[9]L. Wang, Y. Shao, C. Tang*, et al., Asia-Pacific Journal of Chemical Engineering, 2022.
[10]T. Zhu, C. Tang, X. Ning, et al., Fuel, 2022, 311, 122536
[11]T. Zhu, C. Tang, X. Ning, et al. Energy& fuel, 2021 (35): 12288-12296.
[12]H. Liu, C. Tang, L. Zhang et al., Numerical Heat Transfer Part a-Applications, 2015, 68 (9): 993-1009.
[13]L. Deng, C. Tang, X. Tan, et al., Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy. 2017,231(5):371-381.
[14]T. Zhu, X. Ning, C. Tang, et al. Fuel, 2022, 313, 122714
[15]T. Zhu, Y. Hu, C. Tang, et al. Fuel, 2020, 272, 117639
[16]S. Jamil, L. Wang, C. Tang, et al. International Journal of Energy Research. 2021, 1-16.
[17]L. Deng, X. Tan, C. Tang, D. Che. Applied Thermal Engineering. 2016, 108: 538-545.
[18]X. Zhu, C. Wang, C. Tang and D. Che., Drying technology. 2017, 35:1492-1505.
[19]L. Wang, Y. Bu, C. Tang, et al. Asic-Pacific Journal of Chemical Engineering, 2019, e2389.
[20]L. Wang, Y. He, C. Tang, et al., International Journal of Heat and Mass Transfer, 2019, 131: 517-526.
[21]L. Wang, L. Deng, C. Tang, et al., Applied Thermal Engineering, 2015, 90: 478-488.
[22]S. Wu, L. Deng, C. Wang, C. Tang, et al. Applied Thermal Engineering. 2017, 121: 368-379
[23]L. Wang, Y. Bu, Y. He, C. Tang, et al., Thermal Science, 2019, 23: 1251-1262.
[24]L. Wang, Y. Bu, D. Li, C. Tang, International Journal of Thermal Sciences, 2019, 136: 52-59.
EI及中文论文
[25]C. Tang, Y. Hu, T. Zhu, et al. Effect of Refractory Lining Thickness on Slag Layer Behavior in Cyclone Barrel, Environmental Science and Engineering, 2022, 237-249
[26]C. Tang, Y. Sun, Y. Hu, et al., Effect of Na on the NOx Formation Characteristic at High Temperature, International Conference on Applied Energy 2020, Virtual
[27]C. Tang, J. Li, Q. Qi, et al., Optimization design and thermal economy analysis of the flue gas treatment system in power plant, ASME Power & Energy 2015, San Diego.
[28]X. Zhu, C. Wang, C. Tang and D. Che., ASME Power & Energy 2017, Charlotte, North Carolina, USA
[29]S. Wu, W. Bai, C. Tang, et al., ASME Power & Energy 2015, San Diego.
[30]L. Wang, D. Li, Y. Yan, C. Tang, Environmental Science and Engineering, 2022, 945-954
[31]唐春丽,谭晓文,李建波,车得福,加热器类型对机组热经济性的影响,工程热物理年会,2014,西安.
[32]何洋, 王利民, 车得福,唐春丽等. H型翅片管湿烟气对流冷凝传热的数值模拟研究[J]. 化工学报, 2019, 70 (12).
[33]刁美玲,唐春丽,朱信,车得福.超超临界二次再热机组热经济性及技术经济性分析,热力发电,2017,46(8).
[34]白文刚,吴松,唐春丽,谭晓文等. 新一代旋风燃烧锅炉旋风筒热平衡分析,工程热物理年会,2014,西安.
