周密

姓名:周密

职称:讲师、硕导

院系:js06金沙申请优惠大厅-(中国)维基百科

研究方向:流体结构交互作用、电力及能源装备服役安全、氢能安全、实验流体力学、流场可视化等

联系方式:

邮箱:mi.zhou@ncepu.edu.cn

地址:F709


个人简介及主要荣誉称号:

周密,男,1985年1月生,汉族,湖北十堰人。本科、硕士、博士毕业于德国斯图加特大学。2019年到华北电力大学工作至今。


教学与人才培养情况:

主讲本科留学生《实验流体力学》、研究生《流体测量学》(全英文授课)。在德国期间,指导完成各类毕业论文16人次。现指导在读研究生2名,另协助培养研究生2名。


主要科研项目情况:

1. 国家自然科学基金青年项目,热力管道中热分层周向震荡的产生机理及诱发条件的研究(52006067),2021.01-2023.12, 主持

2. 北京市自然科学基金青年项目,槽罐破损特征对液化气扩散机理及云爆威胁的影响(3214057),2021.01-2022.12,主持

3. 德国联邦教育部, 未来能源2020+专项项目, 项目编号02NUK040B, Experimental investigation and numerical simulation on turbulent flow and structure interaction close to a weld connection and leakage, 第一完成人。


代表性论著:

M. Zhou, F. Wiltschko, R. Kulenovic, E. Laurien, “Large-eddy simulation on thermal-mixing experiment at horizontal T-junction with varied flow temperature,” Nuclear Engineering and Design, 388, 111644 (2022).

M. Zhou, R. Kulenovic, E. Laurien, “Advanced flow pattern for describing tangential flow oscillation in thermal-mixing pipe flow at a horizontal T-Junction”, International Journal of Thermal Sciences, 136, pp. 328-336 (2019).

M. Zhou, R. Kulenovic, E. Laurien, “T-Junction Experiments to Investigate Thermal-Mixing Pipe flow with Combined Measurement Techniques”, Applied Thermal Engineering, 150, pp. 237-249 (2019).

M. Zhou, R. Kulenovic, E. Laurien, “T-junction experiment with high temperature and high pressure to investigate flow rate influence on mixing characteristics”, International Journal of Heat and Fluid Flow, 71, pp. 451-459 (2018).

M. Zhou, R. Kulenovic, E. Laurien, “Experimental Investigation on the Thermal Mixing Characteristics at a 90° T-junction with Varied Temperature Differences”,  Applied Thermal Engineering , 128, pp. 1359-1371 (2018).

M. Zhou, R. Kulenovic, E. Laurien, M. Kammerer, X. Schuler, “Thermocouple Measurements to Investigate the Thermal Fatigue of a Cyclical Thermal Mixing Process on a Dissimilar Weld Seam,”  Nuclear Engineering and Design , 320, pp. 77-87 (2017).

E. Laurien, T. Stürzel, M. Zhou, “Unsteady void measurements within debris beds using high speed X-ray tomography,”  Nuclear Engineering and Design , 312, pp. 277-283 (2017).