城市微气候、大气污染物与防灾、绿色建筑节能技术

毕业院校：日本东京大学

社会兼职：
1.2021.6-至今
中国建筑学会建筑物理分会会员
2.2017.3-至今
日本建筑学会会员
3.Building and Environment（SCI）审稿专家
4.International Journal of Heat and Mass Transfer（SCI）审稿专家
5.Journal of Wind Engineering and Industrial Aerodynamics（SCI）审稿专家

[1] W. Oh, R. Ooka, H. Kikumoto, M. Han. Numerical modeling of cough airflow: Establishment of spatial–temporal experimental dataset and CFD simulation method. (SCI检索).[J].Building and Environment.2021,207(PB):
[2] 韩梦涛. 基于LBM-LES的室外湍流非稳态快速模拟方法的开发..[J].建筑科学.2021,37(10):200-207+212
[3] M. Han*, R. Ooka, H. Kikumoto, W. Oh, Y. Bu, S. Hu. Experimental measurements of airflow features and velocity distribution exhaled from sneeze and speech using particle image velocimetry. (SCI检索).[J].Building and Environment.2021,205(November 2021):
[4] M. Han*, R. Ooka, H. Kikumoto. A wall function approach in lattice Boltzmann method: algorithm and validation using turbulent channel flow. (SCI检索).[J].Fluid Dynamics Research.53(Number 4):
[5] M. Han*, R. Ooka, H. Kikumoto, W. Oh, Y. Bu, S. Hu.Measurements of exhaled airflow velocity through human coughs using particle image velocimetry. (SCI检索).[J].Building and Environment.2021,202(September 2021):
[6] Mengtao Han*, Royzo Ooka, Hideki Kikumoto. Effects of wall function model in lattice Boltzmann method-based large-eddy simulation on built environment flows. (SCI检索).[J].Building and Environment.2021,195(December 2020):
[7] Mengtao Han*, Royzo Ooka, Hideki Kikumoto. Validation of lattice Boltzmann method-based large-eddy simulation applied to wind flow around single 1:1:2 building model. (SCI检索).[J].Journal of Wind Engineering and Industrial Aerodynamics.2020,206(November 2020):
[8] Mengtao Han*, Royzo Ooka, Hideki Kikumoto. Lattice Boltzmann method-based large-eddy simulation of indoor isothermal airflow. (SCI检索).[J].International Journal of Heat and Mass Transfer.2018,130700–709
[9] Mengtao Han, Hong Chen*. Effect of external air-conditioner units’ heat release modes and positions on energy consumption in large public buildings. (SCI检索).[J].Building and Environment.2016,11147–60
[10] Mengtao Han, Ryozo Ooka, Hideki Kikumoto, A wall function approach for lattice Boltzmann method, SEISAN KENKYU. 72 (2020) 41–47..[J].SEISAN KENKYU.2019,7241-47
[11] Mengtao HAN, Ryozo Ooka, Hideki Kikumoto, Lattice Boltzmann Method integrated with large-eddy simulation applied to isothermal indoor flow (in Japanese), SEISAN KENKYU. 71 (2019) 23–28..SEISAN KENKYU.2019,7123-28
[12] Mengtao Han, Royzo Ooka, Hideki Kikumoto. Compressibility error of lattice Boltzmann method-based large eddy simulation with BGK model in indoor flows[C]//Proceedings of the 15th International Conference on Wind Engineering (ICWE15), Beijing, China, 2019..[J].Beijing, China:Proceedings of the 15th International Conference on Wind Engineering (ICWE15).2019,315-316
[13] Mengtao Han, Royzo Ooka, Hideki Kikumoto. Comparison of Lattice Boltzmann Method and Finite Volume Method with Large Eddy Simulation in Isothermal Room Flow[C]//7th International Building Physics Conference (IBPC 2018):Healthy, Intelligent and Resilient Buildings and Urban Environments. Syracuse, New York: International Association of Building Physics (IABP), 2018: 1121–1126..[J].Syracus, US:7th International Building Physics Conference (IBPC 2018).2018,1121-1126
[14] Mengtao Han, Royzo Ooka, Hideki Kikumoto. Comparison between lattice Boltzmann method and finite volume method for LES in the built environment[C]//The 7th International Symposium on Computational Wind Engineering 2018 (CWE2018), Seoul, South Korea, 2018..[J].Seoul, South Korea:The 7th International Symposium on Computational Wind Engineering 2018 (CWE2018).2018,
[15] Mengtao Han, Royzo Ooka, Hideki Kikumoto, Keigo Nakashima. Comparison between lattice Boltzmann method and finite volume method for LES in the built environment[C]//International Workshop on Wind-Related Disasters and Mitigation (WRDM). Sendai, Japan, 2017..[J].Sendai, Japan:International Workshop on Wind-Related Disasters and Mitigation (WRDM).2018,
[16] Hideki Kikumoto*, Royzo Ooka, Mengtao Han, Keigo Nakajima. Consistency of mean wind speed in pedestrian wind environment analyses: Mathematical consideration and a case study using large-eddy simulation[J]. Journal of Wind Engineering and Industrial Aerodynamics, 2018, 173: 91–99. (SCI检索).[J].Journal of Wind Engineering and Industrial Aerodynamics.2017,17391-99
[17] 韩梦涛. 建筑声学在绿色建筑技术中的集成应用[J]. 武汉勘察设计, 2016, 01(No.295):32-36..[J].武汉勘察设计.2016,295(1):32-36
[18] 韩梦涛, 张文俊, 饶紫云, 陈庆, 建筑声品质与光环境联合改造方法研究 — 以某医院门诊大厅改造为例 , 环境工程. 33 (2015) 83–88..[J].环境工程.2015,3383–88
[19] 韩梦涛, 王凡. 超大空间声品质研究与改造--以某5000㎡大宴会厅为例[J]. 声学技术, 2014, 000(0z1):64-67..[J].声学技术.2014,64-67
[20] Mengtao Han, Hong Chen, Li Yuan, Ganbo Han, Baofeng Li. CFD analysis on cooling effect on a complex traditional urban area with river wind in summer[C]. 2011 International Conference on Multimedia Technology. IEEE, 2011: 3880–3883. (EI检索).[J].2011 International Conference on Multimedia Technology.2011,3880-3883

[1] 基于LBM的突发城市大气事故污染扩散路径及风险评估的快速预测方法的开发,华中科技大学,
[2] 日本学术振兴会科研费Grant-in-Aid for JSPS Fellows,日本学术振兴会（The Japan Society for the Promotion of Science）,18J13607,2017-10-30-2020-03-31
[3] 既有公共建筑节能改造基准能耗模拟研究与应用,武汉市城市建设委员会,201537,2015-10-01-2018-08-31

[1] 陈宏, 韩梦涛. 街区空间微气候营造策略. 华中科技大学出版社, 2022.1.