杜涛 副教授

• 学院： 建筑工程学院
• 性别： 男
• 出生年月： 1990-03-00
• 职称： 副教授
• 学位： 工学博士
• 学历： 博士研究生
• 毕业院校： 重庆大学
• 联系电话：
• 电子邮箱： chddt@foxmail.com
• 通讯地址： 长安大学建筑工程学院
• 邮编：
• 传真：
• 办公地址：
• 教育经历：

  2007-2011 长安大学 建环本科

  2011-2017 重庆大学 暖通博士

  2015-2016 剑桥大学 博士联培

  
  

杜涛，河南商丘人，工学博士，重庆大学与剑桥大学博士后。2022年进入长安大学建环系任教，主要研究方向为建筑通风、防排烟、气流组织及污染物控制。主持国家自然科学基金青年基金、国家重点研发计划子课题、中国博士后基金特别资助、陕西省自然科学基金及企业委托横向科研项目十余项，参与国家基金面上项目、军工项目等多项，在BAE、ENB、TUST等行业知名期刊发表论文多篇。期待与大家交流沟通！

建筑通风；建筑防排烟；气流组织；污染物控制

高等流体力学，流体力学（水力学），建筑设备

负责的代表性研究课题：

国家自然科学基金青年基金，倾斜隧道火灾烟气非对称蔓延行为及诱导、卷吸空气机理研究。

国家重点研发计划子课题，长大公路隧道燃爆机理及推演研判技术。

中国博士后特别资助，隧道火灾烟气瞬态演化特性研究。

一作/通讯论文：

[21] Tao Du, et al.. Experimental study on the characteristics of buoyant gas flow produced by vertical gas leakage in tunnels under natural ventilation. Physics of Fluids, 2024, 36：057116.

[20] Tao Du, et al.. Brine-water experimental study on the natural ventilation flow rate induced by a localized buoyancy source in an inclined narrow space.Energy and Buildings, 2024: 114104.

[19]Shoupeng Zhang,et al., Tao Du*. Asymmetrical distribution of buoyancy flux and its effect on smoke propagation velocity and backlayering length in inclined tunnel fires, Case Studies in Thermal Engineering, 2024, 62:105205. 

[18] Haibin Wei, et al., Tao Du*.  Experimental comparison on the smoke movement in horizontal and downhill tunnel fires under subcritical ventilation. Case Studies in Thermal Engineering, 2024, 54: 104055.

[17] Tao Du, Haoyue Yu, Xianyuan Lu, Dong Yang*. Brine-water experimental study on the propagation of stratified smoke flow in tunnel fires under subcritical longitudinal ventilation. Tunnelling and Underground Space Technology,  2023, 138: 105176.

[16] 杜涛, 等. 隧道火灾烟气温度及蔓延速度纵向衰减特性. 中国安全科学学报, 2023, 33(2): 140-145.

[15] Tao Du, Ping Li*, Haibin Wei, Dong Yang. On the backlayering length of the buoyant smoke in inclined tunnel fires under natural ventilation. Case Studies in Thermal Engineering, 2022, 39:102455.

[14] Tao Du*,Ping Li, Dong Yang*. Downstream stratification of the buoyant contaminants produced by a highly lazy plume in a longitudinally ventilated tunnel. Building and Environment, 2021, 195, 107767. 

[13] Tao Du, Lingling Yang, Dong Yang*, Song Dong, Wenhui Ji. On the backlayering flow of the buoyant contaminants in a tunnel with forced longitudinal ventilation. Building and Environment,2020, 175, 106798. 

[12] Dong Yang, et al., Tao Du*, et al. Influences of vent location on the removal of gaseous contaminants and indoor thermal environment. Journal of Building Engineering, 2020, 101679. 

[11] Dong Yang, et al., Tao Du*. Experimental study on the performance of hybrid ventilation system combining forced longitudinal flow and shaft natural ventilation in tunnels. Tunnelling and Underground Space Technology, 2020, 103, 103491.

[10] Dong Yang*, Ping Li, et al, Tao Du*, Zhongjie Zhang. Multiple patterns of heat and mass flow induced by the competition of forced longitudinal ventilation and stack effect in sloping tunnels. International Journal of Thermal Sciences, 2019, 138: 35-46. 

[9]Tao Du*, et al. Transient evolution and backlayering of buoyancy-driven contaminants in a narrow inclined space. Building and Environment, 2018,143:59-70. 

[8] Tao Du, et al. Propagation and entrainment of buoyancy-driven flows in a narrow horizontal space and implications for buoyant contaminant transport under natural ventilation. Building and Environment, 2018, 132: 214-224. 

[7] Tao Du, et al. Experimental study on mixing and stratification of buoyancy-driven flows produced by continuous buoyant source in narrow inclined tank. International Journal of Heat and Mass Transfer, 2018, 121:453-462. 

[6] Tao Du, et al. Driving force for preventing smoke backlayering in downhill tunnel fires using forced longitudinal ventilation. Tunnelling and Underground Space Technology, 2018, 79: 76-82. 

[5] Tao Du, et al. Performance evaluation of longitudinal and transverse ventilation for thermal and smoke control in a looped urban traffic link tunnel. Applied Thermal Engineering, 2016, 96: 490-500. 

[4] Tao Du, et al. Measurement of buoyancy driven transient exchange flow rate across a thin horizontal ceiling vent of a non adiabatic enclosure using a modified tracer-gas decay method, International Journal of Ventilation, 2016, 15: 122-133. 

[3] Tao Du, et al. A method for design of smoke control of urban traffic link tunnel (UTLT) using longitudinal ventilation, Tunnelling and Underground Space Technology, 2015, 48: 35-42. 

[2] Tao Du, et al. Longitudinal Ventilation for Smoke Control of Urban Traffic Link Tunnel: Hybrid Field-network Simulation. Procedia Engineering, 2014, 84: 586-594. 

[1] 杜涛，阳东.点热源与燃烧火源诱导的水平开口气流交换率测量与对比分析，2013中国工程热物理燃烧学年会.

其他作者论文：

[13] Xin Guo, Dong Yang*,  Li Jiang, Tao Du, Shan Lyu. Full-field temperature prediction in tunnel fires using limited monitored ceiling flow temperature data with transformer-based deep learning models. Fire Safety Journal, 2024, 148, 104232.

[12] Miao He, Yin Guo, Dong Yang*, Tao Du. Simple model combined with data assimilation to forecast buoyancy-driven ceiling jet propagation in tunnel fires. International Journal of Thermal Sciences, 2024, 198, 198852.

[11] Dong Yang,  et al., Tao Du. Prediction model of buoyancy-driven flow rate in inclined tunnels with a localized buoyancy source: Emphasis on stratification effects. Building and Environment, 2024, 250, 111165.

[10] Wenhui Yuan, Wenhui Zhang, Jidan Zhang, Tao Du, Yanping Yuan*. Examining smoke control in fires occurring in railroad tunnels: A review. Journal of Thermal Analysis and Calorimetry, 2024, 149(1): 13-39.

[9]阳东, 陈艺蕾, 杜涛. 隧道顶部障碍物下游火灾烟气密度跃变特性. 中国安全科学学报, 2023, 33(2):68-74.

[8] Wenhui Ji*, Houhua Wang, Tao Du, et al. Parametric study on a wall-mounted attached ventilation system for night cooling with different supply air conditions, Renewable Energy, 2019, 143: 1865-1876.

[7] Xiaofeng Zhang*, Rong Zeng, Tao Du, et al. Conventional and energy level based exergoeconomic analysis of biomass and natural gas fired polygeneration system integrated with ground source heat pump and PEM electrolyzer, Energy Conversion and Management, 2019, 195: 313-327. 

[6] Ping Li, Tao Du, Dong Yang*. Influences of stack effect and longitudinal ventilation on the movement of buoyancy-driven contaminants in sloping tunnels. 10th Int. Conference on Indoor Air Quality, Ventilation and Energy Conservation in Buildings, 2019: 1-6. 

[5] Dong Yang*, Yingli Liu, Tao Du. Network Flow Modelling for Optimizing Fire Smoke Control in Complex Urban Traffic Link Tunnels: Incorporating Heat Loss and Gas Species Generation Rate Calculation into Models. 11th Asia-Oceania Symposium on Fire Science and Technology, 2018: 993-1007.

[4] Wenhui Ji, et al., Tao Du, Per Heiselberg. Investigation on thermal performance of the wall-mounted attached ventilation for night cooling under hot summer conditions, Building and Environment, 2018, 146: 268-279. 

[3] Dong Yang*, Yao Ding, Tao Du, et al. Buoyant back-layering and the critical condition for preventing back-layering fluid in inclined tunnels under natural ventilation: Brine water experiments. Experimental Thermal and Fluid Science, 2018, 90: 319-329. 

[2] Dong Yang*, Tao Du, et al. A model for analysis of convection induced by stack effect in a shaft with warm airflow expelled from adjacent space, Energy and Buildings, 2013, 62: 107-115. 

[1] Dong Yang*, Baizhan Li, Tao Du, et al. Analytical models for evaluating buoyancy-driven ventilation due to stack effect in a shaft considering heat transfer from shaft interior boundaries, Journal of Central South University of Technology, 2012, 19: 651-656.