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    个人简介

    2010年毕业于中国科学技术大学,2012年被评为副教授,2016年被破格提拔为教授。从事特殊建筑通风与火灾防治研究,建筑环境中的传热传质研究,燃烧理论及应用研究。主持国家自然科学基金项目3项;参加国家重点研发计划项目、973项目与科技部国际合作项目;主持省部级项目4项;主持重要横向工程项目与军工项目10余项。入选万人计划青年拔尖人才,“重庆大学科研后备拔尖人才培育计划”,获得“重庆大学优秀青年教师”称号等。


    研究方向
    建筑环境中的传热传质、特殊建筑火灾防治与烟气控制、通风、燃烧理论及应用

    主讲课程
    《传热学》《燃料与燃烧》

    学术兼职
    国际燃烧学会会员;国家自然科学基金委通讯评议专家;中国消防协会建筑防火专业委员会委员;中国环境科学学会室内环境与健康分会青年委员;Building and Environment、Energy and Buildings、Applied Energy等13个著名国际学术期刊的审稿人。

    主要成果
    主持或主研的科学研究项目:            
    主持国家自然科学基金项目3项;参加国家重点研发计划项目、973项目与科技部国际合作项目;主持省部级项目4项;主持重要横向工程项目与军工项目10余项。部分代表性项目如下:            
    国家自然科学基金面上项目,51976017,隧道火灾烟气行为模式多样性及其诱发、干预机制,2020.1-2023.12,主持            
    国家自然科学基金面上项目,51578087,EAHE与建筑本体蓄热跨时间尺度耦合及协同激发热压潜力研究,2016.1-2019.12,主持            
    重庆市科委项目,cstc2018jscx-msybX0345 ,城市综合管廊防火关键技术研究,2018.8-2020.7,主持            
    国家自然科学基金面上项目,51678088,地下建筑自然通风的热压分布多态性问题,2017.1-2020.12,参加            
    工程研究项目,H20181152,曾家岩大桥隧道工程多匝道区域通风排烟方式定量研究,2018.12-2019.9,主持            
    科技部国家重点研发计划课题,2016YFC0800603,高效复合防排烟技术和关键装置,2016.7-2019.6            
    军工项目,JG2017068-JG2017071,****系统研发,2017.8-2018.9            
    科技部国际科技合作计划项目,2014DFA62970,适宜长江流域分散式采暖关键技术合作研究, 2015.1-2017.12,参加            
    工程研究项目,1042012920160598,深中通道机场互通地下枢纽工程火灾排烟与应急疏散研究项目,2016.9-2017.9,主持            
    工程研究项目,1042012920130309,地下交通环廊火灾防排烟与人员疏散方案模拟研究2013.4-2015.6,主持            
    国家自然科学基金青年基金,51106189 ,腔室水平开口火灾烟气动力学特性及对环境风的响应机制研究,2012.1-2014.12,主持            
    科技部国家基础研究规划项目(973计划),2012CB720103,座舱空气质量与热舒适的系统试实验评估准则,2012.4-2013.12,参加            
    科技部国际科技合作计划项目,2010DFA72740-03,建筑围护结构体系关键技术研究(中美项目),2011.9-2012.12,参加            
    论文:            
    [1] Yang D*, Wei HB, Shi R. A demand-oriented approach for integrating earth-to-air heat exchangers into buildings for achieving year-round indoor thermal comfort [J]. Energy Conversion and Management, 2019, 182:95-107.            
    [2] Yang D*, Guo YH, Zhang JP. Evaluation of the thermal performance of an earth-to-air heat exchanger (EAHE) in a harmonic thermal environment [J]. Energy Conversion and Management, 2016, 109:184-194.            
    [3] Yang D*, Li P. Dimensionless design approach, applicability and energy performance of stack-based hybrid ventilation for multi-story buildings[J].Energy, 2015, 93:128-140.            
    [4] Yang D*, Guo YH. Fluctuation of natural ventilation induced by nonlinear coupling between buoyancy and thermal mass [J]. International Journal of Heat and Mass Transfer, 2016, 96:218-230.            
    [5] Yang D*, Zhang JP. Analysis and experiments on the periodically fluctuating air temperature in a building with earth-air tube ventilation [J]. Building and Environment, 2015, 85:29-39.            
    [6] Yang D*, Li P. Natural ventilation of lower-level floors assisted by the mechanical ventilation of upper-level floors via a stack [J]. Energy and Buildings, 2015, 92:296-305.            
    [7] Yang D*, Zhang JP. Theoretical assessment of the combined effects of building thermal mass and earth-air-tube ventilation on the indoor thermal environment [J]. Energy and Buildings, 2014, 81:182-199.            
    [8] Yang D*, Du T, Peng SN, Li BZ. A model for analysis of convection induced by stack effect in a shaft with warm airflow expelled from adjacent space [J]. Energy and Buildings, 2013, 62:107-115.            
    [9] Yang D*, Huo R, Zhang XL, Zhu S, Zhao XY. Comparative study on carbon monoxide stratification and thermal stratification in a horizontal channel fire [J]. Building and Environment, 2012, 49:1-8.            
    [10] Yang D*, Huo R, Zhang XL, Zhao XY. On the front velocity of buoyancy-driven transient ceiling jet in a horizontal corridor: Comparison of correlations with measurements [J]. Applied Thermal Engineering, 2011, 31:2992-2999.            
    [11] Yang D*, Huo R, Zhang XL, Zhao XY. Comparison of the distribution of carbon monoxide concentration and temperature rise in channel fires: Reduced-scale experiments [J]. Applied Thermal Engineering, 2011, 31(4): 528-536.            
    [12] Yang D, Hu LH*, Huo R, Jiang YQ, Liu S, Tang F. Experimental study on buoyant flow stratification induced by a fire in a horizontal channel[J]. Applied Thermal Engineering, 2010, 30(8-9): 872-878.            
    [13] Yang D*, Ding Y, Du T, Mao SH*, Zhang ZJ. Buoyant back-layering and the critical condition for preventing back-layering fluid in inclined tunnels under natural ventilation: Brine water experiments[J]. Experimental Thermal and Fluid Science, 2018, 90:319-329.            
    [14] Yang D*, Liu YL, Zhao CM, Mao SH. Multiple steady states of fire smoke transport in a multi-branch tunnel: Theoretical and numerical studies[J]. Tunnelling and Underground Space Technology, 2017, 61:189-197.            
    [15] Yang D*, Li BZ, Du T, Li N. Analytical models for evaluating buoyancy-driven ventilation due to stack effect in a shaft considering heat transfer from shaft interior boundaries[J]. Journal of Central South University, 2012, 19(3):651-656.            
    [16] Yang D, Hu LH*, Jiang YQ, Huo R, Zhu S, Zhao XY. Comparison of FDS predictions by different combustion models with measured data for enclosure fires[J]. Fire Safety Journal, 2010, 45(5): 298-313.            
    [17] Yang D*, Li P. Multiple patterns of heat and mass flow induced by the competition of forced longitudinal ventilation and stack effect in sloping tunnels[J]. International Journal of Thermal Sciences, 2019, 138:35-46.            
    [18] Wei HB, Yang D*, Guo YH, Chen MQ. Coupling of earth-to-air heat exchangers and buoyancy for energy efficient ventilation of buildings considering dynamic thermal behavior and cooling/heating capacity[J]. Energy, 2018, 147:587-602.            
    [19] Du T, Yang D*, Wei HB, Zhang ZJ. Experimental study on mixing and stratification of buoyancy-driven flows produced by continuous buoyant source in narrow inclined tank[J]. International Journal of Heat and Mass Transfer, 2018, 121:453-462.            
    [20] Du T, Yang D*, Wei HB, Zhang ZJ. Propagation and entrainment of buoyancy-driven flows in a narrow horizontal space and implications for buoyant contaminant transport under natural ventilation[J]. Building and Environment, 2018, 132:214-224.            
    [21] Du T, Yang D*, Peng SN, Liu YL, Xiao YM. Performance evaluation of longitudinal and transverse ventilation for thermal and smoke control in a looped urban traffic link tunnel[J]. Applied Thermal Engineering, 2016, 96:490-500.            
    [22] Mao SH, Yang D*. One-dimensional analysis for optimizing smoke venting in tunnels by combining roof vents and longitudinal ventilation[J]. Applied Thermal Engineering, 2016, 108:1288-1297.            
    [23] Du T, Yang D*, Ding Y. Driving force for preventing smoke backlayering in downhill tunnel fires using forced longitudinal ventilation[J]. Tunnelling and Underground Space Technology, 2018, 79:76-82.            
    [24] Du T, Yang D*, Peng SN, Xiao YM. A method for design of smoke control of urban traffic link tunnel (UTLT) using longitudinal ventilation[J]. Tunnelling and Underground Space Technology, 2015, 48:35-42.            
    [25] Du T, Yang D*, Peng SN, Li BZ. 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[J]. International Journal of Ventilation, 2016, 15(2):122-133.            
    [26] Du T*, Du JX, Yang D*, Dong S, Yang LL. Transient evolution and backlayering of buoyancy-driven contaminants in a narrow inclined space. Building and Environment, 2018, 143:59-70.            
    [27] Liu YL, Yang D*, Xiao YM, Mao SH*, Yang MJ. Combining diverse driving forces for smoke control in complex urban traffic link tunnels (UTLTs) using one-dimensional flow modelling [J]. Sustainable Cities and Society, 2018, 43:265-274.            
    出版物及代表著作:            
    阳东,蒋亚强,李乐,著. 隧道通风与火灾排烟理论基础及应用,中国建筑工业出版社,2018,北京,29.6 万字.

    研究生培养
    已经培养出10名硕士,联合培养出1名博士;4名博士研究生在读,12名硕士研究生在读。

    联系方式
    yangdong@cqu.edu.cn