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王海东 副教授
发布时间: 2017-09-21   浏览次数: 4485  

 

王海东,上海理工大学建筑环境与能源工程系副教授、系副主任、党支部书记,上海市浦江人才,上海理工大学“志远学者”,2019年上海理工大学纪念“五四”运动一百周年青年“五四”奖章获得者;担任上海市制冷学会理事和上海市绿色建筑评审专家;担任国际中文期刊《城市建筑与发展》编委。

主要开展室内通风空调系统优化方面的研究,提出了适用于室内通风气流组织模拟的粗网格快速CFD方法,开发了一种适用于非稳态通风预测的快速模拟算法,实现了C919国产大型客机舱内和上海地铁站台等多场所在动态气流下的污染物快速寻源定位;作为科技部重点研发计划课题骨干,提出了适用于不同气候分区的住宅建筑通风模式解决方案;将湍流控制理论应用到高大空间建筑室内环境和负荷计算方法研究,解决了非空调区向空调区热量迁移的计算等问题。在国内外权威学术期刊共发表论文30余篇,授权国家发明专利5项,作为主要完成人参编了《住宅通风设计标准》T-CSUS02-2020。

主要研究方向:

§ 建筑环境模拟技术

§ 高大空间建筑通风空调系统节能

§ 室内污染物寻源反计算

§ 绿色可持续建筑

邮箱:whd@usst.edu.cn 

教育背景:

§ 2013:博士美国科罗拉多大学博尔德University of Colorado Boulder

§ 2008:硕士,天津大学

§ 2006:学士,天津大学

科研项目:

§ 不同气候区住宅通风模式、空气净化过滤方法、冷热源回收设施的优化(国家重点研发计划子课题)

§ 建筑环境非稳态问题的快速CFD模拟方法研究 国家自然科学基金)

§ 基于快速CFD反计算方法的建筑环境污染源实时定位研究 上海浦江人才计划

§ 动态通风房间空气污染源实时定位研究教育部留学回国人员启动基金

§ 室内动态气流组织的湍流模拟方法优化研究(上海市教委青年教师资助计划)

专业和学术任职:

§ 行业和学会任职:中文国际期刊《城市建筑与发展》编委;上海市制冷学会理事;上海市绿色建筑协会评审专家;中国建筑学会暖通空调分会会员;美国暖通空调工程师学会(ASHRAE)会员;国际室内空气质量协会ISIAQ)会员等

§ 多次担任国际会议学术委员和分会场主席,包括担任第二届建筑能源与环境大会(COBEE2012)秘书长、第四届国际能源与可持续性会议ASME International Conference on Energy Sustainability)分会场主席、第三届国际建筑能源与环境大会(COBEE2015)、第十届国际供暖通风及空调学术会议(ISHVAC2017)分会场主席、2018城乡能源与环境国际会议(UREE2018)学术委员会委员等

§ 担任多个土木与建筑环境领域国际期刊的审稿人:Building and Environment; Indoor Air; Energy and Buildings; Building Simulation; Sustainable Cities and Society; Indoor and Built Environment; Applied EnergyInternational Journal of Heat and Mass Transfer

主要学术论文:

§ Yang X., Wang H.*, Su C., Wang X., Wang Y. 2020. Heat transfer between occupied and unoccupied zone in large space building with floor-level side wall air-supply system. Building Simulation, 13(6): 1221-1233.

§ Wang H.*, Meng X., Chen J.*. 2020. Effect of air quality and dust deposition on power generation performance of photovoltaic module on building roof. Building Services Engineering Research and Technology, 41(1): 73-85.

§ 范雪妮, 王海东*, 胡毅冰. 2020. 基于粗网格CFD模拟方法的室内空气污染物实时寻源反计算研究. 流体机械, 07: 77-83.

§ Hu Y., Wang H.*, Cheng J., Wang E. 2019. Inverse tracking of an airborne pollutant source location in a residential apartment by joint simulation of CFD and a multizone model. Building Simulation, 12(4): 605-616.

§ Wang H.*, Zhou P., Guo C., Tang X., Xue Y. and Huang C. 2019. On the Calculation of Heat Migration in Thermally Stratified Environment of Large Space Building with Sidewall Nozzle Air-Supply. Building and Environment, 147: 221-230.

§ Wang H.*, Wang H., Gao F., Zhou P., Zhai Z.J.* 2018. Literature review on pressure-velocity decoupling algorithms applied to built-environment CFD simulation. Building and Environment, 143: 671-678.

§ Wang H., Huang C.*, Cui Y. and Zhang Y. 2018. Experimental study on the characteristics of secondary airflow device in a large enclosed space building. Energy and Buildings, 166: 347-357.

§ Wang H., Lu S., Cheng J. and Zhai Z.J. 2017. Inverse modeling of indoor instantaneous airborne contaminant source location with adjoint probability-based method under dynamic airflow field. Building and Environment. 117: 178-190. 

§ Wang H., Tang X. and Huang C. 2017. Investigating ventilation system performance in large space building: A nozzle primary air supply with secondary airflow-relay system. Science and Technology for the Built Environment. 23(2): 296-306.

§ Wang H. and Zhai Z.J. 2016. Advances in building simulation and computational techniques: A review between 1987 and 2014. Energy and Buildings. 128: 319-335.

§ Wang, H., Zhai Z.J. and Liu X. 2014. Feasibility of Utilizing Numerical Viscosity from Coarse Grid CFD for Fast Turbulence Modeling of Indoor Environments. Building Simulation. 7(2): 155-164 

§ Wang, H. and Zhai Z.J. 2012. Application of Coarse Grid CFD on Indoor Environment Modeling: Optimizing the Trade-off between Grid Resolution and Simulation Accuracy. HVAC&R Research. 18(5): 915-933.

§ Wang, H. and Zhai Z.J. 2012. Analyzing Grid-Independency and Numerical Viscosity of Computational Fluid Dynamics for Indoor Environment Applications. Building and Environment. 52: 107-118.

§ Wang, H., Zhai Z.J., Li Y. and Liu X. 2012. Identifying Index (Source) Patient Location of SARS Transmission in a Hospital Ward. HVAC&R Research. 18(4): 616-625.

§ Zhai Z.J. and Wang H. 2011. Optimizing the Trade-off between Grid Resolution and Simulation Accuracy: Coarse Grid CFD Modeling. Final Report of ASHRAE Research Project 1418.

§ Zhai Z.J., Liu X., Wang H., Li Y. and Liu J. 2012. Experimental Verification of Tracking Algorithm for Dynamically-Releasing Single Indoor Contaminant. Building Simulation. 5(1): 5-14.

§ Liu, J., Wang H. and Wen W. 2009. Numerical simulation on a horizontal airflow for airborne particles control in hospital operating room. Building and Environment. 44(11): 2284-2289.

§ Wang H.Zhai J.Z., Li Y. and Liu X. 2010. Identifying Sources of SARS Transmission in a Hospital Ward. IAQ2010. November 10-12, 2010. Kuala Lumpur, Malaysia.

§ 刘俊杰,王海东. 2008. 燃气辐射供暖房间的供暖负荷计算及能耗分析. 暖通空调39(2): 108-112.