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叶蔚,副教授,博士生导师,同济大学建筑与城市规划学院院长协理。兼任中国环境学会室内环境与健康分会青委会副主任委员、全国暖通空调学会通风专委会委员、中国核工业勘察设计协会核能综合利用专业委员会委员、中国建筑节能协会光储直柔专业委员会委员,以及Building Simulation、《绿色建筑》等期刊青年编委,Indoor and Built Environment、International Journal ofVentilation等期刊客座编辑。曾在美国弗吉尼亚理工学院(Virginia Tech)、挪威科技大学(NTNU)及瑞士洛桑联邦理工学院(EPFL)开展联合培养、访问博士后及访问学者研究,另与来自德国、加拿大、丹麦、新加坡的国际知名学者长期开展国际合作。
围绕精密与特殊环境的营造与控制问题,系统开展空调风水输配系统协同调控机理与方法、复杂空间气流组织与污染传播规律、室内环境自动化设计与智能控制方法,以及精密环境高效营造与控制方法等方面的研究,形成了面向高端制造与大科学装置的环境营造技术体系。
主持国家自然科学基金及省部级科研项目多项,出版或参编专著5部,发表学术论文150余篇,其中SCI/EI收录近90篇,授权发明专利及软件著作权多项,参编国家及行业标准8项。相关成果获上海市科技进步二等奖、环境技术进步奖一等奖、黄河水利委员会科学技术奖一等奖等省部级与行业奖励,并获评第三届“暖通空调杰出青年”等荣誉。
[1] 上海市2023年度“科技创新行动计划”自然科学基金项目: 面向大科学装置中高大、狭长空间超高精密恒温环境的营造方法. 项目批准号: 23ZR1468400. 2023.04-2026.03.
[2] 国家自然科学基金面上项目: 快速适配大空间环境营造需求的模块化诱导通风系统设计方法. 项目批准号: 51878463, 2019.01-2022.12.
[3] “十三五”国家重点研发计划专项“建筑室内空气质量控制的基础理论和关键技术研究”子任务: 污染源散发控制及空气质量设计技术研究. 所属子课题编号: 2017YFC0702706-05, 2017.07-2020.12, 结题.
[4] “十三五”国家重点研发计划专项“近零能耗建筑技术体系及关键技术开发”子任务: 近零能耗建筑新风需求形成机理研究. 所属子课题编号: 2017YFC0702601-07, 2017.07-2020.12.
[5] 国家自然科学基金青年基金: 基于臭氧对建材挥发性有机物作用的人居环境新风量快速计算方法. 项目批准号: 21507102, 2016.01-2018.12.
[6] 挪威研究理事会(The Research Council of Norway)资助国际交流项目: Specialist exchange with China (INT-BILAT) project: Ventilation and Airflow Pattern Effects on VOC Distributions in Indoor Environment. Project number: 249136/H30. Cooperator: Prof. Guangyu Cao, 2016.01-2016.02.
[7] 中国博士后科学基金第10批特别资助: 近零能耗建筑新风需求分级控制理论及人行为应对机制. 项目批准号: 2017T100310, 2017.07-2018.06.
[8] 中国博士后基金面上资助(一等): 室内臭氧作用下建材VOC散发估计和新风量快速计算法. 项目批准号: 2015M570386, 2015.06-2016.12.
[9] 横向项目集中在机场、船舶、大科学装置、核电、隧道领域.
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支持扩展名:.rar .zip .doc .docx .pdf .jpg .png .jpeg[1] 空调风水输配系统协同调控机理与方法
[2] 复杂空间气流组织与空气品质调控方法
[3] 室内环境自动化设计与智能控制方法
[4] 精密与特殊环境高效营造与控制方法
[1] 中国环境学会室内环境与健康分会青年委员会,副主任委员
[2] 暖通空调产业技术创新联盟-工业安全与除尘工作委员会,委员
[3] 中国核工业勘察设计协会核能综合利用专业委员会,委员
[4] 中国建筑节能协会光储直柔专业委员会,委员
[5] 中国建筑学会暖通空调分会-通风专业委员会,委员
[6] 暖通空调产业技术创新联盟-通风专业委员会,委员
[7] 国际室内空气品质通风与建筑节能学会(IAQVEC),会员
[8] 国际室内空气质量与气候学会(ISIAQ),会员
[1] CAU3574 供热工程(本科生)
[2] CAU3573 通风工程(本科生)
[3] CAU3577 暖通空调I(本科生)
[4] CAU3576 暖通空调II(本科生)
[5] CAU4576 通风技术中的气流组织(本科生)
[6] CAU4572 从建材散发到健康建筑(本科生)
[7] CME6403 工业设施环境营造与控制(硕士生)
[8] CME6037 室内空气品质及污染物控制(硕士生)
[9] CME8016 建筑热质传输理论及应用(博士生)
l 空调风、水输配系统调控代表性论文
[1] Li, Yiqun; Liu, Mingq; Du, Bowen; Ye, Wei*;Zhang, Xu. Integratingportable air cleaners to reduce mechanical ventilation energy under CO2-basedcontrol: Twin-chamber experiments and multi-city analysis of energy–IAQtrade-offs, Energy and Built Environment. 2026; Online. (https://doi.org/10.1016/j.enbenv.2026.02.001)
[2] Guo, Weichen; Zeng, Jiexiao; Lin, Chengye; Shen,Liecheng; Ye, Wei*;Gao, Jun. A single-degree-of-freedomcoordinated control strategy for distributed variable-speed pumping systems:Integrating hydraulic balance and demand response for enhanced energyefficiency. Energy. 2026; 344: 140045. (https://doi.org/10.1016/j.energy.2026.140045)
[3] Guo, Weichen; Zeng, Jiexiao; Lin, Chengye; Zhu, Xuejin; Zhu, Zhe; Ye, Wei*, Gao, Jun. Integrating thedistribution of chilled water and supply air for energy-efficient cleanrooms inhigh-tech industries: A demand-responsive approach. Energy. 2025;338: 138770. (https://doi.org/10.1016/j.energy.2025.138770)
[4] Li, Yiqun; Liu, Mingqi; Xu, Bin; Ye, Wei*. Rethinking buildingventilation and outdoor airflow rate - Can we engineer clean indoor air? Renewableand Sustainable Energy Reviews. 2025; 215: 115571. (https://doi.org/10.1016/j.rser.2025.115571)
[5] Ye, Wei*;Wei, Yuan; Guo, Weichen; He, Ling; Zhu, Xuejin; Zhu, Zhe; Gao, Jun. Practical methods forconstant temperature control in tunnel-shaped scientific facilities: Uniformvs. pressure-driven air supply with insights from SHINE. BuildingSimulation. 2025; 18(9): 2381-2403. (https://doi.org/10.1007/s12273-025-1318-7).
[6] Guo, Weichen; Hong, Yusong; Wei, Yuan; Zhu, Xuejin; Zhu, Zhe; Ye, Wei*. Stabilizing chilled watertemperature for constant temperature air conditioning: A unified stepperturbation transfer model for widening end control margins with two-stagecontrol. Energy and Buildings.2025; 330: 115367. (https://doi.org/10.1016/j.enbuild.2025.115367)
[7] Li, Yiqun; Fan, Yujie; Wei, Yuan; Liu, Mingqi;Xu, Bin; Ye, Wei*. Can portable air cleanersreconcile conflicting needs for open-door/window autonomy and indoor airquality for occupants in densely populated offices? Applied Energy.2024; 358: 122548. (https://doi.org/10.1016/j.apenergy.2023.122548)
[8] Guo, Weichen; Wang, Zeng; Hong, Yusong; Chen, Difei; Zhu, Xuejin; Zhu,Zhe; Ye, Wei*; Zhang, Xu. Frequency-domain analysisof two controllable attenuators for thermal control processes and perturbationsin an ultra-high-precision constant temperature chilled-water system. AppliedThermal Engineering. 2024; 252: 123663. (https://doi.org/10.1016/j.applthermaleng.2024.123663)
[9] Guo, Weichen; Wang, Zeng; Hong, Yusong; Chen, Difei; Zhu, Xuejin; Zhu,Zhe; Ye, Wei*; Zhang, Xu. Comparingtemperature fluctuation attenuation capabilities and feasible parameter regionsof indirect- and direct-contact heat exchangers for an ultra-high precisionconstant-temperature chilled water system: An experimental and Modelica-basedstudy. Applied Thermal Engineering. 2024; 241: 122379. (https://doi.org/10.1016/j.applthermaleng.2024.122379)
[10] Li, Yiqun; Fan, Yujie; Zhi, Chengqiang; Ye, Wei*; Zhang, Xu.Multi-objective optimization of mechanical ventilation with the aid ofpurifiers in two scenarios: regular operation and mitigating the spread ofrespiratory infectious diseases. Building Simulation. 2023;16(5): 795-811. (https://doi.org/10.1007/s12273-023-0999-z).
l 复杂空间通风与空气品质代表性论文
[1] Tang, Wenhao; Li, Yiqun; Wang, Yuanchen; Ye, Wei*. A comprehensive approach to modeling aerosolemissions from electric toothbrushes and evaluating transmission risks inpublic restrooms. Building andEnvironment. 2025; 269: 112435. (https://doi.org/10.1016/j.buildenv.2024.112435)
[2] Chen, Difei; Liu, Mingqi; Guo, Weichen; Li,Yiqun; Xu, Bin; Ye, Wei*. Energy-efficient operationof portable air cleaners based on real-time prediction of non-uniformconcentrations of indoor air pollutants in open offices. Building and Environment. 2024; 256: 111478. (https://doi.org/10.1016/j.buildenv.2024.111478)
[3] Tang, Wenhao; Li, Yiqun; Du, Bowen; Ye, Wei*. Investigating toothbrushing behavior and its aerosolemissions from using electric toothbrushes. Buildingand Environment. 2023; 242: 110594. (https://doi.org/10.1016/j.buildenv.2023.110594)
[4] Tang, Shengyi; Zhi, Chengqiang; Fan, Yujie; Ye, Wei*; Su, Xing;Zhang, Xu. Unhealthy indoor humidity levels associated with ventilation rateregulations for high-performance buildings in China. Building and Environment. 2020; 177: 106839. (https://doi.org/10.1016/j.buildenv.2020.106839)
[5] Ye, Wei; Zhang, Xu*; Gao, Jun; Cao, Guangyu; Zhou, Xiang;Su, Xing. Indoor air pollutants, ventilation rate determinants and potentialcontrol strategies in Chinese dwellings: A literature review. Science of the Total Environment.2017; 586: 696-729. (http://doi.org/10.1016/j.scitotenv.2017.02.047)
[6] Ye, Wei*; Won, Doyun; Zhang, Xu; Examining theapplicability of empirical models using short-term VOC emissions data frombuilding materials to predict long-term emissions. Building Simulation. 2016; 9(6): 701-715. (http://doi.org/10.1007/s12273-016-0302-7)
[7] Ye, Wei*; Won, Doyun; Zhang, Xu; Practical approaches todetermine ventilation rate for offices while considering physical and chemicalvariables of building material emissions. Buildingand Environment. 2014; 82: 490-501. (http://doi.org/10.1016/j.buildenv.2014.09.017)
[8] Ye, Wei; Cox, Steven S.; Zhao, Xiaomin; Frazier, CharlesE.; Little, John C.*; Partially- irreversible sorption offormaldehyde in five polymers. AtmosphericEnvironment. 2014; 99: 288-297. (http://doi.org/10.1016/j.atmosenv.2014.09.078)
[9] Ye, Wei*; Won, Doyun; Zhang, Xu; A preliminary ventilationrate determination methods study for residential buildings and offices based onVOC emission database. Building andEnvironment. 2014; 79: 168-180.(http://doi.org/10.1016/j.buildenv.2014.05.009)
[10] Ye, Wei*; Little, John C.; Won, Doyun; Zhang, Xu;Screening-level estimates of indoor exposure to volatile organic compoundsemitted from building materials. Buildingand Environment. 2014; 75: 58-66.(http://doi.org/10.1016/j.buildenv.2014.01.018)
l 精密与特殊环境营造控制代表性论文
[1] Ye, Wei*; Hong, Yusong; Fang,Tiancheng; Guo, Weichen; Huo, Huanjie; Zhang, Xu; Locatinga moving heat source in a confined space using Gaussian process regression:Dynamic simulations and experimental validation. Building and Environment. 2026; 287, Part B: 113909. (https://doi.org/10.1016/j.buildenv.2025.113909)
[2] Li,Xiuming; Liu, Haoxue; Liu, Siqi; Zhang, Haiyang; Han, Zongwei*; Gao, Bo*; Zhang, Lun*; Ye,Wei*. Building environment control for advancedprecision instruments - State-of-the-art and future perspectives, CleanEnergy Science and Technology. 2025; 3(4): 460. (https://doi.org/10.18686/cest460)
[3] Wu, Chao; Zhi, Chengqiang; Ye, Wei*; Zhang, Xu*.Scale modeling study of airflow distribution uniformity in large spaces withhigh heat flux panel. Applied Thermal Engineering. 2022; 205:118027. (https://doi.org/10.1016/j.applthermaleng.2021.118027)
[4] Ye, Wei*; Cai, Jian; Huang,Yixiang; Zhi, Chengqiang; Zhang, Xu. Retrospective analysis of a multi-stageexperiment on developing high-performance insulation panels to sustain jetimpingement at high temperatures. Constructionand Building Materials. 2021; 277: 122254. (https://doi.org/10.1016/j.conbuildmat.2021.122254)
[5] Ye, Wei*; Cai, Jian; Huang,Yixiang; Zhi, Chengqiang; Zhang, Xu. Experimental assessment of thermalperformance and bridging effects of low-cost sandwich panels under ahigh-temperature impinging jet. Materials.2020; 13(16): 3620. (https://doi.org/10.3390/ma13163620)
[6] Zhao,Wenxuan; Ye, Wei*; Xue, Yu; Wu, Chao; Zhang, Xu; Ventilationschemes for high-temperature buoyancy-driven plumes from spherical surfaces ofa large-scale experimental facility. Energyand Built Environment. 2020; 1(3): 262-277. (EI: 20223712743765, https://doi.org/10.1016/j.enbenv.2020.02.005)
[7] Ye, Wei*; Zhang, Qianru; Xie, Yuliang; Cai, Jian; Zhang,Xu. Spray cooling for high temperature of exhaust gas using a nozzle array in aconfined space: Analytical and empirical predictions on cooling capacity. Applied Thermal Engineering.2017; 127: 889-900. (http://doi.org/10.1016/j.applthermaleng.2017.08.097)
[8] 郭炜辰, 洪钰淞, 王增, 朱学锦, 朱喆, 叶蔚*. 基于快速傅里叶变换的某超高精密级恒温空调水系统运行波动与扰量特性研究. 建筑科学. 2025, 41(6): 182-189. (https://link.cnki.net/doi/10.13614/j.cnki.11-1962/tu.2025.06.20)
[9] 郭炜辰, 王增, 朱学锦, 朱喆, 叶蔚*, 张旭. 板式换热器和混水泵用于超高精密级恒温空调水系统的适用性对比研究. 制冷学报. 2024, 45(6): 57-62+144. (https://link.cnki.net/doi/10.12465/j.issn.0253-4339.2024.06.057)
[10] 何玲, 霍镜涛, 朱学锦, 朱喆, 叶蔚*, 张旭. 地下近邻平行精密恒温隧道间传热的模拟研究. 暖通空调. 2023, 53(12): 143-148.(https://link.cnki.net/doi/10.19991/j.hvac1971.2023.12.21)
详见以下网页:
课题组主页 https://zhangxu.tongji.edu.cn/af/34/c5914a110388/page.htm
Google scholar http://scholar.google.com/citations?hl=en&user=I73SyVQAAAAJ
ResearchGate https://www.researchgate.net/profile/Wei_Ye8
同济大学机构知识库 http://ir.tongji.edu.cn/Scholar/ScholarCard/43708
l 专著
[1] Ye, Wei; PanYiqun; He, Lianjie; Chen, Bingqian; Liu, Junjie*; Gao, Jun*;Wang, Yi; and Yang Yang. Chapter 3. Design with modeling techniques. In:Industrial Ventilation Design Guidebook Volume 2 (2nd Edition), Edited byGoodfellow, Howard D.; and Wang, Yi. United Kingdom: Academic Press, 2021.(ISBN: 978-0-12-816673-4)
[2] Zhang, Xu*; Ye,Wei. Subchapter 8.10. Urban road tunnels. In: Industrial VentilationDesign Guidebook Volume 2 (2nd Edition), Edited by Goodfellow, Howard D.; andWang, Yi. United Kingdom: Academic Press, 2021. (ISBN: 978-0-12-816673-4)
[3] 中国环境科学学会室内环境与健康分会组织编写. 钱华 主编, 刘志坚, 叶蔚, 郑晓红 副主编. 中国室内环境与健康研究进展报告2018-2019. 北京: 中国建筑工业出版社, 2020.04 (ISBN: 978-7-112-24645-8, CIP: 2020013271)
[4] 王军 主编, 叶蔚, 邵晓亮, 高然 副主编. 室内通风与净化技术. 北京: 中国建筑工业出版社, 2020.02. (ISBN: 978-7-112-24705-9, CIP: 2020011069)
[5] 张旭, 叶蔚, 徐琳 编著. 丛书名: 地下城市空间出版工程·运营与维护管理系列. 书名: 城市地下空间通风与环境控制技术. 上海: 同济大学出版社, 2018.12. (ISBN 978-7-5608-8339-7, CIP: 2018298283)
[6] 叶蔚, 张旭 著. 丛书名: 同济博士论丛. 书名: 新风对室内建材污染物控制的基础研究. 上海: 同济大学出版社, 2017.08. (ISBN: 978-7-5608-7002-1, CIP: 2017093843)
[1] 2025.12: “冷暖思秩、智绿未来”上海冷冻空调行业协会成立四十周年“科技创新者”, 颁发机构: 上海冷冻空调行业协会.
[2] 2023.11: 第三届“暖通空调杰出青年”, 颁发机构:《暖通空调》杂志社.
[3] 2023.11: 2023年黄河水利委员会科学技术奖一等奖, 项目名称: 深埋地下超大空间通风与环境控制关键技术及应用. 排名6/15. 颁发机构: 水利部黄河水利委员会.
[4] 2023.04: 2022年度上海市科技进步奖二等奖, 项目名称: 建筑室内空气污染控制关键技术研究及规模化应用, 排名3/10. 颁发机构: 上海市科学技术奖励管理办公室.
[5] 2023.02: 2022年度环境技术进步奖一等奖, 项目名称: 典型室内空气污染防控关键技术研究及规模化应用, 排名9/15. 颁发机构: 中国环境保护产业协会.
[6] 2021.08: 河南省优秀工程咨询成果一等奖, 项目名称: 江门中微子实验站配套基建工程通风空调系统优化设计, 排名4/10. 颁发机构: 河南省工程咨询协会.
[7] 2019.07: 河南省水利创新成果奖一等奖, 项目名称: 中科院江门中微子实验站深埋地下式超大空间洞室通风空调系统关键技术研究, 排名: 5/15. 颁发机构: 河南省水利学会.
[8] 2019.01: 2018年度708所优秀科研生产外协供方单位, 获奖单位: 同济大学, 颁发机构: 中国船舶工业集团公司第七〇八研究所. (基于课题组完成的项目)
[9] 2018.12: 2018年中国产学研合作创新成果二等奖, 项目名称: 间歇性散发多污染源精细化收集系统及装备的研究与应用, 排名: 5/10. 颁发机构: 中国产学研合作促进会.
[10] 2015.11: 同济大学优秀博士学位论文, 颁发机构: 同济大学.
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