彭晉卿

彭晉卿

彭晉卿,博士,教授,博士生導師,中國高被引學者,現任湖南大學土木工程學院黨委書記,曾任土木工程學院副院長。

基本介紹

  • 中文名:彭晉卿
  • 國籍中國
  • 民族:漢族
  • 畢業院校香港理工大學
  • 學位/學歷:博士
  • 專業方向:建築一體化太陽能綜合利用;光電建築;建築智慧能源系統等;
  • 職務:土木工程學院黨委書記
  • 主要成就:中國高被引學者, 2019年教育部科技進步二等獎
人物經歷,教育背景,工作履歷,學術兼職,研究領域,科研項目,主要貢獻,

人物經歷

教育背景

2011.02-2014.08,香港理工大學屋宇設備工程學系,獲哲學博士學位
2013.08-2013.11,美國勞倫斯伯克利國家實驗室,博士訪問研究
2007.09-2010.07,中國科學院研究生院製冷與低溫工程專業,獲碩士學位
2007.09-2008.07,中國科學技術大學熱科學與能源工程系,碩士專業課學習
2003.09-2007.06,南京師範大學建築環境與設備工程專業,獲學士學位

工作履歷

2022.02 - 至今,湖南大學土木工程學院黨委書記
2021.11-2022.02,湖南大學土木工程學院黨委副書記(主持工作)
2019.08-2021.11,湖南大學土木工程學院副院長
2017.04-至今,湖南大學土木工程學院教授、博士生導師
2017.09-2021.10,美國勞倫斯伯克利國家實驗室高級客座研究員
2015.10-2017.09,美國勞倫斯伯克利國家實驗室博士後研究員(Postdoctoral Research Fellow)
2014.08-2015.09,香港理工大學屋宇設備工程學系博士後研究員(Postdoctoral Research Fellow)
2014.02-2014.08,香港理工大學屋宇設備工程學系副研究員(Research Associate)
2010.08-2011.02,香港理工大學屋宇設備工程學系研究助理(Research Assistant)

學術兼職

[1] 能源領域國際著名期刊《Applied Energy》助理編輯,《Engineering》青年通訊專家,《Building Simulation》領域編輯,《Energy & Built Environment》編委,《Journal of Thermal Science》副主編
[2] SCI 雜誌《Applied Energy》,《Materials Today Energy》,《Building Simulation》,《Sustainability》,《Energies》和《Frontier》客座編輯
[3] 美國採暖、製冷與空調工程師學會(ASHRAE)會員
[4] 國際建築能效模擬委員會(IBPSA)會員
[5] 建築安全與節能教育部重點實驗室副主任
[6] 中國可再生能源學會太陽能建築專委會副主任
[7] 中國建築節能協會建築調試與運維專委會常務理事
[8]中國岩石力學與工程學會能源地下結構與工程專業委員會副主任
[9] 中國光伏行業協會光電建築專業委員會委員
[10] 全國暖通空調學會模擬委員會委員
[11] 全國暖通空調學會青年委員會委員

研究領域

主要從事太陽能建築一體化光伏發電,分散式能源存儲,建築能源需求側管理,建築智慧能源系統,先進窗戶和幕牆技術方面的研究工作。與海外著名研究機構,如美國勞倫斯伯克利國家實驗室、加州大學伯克利分校、香港理工大學、英國拉夫堡大學的研究人員建立了長期合作關係。

科研項目

主持的研究項目:
[1] 國家重點研發計畫“長江流域建築供暖空調解決方案和相應系統”課題五“間歇模式下集散式供暖空調系統構建與最佳化運行關鍵技術研發”(課題編號:2016YFC0700305)
[2]國家自然科學基金項目"真空複合型半透明光伏窗光電熱耦合作用機理及光熱性能調控研究"
[3] 國家自然科學基金項目“太陽光譜影響下通風型半透明光伏幕牆熱電耦合作用機理與實驗研究”
[4] 科技部高端外國專家引進計畫“零能耗建築與可再生能源高效利用”
[5] 湖南省高新技術產業科技創新引領計畫“高效節能真空型光伏幕牆關鍵技術研發與示範套用”
[6] 住房與城鄉建設部科學技術項目“基於分散式儲能與空調需求回響的零能耗建築關鍵技術研究與套用”
[7] 湖南省科技創新平台與人才計畫
[8] 長沙市傑出創新青年培養計畫
作為CO-I或主要完成人完成的科研項目:
[1] 美國能源部 R&D of advanced window technologies for energy saving
[2] 美國能源部 Windows core project—Most efficient ENERGY STAR windows
[3] 美國加州能源署(CEC)High-Performance, Integrated Window and Façade Solutions for California Buildings
[4] Development of novel high dispersed transparent heat insulation paints for glass. Hong Kong ITC supported.
[5] Investigation on the thermal and power performance of vacuum BIPV curtain wall technology and its application potential in buildings in Hong Kong. Hong Kong CIC supported.
[6] Guangdong-Hong Kong Technology Cooperation Funding Scheme (Research Platform) (ZP5N (GHP/040/08GD)) :Investigation and development of large-scale (MW) grid connected thin film photovoltaic power stationsintegrated with buildings
[7] ECF (Environment and Conservation) Project 9/2008: Environmental payback time analysis of building-integrated photovoltaic (BIPV) applications in Hong Kong
[8] Renewable energy application and energy conservation in public rental housing department in Hong Kong. HongKong HA supported.
[9] 2014/15 CUP Public Policy Research (PPR) (2013.A6.010.13A): Study on the Development Potential and EnergyIncentives of Rooftop Solar Photovoltaic Applications in Hong Kong
[10] Feasibility study on tri-generation of power, chilled water and hot water at Shatin sewage treatment works
[11] Thermal performance of the glass with coated transparent heat insulation paint (THIP) as building glazingfacade
[12] Testing and evaluation of indoor and outdoor environment for public housing in Hong Kong. Hong Kong HAsupported.
[13] 2010/12 PolyU FCLU Dean’s Award for Outstanding Achievement in Research Funding 2010 (1-ZV6Z): Overallenergy performance of building-integrated photovoltaic (BIPV) applications in Hong Kong.

主要貢獻

[1] S Li, J Peng*, Y Tan, T Ma, X Li, B Hao. Study of the application potential of photovoltaic direct-driven air conditioners in different climate zones. Energy and Buildings 2020;226: 110387. (SCI)
[2] Y Zhou, S Wang, J Peng, Y Tan, C Li, FYC Boey, Y Long. Liquid Thermo-Responsive Smart Window Derived from Hydrogel. Joule 2020; 4 (11): 2458-2474. (SCI)
[3] Y Tan, J Peng*, DC Curcija, R Hart, JC Jonsson, S Selkowitz. Parametric study of the impact of window attachments on air conditioning energy consumption. Solar Energy 2020; 202: 136-143. (SCI)
[4] J Peng, J Yan, Z Zhai, CN Markides, ES Lee, U Eicker, X Zhao, TE Kuhn, et al. Solar energy integration in buildings. Applied Energy 2020; 264. (SCI)
[5] Y Ke, Y Yin, Q Zhang, Y Tan, ..., J Peng, et al. Adaptive Thermochromic Windows from Active Plasmonic Elastomers. Joule 2019; 3 (3): 858-871. (SCI)
[6] J Peng. Simulation studies on advanced window technologies. Building Simulation 2019; 12 (1): 1-1. (SCI)
[7] J Peng, DC Curcija, A Thanachareonkit, ES Lee, H Goudey, SE Selkowitz. Study on the overall energy performance of a novel c-Si based semitransparent solar photovoltaic window. Applied Energy 2019; 242: 854-872. (SCI)
[8] J Peng, L Lu, M Wang. A new model to evaluate solar spectrum impacts on the short circuit current of solar photovoltaic modules. Energy 2019; 169: 29-37. (SCI)
[9] N Skandalos, D Karamanis, J Peng, H Yang. Overall energy assessment and integration optimization process of semitransparent PV glazing technologies. Progress in Photovoltaics: Research and Applications 2018; 26 (7): 473-490. (SCI)
[10] X Li, J Peng*, N Li, Y Wu, Y Fang, T Li, M Wang, C Wang. Optimal design of photovoltaic shading systems for multi-story buildings. Journal of Cleaner Production 2019; 220: 1024-1038. (SCI)
[11] Meng Wang, Jinqing Peng*, Nianping Li, Hongxing Yang, Chunlei Wang, Xue Li, Tao Lu. Comparison of energyperformance between PV double skin facades and PV insulating glass units. Applied Energy 2017; 194:148-160.(SCI)
[12] Jinqing Peng, Dragan C. Curcija, Lin Lu, Stephen E. Selkowitz, Hongxing Yang, Weilong Zhang. Numericalinvestigation of the energy saving potential of a semi-transparent photovoltaic double-skin facade in acool-summer Mediterranean climate. Applied energy 2016; 165: 345-356. (SCI)
[13] Meng Wang, Jinqing Peng*, Nianping Li, Lin Lu, Tao Ma, Hongxing Yang. Assessment of energy performance ofsemi-transparent PV insulating glass units using a validated simulation model. Energy 2016; 112:538-548.(SCI)
[14] Jinqing Peng, Dragan C. Curcija, Lin Lu, Stephen E. Selkowitz, Robin Mitchell. Developing a method andsimulation model for evaluating the overall energy performance of a ventilated semi-transparentphotovoltaic double-skin façade. Prog. Photovolt: Res. Appl. (2015). (SCI)
[15] Jinqing Peng, Lin Lu, Hongxing Yang, Tao Ma. Comparative study of the thermal and power performances of asemi-transparent photovoltaic façade under different ventilation modes. Applied Energy 2015; 138: 572-583.(SCI)
[16] Jinqing Peng, Lin Lu, Hongxing Yang, Tao Ma. Validation of the Sandia model with indoor and outdoormeasurement for semi-transparent amorphous silicon PV module. Renewable Energy 2015; 80: 316-323. (SCI)
[17] Jinqing Peng, Lin Lu, Hongxing Yang, Jun Han. Investigation on the annual thermal performance of aphotovoltaic wall mounted on a multi-layer façade. Applied Energy 2013;112:646-656. (SCI)
[18] Jinqing Peng, Lin Lu, Hongxing Yang. Review on life cycle assessment of energy payback and greenhouse gasemission of solar photovoltaic systems. Renewable and Sustainable Energy Reviews 2013; 19: 255-274. (SCI)
[19] Jinqing Peng, Lin Lu, Hongxing Yang. Investigation on the development potential of rooftop PV system inHong Kong and its environmental benefits. Renewable and Sustainable Energy Reviews 2013;27:149-162. (SCI)
[20] Jinqing Peng, Lin Lu, Hongxing Yang. An experimental study of the thermal performance of a novelphotovoltaic double-skin facade in Hong Kong. Solar Energy 2013; 97:293-304. (SCI)
[21] Jinqing Peng, Lin Lu, Hongxing Yang, KM Ho, Peter Law. Experimentally diagnosing the shading impact on thepower performance of a PV system in Hong Kong. World Congress on Sustainable Technologies (WCST), IEEEXplore, London, England, Date: DEC 09-12, 2013, Pages: 18-22. (SCI)
[22] Jinqing Peng, Yu Wu, Huajun Liu,et al. The Cryogenic System for ITER CC Superconducting Conductor TestFacility. Cryogenics 2011; 51(1):62-67. (SCI)
[23] K Wang, N Li, J Peng, X Wang, C Wang, M Wang. A highly efficient solution for thermal compensation ofground-coupled heat pump systems and waste heat recovery of kitchen exhaust air. Energy and Buildings2017; 138: 499-513. (SCI)
[24] K Wang, N Li, J Peng, Y He. Study on the Optimizing Operation of Exhaust Air Heat Recovery and SolarEnergy Combined Thermal Compensation System for Ground-Coupled Heat Pump. International Journal ofPhotoenergy 2017. (SCI)
[25] H Cui, N Li, X Wang, J Peng, Y Li, Z Wu. Optimization of reversibly used cooling tower with downwardspraying. Energy 2017; 127: 30-43. (SCI)
[26] X Wei, N Li, J Peng, J Cheng, J Hu, M Wang. Performance analyses of counter-flow closed wet cooling towersbased on a simplified calculation method. Energies 2017; 10 (3):282. (SCI)
[27] Xiaoqing Wei, Nianping Li, Jinqing Peng, Jianlin Cheng, Jinhua Hu and Meng Wang. Modeling and optimizationof a cooling tower-assisted heat pump system. Energies 2017. (SCI)
[28] Li Xue, Peng Jinqing*, Li Nianping, Wang Meng, Wang Chunlei. Study on the comprehensive energy efficiencyof different shading systems in hot summer and cold winter area. Building Science 2017. (In Chinese)
[29] Haijiao Cui, Nianping Li, Jinqing Peng, Jianlin Cheng, Shengbing Li. Study on the dynamic and thermalperformances of a reversibly used cooling tower with upward spraying. Energy 2016; 96: 268–277. (SCI)
[30] Haijiao Cui, Nianping Li, Jinqing Peng, Jianlin Cheng, Nan Zhang, Zhibin Wu. Modelling the particlescavenging and thermal efficiencies of a heat absorbing scrubber. Building and Environmental 2016;111:218-227. (SCI)

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