吴治永
  • 姓名: 吴治永
  • 性别: 男
  • 职称: 副研究员
  • 职务: 
  • 学历: 博士
  • 电话: (86)18612200882
  • 传真: 
  • 电子邮件: wuzhiyongspecial@gmail.com
  • 所属部门: 太阳能热利用技术研究部
  • 通讯地址: 

    简  历:

  • 2016/12-今,副研究员,全职,中国科学院电工研究所,北京, 中国

    2010/7-2016/12,助理研究员,全职,中国科学院电工研究所,北京, 中国

    2006/2-2007/3,售后服务经理,全职,ESI集团 (北京), 中国

    2003/8-2006/2,高级工程师 (涉及软件有CFX, CFD-ACE, CFD-FASTRAN 和iSIGHT等), 全职,ATE technology(北京) 有限公司,中国北京

    1998/8-2001/9,助理工程师,全职,中国航空动力机械研究所(608研究所),湖南株洲

    社会任职:

    研究方向:

    承担科研项目情况:

  • 1.功能梯度容积式太阳能吸热器内耦合传热理论研究,国家自然科学基金,2017.01-2020.12,60万,负责人

    2.紧凑型符合建筑储热蓄冷技术研究,科技部,2020.1-2021.12,93万,项目骨干

    3.全船水幕降温效果数值仿真分析,中国人民解放军92942部队,2020.1-2020.12,28.8万,负责人

    4.规模化热能存储与转换调控系统构建,国家自然科学基金,2023.1-2027.12,300万,项目骨干

    5.太阳能热发电流化床固体颗粒/sCO2换热器气-固传热特性与强化机理研究,北京市自然基金,2022.1-2024.12,8万,参与人

    6.某蝶阀性能数值模拟分析,企业课题,2022.1-2023.6,10万,负责人

    代表论著:

  • [1] J. Wu, N. Li, Z. Wu, Experimental investigation of latent energy storage systems with the tree-pin-shaped fin, Applied Thermal Engineering 227 (2023).

    [2] J. Wu, Z. Wu, Experimental comparison of latent thermal energy storage units with different metal macro-additives, Applied Thermal Engineering 216 (2022).

    [3] Z. Wu, S. Xu, L. Yang, Z. Wang, Numerical investigation of single-blow transient testing technique, International Communications in Heat and Mass Transfer 120 (2021).

    [4] R. Wang, A. Hou, Z. Wu, Tomography-based investigation of flow and heat transfer inside reticulated porous ceramics, Applied Thermal Engineering 184 (2021).

    [5] S. Xu, Z. Wu, H. Lu, L. Yang, Experimental study of the convective heat transfer and local thermal equilibrium in ceramic foam, Processes 8(11) (2020) 1-20.

    [6] Z. Wang, J. Wu, D. Lei, H. Liu, J. Li, Z. Wu, Experimental study on latent thermal energy storage system with gradient porosity copper foam for mid-temperature solar energy application, Applied Energy 261 (2020).

    [7] H. Lu, L. Yang, Z. Wu, S. Xu, Numerical and experimental study on convective heat transfer characteristics in foam materials, Energies 13(2) (2020).

    [8] S.Y. Ding, P.F. He, G.Z. Ma, Z.Y. Wu, L. Tang, S.Y. Chen, Z.G. Xing, H.D. Wang, B.S. Xu, Investigation on the removal of suspended particles during internal rotating plasma spraying using numerical and experimental methods, Surface and Coatings Technology 393 (2020).

    [9] S. Zhang, Z. Wang, Z. Wu, F. Bai, P. Huang, Numerical investigation of the heat transport in a very loose packed granular bed air receiver with a non-uniform energy flux distribution, Renewable Energy 138 (2019) 987-998.

    [10] S.Y. Ding, P.F. He, G.Z. Ma, S.Y. Chen, H.D. Wang, Z.Y. Wu, L. Tang, X. Chen, B.S. Xu, Numerical Simulation and Experimental Study of Heat Accumulation in Cylinder Parts During Internal Rotating Plasma Spraying, Journal of Thermal Spray Technology 28(7) (2019) 1636-1650.

    [11] S. Ding, G. Ma, F. Ding, H. Wang, Z. Wu, B. Xu, Numerical Simulation on Temperature Distribution of Substrate During Plasma Spraying, Zhongguo Biaomian Gongcheng/China Surface Engineering 32(2) (2019) 98-108.

    [12] S. Li, Z. Wu, The numerical analysis of a large diameter spherical valve, Progress in Computational Fluid Dynamics 18(5) (2018) 300-307.

    [13] C. Chang, A. Sciacovelli, Z. Wu, X. Li, Y. Li, M. Zhao, J. Deng, Z. Wang, Y. Ding, Enhanced heat transfer in a parabolic trough solar receiver by inserting rods and using molten salt as heat transfer fluid, Applied Energy 220 (2018) 337-350.

    [14] Z.S. Akhatov, S.Z. Mirzaev, Z. Wu, S.S. Telyaev, E.T. Zhuraev, T.I. Zhuraev, Research on Thermophysical Properties of Nanoliquids Based on SiO2 Nanoparticles for Use as a Heat-Transfer Medium in Solar-Thermal Converters, Applied Solar Energy (English translation of Geliotekhnika) 54(1) (2018) 50-60.

    [15] C. Chang, Z. Wu, H. Navarro, C. Li, G. Leng, X. Li, M. Yang, Z. Wang, Y. Ding, Comparative study of the transient natural convection in an underground water pit thermal storage, Applied Energy 208 (2017) 1162-1173.

    [16] C. Chang, C. Xu, Z.Y. Wu, X. Li, Q.Q. Zhang, Z.F. Wang, Heat Transfer Enhancement and Performance of Solar Thermal Absorber Tubes with Circumferentially Non-uniform Heat Flux, Energy Procedia, 2015, pp. 320-327.

    [17] Z. Wu, S. Li, G. Yuan, D. Lei, Z. Wang, Three-dimensional numerical study of heat transfer characteristics of parabolic trough receiver, Applied Energy 113 (2014) 902-911.

    [18] Z. Wu, D. Lei, G. Yuan, J. Shao, Y. Zhang, Z. Wang, Structural reliability analysis of parabolic trough receivers, Applied Energy 123 (2014) 232-241.

    [19] Z. Wu, A. Hou, C. Chang, X. Huang, D. Shi, Z. Wang, Environmental impacts of large-scale CSP plants in northwestern China, Environmental Science: Processes and Impacts 16(10) (2014) 2432-2441.

    [20] Z. Wu, Z. Wang, Fully coupled transient modeling of ceramic foam volumetric solar air receiver, Solar Energy 89 (2013) 122-133.

    [21] B. Gong, Z. Wang, Z. Li, C. Zang, Z. Wu, Fluctuating wind pressure characteristics of heliostats, Renewable Energy 50 (2013) 307-316.

    [22] Z. Wu, C. Caliot, G. Flamant, Z. Wang, Numerical simulation of convective heat transfer between air flow and ceramic foams to optimise volumetric solar air receiver performances, International Journal of Heat and Mass Transfer 54(7-8) (2011) 1527-1537.

    [23] Z. Wu, C. Caliot, G. Flamant, Z. Wang, Coupled radiation and flow modeling in ceramic foam volumetric solar air receivers, Solar Energy 85(9) (2011) 2374-2385.

    [24] Z. Wu, B. Gong, Z. Wang, Z. Li, C. Zang, An experimental and numerical study of the gap effect on wind load on heliostat, Renewable Energy 35(4) (2010) 797-806.

    [25] Z. Wu, C. Caliot, F. Bai, G. Flamant, Z. Wang, J. Zhang, C. Tian, Experimental and numerical studies of the pressure drop in ceramic foams for volumetric solar receiver applications, Applied Energy 87(2) (2010) 504-513.

    [26] Z.Y. Wu, Y.Z. Lin, G.E. Liu, C. Zhang, Q.H. Xu, Dome structure modification of a high temperature rise combustor based on CFD simulation, Tuijin Jishu/Journal of Propulsion Technology 30(5) (2009) 533-537.

    [27] Z. Wu, Z. Wang, Numerical study of wind load on heliostat, Progress in Computational Fluid Dynamics 8(7-8) (2008) 503-509.

    [28] Z. Wang, Z. Wu, X. Liu, Z. Li, Wind dynamics testing on dahan heliostat, ISES Solar World Congress 2007, ISES 2007, 2007, pp. 1934-1938.

    [29] Y. Lin, B. Song, B. Li, G. Liu, Z. Wu, Investigation of film cooling effectiveness of full-coverage inclined multihole walls with different hole arrangements, American Society of Mechanical Engineers, International Gas Turbine Institute, Turbo Expo (Publication) IGTI, 2003, pp. 651-660.

    专利申请:

    获奖及荣誉:

  • 1.建筑“呼吸式”高效智能新风系统,“国科大杯”创新创业大赛,二等奖 中国科学院大学,2020年10月

    2.建筑“呼吸式”高效智能新风系统,第一届全国碳中和博士生论坛,“创新创业分会场 (种子组)”,获评优秀报告。 清华大学碳中和研究院、中国学位与研究生教育学会,2022年12月