姜玉雁

姜玉雁,中國科學院工程熱物理研究所研究員,博士生導師,中國科學院大學崗位教授。

基本介紹

  • 中文名:姜玉雁
  • 國籍:中國
  • 出生日期:1972年
  • 畢業院校東京大學
  • 教育經歷
2002,東京大學機械工程系,工學博士
1999,清華大學熱能工程系,工學碩士
1996,西安交通大學能動學院,工學學士
  • 工作經歷
2012-現在,中國科學院工程熱物理研究所研究員、博導,新工質發電團隊負責人
2011-2012,CD-adapco公司(Siemens PLM Software公司),高級軟體工程師
2008-2011,日本豐田中央研究所,客員研究員
2005-2008,日本AdvanceSoft株式會社,主任研究員
2002-2005,東京大學生產技術研究所,產學官研究員
  • 研究領域
  • 超臨界二氧化碳透平發電技術
  • 相變傳熱和微尺度傳熱
  • 熱流體數值計算
  • 科研項目
  • 微尺度流動沸騰的不穩定性形成機理與非穩態液膜相變動力學,國家自然科學基金面上項目,No.51376179,2013,負責人
  • 燃氣輪機高溫透平葉片研製與驗證,中科院重點部署項目,2015,課題負責人
  • 燃煤發電系統能源高效清潔利用的基礎研究,國家973項目,No.2015CB201503,2015,子課題負責人
  • 聚光光伏與餘熱利用溫濕度調節系統研究,國家重點研發計畫國際合作重點項目,No.2016YFE0118100,負責人
  • 超臨界二氧化碳透平發電關鍵技術研究,中科院先導A類專項課題,負責人
  • 學術成果
主要從事傳熱、節能技術和新能源發電技術領域的科學研究和技術套用,是大型通用流體仿真軟體FrontFlow/Red的主要開發者之一,該軟體在透平機械、化工、汽車和航空等領域獲得廣泛套用;開發的用於流體機械振動噪聲分析的大規模模擬系統,率先實現了對透平機械噪聲的定量預測,已被流體機械行業廣泛採用;在國際上率先提出智慧型型表面強化相變傳熱的概念,為相變換熱強化和調控提供了新思路;開展新型熱壓轉換傳熱技術研究,在高溫熱防護、餘熱利用和熱管理領域獲得產業化套用。近年從事超臨界二氧化碳發電關鍵技術研究,建成了國內唯一的大型SCO2壓縮機實驗平台,實驗研究取得重要進展。發表研究論文90餘篇,其中SCI收錄30餘篇,申請/授權中日美發明專利30餘項,軟體著作權5項。第16屆國際傳熱學大會分會主席,國內外學術會議特邀報告10餘次。
  • 學術獎勵與兼職
2017年獲得科技部“產學研合作創新獎”,2018年入選“泰山產業領軍人才”項目。中國工程熱物理學會熱管專委會委員,全國電機工程學會透平專委會委員。國家重點研發計畫、自然科學基金評審專家。中國科學院大學崗位教授,《高等傳熱學》首席講師。大連理工大學“吳仲華未來能源技術學院”副院長。
  • 代表性學術論文
  1. Micro-particle image velocimetry visualization study of thermal Buoyant-Marangoni flow in microtubes,SH Kim, T Wang, L Zhang, Y Jiang, Z Li,International Journal of Heat and Mass Transfer 137, 765-774,2019.
  2. Experimental study on visualization of U-shaped array thermosiphon,HC Su, T Li, YY Jiang, C Guo, T Wang, Applied Thermal Engineering 152, 917-924,2019.
  3. Heat transfer and instability characteristics of a loop thermosyphon with wide range of filling ratios,Y Liu, Z Li, Y Li, Y Jiang, D Tang,Applied Thermal Engineering 151, 262-271, 2019.
  4. Heat transfer characteristics of a concentric annular high temperature heat pipe under anti-gravity conditions,J Zhao, DZ Yuan, DW Tang, YY Jiang, Applied Thermal Engineering 148, 817-824, 2019.
  5. Dynamic performance of high concentration photovoltaic/thermal system with air temperature and humidity regulation system (HCPVTH), H Hu, D Yuan, T Wang, Y Jiang, Applied Thermal Engineering 146, 577-587, 2019.
  6. Droplet impact and LFP on wettability and nanostructured surface, SH Kim, Y Jiang, H Kim, Experimental Thermal and Fluid Science 99, 85-93, 2018.
  7. Experimental investigation of geyser boiling in a two-phase closed loop thermosyphon with high filling ratios, Y Liu, Z Li, Y Li, S Kim, Y Jiang,International Journal of Heat and Mass Transfer 127, 857-869, 2018.
  8. Hydrodynamic analysis of the advancing dynamic contact angle in microtube, SH Kim, T Wang, L Zhang, Y Jiang,Journal of Mechanical Science and Technology 32 (11), 5305-5314,2018.
  9. Thermodynamic coupling characteristics in hybrid (dry/wet) cooling system, H Hu, Y Jiang, C Guo, Z Li, International journal of green energy 15 (9), 532-543, 2018.
  10. A study of boiling on surfaces with temperature-dependent wettability by lattice Boltzmann method, L Zhang, T Wang, Y Jiang, SH Kim, C Guo, International Journal of Heat and Mass Transfer 122, 775-784,2018.
  11. Thermodynamic characteristics of thermal power plant with hybrid (dry/wet) cooling system, H Hu, Z Li, Y Jiang, X Du, Energy 147, 729-741,2018.
  12. Analysis of simplified heat transfer models for thermal property determination of nano-film by TDTR method, X Wang, Z Chen, F Sun, H Zhang, Y Jiang, D Tang, Measurement Science and Technology 29 (3), 035902, 2018.
  13. Transient film thickness and microscale heat transfer during flow boiling in microchannels, Y Sun, C Guo, Y Jiang, T Wang, L Zhang, International Journal of Heat and Mass Transfer 116, 458-470, 2018.
  14. Pool boiling heat transfer on deformable structures made of shape-memory-alloys, W Hao, T Wang, Y Jiang, C Guo, C Guo, International Journal of Heat and Mass Transfer 112, 236-247, 2017.
  15. NUMERICAL SIMULATION OF THERMOACOUSTIC WAVES IN A NaK ALLOY, L Zhan, Y Li, Y Jiang, D Tang, Heat Transfer Research 48(2),2017.
  16. Online measurements of surface tensions and viscosities based on the hydrodynamics of Taylor flow in a microchannel, Y Sun, C Guo, Y Jiang, T Wang, L Zhang, Review of Scientific Instruments 87 (11), 114901,2016.
  17. Loop thermosiphon as a feasible cooling method for the stators of gas turbine T Li, Y Jiang, Z Li, Q Liu, DW Tang, Applied Thermal Engineering 109, 449-453, 2016.
  18. Surface with recoverable mini structures made of shape-memory alloys for adaptive-control of boiling heat transfer, T Wang, YY Jiang, HC Jiang, C Guo, CH Guo, DW Tang, LJ Rong, Applied Physics Letters 107 (2), 023904, 2015.
  19. Theoretical and experimental analysis of the evaporating flow in rectangular microgrooves, C Guo, D Yu, T Wang, Y Jiang, D Tang, International Journal of Heat and Mass Transfer 84, 1113-1118,2015.
  20. Dynamic modeling on bubble growth, detachment and heat transfer for hybrid-scheme computations of nucleate boiling, YY Jiang, H Osada, M Inagaki, N Horinouchi, International Journal of Heat and Mass Transfer 56 (1-2), 640-652, 2013.
  21. An integrated numerical simulator for thermal performance assessments of firefighters’ protective clothing, YY Jiang, E Yanai, K Nishimura, H Zhang, N Abe, M Shinohara, Fire Safety Journal, 45 (5), 314-326, 2010.
  22. A Vector Form Exchange-Area-Based Method for Computation of Anisotropic Radiative Transfer, YY Jiang Journal of Heat Transfer, 131 (1), 012701,2009.
  23. A two-step strategy for numerical simulation of radiative transfer with anisotropic scattering and reflection, YY Jiang, Journal of Quantitative Spectroscopy and Radiative Transfer, 109 (4), 636-649, 2008.
  24. Quantitative evaluation of flow-induced structural vibration and noise in turbomachinery by full-scale weakly coupled simulation, YY Jiang, S Yoshimura, R Imai, H Katsura, T Yoshida, C Kato, Journal of Fluids and Structures 23 (4), 531-544, 2007.

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