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姓名: 趙力
性別:
英文名: Zhao Li
人才稱號:
職稱: 教授、博導
職務: null 專業: 熱能工程
所在機構: 熱能與制冷工程系 個人主頁: www.solarsong.net
郵箱: jons@tju.edu.cn 辦公地點: 天津大學機械工程學院熱能系,300072
傳真: +86(0)22 27404188 辦公電話: +86(0)22 27404188
主要學歷: 1991.9-1995.6:河北煤炭建筑工程學院熱能與環境工程系供熱通風與空調專業,大學本科
1995.9-1998.1:天津大學電氣自動化與能源工程學院工程熱物理專業,獲碩士學位
1998.3-2001.2:天津大學建筑工程學院建筑技術科學專業,獲博士學位

主要學術經歷: 2001.3-2003.4:上海交通大學制冷與低溫工程研究所動力工程及工程熱物理博士后流動站,博士后
2003.4-2008.7:天津大學機械工程學院熱能與制冷工程系,副教授(2003.5)
2008.7-2009.8:天津大學機械工程學院熱能與制冷工程系,教授(2008.7),博士生導師(2008.12)
2009.8-2010.2:美國勞倫斯伯克利國家實驗室,訪問學者
2010.2至今:天津大學機械工程學院熱能與制冷工程系,教授

主要研究方向: 1. 太陽能高效熱利用的相關技術研究
2. 新型制冷劑的循環性能研究
3. 制冷熱泵系統的優化、仿真及控制
4. 新型節能技術研究

主要講授課程: 1. 動力裝置設計與優化 (本科生)
2. 能源管理與規范 (本科生)

主要學術兼職: 1. 天津市可再生能源學會常務秘書

主要學術成就: 完成國家級、省部級及橫向課題10余項,發表論文近60篇,SCI收錄16篇,EI收錄40余篇,出版書籍1部,獲得國家發明專利6項,實用新型專利3項。2007年入選教育部新世紀優秀人才支持計劃。

主要科研項目: 1. 國家科技部863探索類項目(2006AA05Z420),新型太陽能低溫高效熱電循環研究。
2. 國家教育部新世紀優秀人才支持計劃項目,水平管中非共沸工質蒸發傳熱窄點的確定與遷移。
3. 國家自然科學基金面上項目(50876071),高溫熱泵工況下自然工質混合物兩類相變傳熱窄點的研究。
4. 天津市國際合作專項(10ZCGHHZ00800),聚焦式太陽能高效復合轉換技術研究。
5. 國家科技部863項目(2012AA051103),200kW級有機朗肯循環太陽能熱發電技術。
6. 國家自然科學基金面上項目(51276123),混合工質組分可調型有機朗肯循環關鍵科學問題研究。
7. 天津市科技支撐重大項目(11ZCZDGX19800),聚焦太陽能分布式復合供能系統研究與示范。
8. 國家自然科學基金面上項目(51476110),非共沸工質冷凝過程中的氣液分離及氣相膨脹壓縮特性研究

代表性論著: 1. Zhao L., Theoretical and Basic Experimental Analysis on Load Adjustment of Geothermal Heat Pump Systems. Energy Conversion and Management. 2003, 44(1): 1-9.
2. Zhao L., Affection of Two Systematic Parameters on the Geothermal Heat Pump System Operation. Renewable Energy. 2003, 28(1): 35-43.
3. Zhao L., Experimental Evaluation of a Non-azeotropic Working Fluid for Geothermal Heat Pump System. Energy Conversion and Management. 2004, 45(9): 1369-1378.
4. Zhao Li, Gao Pan. Influence of Zeotropic Mixtures' Temperature Gliding on the Performance of Heat Transfer in Condenser or Evaporator. Transactions of Tianjin university. 2005, 11(6): 400-406.
5. Pan Gao, Li Zhao. Investigation on Incomplete Condensation of Non-azeotropic Working Fluids in High Temperature Heat Pumps. Energy Conversion and Management. 2006, 47(13-14): 1884-1893.
6. Zhao Li, Gao Pan. Evaluation of zeotropic refrigerants based on nonlinear relationship between temperature and enthalpy. Science in China Series E. 2006, 49(3): 322-331.
7. P. Gao, L. Zhao. Theoretical and experimental investigation on components' proportion of zeotropic mixtures based on relation between temperature and enthalpy during phase change. Energy conversion and management. 2008, 49(6): 1567-1573.
8. X.D. Wang, L. Zhao. Analysis of zeotropic mixtures used in low-temperature solar Rankine cycles for power generation. Solar energy. 2009, 83(5): 605-613.
9. X.D. Wang, L. Zhao, J.L. Wang, W.Z. Zhang, X.Z. Zhao, W. Wu. Performance evaluation of a low-temperature solar Rankine cycle system utilizing R245fa. Solar energy, 2010, 84(3): 353-364.
10. J.L. Wang, L. Zhao, X.D. Wang. A comparative study of pure and zeotropic mixtures in low-temperature solar Rankine cycle. Applied energy, 2010, 87(11): 3366-3373.
11. Wang XD, Zhao L, Wang JL. Experimental investigation on the low-temperature solar Rankine cycle system using R245fa. ENERGY CONVERSION AND MANAGEMENT. 2011, 52(2): 946-952.
12. J.J. Bao, L. Zhao, W.Z. Zhang. A novel auto-cascade low-temperature solar Rankine cycle system for power generation. Solar Energy. 2011, 85(11): 2710-2719.
13. W. Wu, L. Zhao, T. Hob. Experimental investigation on pinch points and maximum temperature differences in a horizontal tube-in-tube evaporator using zeotropic refrigerants. ENERGY CONVERSION AND MANAGEMENT. 2012(56): 22-31.
14. J.L. Wang, L.Zhao, X.D. Wang. An experimental study on the recuperative low temperature solar Rankine cycle using. APPLIED ENERGY. 2012(94):34-40.
15. Z.Y. Liu, L. Zhao, X.Z. Zhao, H.L. Li. The occurrence of pinch point and its effects on the performance of high temperature heat pump. Applied energy. 2012(97): 869-875.
16. J.J. Bao, L. Zhao. Exergy analysis and parameter study on a novel auto-cascade Rankine cycle, Energy, 2012. 48(1):548-565.
17. N. Zheng, W.D. Song, L. Zhao. Theoretical and experimental investigations on the changing regularity of the extreme point of the temperature difference between zeotropic mixtures and heat transfer fluid, energy, 2013. 55(15):541-552.
18. J.J. Bao, L. Zhao. A review of working fluid and expander selections for organic Rankine cycle, Renewable and Sustainable Energy Reviews, 2013. 24(8):325-342.
19. N. Zheng, L. Zhao, X.D. Wang, Y.T. Tan. Experimental verification of a rolling-piston expander that applied for low-temperature Organic Rankine cycle, applied energy, 2013. 112(12):1265-1274.
20.L. Zhao, J.J. Bao. The influence of composition shift on organic Rankine cycle (ORC) with zeotropic mixtures, energy conversion and management, 2014. 83(7):203-211.
21.Y.T. Tan, L. Zhao, J.J. Bao, Q. Liu. Experimental investigation on heat loss of semi-spherical cavity receiver, Energy conversion and management, 2014. 87(11):576-583.
22.L. Zhao, R.K. Zhao, S. Deng, Y.T. Tan, Y.N. Liu. Integrating solar Organic Rankine Cycle into a coal-?red power plant with amine-based chemical absorption for CO2 capture, International Journal of Greenhouse Gas Control, 2014. 31(10):77-86.
23.L. Zhao, J.J. Bao. Thermodynamic analysis of organic Rankine cycle using zeotropic mixtures, applied energy, 2014. 130(10):748-756.
24. L. Zhao, N. Zheng, S. Deng. A thermodynamic analysis of an auto-cascade heat pump cycle for heating application in cold regions, Energy and Buildings, 2014. 82(10):621-631.

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