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      我的主頁      中南大學      能源科學與工程學院      
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饒政華
個人簡介
姓名:饒政華

系所:新能源科學與工程

職稱:副教授

郵箱:raoz@csu.edu.cn

中南大學供熱、通風與空調工程專業學士,中南大學制冷及低溫工程專業工學碩士,中南大學與美國 Missouri University of Science and Technology 聯合培養工程熱物理專業工學博士。

2007年至2009年獲國家留學基金委的資助赴美留學。一直從事動力工程及工程熱物理、制冷與空調相關學科的教學研究工作,參與完成了國家863項目、自然科學基金項目、省部級重大課題和國際合作項目的研究工作。目前主持湖南省自然科學基金項目、教育部科研專項資金項目、美國通用汽車公司等企業委托合作項目。

近年來主要開展了太陽能熱發電、金屬及復合材料加工過程的傳熱傳質、超臨界CO2流動傳熱等研究,研究成果發表于國內外權威學術期刊以及國際學術會議,其中SCI收錄論文30余篇。

科研方向
1、 新能源技術:太陽能熱利用技術,地熱能利用技術,能源利用系統仿真與優化

2、 工程熱物理與能源利用的基礎問題:材料加工過程模擬與分析(傳熱/傳質、流動、熱應力分析),微納尺度傳遞,超臨界流體流動與傳熱

講授課程
1、 本科生課程:太陽能熱利用原理與技術、太陽能熱利用課程設計

2、 研究生課程:能源系統工程(英文)

學術成果
1. 科研項目

1)湖南省自然科學基金項目. 太陽能接收器內熔鹽納米流體粒子微運動及高溫傳熱特性研究.

2)湖南省自然科學基金項目. 超臨界CO2布雷頓循環太陽能發電系統及其高效集熱機理研究.

3)流程工業節能技術湖南省重點實驗室開放研究基金. 超臨界CO2布雷頓循環太陽能熱發電系統性能研究與優化.
4)美國通用汽車公司合作項目. Modeling of Compression Molding and Molding-Induced Distortion of Long Fiber Thermoplastic Composites.
5)美國通用汽車公司合作項目,Modeling and Characterization of Weld Discrepancies and Microstructures in Laser Brazing and Welding of Aluminum Alloys for Automotive Applications.
6)中央高;究蒲袠I務費專項資金資助項目. 可再生能源建筑關鍵技術研究.

2. 科研論文

[1] Rao Z, Ou L, Wang Y, et al. A self-piercing-through riveting method for joining of discontinuous carbon fiber reinforced nylon 6 composite. Composite Structures, 2020:111841.

[2] Wang, Yaqiong; Rao, Zhenghua; Liu, Jiaxing, et al. An optimized control strategy for integrated solar and air-source heat pump water heating system with cascade storage tanks. ENERGY AND BUILDINGS, 2020, 210: 109766.

[3] Rao, Zhenghua; Xue, Tianchen; Huang, Kaixin; Liao, Shengming. Multi-objective optimization of supercritical carbon dioxide recompression Brayton cycle considering printed circuit recuperator design. ENERGY CONVERSION AND MANAGEMENT, 2019, 201: 112094.

[4] Liu, Xiao-jun; Liao, Sheng-ming; Rao, Zheng-hua. An input-output model for energy accounting and analysis of industrial production processes: a case study of an integrated steel plant. JOURNAL OF IRON AND STEEL RESEARCH INTERNATIONAL, 2018, 25(5): 524-538

[5] Li, Min; Zhou, Cheng; Rao, Zhenghua. Hourly 50-year simulations of ground-coupled heat pumps using high-resolution analytical models. ENERGY CONVERSION AND MANAGEMENT, 2019, 193: 15-24.

[6] Chen, Rui; Rao, Zhenghua; Liao, Shengming. Determination of key parameters for sizing the heliostat field and thermal energy storage in solar tower power plants. ENERGY CONVERSION AND MANAGEMENT, 2018, 177: 385-394

[7] J.W. Liu, Z.H. Rao, S.M. Liao, H.L. Tsai. Numerical investigation of weld pool behaviors and ripple formation for a moving GTA welding under pulsed currents, International Journal of Heat and Mass Transfer, 2015, 91, 990-1000.

[8] Yuqiang Li,Gang Liu,Zhenghua Rao,Shengming Liao,Field synergy principle analysis for reducing natural convection heat loss of a solar cavity receiver,Renewable Energy,2015,75:257-265.

[9] Yuqiang Li,Shengming Liao,Zhenghua Rao,Gang Liu,A dynamic assessment based feasibility study of concentrating solar power in China,Renewable Energy,2014,69:34-42.

[10] Z.H. Rao, S.M. Liao. A numerical investigation of turbulent convective heat transfer of supercritical CO2 in vertical mini tubes,Progress in Computational Fluid Dynamics,2014,14(3):166-176.

[11] J.W. Liu, Z.H. Rao, S.M. Liao, P-C Wang. Modeling of transport phenomena and solidification cracking in laser spot bead-on-plate welding of AA6063-T6 alloy. Part I—the mathematical model. International Journal of Advanced Manufacturing Technology, 2014, 73(9-12):1705-1716.

[12] J.W. Liu, Z.H. Rao, S.M. Liao, P-C Wang. Modeling Of Transport Phenomena And Solidification Cracking In Laser Spot Bead-On-Plate Welding Of Aa6063-T6 Alloy. Part II—Simulation Results And Experimental Validation[J]. International Journal of Advanced Manufacturing Technology, 2014, 74(1-4):285-296.

[13] Z.H. Rao, J.W. Liu, P-C Wang, Y.X. Li, S.M. Liao. Modeling of Cold Metal Transfer Spot Welding of AA6061-T6 Aluminum Alloy and Galvanized Mild Steel. Journal of Manufacturing Science & Engineering, 2014, 136(5):2729-2737.

[14] Z.H. Rao, J. Zhou, H.L. Tsai. Determination of equilibrium wire-feed-speeds for stable gas metal arc welding. International Journal of Heat and Mass Transfer, 2012, 54, 55 (2012) 6651–6664.

[15] X. L. Cao, Z. H. Rao, S. M. Liao. Laminar convective heat transfer of supercritical CO2 in horizontal miniature circular and triangular tubes. Applied Thermal Engineering, 2011, 31(14-15): 2374-2384.

[16] Z.H. Rao, S.M. Liao, H.L. Tsai. Modeling of hybrid laser-GMA welding: A review and challenges. Science and Technology of Welding and Joining, 2011, 16(4): 300-305.

[17] Z.H. Rao, J. Hu, S.M. Liao, H.L. Tsai. Modeling of the transport phenomena in GMAW using argon–helium mixtures. Part I – The arc. International Journal of Heat and Mass Transfer, 2010, 53(25/26), 5707–5721.

[18] Z.H. Rao, J. Hu, S.M. Liao, H.L. Tsai. Modeling of the transport phenomena in GMAW using argon–helium mixtures. Part II – The metal. International Journal of Heat and Mass Transfer, 2010, 53(25/26), 5722–5732.

[19] Z.H. Rao, S.M. Liao, H.L. Tsai. Effect of Shielding Gas Composition on Arc Plasma and Metal Transfer in Gas Metal Arc Welding. Journal of Applied Physics, 2010, 107(4), 044902.

[20] Z.H. Rao, J. Zhou, S.M. Liao, H.L. Tsai. Three-dimensional modeling of transport phenomena and their effect on the formation of ripples in gas metal arc welding. Journal of Applied Physics, 2010, 107(5), 054905.

[21] C.H. Lin, Z.H. Rao, L. Jiang, W.J. Tsai, P.H. Wu, C.W. Chien, H.L. Tsai. Investigations of femtosecond–nanosecond dual-beam laser ablation of dielectrics. Optics Letters, 2010, 35(14): 2490-2492.

[22] Z.H. Rao, S.M. Liao, H.L. Tsai, P. C. Wang, R. Stevenson. Mathematical Modeling of Electrode Cooling in Resistance Spot Welding. Welding Journal, 2009, 88(5): 111s-119s.

[23] Z.H. Rao, J. Hu, S.M. Liao, H.L. Tsai. Determination of Equilibrium Wire Feed Speeds for a Stable GMAW Process. In: 2008 ASME International Mechanical Engineering Congress and Exposition (Proceedings of IMECE2008), 2008, Boston, Massachusetts, USA. 67799.

[24] Z.H. Rao, J. Hu, S.M. Liao, H.L. Tsai. Study the Shielding Gas Effect on the Metal Transfer and Weld Pool Dynamics in GMAW. In: 2009 ASME Summer Heat Transfer Conference, July, 2009, San Francisco, California USA. 88407.

[25] Z.H. Rao, C.H. Lin, L. Jiang, W.J. Tsai, P.H. Wu, C.W. Chien, H.L. Tsai. Investigations of Femtosecond-Nanosecond Dual-Beam Laser Ablation of Dielectrics. In: ASME 2009 2nd Micro/Nanoscale Heat & Mass Transfer International Conference (Proceedings of MNHMT2009), December, 2009, Shanghai, China. 18188.

[26] C.H. Lin, Z.H. Rao, L. Jiang, W.J. Tsai, P.H. Wu, C.W. Chien, H.L. Tsai. Enhancement of ablation efficiency by a femto/nano-second dual-beam micromachining system. In: Proceedings of the Society of Photo-Optical Instrumentation Engineers (SPIE), Vol. 7585, January, 2010, San Francisco, California, USA. 758501.

[27] Z.H. Rao, J. Hu, S.M. Liao, H.L. Tsai. Study the Shielding Gas Effects on Transport Phenomena in GMAW Arc. In: The 20th International Symposium on Transport Phenomena, July, 2009, Victoria BC, Canada.

[28] 劉敏; 饒政華; 劉繼雄; 廖勝明. 能流分布對超臨界CO2腔式太陽能吸熱器熱-力特性的影響. 太陽能學報, 2020, 41 (4): 92-98

[29] 黃凱欣,饒政華,廖勝明.超臨界CO2太陽能吸熱器許用能流密度研究. 太陽能學報,2018,39(1): 44-50.

[30] 饒政華,廖勝明. 新能源科學與工程專業課程體系研究. 中國大學教學,2015年第3期:44-47.

[31] 高如超,饒政華,李蕓霄,廖勝明. 脈沖GTAW熔池行為和焊縫成形的三維數值模擬 [J]. 中南大學學報, 2013, 44(11): 4712-4719.

[32] 劉仙萍, 饒政華, 廖勝明. 太陽能光伏/光熱復合集熱器能量轉換性能的數值模擬[J]. 中南大學學報:自然科學版, 2013, 44(6):2554-2560.

[33] 李大鵬, 饒政華, 張翔等. 長沙地區多功能地源熱泵系統的模擬與分析[J]. 中南大學學報:自然科學版, 2013, 44(3).

[34] 南劍, 饒政華, 劉驍浚等. 基于系統節能的冶金過程監測與模擬技術研究進展[J]. 過程工程學報, 2014, (4).

[35] 饒政華, 廖勝明. 二氧化碳微通道氣體冷卻器的數值仿真與結構優化.化工學報, 2005, 56(9):1721-1726.

[36] 饒政華, 廖勝明. 超臨界二氧化碳管內湍流流動和傳熱的數值模擬. 流體機械, 2005, 33(1): 71-75.

[37] 饒政華, 廖勝明. 超臨界二氧化碳水平細微管內層流流動與換熱的數值模擬. 熱科學與技術, 2005, 4(2):113-117.

[38] 饒政華, 廖勝明. 超臨界CO2在水平三角細微管內層流對流換熱的數值模擬. 制冷學報, 2006, 27 (5): 44-47.


3. 授權專利

[1] CN110822928A 用于炭素單體爐的蓄熱式余熱利用裝置、系統及控制方法

[2] CN110428302A 一種區域分布式熱水共享系統及控制方法

[3] CN108124408B 基于熱管技術的數據中心浸沒式液冷機柜

[4] CN108882658A 浸沒式液冷和循環風冷結合的服務器機柜散熱系統

[5] CN201210063648.4 平板式太陽能熱水器裝置

[6] CN201510742601.4 太陽能集熱器和空氣源熱泵聯合供熱水系統及控制方法

[7] CN201210125709.5 平板熱管太陽能光伏光熱復合集熱器及其制作工藝

[8] CN201310098915.6 新風換氣機用平板全熱換熱芯體

[9] CN201310098875.5 新風換氣機用導板膜式全熱換熱芯體

[10] CN201410725581.5 干衣機及其控制方法

[11] CN201410802371.1 熱泵熱水機

[12] CN201410802832.5 空氣源熱泵熱水機



學術獎勵
1、2012年湖南省優秀博士學位論文

2、2010年湖南省自然科學優秀學術論文二等獎

3、2014年第七屆全國大學生節能減排社會實踐與科技競賽一等獎(指導教師)

4、2017年第十屆全國大學生節能減排社會實踐與科技競賽二等獎(指導教師)

5、2019年第十二屆全國大學生節能減排社會實踐與科技競賽一等獎(指導教師)

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