能源與動力工程學院
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                            副教授

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                            姓 名 隆瑞 性 別
                            職 稱 副教授 畢業學校
                            個人主頁 http://orcid.org/0000-0003-4911-1716
                            聯系方式
                            郵 箱 R_Long@hust.edu.cn
                            通訊地址 華中科技大學動力樓412室
                            個人資料簡介
                            隆瑞,男,工學博士,華中科技大學能源與動力工程學院副教授,為劉偉老師熱科學與工程實驗室團隊骨干成員。主要從事新能源與低品位熱能利用,納米通道能量轉換與離子輸運特性相關研究。主持國家自然科學基金青年基金1項,并參與國家自然科學基金重點項目等相關研究。以第一作者或通訊作者身份在J. Power Sources, J. Membrane Sci., Energy, Chem. Eng. J.,Phys. Rev. E, Phys. Chem. Chem. Phys., Appl. Math. Model.等發表31篇SCI收錄論文, 其中中科院分區Top期刊20篇。為Energy, Journal of Power Sources, Energy Conversion and Management, Science of the Total Environment等雜志審稿人。并獲得Energy, Journal of Power Sources, Energy Conversionand Management等雜志杰出審稿人榮譽稱號。
                                  研究小組鼓勵研究生的創新思維,并為研究生自主探索的項目提供充足的設備和經費支持,為學生提供優厚的待遇。研究小組工作充實,氣氛融洽,成果豐碩,充滿活力,期待同學們加入。碩士期間,若有讀博打算,可推薦至本課題組劉偉或劉志春老師名下讀博深造。

                            教育及工作經歷

                              2020.4  華中科技大學,能源學院,工程熱物理系,副教授
                              2016.7-2019 華中科技大學,能源學院,工程熱物理系,講師
                              2012.9-2016.6 華中科技大學,能源學院,工程熱物理,博士
                              2011.9-2012.6 華中科技大學,能源學院,工程熱物理,碩士
                              2007.9-2011.6 華中科技大學,能源學院,熱能與動力工程,學士

                            研究方向

                              1、新能源及低溫熱能利用。利用新的方式比如電池、膜基能量轉換技術來高效利用太陽能、海水鹽梯度能量。
                              2、納米通道能量轉換與離子輸運調控。利用數值模擬和實驗研究手段,基于納米膜回收溶液鹽差能,可用于生物細胞內離子發電,DNA分離等。
                              3、高熱流密度電子器件熱管理。

                            科研項目

                              1、國家自然科學基金青年項目:基于膜蒸餾與反電滲析的低溫余熱利用的新型熱力系統研究(2018-至今)
                              2、國家自然科學基金重點項目:基于斯特林熱機的能量轉換與傳遞過程基礎問題研究 (2018-至今)
                              3、國家973計劃課題項目:余熱能級及梯級利用的定量化原則及其在熱力系統中的應用(2013 - 至今)
                              4、國家自然科學基金重點項目:先進傳熱強化理論及機理研究(2011-2014)

                            代表性論文與專利

                              目前隆瑞老師研究小組在 J. Power Sources, J. Membrane Sci., Energy, Chem. Eng. J.,Phys. Rev. E, Phys. Chem. Chem. Phys., Appl. Math. Model.等發表30余篇SCI收錄論文。具體期刊目錄如下:
                              2019年
                              ?    1. Long R, Lai X, Liu Z, Liu W. Pressure retarded osmosis: Operating in a compromise between power density and energy efficiency. Energy. 2019;172:592-8.
                              ?    2. Kuang Z, Zhang D, Shen Y, Long R*, Liu Z, Liu W. Bioinspired fractal nanochannels for high-performance salinity gradient energy conversion. Journal of Power Sources. 2019;418:33-41.
                              2018年
                              ?    1. Long R, Liu Z, Liu W. Performance analysis for minimally nonlinear irreversible refrigerators at finite cooling power. Physica A, 2018, 496:137-146.
                              ?    2. Long R, Lai X, Liu Z, Liu W. Direct contact membrane distillation system for waste heat recovery: Modelling and multi-objective optimization. Energy, 2018, 148:1060-1068.
                              ?    3. Lai X, Long R*, Liu Z, Liu W*. A hybrid system using direct contact membrane distillation for water production to harvest waste heat from the proton exchange membrane fuel cell. Energy, 2018, 147:578-586.
                              ?    4. Long R, Kuang Z, Liu Z, Liu W. Reverse electrodialysis in bilayer nanochannels:salinity gradient-driven power generation, Physical Chemistry Chemical Physics, 2018, 20: 7295-7302.
                              ?    5. Long R, Li B, Liu Z, Liu W. Reverse electrodialysis: Modelling and performance analysis based on multi-objective optimization. Energy. 2018;151:1-10.
                              ?    6. Long R, Lai X, Liu Z, Liu W. A continuous concentration gradient flow electrical energy storage system based on reverse osmosis and pressure retarded osmosis. Energy.2018;152:896-905.
                              ?    7. Long R, Kuang Z, Liu Z, Liu W. Temperature regulated reverse electrodialysis in charged nanopores. Journal of Membrane Science. 2018;561:1-9.
                              ?    8. Long R, Li B, Liu Z, Liu W. Performance analysis of reverse electrodialysis stacks: Channel geometry and flow rate optimization. Energy. 2018;158:427-36.
                              ?    9. Lai X, Long R*, Liu Z, Liu W*. Stirling engine powered reverse osmosis for brackish water desalination to utilize moderate temperature heat. Energy. 2018;165:916-30.
                              ?    10. D.D. Dai, F. Yuan, R. Long, Z.C. Liu, W. Liu. Imperfect regeneration analysis of Stirling engine caused by temperature differences in regenerator. Energy Conversion and Management, 2018, 158:60-69.
                              ?    11. Dongdong Dai, Fang Yuan, Rui Long, Zhichun Liu, Wei Liu. Performance analysis and multi-objective optimization of a Stirling engine based on MOPSOCD. International Journal of Thermal Sciences, 2018, 124:399-406
                              ?    12.Rui Long*, Zhengfei Kuang, BaodeLi, Zhichun. Liu, Wei Liu*. Exergy analysis andperformance optimization of Kalina cycle system 11 (KCS-11) for low grade wasteheat recovery. 10th InternationalConference on Applied Energy (ICAE2018), 22-25 August 2018, Hong Kong, China.
                              2017年
                              ?    1. Long R, Li B, Liu Z, Liu W. Hybrid membrane distillation-reverse electrodialysis electricity generation system to harvest low-grade thermal energy. Journal of Membrane Science. 2017;525:107-15.
                              2016年
                              ?    1. Long R, Liu W. Efficiency and its bounds of minimally nonlinear irreversible heat engines at arbitrary power. Physical Review E. 2016;94(5):052114.
                              ?    2.Long R, Li B, Liu W. Performance analysis for Feynman's ratchet as a refrigerator with heat leak under different figure of merits. Applied Mathematical Modelling. 2016;40(23–24):10437-46.
                              ?    3.Long R, Li BD, Liu ZC, Liu W. Ecological analysis of a thermally regenerative electrochemical cycle, Energy, 2016; 107: 95-102.
                              ?    4.Long R, Li BD, Liu ZC, Liu W. Performance analysis of a dual loop thermally regenerative electrochemical cycle for waste heat recovery, Energy, 2016; 107: 388-395.
                              ?    5.Long R, Li BD, Liu ZC, Liu W. Performance analysis of a solar-powered electrochemical refrigerator, Chemical Engineering Journal, 2016; 284:325-332.
                              ?    6.Long R, Liu W. Ecological optimization and coefficient of performance bounds for general refrigerators, Physica A, 2016; 443:14-21.
                              ?    7. Li BD,Long R*,Liu ZC,Liu W*. Performance analysis of a thermally regenerative electrochemical refrigerator. Energy,2016,112:43-51.
                              2015年
                              ?    1.Long R, Li BD, Liu ZC, Liu W. Performance analysis of a thermally regenerative electrochemical cycle for harvesting waste heat, Energy, 2015; 87: 463-469.
                              ?    2.Long R, Li BD, Liu ZC, Liu W. Performance analysis of a solar-powered solid state heat engine for electricity generation, Energy, 2015; 93:165-172.
                              ?    3.Long R, Li BD, Liu ZC, Liu W. Multi-objective optimization of a continuous thermally regenerative electrochemical cycle for waste heat recovery, Energy, 2015;93:1022-1029.
                              ?    4.Long R, Li BD, Liu ZC, Liu W. A hybrid system using a regenerative electrochemical cycle to harvest waste heat from the proton exchange membrane fuel cell, Energy, 2015;93: 2079-2086.
                              ?    5.Long R, Liu W. Unified trade-off optimization for general heat devices with nonisothermal processes. Physical Review E, 2015; 91(4):042127.
                              ?    6.Long R, Liu W. Performance of quantum Otto refrigerators with squeezing, Physical Review E, 2015; 91(6):062137.
                              ?    7.Long R, Liu W. Performance of micro two-level heat devices with prior information, Physics Letters A, 2015, 379:1979-1982.
                              ?    8.Long R, Liu W. Ecological optimization for general heat engines. Physica A, 2015; 434:232-239.
                              ?    9.Long R, Liu W. Coefficient of performance and its bounds with the figure of merit for a general refrigerator. Physica Scripta, 2015; 90(2):025207.
                              2014年
                              ?    1. Long R, Bao YJ, Huang XM, Liu W. Exergy analysis and working fluid selection of organic Rankine cycle for low grade waste heat recovery. Energy, 2014; 73:475-483.
                              ?    2.Long R, Liu Z, Liu W. Performance optimization of minimally nonlinear irreversible heat engines and refrigerators under a trade-off figure of merit. Physical Review E, 2014; 89(6):062119.
                              ?    3.Long R, Liu W. Coefficient of performance and its bounds for general refrigerators with nonisothermal processes. Journal of Physics A: Mathematical and Theoretical, 2014; 47(32):325002.


                            所獲榮譽和獎勵

                              1. 華中科技大學博士學位論文創新基金
                              2. 博士研究生國家獎學金
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