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                            教授

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                            姓 名 劉偉 性 別
                            職 稱 教授(博導) 畢業學校
                            個人主頁 http://tsl.www.cafecuruba.com/
                            聯系方式 027-87541998
                            郵 箱 w_liu@hust.edu.cn
                            通訊地址 華中科技大學能源與動力工程學院
                            個人資料簡介
                            劉偉,男,華中科技大學能源與動力工程學院教授,博士生導師,享受國務院政府津貼。兼任中國工程熱物理學會理事、傳熱傳質分會副主任委員,在多個國際會議中擔任組委會主席、國際顧問或科學委員會委員等,在數個國內外學術會議上做特邀報告。曾任中國可再生能源學會理事、湖北省工程熱物理學會副理事長、教育部熱工課程指導分委員會委員、國家級精品課程負責人、國家自然科學獎評審專家、教育部科學技術獎評審專家、國家自然科學基金專家評審組成員等。長期從事工程熱物理及能源領域的教學及科研工作,主持包括國家自然科學基金重點項目、“973”計劃二級課題項目、總裝預研項目在內的國家級和省部級科研項目20余項。獲國家教學成果二等獎1項(排序第一),省部級科研和教學成果一等獎3項(均排序第一)、三等獎2項,主持制定國家標準1部,獲授權國家發明專利18項,出版學術專著3部,出版“十二五”國家級規劃教材和電力出版社規劃教材2部,其中1部獲國家級精品教材。發表學術論文被SCI收錄220余篇,EI收錄300余篇次。培養博士生獲湖北省優秀博士論文3次,與美國MIT、UIUC聯合培養博士生3人。

                            教育及工作經歷

                              1983.04-1987.03 華中工學院動力工程系熱工教研室助教、講師

                              1987.03-1988.05 美國新澤西州迪金森大學理工學院訪問學者

                              1988.05-1994.10 華中理工大學動力工程系熱工教研室講師、副教授

                              1994.10-1995.10 日本愛嬡大學機械系高級訪問學者

                              1995.10-1996.11 華中理工大學動力工程系熱工教研室副教授、教授

                              1996.11-1997.11 華中理工大學能源科學與工程學院副院長、教授

                              1997.11-1998.01 日本愛嬡大學機械系訪問教授

                              1998.02-2000.05 華中理工大學動力工程系系主任、教授、博導

                              2000.05-2001.02 華中科技大學動力工程系系主任、教授、博導

                              2001.02-2002.10 華中科技大學能源與動力工程學院院長、教授、博導

                              2002.10-2003.10 寧夏大學副校長

                              2003.10-2004.12 華中科技大學能源與動力工程學院院長、教授、博導

                              2004.12-2006.01 華中科技大學黨委組織部長、教授、博導

                              2006.01-2008.06 華中科技大學副校長、教授、博導

                              2008.06-至今    華中科技大學能源與動力工程學院教授、博導

                            研究方向

                              電子器件冷卻;強化傳熱理論與技術;熱交換設備與節能;建筑節能;太陽能熱利用;燃料電池熱傳輸;工業余熱回收及利用

                            科研項目

                              [1] 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
                              [2] 國家自然科學基金面上項目:泵輔助毛細回路的機理與實驗研究,2013-2016
                              [3] 國家自然科學基金面上項目:毛細相變回路的界面效應及其穩定性研究,2009-2011
                              [4] 國家自然科學基金面上項目:土壤次生鹽漬化過程的機理研究和模型預報,2004-2006
                              [5] 國家自然科學基金面上項目:REPS系統中的熱物理問題研究,2000-2002
                              [6] 國家自然科學基金重點項目子項目:生物傳熱的熱物理參數與基于光學層析的光參數的關聯研究,1999-2002
                              [7] 國家973計劃子課題項目: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,2013-2017
                              [8] 國家973計劃子課題項目:換熱器內流體誘導振動,2007-2011
                              [9] 國家973計劃子課題項目:多孔介質及微細通道內相變流動機理和傳熱強化研究,2000-2005
                              [10] 國防項目:高熱流器件散熱與控制技術,2006-2010
                              [11] 國防項目:高效微通道熱沉散熱技術,2008-2010
                              [12] 國防項目:CPL熱控技術,2001-2005
                              [13] 國防項目:小型CPL毛細芯研制,2000-2003
                              [14] 教育部博士點基金項目:基于傳熱強化的換熱器設計與評價方法,2011-2013
                              [15] 教育部博士點基金項目:植物根系土壤鹽漬化機理的熱物理研究,2004-2006
                              [16] 教育部博士點基金項目:基于能量和物質遷移的REPS系統熱物理問題研究,2001-2003
                              [17] 湖北省科技攻關項目:超臨界流體萃取技術進行蛋黃卵磷脂提取新工藝研究,2002-2003

                            代表性論文與專利

                              專著與教材:
                              [1] 劉偉,范愛武,黃曉明,《多孔介質傳熱傳質理論與應用》,科學出版社,2006
                              [2] 黃素逸,劉偉,《高等工程傳熱學》,中國電力出版社,2006
                              [3] 劉偉,周懷春,楊昆,《輻射介質傳熱》,中國電力出版社,2009
                              [4] 劉偉,黃曉明,劉志春,《毛細相變回路的理論與實驗研究》,華中科技大學出版社,2010
                              [5] 范愛武,靳世平,劉偉,《微小尺度燃燒》,科學出版社,2012
                               
                              發明專利:
                              [1] 劉偉,楊金國,劉志春等,平板式毛細抽吸兩相回路熱交換系統,授權號:200510001149.2
                              [2] 劉偉,楊金國,劉志春等,一種用于CPL的平面式毛細芯蒸發器,授權號:200510019110.3
                              [3] 劉偉,楊金國,劉志春等,用于CPL的帶有散熱片的平面式毛細芯蒸發器,授權號:200510019111.8
                              [4] 劉偉,劉志春等,具有平面式毛細芯蒸發器和冷凝器的CPL系統,授權號:200510019112.2
                              [5] 劉偉,劉志春等,一種用于CPL的平面式毛細芯冷凝器,授權號:200510019113.7
                              [6] 劉偉,劉志春等,用于LHP和CPL的平面圓盤式毛細芯蒸發器,授權號:200610055641.2
                              [7] 劉志春,劉偉等,縱向擾流管殼式換熱器,授權號:2008102367.17.0
                              [8] 明廷臻,劉偉,劉志春等,一種強化傳熱管,授權號:2008102367.16.6
                               
                              英文雜志論文:
                               
                              劉偉教授課題組最新動態詳見:
                              tsl.www.cafecuruba.com/

                              2014

                               

                              [1] Wang Y, Zhou B, Liu Z, Tu Z, Liu W. Numerical study and performance analyses of the mini-channel with discrete double-inclined ribs. International Journal of Heat and Mass Transfer. 2014;78 498–505.

                              [2] Jiang C, Liu W, Wang HC, Wang DD, Yang JG, Li JY, et al. Experimental investigation of pump-assisted capillary phase change loop. Applied Thermal Engineering. 2014;71(1):581-8.

                              [3] Yang J, Oh S-R, Liu W. Optimization of shell-and-tube heat exchangers using a general design approach motivated by constructal theory. International Journal of Heat and Mass Transfer. 2014;77:1144-54.

                              [4] Yang J, Ma L, Liu J, Liu W. Thermal–hydraulic performance of a novel shell-and-tube oil cooler with multi-fields synergy analysis. International Journal of Heat and Mass Transfer. 2014;77:928-39.

                              [5] Yang J, Ma L, Bock J, Jacobi AM, Liu W. A comparison of four numerical modeling approaches for enhanced shell-and-tube heat exchangers with experimental validation. Applied Thermal Engineering. 2014;65(1–2):369-83.

                              [6] Yang J, Fan A, Liu W, Jacobi AM. Optimization of shell-and-tube heat exchangers conforming to TEMA standards with designs motivated by constructal theory. Energy Conversion and Management. 2014;78:468-76.

                              [7] Ma L, Yang J, Liu W, Zhang X. Physical quantity synergy analysis and efficiency evaluation criterion of heat transfer enhancement. International Journal of Thermal Sciences. 2014;80:23-32.

                              [8] 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.

                              [9] 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.

                              [10] Long R, Bao Y, Huang X, Liu W. Exergy analysis and working fluid selection of organic Rankine cycle for low grade waste heat recovery. Energy. 2014.

                              [11] Jia H, Liu ZC, Liu W, Nakayama A. Convective heat transfer optimization based on minimum entransy dissipation in the circular tube. International Journal of Heat and Mass Transfer. 2014;73:124-9.

                              [12] Wang D, Liu Z, Shen J, Jiang C, Chen B, Yang J, et al. Experimental study of the loop heat pipe with a flat disk-shaped evaporator. Experimental Thermal and Fluid Science. 2014;57:157-64.

                              [13] Pei H, Shen J, Cai Y, Tu Z, Wan Z, Liu Z, et al. Operation characteristics of air-cooled proton exchange membrane fuel cell stacks under ambient pressure. Applied Thermal Engineering. 2014;63(1):227-33.

                              [14] Wan Z, Shen J, Zhang H, Tu Z, Liu W. In situ temperature measurement in a 5kW-class Proton Exchange Membrane Fuel Cell stack with pure oxygen as the oxidant. International Journal of Heat and Mass Transfer. 2014;75:231-4.

                              [15] Ming T, de Richter R, Liu W, Caillol S. Fighting global warming by climate engineering: Is the Earth radiation management and the solar radiation management any option for fighting climate change? Renewable & Sustainable Energy Reviews. 2014;31:792-834.

                              [16] Liu Y, Zhang J, Fan A, Wan J, Yao H, Liu W. Numerical investigation of CH4/O2 mixing in Y-shaped mesoscale combustors with/without porous media. Chemical Engineering and Processing: Process Intensification. 2014;79:7-13.

                              [17] Fang T, Ming T, Tso CP, Huang X, Liu W. Analysis of non-uniform heat loads on evaporators with loop heat pipes. International Journal of Heat and Mass Transfer. 2014;75:313-26.

                              [18] Fan A, Wan J, Liu Y, Pi B, Yao H, Liu W. Effect of bluff body shape on the blow-off limit of hydrogen/air flame in a planar micro-combustor. Applied Thermal Engineering. 2014;62(1):13-9.

                              [19] Wan J, Yang W, Fan A, Liu Y, Yao H, Liu W, et al. A numerical investigation on combustion characteristics of H2/air mixture in a micro-combustor with wall cavities. International Journal of Hydrogen Energy. 2014;39(15):8138-46.

                               

                              2013

                               

                              [20] Zhang X, Liu Z, Liu W. Numerical studies on heat transfer and friction factor characteristics of a tube fitted with helical screw-tape without core-rod inserts. International Journal of Heat and Mass Transfer. 2013;60:490-8.

                              [21] Zhang C-p, Lian Y-f, Yu X-f, Liu W, Teng J-t, Xu T-t, et al. Numerical and experimental studies on laminar hydrodynamic and thermal characteristics in fractal-like microchannel networks. Part B: Investigations on the performances of pressure drop and heat transfer. International Journal of Heat and Mass Transfer. 2013;66:939-47.

                              [22] Zhang C-p, Lian Y-f, Yu X-f, Liu W, Teng J-t, Xu T-t, et al. Numerical and experimental studies on laminar hydrodynamic and thermal characteristics in fractal-like microchannel networks. Part A: Comparisons of two numerical analysis methods on friction factor and Nusselt number. International Journal of Heat and Mass Transfer. 2013;66:930-8.

                              [23] You Y, Fan A, Luo X, Jin S, Liu W, Huang S. An investigation in the effects of recycles on laminar heat transfer enhancement of parallel-flow heat exchangers. Chemical Engineering and Processing. 2013;70:27-36.

                              [24] You Y, Fan A, Lai X, Huang S, Liu W. Experimental and numerical investigations of shell-side thermo-hydraulic performances for shell-and-tube heat exchanger with trefoil-hole baffles. Applied Thermal Engineering. 2013;50(1):950-6.

                              [25] Wan Z, Liu J, Luo Z, Tu Z, Liu Z, Liu W. Evaluation of self-water-removal in a dead-ended proton exchange membrane fuel cell. Applied Energy. 2013;104:751-7.

                              [26] Pei H, Liu Z, Zhang H, Yu Y, Tu Z, Wan Z, et al. In situ measurement of temperature distribution in proton exchange membrane fuel cell I a hydrogen-air stack. Journal of Power Sources. 2013;227:72-9.

                              [27] Ming T, Meng F, Liu W, Pan Y, de Richter RK. Analysis of output power smoothing method of the solar chimney power generating system. International Journal of Energy Research. 2013;37(13):1657-68.

                              [28] Ming T, de Richter RK, Meng F, Pan Y, Liu W. Chimney shape numerical study for solar chimney power generating systems. International Journal of Energy Research. 2013;37(4):310-22.

                              [29] Liu W, Jia H, Liu ZC, Fang HS, Yang K. The approach of minimum heat consumption and its applications in convective heat transfer optimization. International Journal of Heat and Mass Transfer. 2013;57(1):389-96.

                              [30] Guo J, Yan Y, Liu W, Jiang F, Fan A. Effects of upwind area of tube inserts on heat transfer and flow resistance characteristics of turbulent flow. Experimental Thermal and Fluid Science. 2013;48:147-55.

                              [31] Fan A, Wan J, Maruta K, Yao H, Liu W. Interactions between heat transfer, flow field and flame stabilization in a micro-combustor with a bluff body. International Journal of Heat and Mass Transfer. 2013;66:72-9.

                              [32] Fan A, Wan J, Maruta K, Nakamura H, Yao H, Liu W. Flame dynamics in a heated meso-scale radial channel. Proceedings of the Combustion Institute. 2013;34:3351-9.

                              [33] Fan A, Wan J, Liu Y, Pi B, Yao H, Maruta K, et al. The effect of the blockage ratio on the blow-off limit of a hydrogen/air flame in a planar micro-combustor with a bluff body. International Journal of Hydrogen Energy. 2013;38(26):11438-45.

                              [34] Ding G, Tang H, Luo Z, Tu Z, Pei H, Liu Z, et al. Water distribution and removal along the flow channel in proton exchange membrane fuel cells. Journal of Wuhan University of Technology-Materials Science Edition. 2013;28(2):243-8.

                               

                              2012

                               

                              [35] Zhang X, Liu Z, Liu W. Numerical studies on heat transfer and flow characteristics for laminar flow in a tube with multiple regularly spaced twisted tapes. International Journal of Thermal Sciences. 2012;58:157-67.

                              [36] Yuan W, Zhao J, Tso CP, Wu T, Liu W, Ming T. Numerical simulation of the thermal hydraulic performance of a plate pin fin heat sink. Applied Thermal Engineering. 2012;48:81-8.

                              [37] You Y, Fan A, Liu W, Huang S. Thermo-hydraulic characteristics of laminar flow in an enhanced tube with conical strip inserts. International Journal of Thermal Sciences. 2012;61:28-37.

                              [38] You Y, Fan A, Huang S, Liu W. Numerical modeling and experimental validation of heat transfer and flow resistance on the shell side of a shell-and-tube heat exchanger with flower baffles. International Journal of Heat and Mass Transfer. 2012;55(25-26):7561-9.

                              [39] Yang C, Nakayama A, Liu W. Heat transfer performance assessment for forced convection in a tube partially filled with a porous medium. International Journal of Thermal Sciences. 2012;54:98-108.

                              [40] Wan ZM, Wan JH, Liu J, Tu ZK, Pan M, Liu ZC, et al. Water recovery and air humidification by condensing the moisture in the outlet gas of a proton exchange membrane fuel cell stack. Applied Thermal Engineering. 2012;42(0):173-8.

                              [41] Wan ZM, Guo GQ, Su KL, Tu ZK, Liu W. Experimental analysis of flow and heat transfer in a miniature porous heat sink for high heat flux application. International Journal of Heat and Mass Transfer. 2012;55(15–16):4437-41.

                              [42] Wan J, Fan A, Maruta K, Yao H, Liu W. Experimental and numerical investigation on combustion characteristics of premixed hydrogen/air flame in a micro-combustor with a bluff body. International Journal of Hydrogen Energy. 2012;37(24):19190-7.

                              [43] Tu Z-k, Pan M, Liu W, Liu Z-c, Wan Z-m. Modeling of stability of the condensing interface in a capillary pumped loop. International Journal of Heat and Mass Transfer. 2012;55(5-6):1709-15.

                              [44] Ming T, Wang X, de Richter RK, Liu W, Wu T, Pan Y. Numerical analysis on the influence of ambient crosswind on the performance of solar updraft power plant system. Renewable & Sustainable Energy Reviews. 2012;16(8):5567-83.

                              [45] Liu Z, Li H, Chen B, Yang J, Liu W. Operational characteristics of flat type loop heat pipe with biporous wick. International Journal of Thermal Sciences. 2012;58:180-5.

                              [46] Liu W, Liu Z, Ma L. Application of a multi-field synergy principle in the performance evaluation of convective heat transfer enhancement in a tube. Chin Sci Bull. 2012;57(13):1600-7.

                              [47] Li H, Liu Z, Chen B, Liu W, Li C, Yang J. Development of biporous wicks for flat-plate loop heat pipe. Experimental Thermal and Fluid Science. 2012;37:91-7.

                              [48] Jia H, Liu W, Liu Z. Enhancing convective heat transfer based on minimum power consumption principle. Chemical Engineering Science. 2012;69(1):225-30.

                              [49] Fan AW, Deng JJ, Nakayama A, Liu W. Parametric study on turbulent heat transfer and flow characteristics in a circular tube fitted with louvered strip inserts. International Journal of Heat and Mass Transfer. 2012;55(19–20):5205-13.

                              [50] Fan A, Maruta K, Nakamura H, Liu W. Experimental investigation of flame pattern transitions in a heated radial micro-channel. Applied Thermal Engineering. 2012;47:111-8.

                              [51] Chen BB, Liu ZC, Liu W, Yang JG, Li H, Wang DD. Operational characteristics of two biporous wicks used in loop heat pipe with flat evaporator. International Journal of Heat and Mass Transfer. 2012;55(7–8):2204-7.

                              [52] Chen BB, Liu W, Liu ZC, Li H, Yang JG. Experimental investigation of loop heat pipe with flat evaporator using biporous wick. Applied Thermal Engineering. 2012;42(0):34-40.

                               

                              2011

                               

                              [53] Zhang X, Liu W. THERMAL NON-EQUILIBRIUM MODELING OF COUPLED HEAT AND MASS TRANSFER IN BULK ADSORPTION SYSTEM OF POROUS MEDIA. Journal of Porous Media. 2011;14(6):555-63.

                              [54] Wang Y, Liu Z, Huang S, Liu W, Li W. Experimental investigation of shell-and-tube heat exchanger with a new type of baffles. Heat and Mass Transfer. 2011;47(7):833-9.

                              [55] Wan ZM, Liu J, Wan JH, Tu ZK, Liu W. An overall numerical investigation on heat and mass transfer for miniature flat plate capillary pumped loop evaporator. Thermochimica Acta. 2011;518(1–2):82-8.

                              [56] Luo X, Liu Y, Liu W. A Honeycomb Microchannel Cooling System for Microelectronics Cooling. Heat Transfer Engineering. 2011;32(7-8):616-23.

                              [57] Liu Z, Gai D, Li H, Liu W, Yang J, Liu M. Investigation of impact of different working fluids on the operational characteristics of miniature LHP with flat evaporator. Applied Thermal Engineering. 2011;31(16):3387-92.

                              [58] Liu Y, Luo X, Liu W. Experimental Research on a Honeycomb Microchannel Cooling System. Ieee Transactions on Components Packaging and Manufacturing Technology. 2011;1(9):1378-86.

                              [59] Liu W, Liu ZC, Jia H, Fan AW, Nakayama A. Entransy expression of the second law of thermodynamics and its application to optimization in heat transfer process. International Journal of Heat and Mass Transfer. 2011;54(13–14):3049-59.

                              [60] Guo J, Fan A, Zhang X, Liu W. A numerical study on heat transfer and friction factor characteristics of laminar flow in a circular tube fitted with center-cleared twisted tape. International Journal of Thermal Sciences. 2011;50(7):1263-70.

                              [61] Fan A, Deng J, Guo J, Liu W. A numerical study on thermo-hydraulic characteristics of turbulent flow in a circular tube fitted with conical strip inserts. Applied Thermal Engineering. 2011;31(14-15):2819-28.

                               

                              2010

                               

                              [62] Zheng Y, Ming T, Zhou Z, Yu X, Wang H, Pan Y, et al. Unsteady numerical simulation of solar chimney power plant system with energy storage layer. Journal of the Energy Institute. 2010;83(2):86-92.

                              [63] Tu Z, Liu W, Liu Z, Huang X. Interface stability in a capillary loop undergoing phase changes in non-gravitational conditions. Chin Sci Bull. 2010;55(35):4069-73.

                              [64] Ming T, Zheng Y, Liu J, Liu C, Liu W, Huang S. Heat transfer enhancement by filling metal porous medium in central area of tubes. Journal of the Energy institute. 2010;83(1):17-24.

                              [65] Ming T, Zheng Y, Liu C, Liu W, Pan Y. Simple analysis on thermal performance of solar chimney power generation systems. Journal of the Energy Institute. 2010;83(1):6-11.

                              [66] Liu W, Liu Z, Huang S. Physical quantity synergy in the field of turbulent heat transfer and its analysis for heat transfer enhancement. Chin Sci Bull. 2010;55(23):2589-97.

                              [67] Huang ZF, Nakayama A, Yang K, Yang C, Liu W. Enhancing heat transfer in the core flow by using porous medium insert in a tube. International Journal of Heat and Mass Transfer. 2010;53(5–6):1164-74.

                              [68] Fan A, Maruta K, Nakamura H, Kumar S, Liu W. Experimental investigation on flame pattern formations of DME-air mixtures in a radial microchannel. Combustion and Flame. 2010;157(9):1637-42.

                               

                              2009

                               

                              [69] Zhang X, Liu W, Liu Z. Criterion for Local Thermal Equilibrium in Forced Convection Flow Through Porous Media. Journal of Porous Media. 2009;12(11):1103-11.

                              [70] Zhang C-p, Liu W, Wu F, Guo F-z, Zhang X-q. Identification of complex compliance for regenerator in thermoacoustic resonator system. Journal of Central South University of Technology. 2009;16:320-5.

                              [71] Wan Z, Liu W, Tu Z, Nakayama A. Conjugate numerical analysis of flow and heat transfer with phase change in a miniature flat plate CPL evaporator. International Journal of Heat and Mass Transfer. 2009;52(1):422-30.

                              [72] Nakayama A, Kuwahara F, Liu W. A macroscopic model for countercurrent bioheat transfer in a circulatory system. Journal of Porous Media. 2009;12(4).

                              [73] Liu Z, Liu W, Yang J, Gai D. Design and Experimental Research of a Flat-Plate Type CPL with a Porous Wick in the Condenser. Journal of Enhanced Heat Transfer. 2009;16(2):161-70.

                              [74] Liu W, Liu Z, Yang K, Tu Z. Phase change driving mechanism and modeling for heat pipe with porous wick. Chin Sci Bull. 2009;54(21):4000-4.

                              [75] Liu W, Liu Z, Wang Y, Huang S. Flow mechanism and heat transfer enhancement in longitudinal-flow tube bundle of shell-and-tube heat exchanger. Science in China Series E: Technological Sciences. 2009;52(10):2952-9.

                              [76] Liu W, Liu Z, Wang Y, Huang S. Flow mechanism and heat transfer enhancement in longitudinal-flow tube bundle of shell-and-tube heat exchanger. Science in China Series E-Technological Sciences. 2009;52(10):2952-9.

                              [77] Liu W, Liu Z, Ming T, Guo Z. Physical quantity synergy in laminar flow field and its application in heat transfer enhancement. International Journal of Heat and Mass Transfer. 2009;52(19-20):4669-72.

                              [78] Liu W, Liu Z, Guo Z. Physical quantity synergy in laminar flow field of convective heat transfer and analysis of heat transfer enhancement. Chin Sci Bull. 2009;54(19):3579-86.

                              [79] Gai D, Liu Z, Liu W, Yang J. Operational characteristics of miniature loop heat pipe with flat evaporator. Heat and Mass Transfer. 2009;46(2):267-75.

                              [80] Gai D, Liu W, Liu Z, Yang J. Temperature Oscillation of mLHP with Flat Evaporator. Heat Transfer Research. 2009;40(4):321-32.

                              [81] Fan A, Minaev S, Sereshchenko E, Fursenko R, Kumar S, Liu W, et al. Experimental and numerical investigations of flame pattern formations in a radial microchannel. Proceedings of the Combustion Institute. 2009;32:3059-66.

                               

                              2008

                               

                              [82] Zhang X, Liu W. New Criterion for Local Thermal Equilibrium in Porous Media. Journal of Thermophysics and Heat Transfer. 2008;22(4):649-53.

                              [83] Ming T, Liu W, Xu G, Xiong Y, Guan X, Pan Y. Numerical simulation of the solar chimney power plant systems coupled with turbine. Renewable Energy. 2008;33(5):897-905.

                              [84] Ming T, Liu W, Pan Y, Xu G. Numerical analysis of flow and heat transfer characteristics in solar chimney power plants with energy storage layer. Energy Conversion and Management. 2008;49(10):2872-9.

                              [85] Liu Z, Liu W, Yang J. Experimental investigation of new flat-plate-type capillary pumped loop. Journal of Thermophysics and Heat Transfer. 2008;22(1):98-104.

                              [86] Liu W, Yang K. Mechanism and numerical analysis of heat transfer enhancement in the core flow along a tube. Science in China Series E-Technological Sciences. 2008;51(8):1195-202.

                              [87] Fan A, Minaev S, Kumar S, Liu W, Maruta K. Regime diagrams and characteristics of flame patterns in radial microchannels with temperature gradients. Combustion and Flame. 2008;153(3):479-89.

                              [88] Chen W, Liu W. Numerical analysis of heat transfer in a passive solar composite wall with porous absorber. Applied Thermal Engineering. 2008;28(11-12):1251-8.

                               

                              2007

                               

                              [89] Wan Z, Liu W, Zheng Z, Nakayama A. Heat transfer with flow and phase change in an evaporator of miniature flat plate capillary pumped loop. Journal of Thermal Science. 2007;16(3):254-63.

                              [90] Liu Z, Liu W, Nakayama A. Flow and heat transfer analysis in porous wick of CPL evaporator based on field synergy principle. Heat and mass transfer. 2007;43(12):1273-81.

                              [91] Fan A, Minaev S, Kumar S, Liu W, Maruta K. Experimental study on flame pattern formation and combustion completeness in a radial microchannel. Journal of Micromechanics and Microengineering. 2007;17(12):2398-406.

                               

                              2006

                               

                              [92] Nakayama A, Kuwahara F, Liu W. An integrated 2-D Navier–Stokes equation and its application to 3-D internal flows. International Journal of Computational Fluid Dynamics. 2006;20(2):99-104.

                              [93] Ming T, Liu W, Xu G. Analytical and numerical investigation of the solar chimney power plant systems. International Journal of Energy Research. 2006;30(11):861-73.

                              [94] Chen W, Liu W, Liu B. Numerical and experimental analysis of heat and moisture content transfer in a lean-to greenhouse. Energy and buildings. 2006;38(2):99-104.

                              [95] Chen W, Liu W. Numerical simulation of the airflow and temperature distribution in a lean-to greenhouse. Renewable energy. 2006;31(4):517-35.

                               

                              2005

                               

                              [96] Liu BC, Liu W, Peng SW. Study of heat and moisture transfer in soil with a dry surface layer. International Journal of Heat and Mass Transfer. 2005;48(21–22):4579-89.

                              [97] Huang X, Liu W, Nakayama A, Peng S. Modeling for heat and mass transfer with phase change in porous wick of CPL evaporator. Heat and mass transfer. 2005;41(7):667-73.

                               

                              2004

                               

                              [98] Yu B, Liu W. Fractal analysis of permeabilities for porous media. AIChE journal. 2004;50(1):46-57.

                              [99] Yang K, Liu W. A novel model of the pulse decay method for measurement of local tissue blood perfusion. Medical engineering & physics. 2004;26(3):215-23.

                              [100] Chen W, Liu W. Numerical and experimental analysis of convection heat transfer in passive solar heating room with greenhouse and heat storage. Solar Energy. 2004;76(5):623-33.

                              [101] Chen W, Liu W. Numerical analysis of heat transfer in a composite wall solar-collector system with a porous absorber. Applied Energy. 2004;78(2):137-49.

                               

                              2003

                               

                              [102] Zeng T, Liu W. Phonon heat conduction in micro-and nano-core-shell structures with cylindrical and spherical geometries. Journal of applied physics. 2003;93(7):4163-8.

                              [103] Shen S, Liu W, Tao W. Analysis of field synergy on natural convective heat transfer in porous media. International communications in heat and mass transfer. 2003;30(8):1081-90.

                              [104] Liu W, Huang X, Riffat S. Heat and mass transfer with phase change in a rectangular enclosure packed with unsaturated porous material. Heat and mass transfer. 2003;39(3):223-30.

                               

                              Before 2003

                               

                              [105] Liu W, Shen S, Riffat S. Heat transfer and phase change of liquid in an inclined enclosure packed with unsaturated porous media. International journal of heat and mass transfer. 2002;45(26):5209-19.

                              [106] Liu W, Zhao X, Mizukami K. 2D numerical simulation for simultaneous heat, water and gas migration in soil bed under different environmental conditions. Heat and mass Transfer. 1998;34(4):307-16.

                              [107] Peng S, Mizukami K, Liu W, Sebe N, Takeba T. An experimental study of condensation heat transfer in a horizontally rotating cylinder with a scraper. Experimental thermal and fluid science. 1997;14(2):205-12.

                              [108] Liu W, Peng S, Mizukami K. Moisture evaporation and migration in thin porous packed bed influenced by ambient and operating conditions. International journal of energy research. 1997;21(1):41-53.

                              [109] Peng S, Liu W. Mathematical Modeling of Moisture Desorption in a Porous Media. International journal of energy research. 1996;20.

                              [110] Liu W, Peng S, Mizukami K. A general mathematical modelling for heat and mass transfer in unsaturated porous media: an application to free evaporative cooling. Heat and Mass Transfer. 1995;31(1):49-55.

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