表面润湿性影响池沸腾传热的研究进展
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摘要
沸腾传热主要受汽泡产生、成长和脱离的控制,而这些汽泡行为与表面润湿性密切相关,通过改变加热面的润湿性,可在一定程度上调节汽泡在加热面上的发展过程,从而影响沸腾传热。介绍了不同润湿性表面及其对沸腾传热的强化机理和气泡动力学,综述了近年来通过表面润湿改性影响沸腾传热的研究进展,并指明表面润湿性与多尺度结构相结合的沸腾传热的研究新动向,为未来利用润湿性强化沸腾传热提供了一个较为清晰、全面的理论基础。
Boiling heat transfer is mainly controlled by bubble generation,growth and detachment,and these bubble behaviors are related to the surface wettability. By changing the wettability of the heating surface,the development of the bubble on the heating surface can be adjusted to a certain extent,thus affecting the boiling heat transfer. In this paper,the enhancement mechanism of boiling heat transfer and bubble dynamics on different wettability surfaces are introduced. The research progress of boiling heat transfer through modified surface with different wettability in recent years is reviewed. It is shown that the wettability application on boiling heat transfer is the new research trend,this review work is expected to provide a clear and more comprehensive theoretical basis for the boiling heat transfer enhancement using wettability in the future
Boiling heat transfer is mainly controlled by bubble generation,growth and detachment,and these bubble behaviors are related to the surface wettability. By changing the wettability of the heating surface,the development of the bubble on the heating surface can be adjusted to a certain extent,thus affecting the boiling heat transfer. In this paper,the enhancement mechanism of boiling heat transfer and bubble dynamics on different wettability surfaces are introduced. The research progress of boiling heat transfer through modified surface with different wettability in recent years is reviewed. It is shown that the wettability application on boiling heat transfer is the new research trend,this review work is expected to provide a clear and more comprehensive theoretical basis for the boiling heat transfer enhancement using wettability in the future
引文
[1]赵红霞,韩吉田,徐永田,等.强化沸腾传热表面的研究进展[C]//全国水动力学术会议暨两岸船舶与海洋工程水动力学研讨会,2008:1009-1016.ZHAO Hong-xia,HAN Ji-tian,XU Yong-tian,et al. Research anddevelopment of enhanced boiling surface[C]//National Hydrody-namic Conference and Cross-Strait Ship and Ocean EngineeringHydrodynamics Symposium. 2008:1009-1016.
[2] MARCEL C,CLAUSSE A,FRANKIEWICZ C,et al. Numerical in-vestigation into the effect of surface wettability in pool boiling heattransfer with a stochastic-automata model[J]. International Journalof Heat and Mass Transfer,2017,111:657-665.
[3] TAKATA Y,TAKATA K,KAIJIMA K,et al. Enhancement of heattransfer with liquid-vapor phase change by photo-induced hydro-philicity[C]//Proceedings of the 33rd National heat transfer con-ference,Japan:1999.
[4] KIM T J,JI M K,JI H K,et al. Orientation effects on bubble dy-namics and nucleate pool boiling heat transfer of graphene-modifiedsurface[J]. International Journal of Heat and Mass Transfer,2017,108:1393-1405.
[5]李小兵,刘莹.材料表面润湿性的控制与制备技术[J].材料工程,2008(4):74-80.LI Xiao-bing,LIU Ying. Control and prepartion to wettability ofmaterial surfaces[J]. Journal of Materials Engineering,2008(4):74-80.
[6]宋金龙.工程金属材料极端润湿性表面制备及应用研究[D].大连:大连理工大学,2015.SONG Jin-long. Fabrication and application of extreme wettabilitysurfaces on engineering metal materials[D]. Dalian:Dalian Uni-versity of Technology,2015.
[7]王现宝.多尺度仿生交错润湿性表面沸腾传热性能及机理[D].吉林:吉林大学,2015.WANG Xian-bao. Boiling heat transfer performance and mechanismof biomimetic multi-scale interlaced wettability surface[D]. Jilin:Jilin University,2015.
[8] HONG S J,AN S,PARK H G,et al. Enhancement of critical heatflux and superheat through controlled wettability of cuprous-oxidefractal-like nanotextured surfaces in pool boiling[J]. InternationalJournal of Heat and Mass Transfer,2017,107:105-111.
[9] LIANG G,MUDAWAR I. Pool boiling critical heat flux(CHF)-Part 2:Assessment of models and correlations[J]. InternationalJournal of Heat and Mass Transfer,2018,117:1368-1383..
[10]赵耀华.沸腾换热及临界热流的动态微液层模型[J].工程热物理学报,2002,23:85-88.ZHAO Yao-hua. The dynamic microlayer model for nucleate boil-ing heat transfer and CHF[J]. Journal of Engineering Thermo-physics,2002,23:85-88.
[11]郑文秀,厉思杰,白博峰.壁面润湿性对沸腾核化的影响[J].工程热物理学报,2016,37(1):111-115.ZHENG Wen-xiu,LI Si-jie,BAI Bo-feng. Effects of surface wetta-bility on boiling nucleation[J]. Journal of Engineering Thermo-physics,2016,37(1):111-115.
[12] HAI T P,CANEY N,MARTY P,et al. Surface wettability controlby nanocoating:The effects on pool boiling heat transfer and nu-cleation mechanism[J]. International Journal of Heat and MassTransfer,2009,52:5459-5471.
[13] J0 H J,PARK H S,KIM M H. Single bubble dynamics on hydro-phobic–hydrophilic mixed surfaces[J]. International Journal ofHeat and Mass Transfer,2016,93:554-565.
[14] BETZ A R,JENKINS J,KIM C J,et al. Boiling heat transfer onsuperhydrophilic,superhydrophobic,and superbiphilic surfaces[J]. International Journal of Heat and Mass Transfer,2013,57(2):733-741.
[15]龚帅.亲疏水性对池沸腾传热影响的格子Boltzmann方法研究[D].上海:上海交通大学,2015.GONG Shuai. Numerical investigations of surface wettabilityeffects in pool boiling heat transfer by lattice Boltzmann method[D]. Shanghai:Shanghai Jiao Tong University,2015.
[16] SEO G H,JEONG U,HONG H S,et al. Effects of layer-by-layerassembled PEI/MWCNT surfaces on enhanced pool boiling criti-cal heat flux[J]. International Journal of Heat and Mass Transfer,2017,109:564-576.
[17]徐鹏飞,李强,宣益民.超亲水多孔表面制备及其池沸腾换热研究[J].工程热物理学报,2014,35(8):1606-1609.XU Peng-fei,LI Qiang,XUAN Yi-min. Preparation and pool boil-ing heat transfer test of super-hydrophilic surface[J]. Journal ofEngineering Thermophysics,2014,35(8):1606-1609.
[18] HONG S J,KIM M W,KIM K,et al. Effects of capillarity on poolboiling using nanotextured surfaces through electrosprayed BiVO4nanopillars[J]. Chemical Engineering Science,2017,17:1-27.
[19]郑晓欢,纪献兵,王野,等.超亲/疏水性表面池沸腾传热研究[J].化工进展,2016,35(12):3793-3798.ZHENG Xiao-huan,JI Xian-bing,WANG Ye,et al. Pool boilingheat transfer on superhydrophilic and superhydrophobic Surfaces[J]. Chemical Industry and Engineering Progress,2016,35(12):3793-3798.
[20] JAIKUMAR A,GUPTA A,KANDLIKAR S G,et al. Scale effectsof graphene and graphene oxide coatings on pool boiling enhance-ment mechanisms[J]. International Journal of Heat and MassTransfer,2017,109:357-366.
[21] BOURDON B,MARCO P D,RIOBOO R,et al. Enhancing the on-set of pool boiling by wettability modification on nanometricallysmooth surfaces[J]. International Communications in Heat andMass Transfer,2013,45(7):11-15.
[22] ZHANG B J,KIM K J. Nucleate pool boiling heat transfer aug-mentation on hydrophobic self-assembly mono-layered aluminanano-porous surfaces[J]. International Journal of Heat and MassTransfer,2014,73(9):551-561.
[23] TEODORI E,VALENTE T,MALAYAS I,et al. Effect of extremewetting scenarios on pool boiling conditions[J]. Applied ThermalEngineering,2017,115:1424-1437.
[24] HSU C C,LEE M R,WU C H,et al. Effect of interlaced wettabili-ty on horizontal copper cylinders in nucleate pool boiling[J]. Ap-plied Thermal Engineering,2017,112:1187-1194.
[25] BETZ A R,XU J,QIU H,et al. Do surfaces with mixed hydrophil-ic and hydrophobic areas enhance pool boiling[J]. Applied Phys-ics Letters,2010,97(14):1-3.
[26] KUMAR C S S,CHANG Y W,CHEN P H. Effect of heterogene-ous wettable structures on pool boiling performance of cylindricalcopper surfaces[J]. Applied Thermal Engineering,2017,127:1184-1193.
[27] ZUPANˇCIˇCM,STEINBCHER M,GREGORˇCIˇCP,et al. En-hanced pool-boiling heat transfer on laser-made hydrophobic/su-perhydrophilic polydimethylsiloxane-silica patterned surfaces[J].Applied Thermal Engineering,2015,91:288-297.
[28]柴永志,张伟,李亚,等.非均匀润湿性微通道表面池沸腾换热特性[J].化工学报,2017,68(5):1852-1859.CHAI Yong-zhi,ZHANG Wei,LI Ya,et al. Pool boiling heattransfer on heterogeneous wetting microchannel surfaces[J]. CI-ESC Journal,2017,68(5):1852-1859.
[29] COYLE C,O'HANLEY H,PHILLIPS B,et al. Effects of Hydro-phobic Surface Patterning on Boiling Heat Transfer and CriticalHeat Flux of Water at Atmospheric Pressure[C]//ASME 2013Power Conference,Boston,2013.
[30] ZHANG B J,GANGULY R,KIM K J,et al. Control of pool boilingheat transfer through photo-induced wettability change of titaniananotube arrayed surface[J]. International Communications inHeat and Mass Transfer,2017,81:124-130.
[31] TAKATA Y,HIDAKA S,CAO J M,et al. Effect of surface wetta-bility on boiling and evaporation[J]. Energy,2005,30:209-220.
[32] JIN M K,DONG I Y,PARK H S,et al. Smart surface in pool boil-ing:Thermally-induced wetting transition[J]. International Jour-nal of Heat and Mass Transfer,2017,109:231-241.
[33]杨卧龙,纪献兵,徐进良.从自然到仿生到实际应用的超亲水表面[J].化学进展,2016,28(6):763-772.YANG Wo-long,JI Xian-bing,XU Jin-liang. Superhydrophilicsurfaces:From nature to biomimetics to application[J]. Progressin Chemistry,2016,28(6):763-772.
[34] DAS S,SAHA B,BHAUMIK S. Experimental study of nucleatepool boiling heat transfer of water by surface functionalization withSi O2nanostructure[J]. Experimental Thermal and Fluid Science,2017,81:454-465.
[35] ZHANG F,JACOBI A M. Aluminum surface wettability changesby pool boiling of nanofluids[J]. Colloids and Surfaces A:Physi-cochemical and Engineering Aspects,2016,506:438-444.
[36]赵紫薇,薛强,纪献兵,等.烧结多尺度表面与光表面池沸腾换热特性比较[J].工程热物理学报,2013,34(4):680-683.ZHAO Zi-wei,XUE Qiang,JI Xian-bing,et al. Comparison of thepool boiling heat transfer on plain and multi-scale porous coatingsurfaces[J]. Journal of Engineering Thermophysics,2013,34(4):680-683.
[2] MARCEL C,CLAUSSE A,FRANKIEWICZ C,et al. Numerical in-vestigation into the effect of surface wettability in pool boiling heattransfer with a stochastic-automata model[J]. International Journalof Heat and Mass Transfer,2017,111:657-665.
[3] TAKATA Y,TAKATA K,KAIJIMA K,et al. Enhancement of heattransfer with liquid-vapor phase change by photo-induced hydro-philicity[C]//Proceedings of the 33rd National heat transfer con-ference,Japan:1999.
[4] KIM T J,JI M K,JI H K,et al. Orientation effects on bubble dy-namics and nucleate pool boiling heat transfer of graphene-modifiedsurface[J]. International Journal of Heat and Mass Transfer,2017,108:1393-1405.
[5]李小兵,刘莹.材料表面润湿性的控制与制备技术[J].材料工程,2008(4):74-80.LI Xiao-bing,LIU Ying. Control and prepartion to wettability ofmaterial surfaces[J]. Journal of Materials Engineering,2008(4):74-80.
[6]宋金龙.工程金属材料极端润湿性表面制备及应用研究[D].大连:大连理工大学,2015.SONG Jin-long. Fabrication and application of extreme wettabilitysurfaces on engineering metal materials[D]. Dalian:Dalian Uni-versity of Technology,2015.
[7]王现宝.多尺度仿生交错润湿性表面沸腾传热性能及机理[D].吉林:吉林大学,2015.WANG Xian-bao. Boiling heat transfer performance and mechanismof biomimetic multi-scale interlaced wettability surface[D]. Jilin:Jilin University,2015.
[8] HONG S J,AN S,PARK H G,et al. Enhancement of critical heatflux and superheat through controlled wettability of cuprous-oxidefractal-like nanotextured surfaces in pool boiling[J]. InternationalJournal of Heat and Mass Transfer,2017,107:105-111.
[9] LIANG G,MUDAWAR I. Pool boiling critical heat flux(CHF)-Part 2:Assessment of models and correlations[J]. InternationalJournal of Heat and Mass Transfer,2018,117:1368-1383..
[10]赵耀华.沸腾换热及临界热流的动态微液层模型[J].工程热物理学报,2002,23:85-88.ZHAO Yao-hua. The dynamic microlayer model for nucleate boil-ing heat transfer and CHF[J]. Journal of Engineering Thermo-physics,2002,23:85-88.
[11]郑文秀,厉思杰,白博峰.壁面润湿性对沸腾核化的影响[J].工程热物理学报,2016,37(1):111-115.ZHENG Wen-xiu,LI Si-jie,BAI Bo-feng. Effects of surface wetta-bility on boiling nucleation[J]. Journal of Engineering Thermo-physics,2016,37(1):111-115.
[12] HAI T P,CANEY N,MARTY P,et al. Surface wettability controlby nanocoating:The effects on pool boiling heat transfer and nu-cleation mechanism[J]. International Journal of Heat and MassTransfer,2009,52:5459-5471.
[13] J0 H J,PARK H S,KIM M H. Single bubble dynamics on hydro-phobic–hydrophilic mixed surfaces[J]. International Journal ofHeat and Mass Transfer,2016,93:554-565.
[14] BETZ A R,JENKINS J,KIM C J,et al. Boiling heat transfer onsuperhydrophilic,superhydrophobic,and superbiphilic surfaces[J]. International Journal of Heat and Mass Transfer,2013,57(2):733-741.
[15]龚帅.亲疏水性对池沸腾传热影响的格子Boltzmann方法研究[D].上海:上海交通大学,2015.GONG Shuai. Numerical investigations of surface wettabilityeffects in pool boiling heat transfer by lattice Boltzmann method[D]. Shanghai:Shanghai Jiao Tong University,2015.
[16] SEO G H,JEONG U,HONG H S,et al. Effects of layer-by-layerassembled PEI/MWCNT surfaces on enhanced pool boiling criti-cal heat flux[J]. International Journal of Heat and Mass Transfer,2017,109:564-576.
[17]徐鹏飞,李强,宣益民.超亲水多孔表面制备及其池沸腾换热研究[J].工程热物理学报,2014,35(8):1606-1609.XU Peng-fei,LI Qiang,XUAN Yi-min. Preparation and pool boil-ing heat transfer test of super-hydrophilic surface[J]. Journal ofEngineering Thermophysics,2014,35(8):1606-1609.
[18] HONG S J,KIM M W,KIM K,et al. Effects of capillarity on poolboiling using nanotextured surfaces through electrosprayed BiVO4nanopillars[J]. Chemical Engineering Science,2017,17:1-27.
[19]郑晓欢,纪献兵,王野,等.超亲/疏水性表面池沸腾传热研究[J].化工进展,2016,35(12):3793-3798.ZHENG Xiao-huan,JI Xian-bing,WANG Ye,et al. Pool boilingheat transfer on superhydrophilic and superhydrophobic Surfaces[J]. Chemical Industry and Engineering Progress,2016,35(12):3793-3798.
[20] JAIKUMAR A,GUPTA A,KANDLIKAR S G,et al. Scale effectsof graphene and graphene oxide coatings on pool boiling enhance-ment mechanisms[J]. International Journal of Heat and MassTransfer,2017,109:357-366.
[21] BOURDON B,MARCO P D,RIOBOO R,et al. Enhancing the on-set of pool boiling by wettability modification on nanometricallysmooth surfaces[J]. International Communications in Heat andMass Transfer,2013,45(7):11-15.
[22] ZHANG B J,KIM K J. Nucleate pool boiling heat transfer aug-mentation on hydrophobic self-assembly mono-layered aluminanano-porous surfaces[J]. International Journal of Heat and MassTransfer,2014,73(9):551-561.
[23] TEODORI E,VALENTE T,MALAYAS I,et al. Effect of extremewetting scenarios on pool boiling conditions[J]. Applied ThermalEngineering,2017,115:1424-1437.
[24] HSU C C,LEE M R,WU C H,et al. Effect of interlaced wettabili-ty on horizontal copper cylinders in nucleate pool boiling[J]. Ap-plied Thermal Engineering,2017,112:1187-1194.
[25] BETZ A R,XU J,QIU H,et al. Do surfaces with mixed hydrophil-ic and hydrophobic areas enhance pool boiling[J]. Applied Phys-ics Letters,2010,97(14):1-3.
[26] KUMAR C S S,CHANG Y W,CHEN P H. Effect of heterogene-ous wettable structures on pool boiling performance of cylindricalcopper surfaces[J]. Applied Thermal Engineering,2017,127:1184-1193.
[27] ZUPANˇCIˇCM,STEINBCHER M,GREGORˇCIˇCP,et al. En-hanced pool-boiling heat transfer on laser-made hydrophobic/su-perhydrophilic polydimethylsiloxane-silica patterned surfaces[J].Applied Thermal Engineering,2015,91:288-297.
[28]柴永志,张伟,李亚,等.非均匀润湿性微通道表面池沸腾换热特性[J].化工学报,2017,68(5):1852-1859.CHAI Yong-zhi,ZHANG Wei,LI Ya,et al. Pool boiling heattransfer on heterogeneous wetting microchannel surfaces[J]. CI-ESC Journal,2017,68(5):1852-1859.
[29] COYLE C,O'HANLEY H,PHILLIPS B,et al. Effects of Hydro-phobic Surface Patterning on Boiling Heat Transfer and CriticalHeat Flux of Water at Atmospheric Pressure[C]//ASME 2013Power Conference,Boston,2013.
[30] ZHANG B J,GANGULY R,KIM K J,et al. Control of pool boilingheat transfer through photo-induced wettability change of titaniananotube arrayed surface[J]. International Communications inHeat and Mass Transfer,2017,81:124-130.
[31] TAKATA Y,HIDAKA S,CAO J M,et al. Effect of surface wetta-bility on boiling and evaporation[J]. Energy,2005,30:209-220.
[32] JIN M K,DONG I Y,PARK H S,et al. Smart surface in pool boil-ing:Thermally-induced wetting transition[J]. International Jour-nal of Heat and Mass Transfer,2017,109:231-241.
[33]杨卧龙,纪献兵,徐进良.从自然到仿生到实际应用的超亲水表面[J].化学进展,2016,28(6):763-772.YANG Wo-long,JI Xian-bing,XU Jin-liang. Superhydrophilicsurfaces:From nature to biomimetics to application[J]. Progressin Chemistry,2016,28(6):763-772.
[34] DAS S,SAHA B,BHAUMIK S. Experimental study of nucleatepool boiling heat transfer of water by surface functionalization withSi O2nanostructure[J]. Experimental Thermal and Fluid Science,2017,81:454-465.
[35] ZHANG F,JACOBI A M. Aluminum surface wettability changesby pool boiling of nanofluids[J]. Colloids and Surfaces A:Physi-cochemical and Engineering Aspects,2016,506:438-444.
[36]赵紫薇,薛强,纪献兵,等.烧结多尺度表面与光表面池沸腾换热特性比较[J].工程热物理学报,2013,34(4):680-683.ZHAO Zi-wei,XUE Qiang,JI Xian-bing,et al. Comparison of thepool boiling heat transfer on plain and multi-scale porous coatingsurfaces[J]. Journal of Engineering Thermophysics,2013,34(4):680-683.