夏国栋 教授、博士生导师
联系电话:010-67396661-8301
通讯地址:北京市朝阳区平乐园100号
电子邮箱:xgd@bjut.edu.cn
教育背景
1982年--1987年 清华大学 机械工程专业 学士
1991年--1994年 东北电力大学 电厂热能动力工程专业 硕士
1994年--1996年 西安交通大学 热能工程专业 博士
科研工作经历
1996年--1998年 北京理工大学 博士后
1998年-现在 威尼斯wns.8885556 教师
2000年-2001年 德国汉诺威大学 访问学者
研究方向
1.多相流与传热
2.微尺度流动与传热
3.微电子器件冷却技术
4.节能与可再生能源利用
主要科研成果
2017年
1.XiaG D, Cao L, Bi G L. A review on battery thermal management in electric vehicle application.Journal of Power Sources, 2017, 367: 90-105.
Ma DD, Xia G D, Wang J, Yang Y C, Jia YT, Zong L X. An experimental study on hydrothermal performance of microchannelheat sinks with 4-ports and offset zigzag channels. Energy Conversion and Management, 2017, 152:157-165
2.XiaG D, Chen Z, Cheng L X, Ma D D, Zhai Y L. Micro-PIV visualization and numerical simulationof flowand heat transfer in three micro pin-fin heat sinks. International Journal of Thermal Sciences, 2017, 119:9-23.
3.XiaG D, Du M, Cheng L X, Wang W. Experimentalstudy on the nucleate boiling heat transfer characteristics of a water-basedmulti-walled carbon nanotubes nanofluid in a confined space. InternationalJournal of Heat and Mass Transfer, 2017, 113:59-69.
4.Xia G D,Wang W, Cheng L X, Ma D D. Visualization study on the instabilities ofphase-change heat transfer in a flat two-phase closed thermosyphon[J]. AppliedThermal Engineering, 2017, 116:392-405.
5.ChengL X, Xia G D. Fundamental issues,mechanisms and models of flow boiling heat transfer in microscale channels[J]. InternationalJournal of Heat and Mass Transfer, 2017, 108:97-127.
6.Li Y F, Xia G D, Jia Y T, Cheng Y, Wang J.Experimental investigation of flow boiling performance in microchannels with andwithout triangular cavities – A comparative study[J], International Journal ofHeat and Mass Transfer, 2017, 108:1511-1526.
7.Li Y F, Xia G D, Jia Y T, Ma D D, Cai B, WangJ. Effect of geometric configuration on the laminar flow and heat transfer inmicrochannel heat sink with cavities and fins[J]. Numerical HeatTransfer, Part A: Applications, 2017, 71 (5): 528-546.
8.Zhai Y L,Xia G D,Li Z H,Wang H,Experimentalinvestigation and empirical correlations of single and laminar convective heattransfer in microchannel heat sinks[J]. ExperimentalThermal and Fluid Science, 2017, 83:207-214.
9.Wang J, Luo S, Xia G D. Thermophoretic force on nanocylinders in the free moleculeregime[J]. PhysicalReview E, 2017,95,033101.
2016年
1.MaD D, Xia G D, Li Y F, Jia Y T, Wang J. Effects of structural parameterson fluid flow and heat transfer characteristics in microchannel with offsetzigzag grooves in sidewall. International Journal of Heat and Mass Transfer, 2016, 101: 427-435.
2.MaD D, Xia G D, Li Y F, Jia Y T, Wang J. Design study of micro heat sinkconfigurations with offset zigzag channel for specific chips geometrics. EnergyConversion and Management, 2016, 127: 160-169.
3.ChaiL, Xia G D, Wang H S. Laminar flow and heat transfer characteristics ofinterrupted microchannel heat sink with ribs in the transverse microchambers.International Journal of Thermal Science, 2016,110:1-11.
4.Chai L, Xia G D,Wang H S. Numerical study of laminar flow and heat transfer in microchannelheat sink with offset ribs on sidewalls. Applied Thermal Engineering, 2016, 92:32-41.
5.ChaiL, Xia G D, Wang H S. Parametric study on thermal and hydrauliccharacteristics of laminar flow in microchannel heat sink with fan-shaped ribson sidewalls–Part 1: Heat transfer. International Journal of Heat and MassTransfer, 2016, 97: 1069-1080.
6.ChaiL, Xia G D, Wang H S. Parametric study on thermal and hydrauliccharacteristics of laminar flow in microchannel heat sink with fan-shaped ribson sidewalls–Part 2: Pressure drop. International Journal of Heat and MassTransfer, 2016, 97: 1081-1090.
7.ChaiL, Xia G D, Wang H S. Parametric study on thermal and hydrauliccharacteristics of laminar flow in microchannel heat sink with fan-shaped ribson sidewalls–Part 3: Performance evaluation. International Journal of Heat andMass Transfer, 2016, 97: 1091-1101.
8.LiY F, Xia G D, Ma D D, et al. Characteristics of laminar flow and heattransfer in microchannel heat sink with triangular cavities and rectangularribs. International Journal of Heat and Mass Transfer, 2016,98: 17-28.
9.Zhai Y L, Xia G D, Chen Z, Li Z H. Micro-PIVstudy of flow and the formation of vortex in micro heat sinks with cavities andribs. International Journal of Heat and Mass Transfer, 2016,98: 380-389.
10.XiaG D, Li Y F, Wang J, et al. Numerical andexperimental analyses of planar micromixer with gaps and baffles based on fieldsynergy principle. International Communications in Heat and Mass Transfer, 2016, 71: 188-196.
11.XiaG D, Liu R, Wang J, Du M. The characteristicsof convective heat transfer in microchannel heat sinks using Al2O3and TiO2 nanofluids. International Communications in Heat and Mass Transfer, 2016, 76:256-264.
12.LuoS, Wang J, Xia G D, Li Z G. Lift Force on Nanoparticles in Shear Flowsof Dilute Gases: Negative or Positive. Journal of fluid mechanics, 2016, 795:443-454.
13.LuoS, Wang J, Xia G D, Li Z G. Lift force on spherical nanoparticles inshear flows of rarefied binary gas mixtures. Journal of fluid mechanics, 2016, 809:345-359.
14.Zhai Y L, Xia G D, Li Z H, Wang H. Anovel flowarrangement of staggered flow in double-layered microchannelheat sinks for microelectronic cooling. International Communications in Heatand Mass Transfer, 2016, 79:98-104.
15.Xia G D, Jia Y T, Li Y T, Ma D D, Cai B. Numerical simulation andmultiobjective optimization of a microchannel heat sink with arcshaped groovesand ribs. Numerical Heat Transfer, Part A: Applications, 2016, 70:1041-1055
2015年
1.LiuX F, Xia G D, Yang G. Experimental study on the characteristics ofair-water two-phaseflow in verticalhelical rectangular channel, International Journal of Multiphase Flow, 2015, 73:227-237
2.ZhaiY L, Xia G D, Liu X F, et al. Characteristics of Entropy generation andheat transfer in double-layered micro heat sinks with complex structure. EnergyConversion and Management, 2015, 103:477-486.
3.ZhaiY L, Xia G D, Liu X F, et al. Heat transferenhancement of Al2O3-H2O nanofluids flowingthrough a micro heat sink with complex structure. Internationalcommunications in heat and mass transfer, 2015,66:158-166.
4.ZhouM Z, Xia G D, Chai L. Heat transfer performance of submerged impingingjet using silver nanofluids. Heat & Mass Transfer, 2015,51(2):221-229.
5.JiaoY G, Xia G D, Huang S G. Heat transfer characteristics of thewickless jacket-type radial heat pipe. Heat Transfer Research, 2015,46: 751-763.
6.XiaG D, Ma D D, Zhai Y L, Wang W. Effects ofdifferent structures and allocations on fluid flow and heat transfer performancein 3D-IC integrated micro-channel interlayer cooling. International Journal ofHeat and Mass Transfer, 2015, 91: 1167-1175
7.Xia G D,Jiang J, Wang J, et al. Effects of differentgeometric structures on fluid flow and heat transfer performance in microchannelheat sinks. International Journal of Heat and Mass Transfer, 2015, 80: 439-447.
8.ZhaiY L, Xia G D, Liu X F, et al. Exergy analysis and performance evaluationof flow and heat transfer in different micro heat sinks with complex structure.International Journal of Heat and Mass Transfer, 2015,84:293-303.
9.XiaG D, Ma D D. Experimental and numerical studyof fluid flow and heat transfer characteristics in microchannel heat sink withcomplex structure. Energy Conversion and Management. 2015,105:848-857.
10.XiaG D, Li Y F, Wang J. Numerical andexperimental analyses of planar micromixer with gaps and baffles based on fieldsynergy principle. International Communication in Heat and Mass Transfer, 2015, 71:188-196.
11.ChaiL, Wang L, Zhou M Z, Xia G D. Two-phase flow pattern and pressure dropin silicon multi-microchannel with expansion–constriction cross-section.Experimental Thermal and Fluid Science, 2015,60:241-251.
12.Xia G D,Zhang Y Q, Wu Y T, et al. Experimental study on theperformance of single-screw expander with different inlet vapor dryness.Applied Thermal Engineering, 2015, 87:34-40
2014年
1.ZhaiY L, Xia G D, Liu X F, et al. Heat transfer in the microchannels with fan-shaped reentrantcavities and different ribs based on field synergy principle and entropygeneration analysis. International Journal ofHeat and Mass Transfer, 2014, 68: 224-233.
2.JiaoY G, Xia G D, Wang W G. Transientand isothermal characteristics of a particular heat pipe.International Communications in Heat and Mass Transfer,2014, 54: 42-47.
3.XiaG D, Liu X F. An investigation of two-phase flow pressuredrop in helical rectangular channel. International Communications in Heat andMass Transfer, 2014, 54:33-41.
4.ChaiL, Xia G D, Wang L, et al. Gas–liquidtwo-phase flow patterns in microchannels with reentrant cavities in sidewall.Experimental Thermal and Fluid Science, 2014,53: 86-92.
5.XiaG D, Liu X F, Zhai Y, L et al. Single-phaseand two-phase flows through helical rectangular channels in single screwexpander prototype. Journal of Hydrodynamics, Ser. B, 2014, 26(1): 114-121.
6.Xia G D, Jiang H M, Liu R, et al. Effectsof surfactant on the stability and thermal conductivity of Al2O3/de-ionizedwater nanofluids.International Journal of Thermal Science, 2014,48:118-124.
7.LiuX F, Xia G D, Zhai Y L, et al. Numerical analysis ofthe two-phase pressure drop and liquid distribution in single-screw expanderprototype. Chinese Science Bulletin, 59(33):4388-4396, 2014.
8.Zhang Y Q, Wu Y T, Xia GD, et al. Development and experimental study on organic Rankine cycle systemwith single-screw expander for waste heat recovery from exhaust of dieselengine. Energy. 2014, 77: 499-508.
2013年
1.LiJ, Xia G D, Li Y F. Numerical and experimental analyses of planarasymmetric split‐and‐recombine micromixer with dislocation sub‐channels.Journal ofChemical Technology and Biotechnology, 2013,88(9): 1757-1765.
2.ChaiL, Xia G D, Wang L, et al. Heat transfer enhancement in microchannelheat sinks with periodic expansion–constriction cross-sections. InternationalJournal of Heat and Mass Transfer, 2013, 62:741-751.
3.ChaiL, Xia G D, Zhou M Z, et al. Optimum thermal design of interruptedmicrochannel heat sink with rectangular ribs in the transverse microchambers.AppliedThermal Engineering, 2013, 51(1):880-889.
4.XiaG D, Zhai Y L, Cui Z Z. Numericalinvestigation of thermal enhancement in a micro heat sink with fan-shapedreentrant cavities and internal ribs. Applied Thermal Engineering, 2013, 58(1): 52-60.
5.Jiao Y G,Xia G D, Huang S G. The Heat TransferCharacteristics of the Jacket-type Radial Heat Pipe without Wick.Heat Transfer Research,2013, 1547:303.
6.XiaG D, Zhai Y L, Cui Z Z. Characteristics ofentropy generation and heat transfer in a microchannel with fan-shapedreentrant cavities and internal ribs. Science ChinaTechnological Sciences, 2013, 56(7):1629-1635.
2012年
1.XiaG D, Li J, Tian X P, et al. Analysis of flowand mixing characteristics of planar asymmetric split-and-recombine (P-SAR)micromixers with fan-shaped cavities. Industrial &Engineering Chemistry Research, 2012,51(22): 7816-7827.
2.ZhouM Z, Xia G D, Li J, et al. Analysis of factors influencing thermalconductivity and viscosity in different kinds of surfactant solutions.Experimental Thermal and Fluid Science, 2012,36: 22-29.
3.ChaiL, Xia G D, Qi J Z. Experimental and Numerical Study of Flow and HeatTransfer in Trapezoidal Microchannels.Heat TransferEngineering, 2012, 33(11): 972-981.
4.ZhouM Z, Xia G D, Chai L, et al. Analysis of flow and heat transfercharacteristics of micro-pin fin heat sink using silver nanofluids. ScienceChina Technological Sciences, 2012, 55(1):155-162.
5.XiaG D, Chai L. Influence of surfactant ontwo-phase flow regime and pressure drop in upward inclined pipes. Journal ofHydrodynamics, Ser. B, 2012, 24(1): 39-49.
2011年
1.XiaG D, Chai L, Zhou M Z, et al. Effects ofstructural parameters on fluid flow and heat transfer in a microchannel withaligned fan-shaped reentrant cavities. International Journal of ThermalSciences, 2011, 50(3): 411-419.
2.ChaiL, Xia G D, Zhou M Z, et al. Numerical simulation of fluid flow and heattransfer in a microchannel heat sink with offset fan-shaped reentrant cavitiesin sidewall. International Communications in Heat and Mass Transfer, 2011, 38(5): 577-584.
3.XiaG D, Chai L, Wang H Y, et al. Optimum thermaldesign of microchannel heat sink with triangular reentrant cavities. AppliedThermal Engineering, 2011, 31(6): 1208-1219.
科研项目
1.国家重点基础研究发展计划(973计划)、2011CB710704、2011/01–2015/12
2.国家自然科学基金面上项目,51576005、2016/01–2019/12
3.国家自然科学基金面上项目,51176002、2012/01–2015/12
4.国家自然科学基金面上项目,50876003、2009/01–2011/12
5.国家自然科学基金面上项目,50476035、2005/01–2007/12
6.国防预研项目、97J00.05、1998/01–2000/12。
7.北京市自然科学基金-教委联合基金重点项目,KZ201810005006、2018/01–2021/12
8.北京市自然科学基金-教委联合基金重点项目,KZ200710005001、2007/01–2009/12
9.北京市自然科学基金面上项目,3142004、2014/01–2016/12
10.北京市自然科学基金面上项目,3092009、2009/01–2011/12
11.北京市自然科学基金面上项目,3052004、2005/01–2007/12
12.北京市科技计划项目、Z08000903740804、2009/01–2009/7
13.北京市科技计划项目、20070005009、2010/05–2011/12
14.北京市教委科技发展项目、KM200410005008、2004/01–2006/12
15.北京市优秀博士学位论文指导教师科技项目、20131000503、2014/01-2016/12
16.北京市拔尖创新人才项目、PHR200906104、2009/01–2011/12
17.北京市科技新星项目、954810800、1999/01–2004/12
18.北京市中青年骨干教师项目、954810800、2006/01–2008/12
19.教育部博士学科点专项基金项目、20111103110009、2012/01–2014/12
20.教育部博士学科点专项基金项目、20070005009、2008/01–2010/12
21.教育部留学归国基金项目、2003.1-2005.12
22.企事业委托项目等
