基本介紹
- 中文名:徐治國
- 外文名:Zhiguo Xu
- 國籍:中國
- 職業:教授
- 畢業院校:西安交通大學
- 主要成就:2015年度上海交通大學優秀班主任
工作經歷,科研項目,
工作經歷
2016- 上海交通大學機械與動力工程學院 副研究員,博士生導師
2015-2016 上海交通大學機械與動力工程學院 助理研究員,博士生導師
2014-2015 上海交通大學機械與動力工程學院 助理研究員
2012-2014 上海交通大學機械與動力工程學院 博士後
2002-2005 中國石油集團長慶油田 助理工程師
2015-2016 上海交通大學機械與動力工程學院 助理研究員,博士生導師
2014-2015 上海交通大學機械與動力工程學院 助理研究員
2012-2014 上海交通大學機械與動力工程學院 博士後
2002-2005 中國石油集團長慶油田 助理工程師
教育經歷:
2008-2012 西安交通大學 動力工程及工程熱物理專業 工學博士
2005-2008 西安交通大學 動力工程及工程熱物理專業 工學碩士
1998-2002 中國石油大學 電子與信息技術專業 工學碩士
科研項目
2016-2019 國家自然科學基金面上項目:梯度金屬泡沫內流動沸騰傳熱機理研究負責人
2015-2017 上海市自然科學基金面上項目:梯度金屬泡沫池沸騰換熱性能和機理的基礎研究 負責人
2013-2014 中國博士後科學基金一等面上項目:漸變形貌金屬泡沫池沸騰換熱及強化研究 負責人
2015-2017 國家自然科學基金青年項目:熱噴塗中熱質耦合對塗層微結構影響的機理研究 參與人
2017-2021 國家自然科學基金重點項目:微納多孔介質中相干散射和各向異性熱輻射機理及其調控機制
2015-2017 上海市自然科學基金面上項目:梯度金屬泡沫池沸騰換熱性能和機理的基礎研究 負責人
2013-2014 中國博士後科學基金一等面上項目:漸變形貌金屬泡沫池沸騰換熱及強化研究 負責人
2015-2017 國家自然科學基金青年項目:熱噴塗中熱質耦合對塗層微結構影響的機理研究 參與人
2017-2021 國家自然科學基金重點項目:微納多孔介質中相干散射和各向異性熱輻射機理及其調控機制
參與人
2012-2016國家科技部“973”項目:多形態工業餘熱高效存儲的新原理、新技術及其套用參與人
2012-2016國家科技部“973”項目:多形態工業餘熱高效存儲的新原理、新技術及其套用參與人
代表性論文:
[1] Z .G. Xu, C. Y. Zhao. Enhanced boiling heat transfer by gradient porous metals in saturated pure water and surfactant solutions. Applied Thermal Engineering, 2016, 100: 68-77.
[2] Z .G. Xu, C. Y. Zhao. Experimental study on pool boiling heat transfer in gradient metal foams. International Journal of Heat and Mass Transfer, 2015, 85: 824-829.
[3] Z. G. Xu, Z. G. Qu, C. Y. Zhao, W. Q. Tao. Experimental correlation for pool boiling heat transfer on metallic foam surface and bubble cluster growth behavior on grooved array foam surface.International Journal of Heat and Mass Transfer, 2014, 77:1169-1182.
[4] Z .G. Xu, C. Y. Zhao. Influence of nanoparticles on pool boiling heat transfer in porous metals. Applied Thermal Engineering, 2014, 65: 34-41.
[5] Z .G. Xu, C. Y. Zhao. Pool boiling heat transfer of open-celled metal foams with V-shaped grooves for high pore densities. Experimental Thermal and Fluid Science, 2014, 52: 128-138.
[6] Z. G. Xu, C. Y. Zhao. Thickness effect on pool boiling heat transfer of trapezoid-shaped copper foam fins. Applied Thermal Engineering, 2013, 60: 359-370.
[7] Z. G. Xu, Z. G. Qu, C. Y. Zhao, W. Q. Tao. Experimental study of pool boiling heat transfer on metallic foam surface with U-shaped and V-shaped grooves. Journal of Enhanced Heat Transfer, 2012, 19: 549-559.
[8] Z. G. Xu, Z. G. Qu, C. Y. Zhao, W. Q. Tao. Experimental study of pool boiling heat transfer on horizontal metallic foam surface with crossing and single-directional V-shaped groove in saturated water. International Journal of Multiphase Flow, 2012, 41: 44-55.
[9] Z. G. Xu, Z. G. Qu, C. Y. Zhao, W. Q. Tao. Pool boiling heat transfer on open-celled metallic foam sintered surface under saturation condition. International Journal of Heat and Mass Transfer, 2011, 54: 3856-3867.
[10] C. Y. Zhao, Y. N. Ji, Z. G. Xu. Investigation of the Ca(NO3)2-NaNO3 mixture for latent heat storage. Solar Energy Materials & Solar Cells, 2015, 140: 281-288.
[11] H. J. Xu, C. Y. Zhao, Z. G. Xu. Analytical considerations of slip flow and heat transfer through microfoams in mini/micro channels with asymmetric wall heat fluxes. Applied Thermal Engineering, 2016, 93:15-26.
[12] Y. Zhao, C. Y. Zhao, Z. G. Xu. Modeling metal foam enhanced phase change heat transfer in thermal energy storage by using phase field method.International Journal of Heat and Mass Transfer, 2016, 99:170-181.
[13] Z. G. Qu, D. G. Li, J. Y. Huang, Z. G. Xu, X. L. Liu, W. Q. Tao. Experimental investigations of pool boiling heat transfer on horizontal plate sintered with metallic fiber felt. International Journal of Green Energy, 2012, 9: 22-38.[14] H. J. Xu, L. Gong, C. Y. Zhao, Y. Yang, Z. G. Xu. Analytical considerations of local thermal non-equilibrium conditions for thermal transport in metal foams. International Journal of Thermal Sciences, 2015, 95: 73-87.
[15] Z. G. Xu, R.L.Huang, C. Y. Zhao. Experimental Investigation on pool boiling heat transfer of gradient metal foams. 12th International Conference on Heat Transfer, Fluid Mechanics and Thermodynamics, 2016, Malaga, Costa Del Sol, Spain.
[16] Z. G. Xu, C.Y. Zhao. Investigation on pool boiling heat transfer of metal foams with gradient pore densities. Proceedings of the International Conference on Power Engineering, 2015, Yokohama, Japan.
[17] Z. G. Xu, C. Y. Zhao. Groove distance effect on pool boiling heat transfer of metal foams with high pore densities. [Invited talk]. International Workshop on Heat Transfer Advances for Energy Conservation and Pollution Control, 2015, Taipei, Taiwan.
[18] Z. G. Xu, C. Y. Zhao. Pool boiling of open-celled metal foams. International Workshop on Thermal Management of High Power Microsystems Using Multiphase Flow, 2014, Shanghai, China.
[19] Z. G. Xu, C. Y. Zhao. Nanoparticle deposition effect on pool boiling heat transfer of metal foams. International Heat Transfer Symposium, 2014, Beijing, China.
[20] Z. G. Xu, C. Y. Zhao. Single-directional and crossing V-shaped groove effect on pool boiling heat transfer of metal foam with high pore densities. International Conference on Materials for Renewable Energy & Environment, 2013, Chengdu, China.
[21] Z. G. Xu, C. Y. Zhao. Grooves' distance effect on pool boiling heat transfer of metal foams with high pore density. 8th World Conference on Experimental Heat Transfer, Fluid Dynamics and Thermodynamics, 2013, Lisbon, Portugal.
[22] Z. G. Xu, C. Y. Zhao. Thickness effect on pool boiling heat transfer of metal foams with the low pore density. Proceedings of the International Conference on Power Engineering, 2013, Wuhan, China.
[23] Z. G. Xu, Z. G. Qu, C. Y. Zhao, W. Q. Tao. Experimental study of boiling pattern and heat transfer performance of metallic foam surface with square columns. International Workshop on Heat Transfer Advances for Energy Conservation and Pollution Control, 2011, Xi’an, China.
[24] Z. G. Xu, Z. G. Qu, C. Y. Zhao, W. Q. Tao. Experimental study of natural convection in horizontally-positioned open-celled metal foams. International Conference on Materials for Renewable Energy & Environment, 2011, Shanghai, China.
[25] Y. Zhao, C. Y. Zhao, Z. G. Xu. Numerical study of solid-liquid phase change by phase field model. Asian Symposium on Computational Heat Transfer and Fluid Flow, 2015, Busan, Korea.
[2] Z .G. Xu, C. Y. Zhao. Experimental study on pool boiling heat transfer in gradient metal foams. International Journal of Heat and Mass Transfer, 2015, 85: 824-829.
[3] Z. G. Xu, Z. G. Qu, C. Y. Zhao, W. Q. Tao. Experimental correlation for pool boiling heat transfer on metallic foam surface and bubble cluster growth behavior on grooved array foam surface.International Journal of Heat and Mass Transfer, 2014, 77:1169-1182.
[4] Z .G. Xu, C. Y. Zhao. Influence of nanoparticles on pool boiling heat transfer in porous metals. Applied Thermal Engineering, 2014, 65: 34-41.
[5] Z .G. Xu, C. Y. Zhao. Pool boiling heat transfer of open-celled metal foams with V-shaped grooves for high pore densities. Experimental Thermal and Fluid Science, 2014, 52: 128-138.
[6] Z. G. Xu, C. Y. Zhao. Thickness effect on pool boiling heat transfer of trapezoid-shaped copper foam fins. Applied Thermal Engineering, 2013, 60: 359-370.
[7] Z. G. Xu, Z. G. Qu, C. Y. Zhao, W. Q. Tao. Experimental study of pool boiling heat transfer on metallic foam surface with U-shaped and V-shaped grooves. Journal of Enhanced Heat Transfer, 2012, 19: 549-559.
[8] Z. G. Xu, Z. G. Qu, C. Y. Zhao, W. Q. Tao. Experimental study of pool boiling heat transfer on horizontal metallic foam surface with crossing and single-directional V-shaped groove in saturated water. International Journal of Multiphase Flow, 2012, 41: 44-55.
[9] Z. G. Xu, Z. G. Qu, C. Y. Zhao, W. Q. Tao. Pool boiling heat transfer on open-celled metallic foam sintered surface under saturation condition. International Journal of Heat and Mass Transfer, 2011, 54: 3856-3867.
[10] C. Y. Zhao, Y. N. Ji, Z. G. Xu. Investigation of the Ca(NO3)2-NaNO3 mixture for latent heat storage. Solar Energy Materials & Solar Cells, 2015, 140: 281-288.
[11] H. J. Xu, C. Y. Zhao, Z. G. Xu. Analytical considerations of slip flow and heat transfer through microfoams in mini/micro channels with asymmetric wall heat fluxes. Applied Thermal Engineering, 2016, 93:15-26.
[12] Y. Zhao, C. Y. Zhao, Z. G. Xu. Modeling metal foam enhanced phase change heat transfer in thermal energy storage by using phase field method.International Journal of Heat and Mass Transfer, 2016, 99:170-181.
[13] Z. G. Qu, D. G. Li, J. Y. Huang, Z. G. Xu, X. L. Liu, W. Q. Tao. Experimental investigations of pool boiling heat transfer on horizontal plate sintered with metallic fiber felt. International Journal of Green Energy, 2012, 9: 22-38.[14] H. J. Xu, L. Gong, C. Y. Zhao, Y. Yang, Z. G. Xu. Analytical considerations of local thermal non-equilibrium conditions for thermal transport in metal foams. International Journal of Thermal Sciences, 2015, 95: 73-87.
[15] Z. G. Xu, R.L.Huang, C. Y. Zhao. Experimental Investigation on pool boiling heat transfer of gradient metal foams. 12th International Conference on Heat Transfer, Fluid Mechanics and Thermodynamics, 2016, Malaga, Costa Del Sol, Spain.
[16] Z. G. Xu, C.Y. Zhao. Investigation on pool boiling heat transfer of metal foams with gradient pore densities. Proceedings of the International Conference on Power Engineering, 2015, Yokohama, Japan.
[17] Z. G. Xu, C. Y. Zhao. Groove distance effect on pool boiling heat transfer of metal foams with high pore densities. [Invited talk]. International Workshop on Heat Transfer Advances for Energy Conservation and Pollution Control, 2015, Taipei, Taiwan.
[18] Z. G. Xu, C. Y. Zhao. Pool boiling of open-celled metal foams. International Workshop on Thermal Management of High Power Microsystems Using Multiphase Flow, 2014, Shanghai, China.
[19] Z. G. Xu, C. Y. Zhao. Nanoparticle deposition effect on pool boiling heat transfer of metal foams. International Heat Transfer Symposium, 2014, Beijing, China.
[20] Z. G. Xu, C. Y. Zhao. Single-directional and crossing V-shaped groove effect on pool boiling heat transfer of metal foam with high pore densities. International Conference on Materials for Renewable Energy & Environment, 2013, Chengdu, China.
[21] Z. G. Xu, C. Y. Zhao. Grooves' distance effect on pool boiling heat transfer of metal foams with high pore density. 8th World Conference on Experimental Heat Transfer, Fluid Dynamics and Thermodynamics, 2013, Lisbon, Portugal.
[22] Z. G. Xu, C. Y. Zhao. Thickness effect on pool boiling heat transfer of metal foams with the low pore density. Proceedings of the International Conference on Power Engineering, 2013, Wuhan, China.
[23] Z. G. Xu, Z. G. Qu, C. Y. Zhao, W. Q. Tao. Experimental study of boiling pattern and heat transfer performance of metallic foam surface with square columns. International Workshop on Heat Transfer Advances for Energy Conservation and Pollution Control, 2011, Xi’an, China.
[24] Z. G. Xu, Z. G. Qu, C. Y. Zhao, W. Q. Tao. Experimental study of natural convection in horizontally-positioned open-celled metal foams. International Conference on Materials for Renewable Energy & Environment, 2011, Shanghai, China.
[25] Y. Zhao, C. Y. Zhao, Z. G. Xu. Numerical study of solid-liquid phase change by phase field model. Asian Symposium on Computational Heat Transfer and Fluid Flow, 2015, Busan, Korea.
代表性發明專利:
[1] 徐治國,趙長穎.漸變形貌特徵的通孔金屬泡沫及其製備方法和換熱裝置.發明專利,公布號:CN103060592A.
[2] 徐治國,趙長穎.基於衝擊射流的高孔密度通孔金屬泡沫電子器件散熱裝置.發明專利,授權號:ZL201310027366.3.
[3] 徐治國,趙長穎.具有漸變形貌特徵的通孔金屬泡沫熱管換熱裝置.發明專利,授權號:ZL201410160129.9.
[4] 徐治國,趙長穎.漸變金屬泡沫基相變蓄熱裝置.發明專利,公布號:CN103234377A.
[5] 徐治國,趙長穎.預混預熱型梯密度金屬泡沫燃燒器.發明專利,授權號:ZL201310496700.X.
[6] 徐治國,趙長穎.梯密度通孔金屬泡沫及其製備方法.發明專利,授權號:ZL201310499157.9.
[7] 徐治國,趙長穎.梯密度通孔金屬泡沫及其簡易製備方法.發明專利,授權號:ZL201410563901.1.
[8] 徐治國,趙長穎.基於金屬泡沫的汽車尾氣淨化器.發明專利,公布號:CN104594995A.
[9] 徐治國,趙長穎.梯度金屬泡沫散熱裝置.發明專利,公布號:CN104729338A.
[10]徐治國,趙長穎.孔密度漸變通孔金屬泡沫熱管換熱裝置.發明專利,授權號:ZL201410483506.2.
[11]徐治國,趙長穎.金屬纖維氈的製備方法.發明專利,授權號:ZL201410061055.3.
[12] 紀育楠,趙長穎,徐治國.相變蓄熱介質.發明專利,公布號:CN103923615A.
[13] 趙長穎,陳雲宇,徐治國.相變蓄熱介質及其製備及套用.發明專利,公布號:CN105131911A.
[2] 徐治國,趙長穎.基於衝擊射流的高孔密度通孔金屬泡沫電子器件散熱裝置.發明專利,授權號:ZL201310027366.3.
[3] 徐治國,趙長穎.具有漸變形貌特徵的通孔金屬泡沫熱管換熱裝置.發明專利,授權號:ZL201410160129.9.
[4] 徐治國,趙長穎.漸變金屬泡沫基相變蓄熱裝置.發明專利,公布號:CN103234377A.
[5] 徐治國,趙長穎.預混預熱型梯密度金屬泡沫燃燒器.發明專利,授權號:ZL201310496700.X.
[6] 徐治國,趙長穎.梯密度通孔金屬泡沫及其製備方法.發明專利,授權號:ZL201310499157.9.
[7] 徐治國,趙長穎.梯密度通孔金屬泡沫及其簡易製備方法.發明專利,授權號:ZL201410563901.1.
[8] 徐治國,趙長穎.基於金屬泡沫的汽車尾氣淨化器.發明專利,公布號:CN104594995A.
[9] 徐治國,趙長穎.梯度金屬泡沫散熱裝置.發明專利,公布號:CN104729338A.
[10]徐治國,趙長穎.孔密度漸變通孔金屬泡沫熱管換熱裝置.發明專利,授權號:ZL201410483506.2.
[11]徐治國,趙長穎.金屬纖維氈的製備方法.發明專利,授權號:ZL201410061055.3.
[12] 紀育楠,趙長穎,徐治國.相變蓄熱介質.發明專利,公布號:CN103923615A.
[13] 趙長穎,陳雲宇,徐治國.相變蓄熱介質及其製備及套用.發明專利,公布號:CN105131911A.
學術兼職:
[1]《InternationalJournalofHeatandMassTransfer》期刊審稿人
[2]《InternationalJournalofThermalSciences》期刊審稿人
[3]《AppliedThermalEngineering》期刊審稿人
[4]《CanadianJournalofPhysics》期刊審稿人
[5]《JounalofPorousMedia》期刊審稿人
[6]《中國石油大學學報》期刊審稿人
[7]《熱科學與技術》期刊審稿人
[2]《InternationalJournalofThermalSciences》期刊審稿人
[3]《AppliedThermalEngineering》期刊審稿人
[4]《CanadianJournalofPhysics》期刊審稿人
[5]《JounalofPorousMedia》期刊審稿人
[6]《中國石油大學學報》期刊審稿人
[7]《熱科學與技術》期刊審稿人
榮譽獎勵:
2015上海交通大學優秀班主任
2015SessionChairofInternationalConferenceonPowerEngineering,Yokohama,Japan
2014SessionChairofInternationalHeatTransferSymposium,Beijing,China
2013SessionChairofInternationalConferenceonPowerEngineering,Wuhan,China
2012《西安交通大學學報》年度最具學術影響力優秀論文
2011中國光華科技基金會獎勵
2015SessionChairofInternationalConferenceonPowerEngineering,Yokohama,Japan
2014SessionChairofInternationalHeatTransferSymposium,Beijing,China
2013SessionChairofInternationalConferenceonPowerEngineering,Wuhan,China
2012《西安交通大學學報》年度最具學術影響力優秀論文
2011中國光華科技基金會獎勵
