热科学和能源工程系

王建华 教授

发布者:webmaster  时间:2022-08-24  浏览次数:14332

王建华



一、联系方式

单位:中国科学技术大学工程科学学院

热科学和能源工程系

地址:合肥市金寨路96

邮编:230027

电话:0551-63600945

传真:0551-63606459

电子邮件:jhwang@ustc.edu.cn

二、学历及学位

  • 78.02-82.02 合肥工业大学,精密机械工程系,工学学士

  • 83.09-86.07 哈尔滨工业大学,动力工程系,工学硕士

  • 98.02-02.12 德国斯图加特大学,能源工程学院,热流体机械研究所,工学博士(Dr.-Ing.


三、主要海外留学及工作经历

  • 92.02-93.08德国宇航院哥庭根流体力学研究所,从事实验流体力学先进测量技术研究,中科院访问学者

  • 96.06-96.12香港城市大学,从事数学模型和数值计算方法研究,资深助理研究员(SR

  • 98.04-02.12德国斯图加特大学,热流体机械研究所,从事强化冷却技术实验研究,全职研究伙伴 (Wissenschaftliche Mitarbeiterin BatA2)


四、近年来研究方向

1 )多孔介质传热传质过程的数学模型、数值模拟方法及实验技术研究

2 )空天飞行器主动热防护技术及相关材料/结构设计问题研究

3 )强化冷却结构多场耦合问题实验技术及数值模拟方法研究

4 )现代化光学诊断及数字图像处理技术在热物理量测量方面的应用

5 )新能源、洁净能源基础理论及应用技术研究


五、教学经历

1)基础流体力学

2)传热及流动过程的数值计算方法

3)气体动力学

4)热过程的数值模拟

5)传热传质学(双语课)

6)高等计算流体力学(研究生课程)


六、主要社会工作

  • 《航空动力学报》编辑委员会成员

  • Committee Member of ASME/HTD Gas Turbine Heat Transfer (K-14)

  • Committee Member of ASME/IGTI Heat Transfer


七、公开发表的代表性论文   

1、杂志论文

[1] Tiao Zhang, Jian Pu, Wen-Li Zhou, Jian-Hua Wang*, Wei-Long Wu, Yun Cheng, Effect of transverse trench on film cooling performances of typical fan-shaped film-holes at concave and convex walls, International Journal of Heat and Mass Transfer175(2021)121384.

[2] Xu Wang, Huazhao Xu, Jianhua Wang, Wei Song, Lei Wang, High pressure turbine blade internal cooling in a realistic rib roughened two-pass channel, International Journal of Heat and Mass Transfer,170(2021)121019.

[3] Xin Huang, Jian Pu, Tiao Zhang, Jian-Hua Wang*, Wei-Long Wu, Xiang-Yu Wu, Effect of length-to-diameter ratio on film cooling and heat transfer performances of simple and compound cylindrical-holes in transverse trenches with various depths, International Journal of Heat and Mass Transfer, 185 (2022) 122328.

[4] Hao Su, Fei He*, Jianhua Wang*, Nan Wu, Ran Yao, Haitao Han, Min Chu, Numerical investigation on the characteristics of coolant flow, heat absorption and phase change in transpiration cooling process, International Journal of Heat and Mass Transfer, 142(2019) 68-76.

[5] Ran Yao, Jianhua Wang*, Ming Wang, Lei Wang, Influence of flat endwall simplification in gas turbines on cooling performance, International Journal of Heat and Mass Transfer, 130(2019) 1226-1237.

[6] Hao Su, Jianhua Wang*, Fei He*, Liang Chen, Bangcheng Ai, Numerical investigation on transpiration cooling with coolant phase change under hypersonic conditions, International Journal of Heat and Mass Transfer, 129(2019) 480-490.

[7] Nan Wu, Jianhua Wang*, Fei He, Liang Chen, Bangcheng Ai, Optimization transpiration cooling of nose cone with non-uniform permeability, International Journal of Heat and Mass Transfer, 127(2018) 882-891.

[8] Nan Wu, Jianhua Wang*, Wenjie Dong, Rui Ding, An experimental investigation on combined sublimation and transpiration cooling for sintered porous plates, International Journal of Heat and Mass Transfer, 116(2018)685-693.

[9] Jianhua Wang*, Lianjin Zhao, Xiaochun Wang, Jie Ma, Jia Lin, An Experimental Investigation on Transpiration Cooling of Wedge Shaped Nose Cone with Liquid Coolant, International Journal of Heat and Mass Transfer, 75 (2014) 442–449.

[10] Jianhua Wang*, Zhixin Feng, Qian Zhang, Xiangyu Wu, Shiyan Ma, Experimental Investigations on Overall Cooling Effect of Ribbed Channel with Air Bleeds, International Journal of Heat and Mass Transfer, 55 (2012) 4800–4807.

[11] Liu H. C., Wang J. H.*, Numerical Investigation on Synthetical Performances of Fluid Flow and Heat Transfer of Semiattached Rib-channels, International Journal of Heat and Mass Transfer, 54 (2011) 575–583.

[12] Shi J. X., Wang J. H.*, Inverse Problem of Transpiration Cooling for Estimating Wall Heat Flux by LTNE Model and CGM Method, International Journal of Heat and Mass Transfer, (2009)52: 2714-2720.

[13] Meng Wang, Jianhua Wang*, Jian Pu, Fei He, Transient heat dissipation performances of transpiration cooling with coolant phase change, International Communications in Heat and Mass Transfer 135 (2022) 106082.

[14] Yuefeng Li, Huazhao Xu, Jianhua Wang*, Junqiang Zhu, Hang Su, Numerical study of unsteady flow and cooling characteristics of turbine blade cutback trailing edges integrated with pin fins and film holes, Aerospace Science and Technology 126 (2022) 107604.

[15] Fei He, Nan Wu, Fangyuan Ran, Jianhua Wang, Numerical investigation on the transpiration cooling of three-dimensional hypersonic inlet, Aerospace Science and Technology 106 (2020) 106152.

[16] Yumei Lv, Fei He*, Wei Dai, Yulong Ma, Taolue Liu, Yifei Liu, Jianhua Wang, Design of Economical and Achievable Aluminum Carbon Composite Aerogel for Efficient Thermal Protection of Aerospace, Gels 2022, 8, 509.

[17] Yumei Lv, Fei He*, Rui Ding, Nan Wu, Taolue Liu, Jianhua Wang*, Design of the Thermal Restructured Carbon−Inorganic Composite Aerogel for Efficient Thermal Protection of Aero-Engines, ACS Applied Materials & Interfaces, https:// doi.org/10.1021/acsami.2c09891.

[18] Fei He, Wenjie Dong, Jianhua Wang*, Jianxing Zhou, Longsheng Tang, Transient model and its application to investigate the injection mode and periodical operation of transpiration cooling with liquid coolant phase change, Applied Thermal Engineering 181(2020)115956.

[19] Xin Huang, Jian Pu*, Jian-hua Wang*, Yun-feng Qu, Jia-hui He, Performances of laminated cooling configurations with TBC, Applied Thermal Engineering, 181 (2020) 116020.

[20]Jian Pu, Wei Wang, Jian-hua Wang*, Wei-long Wu, Ming Wang, Experimental study of free-stream turbulence intensity effect on overall cooling performances and solid thermal deformations of vane laminated end-walls with various internal pin–fin configurations,173 (2020) 115232.

[21]Rui Ding, Jianhua Wang*, Fei He*, Meng Wang, Yun Luan, Guangqi Dong, Longsheng Tang, Numerical investigation on a double layer combined cooling structure for aerodynamic heat control of hypersonic vehicle leading edge, Applied Thermal Engineering,169(2020)114949.

[22]Taolue Liu, Hao Su, Zhengwei Chen, Fei He*, Jianhua Wang*, Numerical investigation on the transient transport and heat transfer characteristics of transpiration cooling with liquid phase change during coolant adjustment, Applied Thermal Engineering,209(2022)118277.

[23]Weilong Wu, Ran Yao*, Jianhua Wang*, Hang Su, Xiangyu Wu, Leading edge impingement cooling analysis with separators of a real gas turbine blade, Applied Thermal Engineering,208(2022)118275.

[24] Kang Qian, Jianhua Wang*, Fei He*, Yadong Wu, Zihe Zhou, An experimental investigation on transpiration cooling performances using solid hydrogel as coolant, Applied Thermal Engineering 158(2019)113753.

[25] Wei Wang, Jian Pu*, Jian-hua Wang*, Wei-long Wu, Ming Wang, An experimental investigation on cooling characteristics of a vane laminated end-wall with axial-row layout of film-holes, Applied Thermal Engineering 148 (2019) 953–962.

[26] Rui Ding, Jianhua Wang*, Fei He*, Guangqi Dong, Longsheng Tang, Numerical investigation on the performances of porous matrix with transpiration and film cooling, Applied Thermal Engineering 146 (2019) 422-431.

[27] Wenjie Dong, Jianhua Wang*, Siyuan Chen, Bangcheng Ai, Xiaoguang Luo, Modelling and investigation on heat transfer deterioration during transpiration cooling with liquid coolant phase-change, Applied Thermal Engineering 128 (2018) 381–392.

[28] Lin Shen, Jianhua Wang*, Numerical investigation on the optimization of local transpiration cooling effectiveness, Applied Thermal Engineering 127 (2017) 58–69.

[29] Zhaoqing Ke, Jianhua Wang*, Conjugate heat transfer simulations of pulsed film cooling on an entire turbine vane, Applied Thermal Engineering, 109 (2016) 600–609.

[30] Lin Shen, Jianhua Wang*, Wenjie Dong, Jian Pu, Jinlong Peng, Dejun Qu, Lianzhong Chen, An experimental investigation on transpiration cooling with phase change under supersonic condition, Applied Thermal Engineering 105 (2016) 549–556.

[31] Zhaoqing Ke, Jianhua Wang*, Numerical investigations of pulsed film cooling on an entire turbine vane, Applied Thermal Engineering, 87 (2015) 117-126.

[32] Fei He, Jianhua Wang*, Lucheng Xu, Xiaochun Wang, Modeling and Simulation of Transpiration Cooling with Phase Change, Applied Thermal Engineering, 58 (2013) 173-180.

[33] Jin-Long Liu, Jian-Hua Wang*, Thermodynamic analysis of a novel tri-generation system based on compressed air energy storage and pneumatic motor, Energy, 91 (2015) 420-429.

[34] Fei He, Jianhua Wang*, Numerical Investigation on Critical Heat Flux and Coolant Volume Required for Transpiration Cooling with Phase Change, Energy Conversion and Management, 80 (2014) 591–597.

[35] Jin-Long Liu, Jian-Hua Wang*, A comparative research of two adiabatic compressed air energy storage systems, Energy Conversion and Management, 108 (2016) 566–578.

[36] Prasert Prapamonthon, Huazhao Xu, Wenshuo Yang, Jianhua Wang*, Numerical Study of the Effects of Thermal Barrier Coating and Turbulence Intensity on Cooling Performances of a Nozzle Guide Vane, Energies 2017, 10, 362.

[37] Xiaochun Wang, Jianhua Wang*, Fei He*, Hong Zhang, Effect of Relative Movement between the Shroud and Blade on Tip Leakage Flow Characteristics, Energies 2017, 10, 1600; doi:10.3390/en10101600.

[38]Ren-bin Yu, Jian Pu*, Peng Wang, Jian-hua Wang*, Bo Wan, Jian-xia Luo, Shu-qing Tian, Auxiliary hole influence on internal flow characteristics in bend region of a real investment-casting blade coolant channel, Experimental Thermal and Fluid Science, 102(2019)123-136.

[39]Wen-li Zhou, Jian Pu*, Xin Huang, Jian-hua Wang*, Wei Song, Wei-long Wu, Experimental investigation of inclination angle effect on unsteady film coverage of double-row staggered-holes at vane leading edge using time-resolved quantitative light sheet technique, Experimental Thermal and Fluid Science, 123(2021)110344.

[40] Nan Wu, Jianhua Wang*, Fei He*, Guangqi Dong, Longsheng Tang, An experimental investigation on transpiration cooling of a nose cone model with a gradient porosity layout, Experimental Thermal and Fluid Science 106 (2019) 194–201.

[41] Ren-bin Yu, Jian Pu*, Peng Wang, Jian-hua Wang*, Bo Wan, Jian-xia Luo, Shu-qing Tian, Auxiliary hole influence on internal flow characteristics in bend region of a real investment-casting blade coolant channel, Experimental Thermal and Fluid Science,102(2019)123-136.

[42] Hang Su, Jian Pu*, Jian-hua Wang*, Rui-ming Yuan, Yong-xian Luan, Bin-peng Kang, An experimental investigation of cooling characteristics at a vane end-wall with a locally enhanced hole-layout, Experimental Thermal and Fluid Science, 96 (2018)137-145.

[43]Jian Pu, Jian-hua Wang*, Shi-yan Ma, Xiang-yu Wu, An experimental investigation of geometric effect of upstream converging slot-hole on end-wall film cooling and secondary vortex characteristics, Experimental Thermal and Fluid Science 69 (2015) 58–72.

[44] Jian Pu, Jun Yu, Jian-hua Wang*, Wen-shuo Yang, Zhi-qiang Zhang, Lei Wang,An experimental investigation of secondary flow characteristics in a linear turbine cascade with upstream converging slot-holes using TR-PIV, Experimental Thermal and Fluid Science 59 (2014) 56–71.

[45] Jian Pu, Zhao-Qing Ke, Jian-Hua Wang*, Hong-De You, Zhi-Neng Du, An Experimental Investigation on Fluid Flow Characteristics in a Real Coolant Channel of LP Turbine Blade with PIV Technique, Experimental Thermal and Fluid Science 45 (2013) 43–53.

[46]Jian Pu, Ren-bin Yu, Jian-hua Wang, Bo Wan, Jian-xia Luo, Shu-qing Tian, POD analysis of passage-layout effect on unsteady internal flow in a realistic blade serpentine coolant channel with low aspect ratios, Journal of Visualization,DOI 10.1007/s12650-020-00669-4.

[47]Pu Jian, Zhang Tiao, Huang Xin, Wang Jianhua*, Wu Weilong, Overall Thermal Performances of Double-Wall Effusion Cooling Covered by Simulated Thermal Barrier Coatings, Journal of Thermal Science Vol.31, No.1 (2022) 224-238.

[48]Wen-li Zhou, Jian Pu*, Jian-hua Wang*, Hang Su, Yun Cheng, Experimental investigation of hole-geometry effect on unsteady characteristics of film cooling at turbine vane leading edge, International Journal of Thermal Sciences 179 (2022) 107715.

[49]Ran Yao, Hang Su, Yun Cheng, Jianhua Wang*, Jian Pu, Numerical investigation of a novel multistage swirl cooling conception in blade leading edge of gas turbine, International Journal of Thermal Sciences 172 (2022) 107269.

[50]Yumei Lv, Taolue Liu, Xin Huang, Fei He*, Longsheng Tang, Jianxing Zhou , Jianhua Wang*, Numerical investigation and optimization of flat plate transpiration-film combined cooling structure, International Journal of Thermal Sciences 179 (2022) 107673.

[51]Tiao Zhang, Jian Pu*, Shuai Xu, Jian-hua Wang*, Wei-long Wu, Fu-qiang Wang, Experimental study of transverse trench effect on unsteady film cooling effectiveness of backward cylindrical-holes with various compound angles, International Journal of Thermal Sciences 159 (2021) 106563.

[52]Yun Luan, Fei He*, Jianhua Wang*, Yadong Wu, Guangsheng Zhu, An experimental investigation on instability of transpiration cooling with phase change, International Journal of Thermal Sciences 156 (2020) 106498.

[53] Hao Su, Fei He*, Jianhua Wang*, Nan Wu, Ran Yao, Haitao Hanb Min ChuNumerical investigation on the characteristics of coolant flow, heat absorption and phase change in transpiration cooling process,International Journal of Thermal Sciences 142 (2019) 68-76.

[54]Lianjin Zhao, Jianhua Wang*, Jie Ma, Jia Lin, Jinlong Peng, Dejun Qu, Lianzhong Chen, An Experimental Investigation on Transpiration Cooling under Supersonic Condition using a Nose Cone Model, International Journal of Thermal Sciences 84 (2014) 207-213.

[55] Shi J. X., Wang J. H., Inverse problem of estimating space and time dependent hot surface heat flux in transient transpiration cooling process, International Journal of Thermal Sciences, (2009)48:1398-1404.

[56] Shi J. X., Wang J. H.*, Optimized Structure of Two Layered Porous Media with Genetic Algorithm for Transpiration Cooling, International Journal of Thermal Sciences, (2008) 47:1595 -1601.

[57] Wang Xu, Xu Huazhao*, Wang Jianhua*, Song Wei, Wang Ming, Multi-objective optimization of discrete film hole arrangement on a high pressure turbine end-wall with conjugate heat transfer simulations, International Journal of Heat and Fluid Flow,78 (2019)108428.

[58]Fu-qiang Wang, Jian Pu*, Jianhua Wang, Weidong Xia, Numerical Investigation of Effects of Blockage, Inclination Angle, and Hole-Size on Film Cooling Effectiveness at Concave Surface, ASME Journal of Turbomachinery, 2021, vol. 143 / 021007-1.

[59]Yue-feng Li, Hua-zhao Xu, Jianhua Wang*, Wei Song, Ming Wang, Tai-qiu Liu, Xu Wang, Application of Scale Adaptive Simulation Model to Studying Cooling Characteristics of a High Pressure Turbine Blade Cutback Trailing Edge With Different Cooling Configurations, ASME Journal of Turbomachinery 2021, vol. 143 / 081010-1.

[60] Wenshuo Yang, Jian Pu, Jianhua Wang*, The Combined Effects of an Upstream Ramp and Swirling Coolant Flow on Film Cooling Characteristics, ASME Journal of Turbomachinery, Nov. 2016, Vol. 138 / 111008.

[61] Wang J. H., Shi J. X., Discussion of Boundary Conditions of Transpiration Problems Using LTNE Model, ASME Journal of Heat Transfer, Jan. 2008,Vol.130, No.1.

[62] Wang J. H., Wang H. N., A Discussion of Transpiration Cooling Problems Through an Analytical Solution of Local Thermal Non-Equilibrium Model, ASME Journal of Heat Transfer, Oct. 2006, Vol. 128, 1093-1098.

[63] Wenjie Dong, Jianhua Wang*, A New Model and its Application to Investigate Transpiration Cooling with Liquid Coolant Phase Change, Transp. Porous Med (2018) 122:575–593.

[64] Kuan Wei, Jianhua Wang*, Mao Mao, Model Discussion of Transpiration Cooling with Boiling, Transp. Porous Med., 25, April, 2012, DOI 10.1007/s11242-012-0006-0.

[65] J. X. Shi , J. H. Wang*, A Numerical Investigation of Transpiration Cooling with Liquid Coolant Phase Change, Transp. Porous Med., (2011) 87:703–716, DOI 10.1007 /s11242- 010 -9710-9.

[66] Shi J. X., Wang, J. H.*, A Numerical Investigation on the Laminar Boundary Flow Layer with Transpiration Cooling, Transp. Porous Med., 2008. 9. DOI 10.1007/s11242-008-9279 -8.

[67]Fei He, Jianhua Wang, Wenjie Dong & Nan Wu, Model comparison, thermal nonequilibrium characteristic and boundary conditions discussion of two-phase flow with phase change in porous media, Numerical Heat Transfer, Part B: Fundamentals, 2019, VOL. 76, NO. 2, 88–105.

[68] Wang J. H., Gan M., Detecting and Characterization of Penetrating Pores of Porous Materials, Materials Characterization, 58(2007)8-12.

[69]Fei He, Wenjie Dong, Jianhua Wang*, Modeling and Numerical Investigation of Transient Two-Phase Flow with Liquid Phase Change in Porous Media, Nanomaterials 2021, 11, 183.  

[70] Wang J. H., Han X. S., Numerical Investigation of Transpiration and Ablation Cooling, Heat Mass Transfer, (2007)43:274-284.

[71] Wang J. H., Wang H. N., Sun J. G., Wang J., Numerical Simulation of Control Ablation by Transpiration Cooling, Heat Mass Transfer, (2007) 43:471-478.

[72] Prasert Prapamonthon, Huazhao Xu, Zhaoqing Ke, Wenshuo Yang, Jianhua Wang*, Thermal barrier coating and turbulence intensity effects on leading edge cooling using conjugate heat transfer analysis, Transactions of the Canadian Society for Mechanical Engineering, Vol. 41, No. 2, 2017.

[73]He Fei, Wang Jianhua, Dong Wenjie, Wu Nan, Model comparison, thermal nonequilibrium characteristic and boundary conditions discussion of two-phase flow with phase change in porous media, Numerical Heat Transfer Part B-Fundamentals, 2019, Vol. 76, No. 2, 88–105.

[74] Lin Jia, Lingjin Zhao, Wang J. H.*, Numerical Investigation on Aerothermos-dynamic Characteristics of Wedge Shaped Nose Cone of Near Space Supersonic Flight, Applied Mechanics and Materials , Vols. 541-542 (2014) pp 608- 612.

[75] Lingjin Zhao, Lin Jia, Wang J. H.*, Jinlong Peng, Dejun Qu, Lianzhong Chen, An Experimental Investigation on Transpiration Cooling for Supersonic Vehicle Nose Cone using Porous Material, Applied Mechanics and Materials ,Vols. 541-542 (2014) pp 690-694.

[76] Wang J. H., Messner J., Stetter H., An Experimental Investigation of Transpiration Cooling, Part I- An Application Investigation on Infrared Measurement Technique, International J. of Rotating Machinery, April 2003, Vol 9, No. 3, 154-163.

[77] Wang J. H., Messner J., Stetter H., An Experimental Investigation of Transpiration Cooling, Part II- Comparison of Cooling Methods and Media, International J. of Rotating Machinery, Aug. 2004,Vol 9, No.10, 355-363.

[78] Peng L. M., Wang J. H., Li H., Zhao J. H., He L., Synthesis and Microstructural Characterization of Ti-Al 3 Ti Metal-intermetallic Laminate Composites, Scripta Materialia, 52 (2005) 243-248.

[79] Peng L. M., Wang J. H. , Li H., He L., Zhao J. H., Synthesis and Mechanical Properties of Ternary Molybdenum Carbosilicide and Its Composite, J. of Materials Science, 40 (2005) 2705-2707.

[80] Peng L.M., Li H., Wang J. H. , Processing and Mechanical Behavior of Laminated Ti- Al 3 Ti Composites, J. of Materials Science and Eng. A 406 (2005)309-318.

[81] Peng L. M., Li H., Wang J. H., Gong, M., High Strength and High Fracture Toughness Ceramic-iron Aluminid3 (Fe 3 Al) Composites, Materials Letters 60 (2006) 883-887.

[82] Peng L. M., Li H., Wang J. H., Gong, M., Synthesis and Microstructural Characterization of Aluminum Borate Whiskers, Ceramics International 32 (2006)365-368.

[82] Peng L. M., Wang J. H., Li H., Gong M., Processing and Mechanical Properties of Multiphase Composites Based on Mo-Si-Al-C system, J. of Alloys and Compounds 420(2006) 77-82.

[83] 栾芸,贺菲,王建华,飞行器鼻锥凹腔—发散组合冷却数值模拟,航空学报 2021.42(2)623937.

[84]周子鹤, 苏浩, 贺菲,王建华, 发散冷却系统冷却能力的数值分析, 航空动力学报,2021.06. 36(11)2363-2371.

[86]袁瑞明,浦 健*,王 位,王建华,栾永先, 温比对第一级导叶端壁气膜冷却特性的影响, 航空动力学报, (2018)33卷 第8期.

[87] 胡冰城,王建华*,徐华昭,吴伟龙,徐景亮, 具有热障涂层的导向叶片耦合数值研究, 航空动力学报, (2017)32卷 第10.

[88]林佳, 王建华*, 超音速飞行器鼻锥空间气动热特性数值研究,航空动力学报, (2014)29卷 第10.

[89] 马杰,林佳,王建华,液态水相变发散冷却的实验,航空动力学报,(2014)第29卷,第3,556-562.

[90] 贾闪,王晓春,王建华, 具有发散冷却功能的曲目结构边界层特性实验研究,航空动力学报,(2010)第25卷,第2.

[91] 吕锡嘉, 王建华*, 刘庆东, 吴向宇,应用红外热像技术实验研究层板结构冷却特性,航空动力学报(2009)第24卷,第10.

[92] 时骏祥,王建华*,基于遗传算法的双层发散冷却优化,航空动力学报,(2009)第24卷,第2.

[93] 谢远远,王建华*,发散冷却控制烧蚀过程的数值研究,航空动力学报,(2008)第23卷,第8.

[94] 时骏祥,王建华*,发散冷却最小冷却介质注射量的数值研究,航空动力学报,(2007)第22卷,第2.

[95] 马龙,王建华*,吴向宇,杜治能,利用红外技术进行层板冷却特性实验研究,航空动力学报,(2007)第23卷,第4.

[96] 孙纪国,王建华,烧结多孔结构的渗透和流阻特性研究,航空动力学报,(2008)第23卷,第1.

[97]王海南,王建华*,一维、稳态、非热平衡发汗冷却的解析解研究,航空动力学报,2006, vol.21, No.1, pp. 77-82.

[98] 杨帆,胡阳洋,王建华*,重型卡车风阻优化,交通运输工程学报,(2013)第3卷,第654-61.

[99] 张洪,王建华*,张清波,透平叶片顶部间隙流动特性的实验和数值研究,实验流体力学,(2012)第26卷,第3.

[100] 李谦,王建华*,吴向宇,杨士杰,冷却介质在层板内流动特性研究,第一部分,利用粒子图像测速技术再现复杂流场,实验流体力学,(2007)第21卷,第4.

[101] 王储,王建华*,杜治能,杨士杰,冷却介质在层板内流动特性研究,第二部分,数值模拟复杂结构内流场,实验流体力学,(2007)第21卷,第4.

[102] 苏杭,浦健*,王位,王建华,栾永先,一种降低端壁温度的离散气膜孔布置,工程热物理学报,(2018)第39卷,第7期。

[103] 张粜,浦健,徐帅,王建华, 横流下前向与反向复合角沟槽孔气膜冷却效率, 工程热物理学报,2021.09.42(5)1161-116.

[104] 王位,浦健,王建华,栾永先,康滨鹏, 改善局部难冷区域的一种导叶层板端壁, 工程热物理学报, 2020.03. 41(3)581-586.

[105] 王位,浦健,王建华,栾永先,康滨鹏,实验研究层板结构对端壁冷却的影响,工程热物理学报,(2019)第40卷,第6.

[106] 张粜,浦健,徐帅,王建华, 横流下前向与反向复合角沟槽孔气膜冷却效率, 工程热物理学报, 第42卷第5期, 20215.

[107] 冉方圆, 贺菲, 伍楠,王建华, 丙二醇改性水溶液的发汗冷却实验研究,推进技术, 2021.05(42)3, 587-592

[108] 周杰,王建华*,气动汽车高压气体减压过程的能量损失与补偿,液压与气动,(2007)第7期,28-32.

[109] 聂晶,王建华*, 叶片气动马达传动装置出口冷气特性研究,液压与气动,(2013)第11期,第267卷,75-83.

[110] 丁亮, 马杰, 王建华*, 烧结多孔介质渗透特性实验研究, 力学季刊, 33(3), pp 375-381, 2012/9.

[111] 王晓春, 王建华, 刘朋欣, 涡轮叶片端壁表面温度相似性研究, 热能动力工程, (2015) 01, pp 1-5+157.


   2、会议论文

[1] Fu-qiang Wang, Jian Pu*, Jian-hua Wang*, Wei-dong Xia, Numerical Investigation Of Effects Of Blockage, Inclination Angle And Hole-Size On Film Cooling Effectiveness At Concave Surface, ASME Turbo Expo 2020 Turbomachinery Technical Conference and Exposition,GT2020-15182.

[2] Yuefeng Li, Huazhao Xu, Jianhua Wang, Wei Song, Ming Wang, Taiqiu Liu, Xu Wang, Application Of Scale Adaptive Simulation Model To Studying Cooling Characteristics Of A High Pressure Turbine Blade Cutback Trailing Edge With Different Cooling, ASME Turbo Expo 2020 Turbomachinery Technical Conference and Exposition,GT2020-14234.

[3] Xu Wang, Huazhao Xu, Jianhua Wang, Yuefeng Li, Wei Song, Multi-objective 0imization on the fluid flow and heat transfer of Semi-attached rib-channels, ASME Turbo Expo Turbomachinery Technical Conference and Exposition, GT2021-58725.

[4] Wen-li Zhou, Jian Pu*, Tiao Zhang, Jian-hua Wang*, Wei-long Wu, Hang Su, Wall curvature effect on overall thermal performances of film Cooling covered by thermal barrier coatings with various geometries, ASME Turbo Expo 2022 Turbomachinery Technical Conference and Exposition,GT2022-82796.

[5] Weilong Wu, Huazhao Xu*, Jianhua Wang*, Xianyu Wu, Lei Wang, Numerical Investigation on the Influences of Pin-Fin on Cooling Air Flow of Turbine Blade Trailing Edge, ASME Paper, GT 2019-91989 June 17-21, 2019 in Phoenix, Arizona, USA.

[6] Wei Song, Ming Wang, Taiqiu Liu, Zhineng Du, Huazhao Xua*, Xiaofang Cheng, Jianhua Wang*, Numerical investigation on Cooling Air Flow and Resistance Characteristics inner Laminated Cooling Structures, ASME Paper, GT2019-92025 June 17-21, 2019 in Phoenix, Arizona, USA.

[7] Ran Yao, Jian-hua Wang*, Numerical Investigation on the Differences between Temperature Ratio and Density Ratio in Film-cooled Endwall, ASME Paper, GT 2018-75255 June 11-15, 2018, Oslo, Norway.

[8] Peng Wang, Jian Pu*, Ren-bin Yu, Jian-hua Wang, Bo Wan, Jian-Xia Luo, Shu-qing Tian, An experimental investigation on internal flow characteristics in a realistic and entire coolant channel with ribs and film holes, ASME Paper, GT2018-75715 June 11-15, 2018, Oslo, Norway.

[9] Kang Qian, Yadong WuZihe Zhou, Nan Wu, Fei He*, Jianhua Wang, Meng Wang,An Experimental Investigation on the Analogous Transpiration Cooling Utilizing Hydrogels as Coolants, The 4th International Conference on Mechanical and Aero-nautical Engineering (ICMAE) Dec. 2018, id : C017.

[10]Meng Wang, Fei He*, Nan Wu, Jianhua Wang, Guangqi Dong, Numerical Simulation of Transpiration Cooling within Variable Property of Water and Steam, The 4th International Conference on Mechanical and Aeronautical Engineering (ICMAE) Dec. 2018, Hong Kong, id : C018.

[11]Ran Yao, Jianhua Wang*, Wenshuo Yang, Wei Wang, Zhineng Du, Ming Wang, A Numerical Investigation on the Differences between Annular and Flat Film Cooled Endwalls, ASME Paper, GT2017-63337, June 26-30, 2017, Charlotte, NC, USA.

[12]Wei Wang, Jian Pu, Rui-ming Yuan, Jian-hua Wang, Bin-peng Kang, Yong-xian Ruan, An experimental investigation on the overall cooling performances of two turbine endwall structures, ASME GT2017-63226, June 26-30, 2017, Charlotte, NC, USA.

[13] N Wu, J H Wang*, L Shen, G Q Dong and J H Xie, Numerical study of a three dimensional interaction between two bow shock waves and the aerodynamic heating on a wedge shaped nose cone, ICMAE [C]187, 2016 Dec. 29-31, Hong Kong.

[14] Lin Shen, Jianhua Wang*, Wenjie Dong, A numerical investigation on aero-thermodynamic characteristics of a nose cone in wind tunnel and near space flight environment, International Conference on Computational Methods for Thermal Problems, [C] 220-223, 2016 July 6-8, Georgia Tech, Atlanta, USA.

[15] Wenjie Dong, Jianhua Wang*, Lin Shen, Effects of permeability on two-dimensional transpiration cooling, International Conference on Computational Methods for Thermal Problems, [C] 272-275, 2016 July 6-8, Georgia Tech, Atlanta, USA.

[16] Xue-yi Wang, Jian Pu, Rui-ming Yuan, Jian-hua Wang, Combined influences of surface deposition and hole-blockage on film-cooling performances. ASME GT2016-56902, June 13-17, 2016, Seoul, South Korea.

[17] Qingbo Zhang, Huazhao Xu, Jianhua Wang, Ge Li, Lei Wang, Xiangyu Wu, Shiyan Ma, Evaluation of CFD predictions using different turbulence models on a film cooled guide vane under experimental conditions, ASME GT2015-42563, June 15-19, 2015, Montréal, Canada.

[18] Wenshuo Yang, Jian Pu, Jianhua Wang*, Combination effects of upstream-ramp and swirling coolant flow on film cooling characteristics, ASME GT2015-43051, June 15-19, 2015, Montréal, Canada.

[19] Prasert Prapamonthon, Huazhao Xu, Wenshuo Yang, Jianhua Wang, Predicting Adiabatic Film Effectiveness of a Turbine Vane by Two-equation Turbulence Model, ASME GT2015-42565, June 15-19, 2015, Montréal, Canada.

[20] Zhaoqing Ke, Jian Pu, Jianhua Wang, Lei Wang, Zhiqiang Zhang, Xiangyu Wu, Investigation on Fluid Flow and Heat Transfer Performances within a Real Turbine Blade Channel, ASME Turbo Expo GT2014-25097, June 16-20, 2014, Düsseldorf, Germany.

[21] Huazhao Xu, Jianhua Wang*, Ting Wang, A Numerical Investigation of Stator-Rotor Interaction Effects on Flow Field and Film Cooling Effectiveness in a 3D Transonic Turbine Stage with Highly Twisted Rotors, ASME International Mechanical Engineering Congress & Exposition, IMECE2013-66784,Nov. 15-21, 2013, San Diego, California, USA.

[22] Huazhao Xu, Jianhua Wang*, Ting Wang,Numerical Investigations of Wake and Shock Wave Effects on Film Cooling Performance in a Transonic Turbine Stage, Part 2 – Unsteadiness Effect in a 2D Rotating Passage, ASME Turbo Expo GT2013-94545, June 3-7 , 2013, San Antonio, Texas, USA.

[23] Huazhao Xu, Jianhua Wang*, Ting Wang, Numerical Investigations of Wake and Shock Wave Effects on Film Cooling Performance in a Transonic Turbine Stage, Part 1–Methodology Development and Qualification over Stationary Stators and Rotors, ASME Turbo Expo GT2013-94544, June 3-7 , 2013, San Antonio, Texas, USA.

[24] Jian Pu, Zhaoqing Ke, Jianhua Wang, Lei Wang, Hongde You, An Experimental Investigation of Tip Coolant Ejection Effect on Internal Flow Behaviors Within a Realistic Blade Coolant Channel,ASME Turbo Expo GT2013-94136, July 3-7, 2013, San Antonio, Texas, USA.

[25] Jianhua Wang*, Xiaochun Wang, Lianjin Zhao, Fei He, Shiyan Ma, Changming Hao, An Experimental and Numerical Investigation on Endwall Film Cooling, ASME Turbo Expo GT2013-94267, July 3-7, 2013, San Antonio, Texas, USA.

[26] Zhixin Feng, Zhongwang Dou, Jianhua Wang, Shiyan Ma, Zhiqiang Zhang, Numerical Investigations of Cooling Enhancement with Internal Ribs and External Coolant Film, ASME Turbo Expo 2012 Power for Land, Sea, and Air, June 11-15, 2012, Copenhagen, Denmark, GT2012-68682.

[27] Chengyun Xin, Jianhua Wang*, Jianheng Xie, Yuee Song, Modeling and Numerical Simulations of Vapor-Liquid Flow and Heat Transfer within Micro-channel Heat Sinks, Proc. of the ASME 2012 3rd Micro/Nanoscale Heat & Mass Transfer International Conference, March 3-6, 2012, Atlanta, Georgia, USA, MNHMT2012-75239.

[28] Jianhua Wang*, Yejun Zhu, Jian Kuang, Xiaochun Wang, Numerical Investigation on Film Cooling Performances, ASME Turbo Expo 2011 Power for Land, Sea, and Air, June 6-10, 2011, Vancouver, Canada, GT2011-45775.

[29]Wang J. H.*, Liu Y. L., Wang X. C., Du Z. N., Yang S.J., Characteristics of Tip Leakage of the Turbine Blade with Cutback Squealer and Coolant Injection, ASME Turbo Expo 2010 Power for Land, Sea, and Air, June 14-18, 2010, Glasgow, UK, GT2010-22566.

[30]Wang J. H.*, Liu H. C., Mao M., Li X., Zhang Z. Q., Numerical Investigation of Fluid Flow and Heat Transfer Performances of Semiattached Rib Channel Design, ASME Turbo Expo 2010 Power for Land, Sea, and Air, June 14-18, 2010, Glasgow, UK, GT2010-22563.

[31]Zhang H., Wang J. H.*, Wu X. Y., Lu H. Y., A Simplified Approach to Design Transverse Ribs Which Array Alternately in Rectangular Channel, ASME Turbo Expo 2010 Power for Land, Sea, and Air, June 14-18, 2010, Glasgow, UK, GT2010-22562.

[32] Wang J. H.*, Lv X. J., Liu Q.D., Wu X. Y., An Experimental Investigation on Cooling Performance of a Laminated Configuration Using Infrared Thermal Image Technique, ASME Turbo Expo 2008 Power for Land, Sea, and Air, June 8-12, 2009, Orlando, Florida, USA, GT2009-59838.

[33] Wang J. H.*, Xu H. Z., Lv X. J., DuZ. N., Yang S. J., A Nunmerical Investigation on Fluid-Thermal- Structure Coupling Characteristics of Laminated Film Cooling Configurations, ASME Turbo Expo 2008 Power for Land, Sea, and Air, June 8-12, 2009, Orlando, Florida, USA, GT2009-59604.

[34] Wang, J. H.*, Xu, H. Z., Liu, Y. L., Du, Z. N., Yang, S. J., Experimental and Numerical Investigations on Turbine Airfoil Cooling Designs, Part I-An Investigation on Flow Features by Particle Image Velocimetry, ASME Turbo Expo 2008 Power for Land, Sea, and Air, June 14-17, 2008, Berlin, Germany, GT2008-50673.

[35] Wang, J. H.*, Xu, H. Z., Liu, Y. L., Wu, X. Y., Yang, S. J., Experimental and Numerical Investigations on Turbine Airfoil Cooling Designs, Part II-An Investigation on Heat Transfer Features by Infrared Thermal Imaging Technique, ASME Turbo Expo 2008 Power for Land, Sea, and Air, June 14-17, 2008, Berlin, Germany, GT2008-50674.

[36] Wang, J. H., Messner, J., Casey, V. M., Performance Investigation on Film and Transpi- ration Cooling, ASME Turbo Expo 2004 Power for Land, Sea, and Air, 14-17 June 2004, Vienna, Austria,GT2004-54132, ISBN: 0-7917-3739-4.

[37] Wang H. N., Wang, J. H.*, A Numerical Investigation of Ablation and Transpiration Cooling Using the Local Thermal Non-equilibrium Model, Proc. of 42nd AIAA/ASME/ SAE /ASEE Joint Propulsion Conference & Exhibit, 2006 July 09-12, Sacarmento California, USA AIAA -5264.

[38] Yun Luan, Junhang Luo, Beibei Wu, Fei He, Jianhua Wang, Transient numerical investigation of a thermal-driving water pipe cooling system, 2021 7th International Conference on Mechanical Engineering and Automation Science (ICMEAS),68-74.

[39] Exit-Shape Effect Of Film Holes At Pressure Side On Trailing Edge Cutback Film Cooling Characteristics2020.04Proceedings of the Fourth Chinese International Turbomachinery Conference

[40] Meng Wang, Jianhua Wang*, Fei He*, Kang Qian, Yadong Wu, Guangsheng Zhu, Numerical comparison of transpiration cooling designs using real gas effects and approximate gas model, Journal of Physics: Conference Series, 2021.11,2097, 012021.

[41]Yi Li, Jianhua Wang*, Xu Wang*, Weilong Wu, Hang Su, Influences of Pressure ratio and Fluid Temperature on overall Cooling Performances of Ribbed Channel with Film Holes, Journal of Physics: Conference Series, 2021.11,2087,012043.

[42] Tiao Zhang, Jian Pu, Jian-Hua Wang, Eexperiment Study of Time-Resolved Film Cooling Effectiveness of Compound-Angled Fan-Shaped Film-Hole at Curved Wall, GPPS-TC-2021-0257.

[43] Jianhua Wang, Salman Khalid, Fei He, Wanfan Wu, Electrochemical Kinetic Property Determination of MIECs by Comprehensive Multi-physical Coupling Model, 020 IOP Conf. Ser.: Mater. Sci. Eng. 751 (2020) 012053.

[44] Wang, J. H., Messner, J., Stetter, H., An Experimental Investigation of Transpiration Cooling, Part I- An Application Investigation on Infrared Measurement Technique, Proc. ISROMAC-9, 10-14 Feb. 2002, Honolulu, Hawaii, USA.

[45] Wang, J. H., Messner, J., Stetter, H., An Experimental Investigation of Transpiration Cooling, Part II- Comparison of Cooling Methods and Media, Proc. ISROMAC-9, 10-14 Feb. 2002, Honolulu, Hawaii, USA.

[46] Stetter, H., Wang, J. H., Basic Performance Characteristics of a Transpiration Cooling Method for Turbine Nozzle Guide Vane Using Evaporating Liquids, [C] The 4th European Conference on Turbomachinery, 20-23 March 2001, Firenze, Italy , ISBN 88-86281-57-9.

[47] Stetter, H., Wang, J. H., Messner, J., An Experimental Investigation of Transpiration Cooling, Part I- Feasibility Test and Performance Estimation, [C] ISROMAC-8, 26-30 March 2000 Honolulu, Hawaii, USA, Vol. 1, pp.778-785.

[48] Wang, J. H., Stetter, H., An Experimental Investigation of Transpiration Cooling, Part II- Performance Comparison With Film Cooling, [C] ISROMAC-8, 26-30 March 2000, Honolulu, Hawaii, USA, Vol. 1, pp.786-792.

[49] Wang, W., Pu, J., Wang, J.H., Luan, Y.X., Kang, B.P., An experimental investigation of cooling characteristics at a vane laminated end-wall, Proc. of the 16th International Heat Transfer Conference, Aug. 2018 Beijing, IHTC 16-23446.

[50] Ding Rui, He Fei*, Wang Jianhua, Tang Longsheng, Dong Guangqi, Numerical Investigation on the Performance of transpiration Cooling combined with Film Cooling2018.08Proc. of the 16th International Heat Transfer Conference, Aug. 2018 Beijing,IHTC16-23577.

[51] Hao Su, Fei He*, Jianhua Wang, Liang Chen, Bangcheng Ai, Numerical investigation on the cooling performance and configuration optimization of transpiration cooling with phase change, Proc. of the 16th International Heat Transfer Conference, Aug. 2018 Beijing,IHTC16-23916.

[52] Prasert Prapamonthon, Huazhao Xu, Jianhua Wang. Film Cooling Performances at Different Turbulence Intensities Using Conjugate Heat Transfer Analysis. Proceedings of the Second International Conference on Applied Engineering, Materials and Mechanics 2017, April 14-16, 2017, Tianjin, China, CMM149.

[53] Fei He, Liang Ding, Hong Zhang, Jianhua Wang, The Transportation Characteristics of Porous Media at High Temperature, International Conference on Remote Sensing, Environment and Transportation Engineering (RSETE), 2011, 6545-6548.

[54] Liang Ding, Kuan Wei, Qian Zhang, Jianhua Wang, An Experimental Investigation on Transpiration Cooling of Porous Flat Plate, International Conference on Remote Sensing, Environment and Transportation Engineering (RSETE), 2011.

[55]Qian, Kang ;Wu, Yadong ;Zhou, Zihe ;Wu, Nan ;He, Fei ;Wang, Jianhua ;Wang, Meng, An Experimental Investigation on the Analogous Transpiration Cooling Utilizing Hydrogels as Coolants, IOP Conference Series: Materials Science and Engineering, 2019.03.

[56] Wang, Meng ;He, Fei ;Wu, Nan ;Wang, Jianhua ;Dong, Guangqi, Numerical Simulation of Transpiration Cooling within Variable Property of Water and Steam,IOP Conference Series: Materials Science and Engineering, 2019.03.

[57] Hao Su, Fei He, Jianhua Wang, Liang Chen, Bangcheng Ai, Numerical investigation on the cooling performance and configuration optimization of transpiration cooling with phase change, Proceedings of the 16th International Heat Transfer Conference, 2018.08.

[58] Ding Rui, He Fei, Wang Jianhua, Tang Longsheng, Dong Guangqi, Numerical investigation on the performance of transpiration cooling combined with film cooling,Proceedings of the 16th International Heat Transfer Conference,2018.08.