王 平 教授 博士生导师

邮箱：pingwang@ujs.edu.cn

地址：江苏大学 能源研究院

研究方向：湍流燃烧、大涡模拟、燃烧诊断、燃气轮机清洁燃烧技术、可替代燃料燃烧技术

个人履历：2001-2005年在瑞典隆德大学学习，获工学博士学位。2005-2011年在德国卡尔斯鲁厄大学任助理研究员，是德国科学基金会SFB606项目中A6、B10子项目的主要研究人员，专注于燃气轮机燃烧室中贫油预混合燃烧的大涡模拟研究。在德累斯顿工业大学做访问学者期间，负责指导了3名来自英国Loughborough大学的ERASMOS项目硕士研究生。2012年回国从事科研和教学工作，迄今主持国家自然科学基金面上项目2项，江苏省自然科学基金面上项目2项，及上海电气集团及其他企业科技开发项目10余项，发表学术论文100余篇，SCI、EI收录50余篇，建立了一个设备比较齐全的燃烧实验室，拥有发明专利、软件著作权7项。目前与上海电气集团、意大利燃烧与环境中心（CCA）、意大利赛斯塔（Sesta）燃烧实验室等建立了密切的科研合作关系，并与CCA建立了“中意燃气轮机燃烧技术国际联合实验室”，共同开展燃气轮机燃烧技术的研究。

研究方向：

氨-氢零碳燃料清洁燃烧技术

燃气轮机燃烧技术

湍流燃烧的大涡模拟及实验测量

亚网格燃烧模型的应用与开发

贫燃预混、部分预混、分级燃烧技术

承担项目

2026-2029，富燃-淬熄-贫燃(RQL)燃烧模式下氨气湍流燃烧耦合机理与NOx生成机制研究，国家自然科学基金面上项目，编号: 52576119，主持

2023-2026，30兆瓦燃气轮机纯氢微混燃烧喷嘴开发及验证，无锡明阳氢燃动力科技有限公司，主持

2023-2024，湍流旋转氨气火焰的稳定性及排放特性的实验与大涡模拟研究，浙江大学能源清洁利用国家重点实验室开放基金课题，编号： ZJUCEU2022020

2023-2023，氢燃料燃气轮机清洁燃烧系统燃烧性能仿真分析，无锡明阳氢燃动力科技有限公司，主持

2022-2027，泰州盛欣印染机械有限公司产学研合作项目，主持

2022-2025，江苏叶茂厨卫科技有限公司产学研合作项目，主持

2020-2021，针对下一代的洁净燃烧技术开发火焰图像处理工具，江苏省科技厅“省外专百人计划”项目，编号：BX2019115，主持

2019-2021，燃烧热声震荡动态测量技术开发及验证，上海电气集团有限责任公司，编号：20190452，主持

2019-2020，带压层流预混平面火焰数值仿真研究，中国空气动力研究与发展中心，主持

2018-2020，含氢中、低热值燃气在分层燃烧模式下燃烧稳定性的实验及LES研究，国家自然科学基金“面向发动机的湍流燃烧基础研究”重大研究计划培育项目，编号：91741117，主持

2016-2019，受限空间内湍流部分预混燃烧特性及模型研究，国家自然科学基金面上项目，编号: 51576092，主持

2016-2019，湍流燃烧大涡模拟计算模型研究及程序开发，上海电气燃气轮机有限公司，主持

2015-2018，生物质二甲醚在燃气轮机中与天然气掺混燃烧机理研究，江苏省自然科学基金，编号：BK20151344，主持

2012-2015，低压预混合CH₄/air火焰受激振荡的高精度数值模拟研究（12JDG032），江苏大学高级人才科研启动基金项目，主持

2009-2012，燃烧室内振荡流动的大涡模拟研究，德国科学基金会，SFB606-B10

2005-2008，带引射火焰的燃烧器中振荡流动问题的大涡模拟研究，德国科学基金会，SFB606-A6

主讲课程

燃烧学(本科生)，燃烧科学与技术(本科生)，湍流燃烧与工程应用(硕士生)，燃烧诊断学(硕士生)，燃烧理论与燃烧系统(硕士生)，气液燃烧理论与工程应用(博士生)

学术及科研成果

论文

[1] Ping Wang*, Jinzhao Zhang, Ruiyang Shuai, Agustin Valera-Medina, Weijia Qian, Antonio Ferrante, Haotian Qi, Yongzhi Wang. Effects of combustor geometry on NH3-CH4 swirling turbulent premixed flames: a combined experimental and large eddy simulation analysis of combustion dynamics and NO emissions. International Journal of Hydrogen Energy 180 (2025) 151775.

[2] Ping Wang*, Ruiyang Shuai, Jinzhao Zhang, Zeyu Zhang, Agustin Valera-Medina, Weijia Qian, Antonio Ferrante, Haotian Qi, Yongzhi Wang. Impact of Reynolds number on the flow field structure and NOx emissions in turbulent NH3-CH4-air flames within a swirl burner. Applied Thermal Engineering, 2025, 127981.

[3] Ping Wang*, Zeyu Zhang, Zhengchun Yang, Subhajit Roy, Weijia Qian, Kang Cheng. Exploring the combustion characteristics of turbulent premixed ammonia/ hydrogen/ air flames via DTF model-based large eddy simulation. Thermal Science 2025 29(1B), 675-689.

[4] Ping Wang*, Zeyu Zhang, Kang Cheng, Ruiyang Shuai, Weijia Qian, Wenfeng Liu, Ferrante Antonio. LES of turbulent NH3-CH4-air lean premixed swirling flame and improving the prediction accuracy of chemical reactor network method under different wall temperature/heat loss effects. Fuel 379 (2025) 133064, 1-13.

[5] 帅瑞洋，王平*，钱伟佳，戴凯论，张泽雨，ROY Subhajit. 雷诺数对NH3-CH4 预混旋流火焰燃烧特性的影响. 推进技术, 2025,46(7): 2406062.

[6] 张泽雨, 王平*, 戴凯论, 钱伟佳, Roy Subhajit, 帅瑞洋, Ferrante Antonio. 轴向双级氨/甲烷湍流预混火焰燃烧特性及NO生成. 化工学报, 2025, 76(2): 835-845.

[7] Weijia Qian, Ruiyang Shuai, Qingkun Meng, Subhajit Roy, Songbai Yao, Ping Wang*. Mechanistic Insights into Effects of Perforation Direction on Thermal Hydraulic Performance of Ribs in a Rectangular Cooling Channel. Aerospace 2024, 11, 675.

[8] Ping Wang*, Zeyu Zhang, Kang Cheng, Weijia Qian, Ruiyang Shuai, Kailun Dai , Antonio Ferrante, Haotian Qi. Large eddy simulations and experimental studies of the influence of equivalence ratio on the combustion characteristics of turbulent NH3-CH4 premixed flames. Physics of Fluids 2024, 36, 125131, 1-13.

[9] Weijia Qian, Ruiyang Shuai, Qingkun Meng, Subhajit Roy, Songbai Yao, Ping Wang*. Mechanistic Insights into Effects of Perforation Direction on Thermal Hydraulic Performance of Ribs in a Rectangular Cooling Channel. Aerospace 2024, 11, 675.

[10] Ping Wang*, Wenfeng Liu, Weijia Qian, Kang Cheng, Yongqian Wang, Subhajit Roy, Investigation of no emission characteristic of ammonia-hydrogen flame in a two-stage model combustor. Thermal Science, 2024, 28(2C), 1689-1699.

[11] Subhajit Roy, Ruiyang Shuai, Ping Wang*, Zeyu Zhang, Weijia Qian, Antonio Ferrante, Kailun Dai, Combustor shape optimization and NO emission characteristics for premixed NH3-CH4 turbulent swirling flame towards sustainable combustion, Aerospace Science and Technology, 150, 2024, 109216, 1-13.

[12] Seyed Mohammad Hashemi, Ping Wang*, Chenlin Mao, Kang Cheng, Ying Sun and Zhicheng Yin. Experimental study on the pollutant emissions of premixed ammonia/methane/air flame within porous burner. Proceedings of the Institution of Mechanical Engineers Part C-Journal of Mechanical Engineering Science, 238(9), 2024, 4139-4146.

[13] Seyed Mohammad Hashemi, Ping Wang*, Chenlin Mao, Kang Cheng, Ying Sun, Zhicheng Yin, Combustion performance of the Premixed Ammonia-Hydrogen-Air Flame in Porous Burner, Combustion Science and Technology, (2024) 196(16), 4121–4138.

[14] 杨证淳，王平*，钱伟佳，张泽雨，程康.旋流数对氨气-甲烷旋流预混合火焰燃烧特性的影响研究.推进技术, 2024, 45(10): 2308025. 1-8.

[15] 刘文锋,帅瑞洋,王平*,钱伟佳,王永倩,杨证淳,张泽雨, Antonio Ferrante.湍流旋流氨气–甲烷预混火焰燃烧特性研究. 工程热物理学报, 45(6) 2024, 1598-1604.

[16] 袁梦铖,王平*,张洋, 田野，陈爽，程康.氢燃料双模态冲压发动机火焰结构及其稳定机制的LES研究[J].推进技术,2024,45(01):158-169.

[17] Benoît Fiorina*, Tan Phong Luu, Samuel Dillon, Renaud Mercier, Ping Wang, Lorenzo Angelilli, Pietro Paolo Ciottoli et al., A joint numerical study of multi-regime turbulent combustion, Applications in Energy and Combustion Science. 16 (2023) 100221.

[18] Mustafa Alnaeli, Mohammad Alnajideen*, Rukshan Navaratne, Hao Shi, Pawel Czyzewski, Ping Wang, Seven Eckart, Ali Alsaegh, Ali Alnasif, Syed Mashruk, Agustin Valera Medina, Philip John Bowen. High-Temperature Materials for Complex Components in Ammonia/Hydrogen Gas Turbines: A Critical Review. Energies 2023, 16, 6973.

[19] Alnasif A, Mashruk S, Shi H, Alnajideen M, Wang Ping, Pugh D, Valera-Medina A*, Evolution of ammonia reaction mechanisms and modeling parameters: A review. Applications in Energy and Combustion Science 15(2023) 100175, 1-17.

[20] Mengcheng Yuan, Ping Wang*, Yang Zhang, Ye Tian, Shuang Chen, Subhajit Roy, Kang Cheng, Large eddy simulation of a dual-mode scramjet with direct injection: Flame dynamics under flow separation induced by heat-release. Aerospace Science and Technology, 139(2023)108401, 1-13.

[21] Prashant Shrotriya, Ping Wang*, Hai-xiang Zeng, Xi-rui Zhou, Antonio Ferrante, Fei Tian, Large eddy simulation of partially premixed flames with inhomogeneous inlets based on the DTF combustion model. Aerospace Science and Technology, 139 (2023) 108400, 1-17.

[22] Mengcheng Yuan, Ping Wang*, Yang Zhang, Antonio Ferrante, Large eddy simulation of flame and thermal-acoustic characteristics in a strut-based scramjet with dynamic thickened flame model. Case Studies in Thermal Engineering 41, (2023), 102560, 1-12.

[23] 程康,王平*,毛晨林,Valera-Medina Agustin,王永倩,杨证淳,刘文锋,田飞, 氨气-氢气富燃湍流旋转火焰的大涡模拟,燃烧科学与技术, 2023, 29(5): 561-568.

[24] 孙颖，王平*，姜霖松，尹智成，Antonio Ferrante, 随机填充型多孔介质材料的表面燃烧现象, 西华大学学报（自然科学版），2023, 42(3): 78-85.

[25] 尹智成, 王平*, 姜霖松, 孙颖, 何祖强. 简单立方堆积床内火焰特性的试验研究. 上海交通大学学报, 2023, 57(3): 326-334.

[26] 孙晨洋，王平*，祁浩天，袁梦铖，基于FW-H方程的涡扇发动机射流噪声特性数值研究，噪声与振动控制，2023, 43(1): 154-158.

[27] Haotian Qi, Ping Wang*, Linsong Jiang, Numerical Investigation on Aerodynamic Performance and Interaction of a Lift-Offset Coaxial Rotor in Forward Flight, International Journal of Aeronautical and Space Sciences (2022) 23:255–264.

[28] Haotian Qi*, Ping Wang*, Linsong Jiang, Yang Zhang, Investigation on Aerodynamic Noise Characteristics of Coaxial Rotor in Hover, Applied Science 2022, 12, 2813.

[29] Alnasif*, S. Mashruk, M. Kovaleva, Ping Wang, A. Valera‑Medina, Experimental and numerical analyses of nitrogen oxides formation in a high ammonia‑low hydrogen blend using a tangential swirl burner, Carbon Neutrality (2022) 1:24，1:20.

[30] Ping Wang*, Xiangyu Wei, Prashant Shrotriya, Weichao Li, Antonio Ferrante, Investigation of Isothermal Flow inside a New Combustor with Two-Stage Axial Swirler, Journal of Applied Fluid Mechanics, Vol. 15, No. 2, pp. 325-336, 2022.

[31] Ping Wang, Seyed Mohammad Hashemi*, HongkaiHe, KangCheng, Investigation of the partially premixed turbulent combustion through the PRECCINSTA burner by large eddy simulation, Aerospace Science and Technology, 121(2022), 107336.

[32] 袁梦铖,王平*,俞南嘉,张洋,程康,基于动态火焰增厚模型气氧/气甲烷剪切火焰燃烧不稳定性的LES 研究. 推进技术，2022，43(12): 210808. 220-228.

[33] 王永倩,王平*,程康,毛晨林,刘文锋,尹智成,Antonio Ferrante, 氨气/甲烷贫预混旋转湍流火焰稳定性及NO生成. 化工学报, 2022，73(9):4087-4094.

[34] 徐欣宇、王平*、姜霖松、李伟超、曾海翔、何祖强、Prashant Shrotriya, 双旋流火焰不稳定性模态转变研究, 燃烧科学与技术, 2022, 28(4): 471-480.

[35] 曾海翔，王平*，Prashant Shrotriya，姜霖松，Meenatchidevi Murugesan，带有局部熄火现象的部分预混火焰大涡模拟研究，上海交通大学学报, 2022, 56(1):35-44.

[36] 周希瑞，王平*，曾海翔，张洋，Prashant Shrotriya，Antonio Ferrante，祁浩天，甲烷及掺氢燃气吹熄极限的大涡模拟研究，上海交通大学学报, 2022, 56(5): 635-647.

[37] 尹智成, 王平*, 姜霖松, Seyed Mohammad Hashemi. 随机堆积床中过滤燃烧的实验研究. 热能动力工程，2022, 37(11):115-121.

[38] 毛晨林, 王平*,Prashant Shrotriya,何宏凯,Antonio Ferrante. 含氨燃料预混火焰的层流火焰速度及NO排放特性. 化工学报, 2021, 72(10): 5330-5343.

[39] 何祖强，王平*，Murugesan Meenatchidevi，Ferrante Antonio，李伟超，姜霖松，新型双旋流燃烧室热声振荡的实验研究，实验流体力学，2021，35(1):44-52.

[40] 徐欣宇，王平*，余倩，曾海翔，不同混合物浓度梯度下三重火焰的直接数值模拟，江苏大学学报，2021,42(1)：118-124.

[41] Prashant Shrotriya, Ping Wang*, Linsong Jiang, Meenatchidevi Murugesan, REDIM-PFDF modelling of turbulent partially-premixed flame with inhomogeneous inlets using Top-hat function for multi-stream mixing problem, Aerospace Science and Technology. 2020, V107, 106258:1-11.

[42] Hongkai He, Ping Wang*, Liang Xu, Qian Xu, Linsong Jiang, Prashant Shrotriya, LES of lean premixed swirling flames via dynamically thickened flame model coupling with the REDIM chemistry table, Combustion, Explosion, and Shock Waves, 2020, 56(6), pp. 634–647.

[43] Prashant Shrotriya, Ping Wang*, Linsong Jiang, Meenatchidevi Murugesan, REDIM-PFDF Sub-grid Scale Combustion Modeling for Turbulent Partially-premixed Flame: Assessment of Combustion Modes, Combustion Science and Technology, 2020, 194(4): (1782391): 745-767.

[44] Haixiang Zeng, Ping Wang*, Qian Yu, Meenatchidevi Murugesan, Linsong Jiang, Prashant Shrotriya, Direct numerical simulation of triple flames by using 2D Reaction-Diffusion Manifold tabulation method, Thermal Science, 2021, Vol 25, No. 4A, pp. 2653-2664

[45] 曾海翔，王平*，余倩，李伟超，陈明敏，三岔火焰及分层火焰的直接数值模拟分析，燃烧科学与技术，2019，25(6)：524-532.

[46] P. Shrotriya, Ping Wang*, M. Chen, L. Jiang, Assessment of multiple combustion modes present in turbulent partially-premixed flame by REDIM-PFDF Model, 12th Asia-Pacific Conference on Combustion, Fukuoka International Congress Center, Fukuoka, Japan 1st -5th July 2019, No. 1089.

[47] P. Shrotriya, Ping Wang*, Computational Study of Turbulent Partially-Premixed Flame with Inhomogeneous Inlets, ICDERS, July 28th – August 2nd, 2019 Beijing, China.

[48] 曾海翔,王平*, P. Shrotriya, T. Zirwes,姜霖松, 基于动态增厚火焰模型的部分预混火焰大涡模拟研究, 2019年中国工程热物理学会燃烧学学术年会，编号：194332，天津，2019.10.24-27.

[49] 李伟超，王平*,侯天增，余倩，陈明敏，曾海翔, 非均匀入流部分预混射流火焰的大涡模拟, 燃烧科学与技术, 2019，25(1)：066-072.

[50] Ping Wang*, Q. Yu, P. Shrotriya, M. Chen, Numerical analysis of equivalence ratio fluctuations ina partially premixed gas turbine combustor using LES, ASME Journal of Engineering for Gas Turbines and Power, 2019, 141(4): 041010. (SCI)

[51] 徐亮，王平*，余倩，侯天增，王海连，陈明敏，何磊，基于DTF和REDIM技术构建的亚网格燃烧模型及其验证，推进技术，2019，40(2) 347-354.

[52] 余倩，王平*，P Shrotriya，张春，曾海翔，李伟超，三重火焰及分层火焰的直接数值模拟分析，2018年中国工程热物理学会燃烧学学术年会，编号：184001，哈尔滨，9.13-16.

[53] Prashant Shrotriya, Ping Wang*, Hou-tian Zeng, Qian Yu, Z.C.，Large Eddy Simulation of Turbulent Partially Premixed Flame with Inhomogeneous Inlets, 2018年中国工程热物理学会燃烧学学术年会，编号：184052，哈尔滨，9.13-16.

[54] Ping Wang*, Tian-zeng Hou, Cai-jun Wang, Gerd Steinhilber, Ulrich Maas, Large Eddy Simulations of the Darmstadt Turbulent Stratified Flames with REDIM Reduced Kinetics, Flow, Turbulence and Combustion, 2018, 101(1), 219–245.

[55] 王平*，余倩，王宝同，徐亮, 燃气轮机旋流通道小孔射流问题的大涡模拟研究, 江苏大学学报, 2018, 39(4)，377-384.

[56] 张春，王平*，侯天增，王蔡军，余倩，剪切层强度对湍流分层火焰传播特性的影响，燃烧科学与技术，2018，24(4) 376-382.

[57] 王平*，侯天增，余倩, 火焰增厚燃烧模型计算旋转预混火焰的参数敏感性分析, 推进技术, 2018, 39(2), 358-365.

[58] 王平*,张春,候天增,王蔡军,余倩,湍流分层火焰中分层剪切效应的大涡模拟研究,中国工程热物理学会燃烧学年会，南京，2017，编号：174038.

[59] 徐亮,王平*,余倩,侯天增,基于DTF和REDIM技术构建的亚网格燃烧模型,中国工程热物理学会燃烧学年会，南京，2017，编号：174045.

[60] 侯天增,王平*,余倩,王蔡军,非均匀射流部分预混火焰的大涡模拟研究,中国工程热物理学会燃烧学年会，南京，2017，编号：174303.

[61] Liang Xu, Ping Wang*, Qian Yu, Tian-zeng Hou, A sub-grid scale combustion model based on thickened-flame method and REDIM chemistry table, 11th Asia-Pacific Conference on Combustion, The University of Sydney, Australia, 10th -14th December 2017, No. 133.

[62] Tian-zeng Hou, Ping Wang*, Qian Yu, Cai-jun Wang, Large Eddy Simulation of Turbulent Flame with Inhomogeneous Inlets, 11th Asia-Pacific Conference on Combustion, The University of Sydney, Australia, 10th -14th December 2017, No. 132.

[63] 王平*，王宝同，滤波PDF积分方法对湍流火焰计算的影响，江苏大学学报，2016,37(12)：134-140.

[64] Ping Wang*, J. Froehlich, U. Maas, Z.X. He, C.J. Wang，A detailed comparison of two sub-grid scale combustion models via large eddy simulation of the PRECCINSTA gas turbine model combustor, Combustion and Flame, 164:329–345,2016.

[65] 王蔡军，陆少杰，王平*，Darmstadt 大学湍流分层火焰的大涡模拟研究，2015年中国工程热物理学会燃烧学分会年会，北京，编号：154163.

[66] 王蔡军，陆少杰，王平*, 基于REDIM方法构建的亚网格燃烧模型及其应用，化工学报,2015,66(12): 4948-4959. （EI）

[67] Lu Shao-jie, Wang Cai-jun, Ping Wang*, Large Eddy Simulation of the Darmstadt Turbulent Stratified Flame with REDIM Chemistry Table, The 10th Asia-Pacific Conference on Combustion, paper no. 135, July 19-22, 2015, Beijing, China.

[68] 李宁宁，王平*，王蔡军，一种基于MMC和REDIM技术的燃烧模型，工程热物理学报，2015(4)：912-916.

[69] 王平*，陆少杰，两种亚网格燃烧模型的对比研究，工程热物理学报，2014(12)：2526-2530.

[70] 陆少杰，王平*，王宝同，李宁宁，贫燃预混湍流分层火焰的大涡模拟研究，2014年中国工程热物理学会燃烧学分会年会，西安，编号：144106.

[71] Ping Wang*, Platova N.A., Froehlich J., Maas U., Large Eddy Simulation of the PRECCINSTA burner, International Journal of Heat and Mass Transfer, 70: 486-495, 2014. （SCI）

[72] Ping Wang*, Zieker F., Schiessl R., Platova N.A., Froehlich J., Maas U., Large eddy simulations and experimental studies of turbulent premixed combustion near extinction, Proceedings of the Combustion Institute 34: 1269-1280, 2013. （SCI)

[73] Ping Wang**, Large eddy simulation of an industry gas-turbine model combustor using REDIM technique, Asian congress on gas turbines: tradition, challenge and future, ACGT2012-2077, Shanghai, 2012.08.20-22

[74] 王平，某工业燃气轮机模型燃烧室内贫油预混合旋转火焰的大涡模拟研究，高等学校工程热物理第十八届全国学术会议，编号C-120016，2012.05.17-20，广州

[75] Ping Wang*, Zieker F., Schiessl R., Platova N.A., Froehlich J., Maas U., Large eddy simulation and experimental studies of turbulent premixed combustion near extinction. Proceedings of the 5th European Combustion Meeting, 28 Jun. – 1 July, paper no. 355:1-6, Cardiff, UK, 2011.

[76] Ping Wang* Froehlich J., Maas U., LES of turbulent premixed swirling flames in complex geometry using thickened-flame type of models. Proceedings of the 5th European Combustion Meeting, 28 Jun. – 1 July, paper no. 356:1-6, Cardiff, UK, 2011.

[77] Platova N.A., Wang Ping*, Froehlich Jochen, Maas Ulrich, REDIM with presumed FDF for LES of turbulent premixed flame. Proceedings of the 7th International Symposium on Turbulence and Shear Flow Phenomena, 28-31 July, Paper no. 3B1P:1-6, Ottawa, Canada, 2011.

[78] Wang Ping*, Froehlich J., Maas U., Impact of location and flow rate oscillation of the pilot jet on the flow structures in swirling premixed flames. Journal of Turbulence, 11(11): 1-19, 2010. （SCI）

[79] Wang Ping*, Froehlich J., Maas U., Large-eddy simulation of lean premixed flames in a model swirl burner. High Performance Computing in Science and Engineering’2009, editors: W.E. Nagel, D.B. Kr?ner, M.M. Resch, pp. 209-223.

[80] Wang Ping*, Froehlich J., Maas U., Large eddy simulation of a lean premixed swirl flame in complex geometry - comparison of two turbulent combustion models. The 12th EUROMECH European Turbulence Conference, Marburg, Germany, Sept. 2009, pp. 885-888.

[81] Wang Ping*, Froehlich J., Impact of reaction and location of a pilot jet on the flow structures in a co-annular swirl burner. The 6th international symposium on Turbulence and Shear Flow Phenomena (TSFP-6), Seoul, Korea, June, 2009, pp. 327-332.

[82] Wang Ping*, Froehlich J., Flame response to a pulsating pilot jet in an unconfined double-concentric swirl burner. European Combustion Meeting, Vienna, Austria, April, 2009, Paper-811389.

[83] Wang Ping*, Froehlich J., Michelassi V., Rodi W., Impact of density difference on turbulent round jets. High Performance Computing in Science and Engineering ’2008, editors: W.E. Nagel, D.B. Kr?ner, M.M. Resch. 2009, pp.285-299.

[84] Wang Ping*, Froehlich J., Michelassi V., Rodi W., Large eddy simulation of variable density turbulent axisymmetric jets. Int. Journal of Heat and Fluid Flow, 29: 654-664, 2008. （SCI）

[85] Wang Ping*, Froehlich J., Michelassi V., Rodi W., Large eddy simulation of variable density turbulent axisymmetric jets. The 5th international symposium on Turbulence and Shear Flow Phenomena (TSFP-5), Munich, Germany, August, 2007.

[86] Wang Ping, Bai X.S., Wessman M., Klingmann J., Large eddy simulation and experimental studies of a confined turbulent swirling flow. Physics of Fluids, Vol. 16(9), 3306-3324, 2004. （SCI）

[87] Wang Ping, Bai X.S., Large eddy simulation of turbulent swirling flows in a dump combustor: a sensitivity study. Int. Journal for Numerical Methods in Fluids, vol. 47: 99-120, 2004. （SCI）

[88] Wang Ping, Bai X.S., Large eddy simulation of turbulent premixed flames using level-set G equation. Proceedings of the Combustion Institute, vol. 30: 583-591, 2005. （SCI）

[89] Wang Ping, Bai X.S., Large eddy simulation of premixed turbulent flames by G-equation, The 3rd Mediterranean Combustion Symposium, Marrakech, Morocco. 8-13, June, 2003.

[90] Zhu Z.Q., Wang P., Tuo S.F., An adaptive solution of the 3-D Euler equations on an unstructured grid. ACTA Mechanics, No.155, 215-231, 2002. （SCI）

[91] 王平，朱自强，拓双芬。 多点择优推进阵面法生成曲面三角形网格。中国计算物理，19(3)， 213-216，2002。

[92] 王平，朱自强，拓双芬，尹幸愉。二维结构/非结构混合网格的生成及其流场模拟。中国航空学报，22(6)，536-538，2001。（EI）

[93] 王平，朱自强，拓双芬，尹幸愉。三维自适应非结构网格的Euler方程解。中国航空学报，22(6)，495-499，2001。（EI）

[94] Zhu Z.Q., Wang P., Lv X.B., Adaptive multigrid solution of the 2D Euler equations on unstructured grid. ACTA Mechanics, No.144, 43-56, 2000. （SCI）

[95] 王平，朱自强，吕晓斌。 迎风格式在二维非结构网格中的应用。北京航空航天大学学报，26(5)，588-591，2000。

[96] 王平，朱自强，吕晓斌。二维非结构自适应多重网格的Euler方程解。中国计算物理，17(5)，497-503，2000。

[97] 王平，朱自强。二维非结构网格的生成及其Euler方程解。北京航空航天大学学报， 26(2)，190-193，2000。

[98] 王平，王适存，郭才根。共轴式旋翼气动特性分析及实验研究。中国第十三届直升机年会，1997。

[99] 王平，王适存，郭才根。共轴式旋翼悬停状态气动特性的固定尾迹分析。南京航空航天大学学报，29，708–711，1997。

发明专利

[1] 一种基于激光传感的燃烧室PIV测试用粒子浓度自适应调控装置，王平,李壮,戴凯论,张津照,周杰，发明专利申请号：2025107972784，申请日：2025.06.16

[2] 一种可调节多喷嘴氢气微混燃烧实验装置，发明专利申请号：2024103642174，申请日：2024.03.28

[3] 一种带有两个径向旋转入流通道的分级燃烧器，专利授权号：ZL202111090836.1，2024

[4] 一种能实现多重混合的可视化燃烧实验平台，专利授权号：ZL202010579611.1，2022

[5] 2D-FFT火焰热释放可视化解析程序，软件著作权，登记号：2022SR0279081，2022

[6] WP-Foam湍流燃烧大涡模拟计算软件，软件著作权，登记号：2020SR0290663，2020

[7] 一种带有双旋转入流通道可用于多燃料掺混燃烧现象研究的燃烧器，专利授权号：ZL201610461453.3，2018

[8] 一种可升降的光学仪器平台，专利授权号：ZL201610582306.1，2018

[9] 一种将微细固体颗粒撒播到气流中的粒子撒播器，专利授权号：ZL201610188713.4，2018