Ping WANG Professor
Tel: +86-88780215
Email: pingwang@ujs.edu.cn
Add. : Room XX, Energy Research Institue, Jiangsu University
Resarch Interests:Turbulent combustion,Combustion modeling, Large-eddy simulation,Gas-turbine combustor simulation
Education
Ph.D., 2005 Combustion Simulation, Lund University, Sweden
Ph.D., 2001 Fluid dynamic, Beijing university of aeronautics and astronautics, China
M.S., 1997 Helicopter design, Nanjing University of Aeronautics and Astronautics, China
B.S., 1994 Helicopter design, Nanjing University of Aeronautics and Astronautics, China
Professional experience
2012,01-present: Professor, Jiangsu University
2005,05-2011,12: Research Assistant, Karlsruhe Institute of Technology, Germany
Research Interests
Turbulent combustion, Combustion modeling, Large-eddy simulation, Gas-turbine combustor simulation
Courses Taught
Bachelor courses: Combustion
Master courses:Turbulent combustion and its application
Doctor courses:Combustion theory of liquid and gaseous fuels and its application
Projects
2016-2019, Natural Science Foundation of China, Characteristics of confined turbulent partially premixed combustion and its modeling study, 51576092
2015-2018, Natural Science Foundation of Jiangsu Province, Characteristics of mixing combustion of bio DME with natural gas in gas turbine, BK20151344
2016, Large eddy simulation of lean premixed combustion, Shanghai Electric
2012-2015, High resolution numerical study of forced oscillating premixed methane/air flame in a low pressure chamber, 12JDG032, Jiangsu University
2009-2011, Large eddy simulation of oscillating reactive flow in combustion chambers, German Research Foundation (DFG), SFB606-B10
2005-2008, Large eddy simulation of the oscillating flow in burner configurations with piloted premixed flames, German Research Foundation (DFG), SFB606-A6
Selected Papers
[1] P. Wang*, J. Fröhlich, 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 (SCI) (http://www.sciencedirect.com/science/article/pii/S0010218015004290).
[2] Lu Shao-jie, Wang Cai-jun, Wang Ping*, 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.
[3] Wang Ping*, Platova N.A., Fröhlich J., Maas U., Large Eddy Simulation of the PRECCINSTA burner, International Journal of Heat and Mass Transfer, 70: 486-495, 2014. (SCI)
[4] Wang Ping*, Zieker F., Schießl R., Platova N.A., Fröhlich 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)
[5] Wang Ping*, 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
[6] Wang Ping*, Zieker F., Schießl R., Platova N.A., Fröhlich 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.
[7] Wang Ping*, Fröhlich 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.
[8] Platova N.A., Wang Ping*, Fröhlich 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.
[9] Wang P., Fröhlich 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)
[10] Wang P., Fröhlich 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. Kröner, M.M. Resch, pp. 209-223.
[11] Wang P., Fröhlich 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.
[12] Wang P., Fröhlich 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.
[13] Wang P., Fröhlich J., Flame response to a pulsating pilot jet in an unconfined double-concentric swirl burner. European Combustion Meeting, Vienna, Austria, April, 2009, Paper-811389.
[14] Wang P., Fröhlich 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. Kröner, M.M. Resch. 2009, pp.285-299.
[15] Wang P., Fröhlich 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)
[16] Wang P., Fröhlich 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.
[17] Wang P., 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)
[18] Wang P., 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)
[19] Wang P., 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)
[20] Wang P., Bai X.S., Large eddy simulation of premixed turbulent flames by G-equation, The 3rd Mediterranean Combustion Symposium, Marrakech, Morocco. 8-13, June, 2003.
[21] 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)
[22] 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)