Zonal RANS-IDDES and RANS computations of turbulent wake exposed to adverse pressure gradient

被引:4
|
作者
Guseva, E. K. [1 ]
Strelets, M. Kh [1 ]
Travin, A. K. [1 ]
Burnazzi, M. [2 ]
Knopp, T. [2 ]
机构
[1] Peter Great St Petersburg Polytech Univ SPBPU, Polytech Skaya Str 29, St Petersburg 195251, Russia
[2] Deutsch Zentrum Luft & Raumfahrt eV DLR, Bunsenstr 10, D-37073 Gottingen, Germany
来源
INTERNATIONAL CONFERENCE PHYSICA.SPB/2018 | 2018年 / 1135卷
关键词
D O I
10.1088/1742-6596/1135/1/012092
中图分类号
O4 [物理学];
学科分类号
0702 ;
摘要
Results are presented of scale-resolving Zonal RANS-IDDES and pure RANS computations of a turbulent wake exposed to adverse pressure gradient. The RANS-IDDES is performed with the use of the NTS code of SPBPU, and the RANS computations are carried with the use of the TAU code of DLR. It is shown that none of the considered RANS models (two linear eddy viscosity models and a full differential Reynolds stress transport model) is capable of reproducing the mean wake characteristics and turbulent statistics predicted by the RANS-IDDES. Accumulated RANS-IDDES database may be used for improvements of RANS models.
引用
收藏
页数:6
相关论文
共 50 条
  • [31] Turbulent mixing layer in adverse pressure gradient
    König, O
    Schulülter, J
    Fiedler, HE
    PROGRESS IN FLUID FLOW RESEARCH: TURBULENCE AND APPLIED MHD, 1998, 182 : 15 - 29
  • [32] Evaluation of grey area mitigation tools within zonal and non-zonal RANS-LES approaches in flows with pressure induced separation
    Probst, A.
    Schwamborn, D.
    Garbaruk, A.
    Guseva, E.
    Shur, M.
    Strelets, M.
    Travin, A.
    INTERNATIONAL JOURNAL OF HEAT AND FLUID FLOW, 2017, 68 : 237 - 247
  • [33] On the Effectiveness of Scale-Averaged RANS and Scale-Resolved IDDES Turbulence Simulation Approaches in Predicting the Pressure Field over a NASCAR Racecar
    Misar, Adit
    Davis, Phillip
    Uddin, Mesbah
    FLUIDS, 2023, 8 (05)
  • [34] An experimental investigation of the planar turbulent wake in constant pressure gradient
    Liu, XF
    Thomas, FO
    Nelson, RC
    PHYSICS OF FLUIDS, 2002, 14 (08) : 2817 - 2838
  • [35] Wake layer in a thermal turbulent boundary layer with pressure gradient
    Afzal, N
    HEAT AND MASS TRANSFER, 1999, 35 (04) : 281 - 288
  • [36] Wake layer in a thermal turbulent boundary layer with pressure gradient
    N. Afzal
    Heat and Mass Transfer, 1999, 35 : 281 - 288
  • [37] Investigations of Unsteady Transonic and Supersonic Wake Flow of Generic Space Launcher Configurations Using Zonal RANS/LES and Dynamic Mode Decomposition
    Statnikov, V.
    Sayadi, T.
    Meinke, M.
    Schmid, P.
    Schroeder, W.
    HIGH PERFORMANCE COMPUTING IN SCIENCE AND ENGINEERING'14: TRANSACTIONS OF THE HIGH PERFORMANCE COMPUTING CENTER, STUTTGART (HLRS) 2014, 2015, : 379 - 401
  • [38] Effects of an adverse pressure gradient on a turbulent boundary layer
    Lee, Joung-Ho
    Sung, Hyung Jin
    INTERNATIONAL JOURNAL OF HEAT AND FLUID FLOW, 2008, 29 (03) : 568 - 578
  • [39] Estimating turbulent-boundary-layer wall-pressure spectra from CFD RANS solutions
    Peltier, L. J.
    Hambric, S. A.
    JOURNAL OF FLUIDS AND STRUCTURES, 2007, 23 (06) : 920 - 937
  • [40] Numerical simulation of turbulent heat transfer past a backward-facing step: 2D/3D RANS versus IDDES solutions
    Smirnov, E. M.
    Smirnovsky, A. A.
    Schur, N. A.
    Zaitsev, D. K.
    Smirnov, P. E.
    7TH EUROPEAN THERMAL-SCIENCES CONFERENCE (EUROTHERM2016), 2016, 745
12345