Linear spatial instability analysis in 3D boundary layers using plane-marching 3D-LPSE 被引量：2

Linear spatial instability analysis in 3D boundary layers using plane-marching 3D-LPSE

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摘要 It is widely accepted that a robust and efficient method to compute the linear spatial amplified rate ought to be developed in three-dimensional （3D） boundary layers to predict the transition with the e^N method, especially when the boundary layer varies significantly in the spanwise direction. The 3D-linear parabolized stability equation （3D- LPSE） approach, a 3D extension of the two-dimensional LPSE （2D-LPSE）, is developed with a plane-marching procedure for investigating the instability of a 3D boundary layer with a significant spanwise variation. The method is suitable for a full Mach number region, and is validated by computing the unstable modes in 2D and 3D boundary layers, in both global and local instability problems. The predictions are in better agreement with the ones of the direct numerical simulation （DNS） rather than a 2D-eigenvalue problem （EVP） procedure. These results suggest that the plane-marching 3D-LPSE approach is a robust, efficient, and accurate choice for the local and global instability analysis in 2D and 3D boundary layers for all free-stream Mach numbers. It is widely accepted that a robust and efficient method to compute the linear spatial amplified rate ought to be developed in three-dimensional （3D） boundary layers to predict the transition with the e^N method, especially when the boundary layer varies significantly in the spanwise direction. The 3D-linear parabolized stability equation （3D- LPSE） approach, a 3D extension of the two-dimensional LPSE （2D-LPSE）, is developed with a plane-marching procedure for investigating the instability of a 3D boundary layer with a significant spanwise variation. The method is suitable for a full Mach number region, and is validated by computing the unstable modes in 2D and 3D boundary layers, in both global and local instability problems. The predictions are in better agreement with the ones of the direct numerical simulation （DNS） rather than a 2D-eigenvalue problem （EVP） procedure. These results suggest that the plane-marching 3D-LPSE approach is a robust, efficient, and accurate choice for the local and global instability analysis in 2D and 3D boundary layers for all free-stream Mach numbers.

作者 Jianxin LIU Shaolong ZHANG Song FU

机构地区 Department of Mechanism School of Aerospace Engineering

出处《Applied Mathematics and Mechanics(English Edition)》 SCIE EI CSCD 2016年第8期1013-1030,共18页 应用数学和力学（英文版）

基金 Project supported by the National Natural Science Foundation of China(Nos.11272183,11572176,11402167,11202147,and 11332007) the National Program on Key Basic Research Project of China(No.2014CB744801)

关键词 three-dimensional linear parabolized stability equation （3D-LPSE） bi-global instability three-dimensional （3D） boundary layer Gortler fow crossflow vortex three-dimensional linear parabolized stability equation （3D-LPSE）, bi-global instability, three-dimensional （3D） boundary layer, Gortler fow, crossflow vortex

分类号 O357.41 [理学—流体力学] O354.4 [理学—流体力学]

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参考文献1

1张永明,周恒.抛物化稳定性方程在可压缩边界层中应用的检验[J].应用数学和力学,2007,28(8):883-893. 被引量：13

二级参考文献17

1Gaster M.On the effects of boundary-layer growth on flow stability[J].Journal of Fluid Mechanics,1974,66(3):465-480.
2于秀阳周恒.平板边界层流的非平行性对流动稳定性的影响.力学学报,1986,18(4):297-306.
3Herbert Th,Bertolotti F P.Stability analysis of nonparallel boundary layers[J].Bull Am Phys Soc,1987,32(11):2079-2086.
4Bertolotti F P,Herbert Th,Spalart P R.Linear and nonlinear stability of the Blasius boundary layer[J].Journal of Fluid Mechanics,1992,242(1):441-474.
5Schubauer G B,Skramstad H K.Laminar boundary-layer oscillations and transition on a flat plate[J].J Res Natl Bur Stand,1947,38(1):251-292.
6Ross J A,Barnes F H,Burns J G,et al.The flat plate boundary layer part-3-comparison of theory with experiment[J].Journal of Fluid Mechanic,1970,43(4):819-832.
7Strazisar A J,Reshotko E,Prahl J M.Experimental study of the stability of heated laminar boundary layers in water[J].Journal of Fluid Mechanics,1977,83(2):225-247.
8Kachanov Yu S,Kozlov V V,Levchenko V Ya.Nonlinear development of a wave in a boundary layer[J].Fluid Dynamics,1977,12(3):383-390.
9Esfahanian V,Hejranfar K,Sabetghadam F.Linear and nonlinear PSE for stability analysis of the Blasius boundary layer using compact scheme[J].Journal of Fluids Engineering,2001,123(3):545-550.
10Mujeeb R,Malik M R,Choudhari M M,et al.Secondary instability of crossflow vortices and sweptwing boundary-layer transition[J].Journal of Fluid Mechanics,1999,399(1):85-115.

共引文献12

1张永明,周恒.PSE在超音速边界层二次失稳问题中的应用[J].应用数学和力学,2008,29(1):1-7. 被引量：8
2张永明,周恒.PSE在可压缩边界层转捩问题中的应用[J].应用数学和力学,2008,29(7):757-763. 被引量：10
3涂国华,袁湘江,毛枚良,陆利蓬.小扰动在二维超声速边界层中的弱非线性传播[J].航空学报,2009,30(9):1635-1640.
4李佳,罗纪生.Applications of parabolized stability equation for predicting transition position in boundary layers[J].Applied Mathematics and Mechanics(English Edition),2012,33(6):679-686. 被引量：1
5李佳,罗纪生.PSE在边界层中预测转捩位置的应用[J].应用数学和力学,2012,33(6):643-650. 被引量：2
6REN Jie,FU Song.Competition of the multiple Grtler modes in hypersonic boundary layer flows[J].Science China(Physics,Mechanics & Astronomy),2014,57(6):1178-1193. 被引量：6
7Yongming ZHANG,Caihong SU.Self-consistent parabolized stability equation(PSE) method for compressible boundary layer[J].Applied Mathematics and Mechanics(English Edition),2015,36(7):835-846. 被引量：1
8Gaotong YU,Jun GAO,Jisheng LUO.Stability analysis method considering non-parallelism:EPSE method and its application[J].Applied Mathematics and Mechanics(English Edition),2016,37(1):27-36. 被引量：3
9李佳,罗纪生.抛物化稳定性方程在曲面边界层中的应用[J].航空动力学报,2015,30(12):2976-2982. 被引量：3
10Yufeng HAN,Jianxin LIU,Jisheng LUO.Improvement for expansion of parabolized stability equation method in boundary layer stability analysis[J].Applied Mathematics and Mechanics(English Edition),2018,39(12):1737-1754. 被引量：1

同被引文献11

1SU CaiHong1 & ZHOU Heng1,2 1 Department of Mechanics, Tianjin University, Tianjin 300072, China,2 Liu-Hui Center of Applied Mathematics, Nankai University and Tianjin University, Tianjin 300072, China.Transition prediction of a hypersonic boundary layer over a cone at small angle of attack——with the improvement of e^N method[J].Science China(Physics,Mechanics & Astronomy),2009,52(1):115-123. 被引量：26
2SU CaiHong1 & ZHOU Heng1,2 1 Department of Mechanics,Tianjin University,Tianjin 300072,China,2 Liu-Hui Center of Applied Mathematics,Nankai University and Tianjin University,Tianjin 300072,China.Transition prediction for supersonic and hypersonic boundary layers on a cone with angle of attack[J].Science China(Physics,Mechanics & Astronomy),2009,52(8):1223-1232. 被引量：10
3张永明,周恒.Verification of parabolized stability equations for its application to compressible boundary layers[J].Applied Mathematics and Mechanics(English Edition),2007,28(8):987-998. 被引量：4
4张永明,周恒.PSE as applied to problems of transition in compressible boundary layers[J].Applied Mathematics and Mechanics(English Edition),2008,29(7):833-840. 被引量：1
5SU CaiHong,ZHOU Heng.Transition prediction of the supersonic boundary layer on a cone under the consideration of receptivity to slow acoustic waves[J].Science China(Physics,Mechanics & Astronomy),2011,54(10):1875-1882. 被引量：6
6SU CaiHong1,2 1 Department of Mechanics,Tianjin University,Tianjin 300072,China,2 Tianjin Key Laboratory of Modern Engineering Mechanics,Tianjin 300072,China.The reliability of the improved e^N method for the transition prediction of boundary layers on a flat plate[J].Science China(Physics,Mechanics & Astronomy),2012,55(5):837-843. 被引量：7
7罗纪生.高超声速边界层的转捩及预测[J].航空学报,2015,36(1):357-372. 被引量：47
8Jun Gao,Ji-Sheng Luo,Xue-Song Wu.Receptivity of hypersonic boundary layer due to fast-slow acoustics interaction[J].Acta Mechanica Sinica,2015,31(6):899-909. 被引量：5
9陈坚强,涂国华,张毅锋,徐国亮,袁先旭,陈诚.高超声速边界层转捩研究现状与发展趋势[J].空气动力学学报,2017,35(3):311-337. 被引量：99
10高军,李佳.高超声速边界层中模态转化的数值研究[J].力学学报,2018,50(6):1368-1378. 被引量：2

引证文献2

1苏彩虹,宋明真.超声速边界层中的模态转换及壁温影响效应[J].空气动力学学报,2020,38(6):1056-1063. 被引量：2
2谷晓培,刘建新.基于APSE确定高超声速边界层第二模态中性曲线下支[J].空气动力学学报,2021,39(2):62-72.

二级引证文献2

1苏彩虹.高超声速边界层转捩预测中的关键科学问题--感受性、扰动演化及转捩判据研究进展[J].空气动力学学报,2020,38(2):355-367. 被引量：11
2武利龙,罗金玲,李超,肖志祥,操小龙.内流壁温效应对高速飞行器气动特性的影响[J].空气动力学学报,2022,40(1):84-91.

1Charles L. Merkle,Feng Jin-zhang(Propulsion Engineering Research, The Pennsylvania State University, University Park, PA 16802, USA).A UNIFIED TIME-MARCHING PROCEDURE FOR COMPRESSIBLE INCOMPRESSIBLE FLOWS[J].Journal of Hydrodynamics,1995,7(4):13-21.
2Zhou Fujun,Cui Shangbin.LOCAL AND GLOBAL EXISTENCE OF SOLUTIONS OF THE GINZBURG-LANDAU TYPE EQUATIONS[J].Journal of Partial Differential Equations,2007,20(3):220-246.
3Gaotong YU,Jun GAO,Jisheng LUO.Stability analysis method considering non-parallelism:EPSE method and its application[J].Applied Mathematics and Mechanics(English Edition),2016,37(1):27-36. 被引量：3
4LUO Wenyu,ZHANG Renhe,SCHMIDT Henrik.A two-way marching coupled-mode method for range-dependent propagation[J].Chinese Journal of Acoustics,2012,31(4):371-391.
5Yongming ZHANG,Caihong SU.Self-consistent parabolized stability equation(PSE) method for compressible boundary layer[J].Applied Mathematics and Mechanics(English Edition),2015,36(7):835-846. 被引量：1
6刘鲁江.超自然电子异象(EVP)的思考[J].大科技（科学之谜）（A）,2008(11):54-54.
7Wei KONG,Jisheng LUO.Global instability of Stokes layer for whole wave numbers[J].Applied Mathematics and Mechanics(English Edition),2016,37(8):999-1012.
8Jing Hui QIU,Fei HE.A General Vectorial Ekeland's Variational Principle with a P-distance[J].Acta Mathematica Sinica,English Series,2013,29(9):1655-1678. 被引量：4
9白成林,张霞,张立华.Some new solutions derived from the nonlinear (2+1)-dimensional Toda equation-an efficient method of creating solutions[J].Chinese Physics B,2009,18(2):475-481. 被引量：4
10Joao-Paulo DIAS,Mario FIGUEIRA,Vladimir V. KONOTOP.The Cauchy Problem for Coupled Nonlinear Schrdinger Equations with Linear Damping： Local and Global Existence and Blowup of Solutions[J].Chinese Annals of Mathematics,Series B,2016,37(5):665-682.

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2016年第8期

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