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Shen, Yiqing; Zha, Gecheng; Chen, Xiangying

High order conservative differencing for viscous terms and the application to vortex-induced vibration flows. (English) Zbl 1422.76138

J. Comput. Phys. 228, No. 22, 8283-8300 (2009).
Summary: A new set of conservative 4th-order central finite differencing schemes for all the viscous terms of compressible Navier-Stokes equations are proposed and proved in this paper. These schemes are used with a 5th-order WENO scheme for inviscid flux and the stencil width of the central differencing scheme is designed to be within that of the WENO scheme. The central differencing schemes achieve the maximum order of accuracy in the stencil. This feature is important to keep the compactness of the overall discretization schemes and facilitate the boundary condition treatment. The algorithm is used to simulate the vortex-induced oscillations of an elastically mounted circular cylinder. The numerical results agree favorably with the experiment.

Cited in 15 Documents

MSC:

76M20 Finite difference methods applied to problems in fluid mechanics
76N15 Gas dynamics (general theory)
35Q30 Navier-Stokes equations

Keywords:

central differencing; high order accuracy; Navier-Stokes equations; viscous terms; vortex-induced vibration
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References:

[1] Ekaterinaris, J. A., High-order accurate low numerical diffusion methods for aerodynamics, Progress in Aerospace Sciences, 41, 192-300 (2005)
[2] Wang, Z. J., High-order methods for the Euler and Navier-Stokes equations on unstructured grids, Progress in Aerospace Sciences, 43, 1-41 (2007)
[3] Harten, A.; Engquist, B.; Osher, S.; Chakravarthy, S., Uniformly high order essentially non-oscillatory schemes, III, Journal of Computational Physics, 71, 231-303 (1987) · Zbl 0652.65067
[4] Shu, C.-W.; Osher, O., Efficient implementation of essentially non-oscillatory shock capturing schemes, Journal of Computational Physics, 77, 439-471 (1988) · Zbl 0653.65072
[5] Jiang, G. S.; Shu, C. W., Efficient implementation of weighted ENO schemes, Journal of Computational Physics, 126, 202-228 (1996) · Zbl 0877.65065
[6] C.W. Shu, Essentially non-oscillatory and weighted essentially non-oscillatory schemes for hyperbolic conservation laws, NASA/CR-97-206253, ICASE Report No. 97-65, Nov. 1997.; C.W. Shu, Essentially non-oscillatory and weighted essentially non-oscillatory schemes for hyperbolic conservation laws, NASA/CR-97-206253, ICASE Report No. 97-65, Nov. 1997.
[7] Balsara, D. S.; Shu, C.-W., Monotonicity preserving weighted essentially non-oscillatory schemes with increasingly high order of accuracy, Journal of Computational Physics, 160, 405-452 (2000) · Zbl 0961.65078
[8] Y.Q. Shen, G.-C. Zha, Improvement of the WENO scheme smoothness estimator, AIAA Paper 2008-3993, June 2008.; Y.Q. Shen, G.-C. Zha, Improvement of the WENO scheme smoothness estimator, AIAA Paper 2008-3993, June 2008. · Zbl 1426.76488
[9] Shen, Y.-Q.; Zha, G.-C.; Wang, B.-Y., Improvement of stability and accuracy of implicit WENO scheme, AIAA Journal, 47, 331-344 (2009)
[10] Titarev, V. A.; Toro, E. F., Finite-volume WENO schemes for three-dimensional conservation laws, Journal of Computational Physics, 201, 238-260 (2004) · Zbl 1059.65078
[11] Zhou, T.; Li, Y.; Shu, C. W., Numerical comparison of WENO finite volume and Runge-Kutta discontinuous Galerkin methods, Journal Scientific Computing, 16, 145-171 (2001) · Zbl 0991.65083
[12] Lele, S. A., Compact finite difference schemes with spectral-like resolution, Journal of Computational Physics, 103, 11, 6-42 (1992) · Zbl 0759.65006
[13] S. De Rango, D.W. Zingg, Aerodynamic computations using a higher-order algorithm, AIAA 99-0167, 1999.; S. De Rango, D.W. Zingg, Aerodynamic computations using a higher-order algorithm, AIAA 99-0167, 1999.
[14] Zingg, D. W.; De Rango, S.; Nemec, M.; Pulliam, T. H., Comparison of several spatial discretizations for the Navier-Stokes equations, Journal of Computational Physics, 160, 683-704 (2000) · Zbl 0967.76073
[15] Y.Q. Shen, B.Y. Wang, G.C. Zha, Implicit WENO scheme and high order viscous formulas for compressible flows, AIAA-2007-4431, June 2007.; Y.Q. Shen, B.Y. Wang, G.C. Zha, Implicit WENO scheme and high order viscous formulas for compressible flows, AIAA-2007-4431, June 2007.
[16] Sarpkaya, T., A critical review of the intrinsic nature of vortex-induced vibrations, Journal of Fluids and Structures, 19, 389-447 (2004)
[17] Williamson, C. H.K.; Govardhan, R., Vortex-induced vibrations, Annual Review of Fluid Mechanics, 36, 413-455 (2004) · Zbl 1125.74323
[18] Williamson, C. H.K.; Govardhan, R., A brief review of recent results in vortex-induced vibrations, Journal of Wind Engineering and Industrial Aerodynamics (2007) · Zbl 1125.74323
[19] Al Jamal, H.; Dalton, C., The contrast in phase angles between forced and self-excited oscillations of a circular cylinder, Journal of Fluids and Structures, 20, 467-482 (2005)
[20] Gabbai, R. D.; Benaroya, H., An overview of modeling and experiments of vortex-induced vibration of circular cylinders, Journal of Sound and Vibrations, 282, 575-616 (2005)
[21] Meynen, S.; Verma, H.; Hagedorn, P.; Schafer, M., On the numerical simulation of vortex-induced vibrations of oscillating conductors, Journal of Fluids and Structures, 21, 41-48 (2005)
[22] Mittal, S.; Raghuvanshi, A., Control of vortex shedding behind circular cylinder for flows at low Reynolds numbers, International Journal for Numerical Methods in Fluids, 35, 421-447 (2001) · Zbl 1013.76049
[23] Mittal, S.; Kumar, V., Flow-induced vibrations of a light circular cylinder at Reynolds numbers \(10^3-10^4\), Journal of Sound and Vibration, 245, 923-946 (2001)
[24] Prasanth, T. K.; Behara, S.; Singh, S. P.; Kumar, R.; Mittal, S., Effect of blockage on vortex-induced vibrations at low Reynolds numbers, Journal of Fluids and Structures, 22, 865-876 (2006)
[25] Blackburn, H. M.; Henderson, R. D., A study of the two-dimensional flow past an oscillating cylinder, Journal of Fluid Mechanics, 385, 255-286 (1999) · Zbl 0938.76022
[26] Blackburn, H. M.; Govardhan, R. N.; Williamson, C. H.K., A complementary numerical and physical investigation of vortex-induced, Journal of Fluids and Structures, 15, 481-488 (2000)
[27] Evangelinos, C.; Lucor, D.; Karniadakis, G. E., DNS-derived force distribution on flexible cylinders subject to vortex-induced vibration, Journal of Fluids and Structures, 14, 429-440 (2000)
[28] Lucor, D.; Foo, J.; Karniadakis, G. E., Vortex mode selection of a rigid cylinder subject to VIV at low mass-damping, Journal of Fluids and Structures, 20, 483-503 (2005)
[29] Dong, S.; Karniadakis, G. E., DNS of flow past a stationary and oscillating cylinder at Re=10,000, Journal of Fluids and Structures, 20, 519-531 (2005)
[30] Wanderley, J. B.V.; Levi, C. A., Validation of a finite difference method for the simulation of vortex-induced vibrations on a circular cylinder, Ocean Engineering, 29, 445-460 (2002)
[31] Ryan, K.; Pregnalato, C. J.; Thompson, M. C.; Hourigan, K., Flow-induced vibrations of a tethered circular cylinder, Journal of Fluids and Structures, 19, 1085-1102 (2004)
[32] Placzek, A.; Sigrist, J. F.; Hamdouni, A., Numerical simulation of an oscillating cylinder in a cross-flow at low Reynolds number: forced and free oscillations, Computers and Fluids (2008)
[33] Guilmineau, E.; Queutey, P., Numerical simulation of vortex-induced vibration of a circular cylinder with low mass damping, Journal of Fluids and Structures, 19, 449-466 (2004) · Zbl 0857.76059
[34] Guilmineau, E.; Queutey, P., A numerical simulation of vortex shedding from an oscillating circular cylinder, Journal of Fluids and Structures, 16, 773-794 (2002)
[35] Pan, Z. Y.; Cui, W. C.; Miao, Q. M., Numerical simulation of vortex-induced vibration of a circular cylinder at low mass-damping using RANS code, Journal of Fluids and Structures, 23, 23-37 (2007)
[36] Tutar, M.; Holdo, A. E., Large Eddy Simulation of a smooth circular cylinder oscillating normal to a uniform flow, ASME Journal of Fluids Engineering, 122, 694-702 (2000)
[37] Al Jamal, H.; Dalton, C., Vortex-induced vibrations using large eddy simulation at a moderate Reynolds number, Journal of Fluids and Structures, 19, 73-92 (2004)
[38] X.-Y. Chen, G.-C. Zha, Z.-J. Hu, Numerical Simulation of flow induced vibration based on fully coupled-structural interactions, AIAA Paper 2004-2240, AIAA 34th AIAA Fluid Dynamics Conference, 2004.; X.-Y. Chen, G.-C. Zha, Z.-J. Hu, Numerical Simulation of flow induced vibration based on fully coupled-structural interactions, AIAA Paper 2004-2240, AIAA 34th AIAA Fluid Dynamics Conference, 2004.
[39] Chen, X.; Zha, G.-C., Fully coupled fluid-structural interactions using an efficient high solution upwind scheme, Journal of Fluid and Structure, 20, 1105-1125 (2005)
[40] Thomas, P.; Lombard, C., Geometric conservation law and its application to flow computations on moving grids, AIAA Journal, 17, 10, 1030-1037 (1979) · Zbl 0436.76025
[41] Mavriplis, D. J.; Yang, Z., Construction of the discrete geometric conservation law for high-order time-accurate simulations on dynamic meshes, Journal of Computational Physics, 213, 557-573 (2006) · Zbl 1136.76402
[42] Visbal, M. R.; Gaitonde, D. V., On the use of higher-order finite-difference schemes on curvilinear and deforming meshes, Journal of Computational Physics, 181, 155-185 (2002) · Zbl 1008.65062
[43] Kamakoti, R.; Shyy, W., Fluid-structure interaction for aeroelastic applications, Progress in Aerospace Sciences, 40, 535-558 (2004)
[44] Etienne, S.; Garon, A.; Pelletier, D., Perspective on the geometric conservation law and finite element methods for ale simulations of incompressible flow, Journal of Computational Physics, 228, 2313-2333 (2009) · Zbl 1275.76159
[45] Z.-J. Hu, G.-C. Zha, Numerical study on flow separation of a transonic cascade, AIAA Paper 2004-0199, Jan. 2004.; Z.-J. Hu, G.-C. Zha, Numerical study on flow separation of a transonic cascade, AIAA Paper 2004-0199, Jan. 2004.
[46] Y.Q. Shen, B.Y. Wang, G.C. Zha, Comparison study of implicit Gauss-Seidel line iteration method for transonic flows, AIAA-2007-4332, June 2007.; Y.Q. Shen, B.Y. Wang, G.C. Zha, Comparison study of implicit Gauss-Seidel line iteration method for transonic flows, AIAA-2007-4332, June 2007.
[47] A. Roshko, On the development of turbulent wakes from vortex streets, NACA Rep. 1191, 1954.; A. Roshko, On the development of turbulent wakes from vortex streets, NACA Rep. 1191, 1954.
[48] Goldstein, S., Modern Developments in Fluid Dynamics (1938), Clarendon Press: Clarendon Press Oxford · JFM 64.1451.01
[49] J. Alonso, L. Martinelli, A. Jameson, Multigrid unsteady Navier-Stokes calculations with aeroelastic applications, AIAA Paper 95-0048, 1995.; J. Alonso, L. Martinelli, A. Jameson, Multigrid unsteady Navier-Stokes calculations with aeroelastic applications, AIAA Paper 95-0048, 1995.
[50] O.M. Griffin, Vortex-induced vibrations of marine structures in uniform and sheared currents, NSF Workshopon Riser Dynamics, University of Michigan, 1992.; O.M. Griffin, Vortex-induced vibrations of marine structures in uniform and sheared currents, NSF Workshopon Riser Dynamics, University of Michigan, 1992.
[51] S.A. Morton, R.B. Melville, M.R. Visbal, Accuracy and coupling issues of aeroelastic Navier-Stokes solutions on deforming meshes, AIAA Paper-97-1085, 1997.; S.A. Morton, R.B. Melville, M.R. Visbal, Accuracy and coupling issues of aeroelastic Navier-Stokes solutions on deforming meshes, AIAA Paper-97-1085, 1997.
[52] H. Blackburn, G. Karniadakis, Two and three-dimensional vortex-induced vibration of a circular cylinder, in: ISOPE-93 Conference, Singapore, 1993.; H. Blackburn, G. Karniadakis, Two and three-dimensional vortex-induced vibration of a circular cylinder, in: ISOPE-93 Conference, Singapore, 1993.
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