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Applied Mathematics and Mechanics >

2021 , Vol. 42 >Issue 3: 387 - 404

DOI: https://doi.org/10.1007/s10483-021-2711-5

Articles

Kinematic and mixing characteristics of vortex interaction induced by a vortex generator model: a numerical study

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  • School of Aeronautics and Astronautics, Shanghai Jiao Tong University, Shanghai 200240, China

Received date: 2020-07-15

  Revised date: 2020-12-28

  Online published: 2021-02-23

Supported by

Project supported by the National Natural Science Foundation of China (Nos. 91741113, 91841303, and 91941301)

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Abstract

The underlying effect of vortex interaction characterized by the merging and non-merging on mixing enhancement is of fundamental significance to understand the flow dynamics of strut injectors in scramjets. Starting from a simplified configuration of a vortex generator, this study focuses on the influence of geometric parameters on vortex structures and fluid mixing through compressible Navier-Stokes (NS) simulations. By adjusting the induction of outer vortices, the inner co-rotating vortex pair exhibits two modes of interaction (merging/separation regime) reflected by closer/farther vortex centers. Defined by the zero variation rate of the inner vortex spacing, the critical state of equilibrium is determined. The critical condition is well predicted by a theoretical model based on the Biot-Savart law. Through the introduction of mixedness and mixing time, the intrinsic impact of interaction modes on fluid mixing is revealed. Compared with the vortex dynamics in the merging regime, the one in the separation regime is more effective for passive scalar mixing augmentation. With efficient material stretching characterized by the higher interface stretching factor and averaging finite-time Lyapunov exponent (FTLE), the mixing time is shortened by as much as 2.5 times in the separation regime. The implication of the present two interaction regimes in mixing enhancement physically reflected by the averaging FTLE has the potential to improve the combustion performance and shorten the combustor chamber.

Key words: vortex interaction mode; fluid mixing; Lagrangian coherent structure (LCS); stretching effect

Cite this article

Ziang WANG, Bin YU, Bin ZHANG, Miaosheng HE, Hong LIU . Kinematic and mixing characteristics of vortex interaction induced by a vortex generator model: a numerical study[J]. Applied Mathematics and Mechanics, 2021 , 42(3) : 387 -404 . DOI: 10.1007/s10483-021-2711-5

References

[1] CURRAN, E. T., HEISER, W. H., and PRATT, D. T. Fluid phenomena in scramjet combustion systems. Annual Review of Fluid Mechanics, 28(1), 323-360(1996)
[2] MARBLE, F. E. Growth of a diffusion flame in the field of a vortex. Recent Advances in the Aerospace Sciences, Springer, Boston, 395-413(1985)
[3] VAN LERBERGHE, W. M., SANTIAGO, J. G., DUTTON, J. C., and LUCHT, R. P. Mixing of a sonic transverse jet injected into a supersonic flow. AIAA Journal, 38(3), 470-479(2000)
[4] KNOWLES, K. and SADDINGTON, A. J. A review of jet mixing enhancement for aircraft propulsion applications. Proceedings of the Institution of Mechanical Engineers, 220(2), 103-127(2006)
[5] BOURDON, C. J. and DUTTON, J. C. Mixing enhancement in compressible base flows via generation of streamwise vorticity. AIAA Journal, 39(8), 1633-1635(1996)
[6] SMITH, L. L., MAJAMAKI, A. J., and LAM, I. T. Mixing enhancement in a lobed injector. Physics of Fluids, 9(3), 667-678(1997)
[7] HIEJIMA, T. and ODA, T. Shockwave effects on supersonic combustion using hypermixer struts. Physics of Fluids, 32(1), 016104(2020)
[8] VERGINE, F., CRISANTI, M., and MADDALENA, L. Supersonic combustion of pylon-injected hydrogen in high-Enthalpy flow with imposed vortex dynamics. Journal of Propulsion and Power, 31(1), 89-103(2014)
[9] VERGINE, F. and MADDALENA, L. Study of two supersonic streamwise vortex interactions in a mach 2.5 flow: merging and no merging configurations. Physics of Fluids, 27(7), 076102(2015)
[10] LEWEKE, T., DIZES, S. L., and WILLIAMSON, C. H. K. Dynamics and instabilities of vortex pairs. Annual Review of Fluid Mechanics, 48, 507-541(2016)
[11] SAFFMAN, P. G. and SZETO, R. Equilibrium shapes of a pair of equal uniform vortices. Physics of Fluids, 23(12), 2339(1980)
[12] MEUNIER, P., EHRENSTEIN, U., and LEWEKE, T. A merging criterion for two-dimensional co-rotating vortices. Physics of Fluids, 14(8), 2757(2002)
[13] CERRETELLI, C. and WILLIAMSON, C. H. K. The physical mechanism for vortex merging. Journal of Fluid Mechanics, 475, 41-77(2003)
[14] DIZES, S. L. and VERGA, A. Viscous interactions of two co-rotating vortices before merging. Journal of Fluid Mechanics, 467, 389-410(2002)
[15] MELANDER, M. V., MCWILLIAMS, J. C., and ZABUSKY, N. J. Axisymmetrization and vorticity-gradient intensification of an isolated two-dimensional vortex through filamentation. Journal of Fluid Mechanics, 178, 137-159(1987)
[16] MELANDER, M. V., ZABUSKY, N. J., and MCWILLIAMS, J. C. Symmetric vortex merger in two dimensions — causes and conditions. Journal of Fluid Mechanics, 195, 303-340(1988)
[17] QIN, S., LIU, H., and XIANG, Y. On the formation modes in vortex interaction for multiple co-axial co-rotating vortex rings. Physics of Fluids, 30(1), 011901(2018)
[18] HUANG, H. M. and XU, X. L. Simulation on motion of particles in vortex merging process. Applied Mathematics and Mechanics (English Edition), 31(4), 461-470(2010) https://doi.org/10.1007/s10483-010-0406-x
[19] BRANDT, L. K. and NOMURA, K. K. The physics of vortex merger: further insight. Physics of Fluids, 18(5), 051701(2006)
[20] VILLERMAUX, E. Mixing versus stirring. Annual Review of Fluid Mechanics, 51, 245-273(2019)
[21] TOMKINS, C., KUMAR, S., ORLICZ, G., and PRESTRIDGE, K. An experimental investigation of mixing mechanisms in shock-accelerated flow. Journal of Fluid Mechanics, 611, 131150(2008)
[22] CETEGEN, B. M. and MOHAMAD, N. Experiments on liquid mixing and reaction in a vortex. Journal of Fluid Mechanics, 249, 391-414(1993)
[23] MEUNIER, P. and VILLERMAUX, E. How vortices mix. Journal of Fluid Mechanics, 476, 213-222(2003)
[24] KUMAR, S., ORLICZ, G., and TOMKINS, C. Stretching of material lines in shock-accelerated gaseous flows. Physics of Fluids, 17(8), 082107(2005)
[25] SOULOPOULOS, N., HARDALUPAS, Y., and TAYLOR, A. Mixing and scalar dissipation rate statistics in a starting gas jet. Physics of Fluids, 27(12), 125103(2015)
[26] MADDALENA, L., VERGINE, F., and CRISANTI, M. Vortex dynamics studies in supersonic flow: merging of co-rotating streamwise vortices. Physics of Fluids, 26(4), 046101(2014)
[27] YU, B., HE, M., and ZHANG, B. Two-stage growth mode for lift-off mechanism in oblique shock-wave/jet interaction. Physics of Fluids, 32, 116105(2020)
[28] PLATTEN, J. K. The soret effect: a review of recent experimental results. Journal of Applied Mechanics, 73(1), 5-15(2006)
[29] ERN, A. and GIOVANGIGLI, V. Multicomponent Transport Algorithms, Springer, Berlin/Heidelberg (1994)
[30] KEE, R., COLTRIN, M. E., and GLARBORG, P. Chemically Reacting Flow: Theory and Practice, John Wiley and Sons, New Jersey (2005)
[31] KEE, R., RUPLEY, F., and MEEKS, E. Chemkin-III: a FORTRAN chemical kinetics package for the analysis of gas-phase chemical and plasma kinetics. Sondia National Laboratories, Technical Report, Livermove SAND96-8216(1996)
[32] WANG, Z. A., YU, B., and CHEN, H. Scaling vortex breakdown mechanism based on viscous effect in shock cylindrical bubble interaction. Physics of Fluids, 30(12), 126103(2018)
[33] LI, Y. X., WANG, Z. A., and YU, B. Gaussian models for late-time evolution of two-dimensional shock-light cylindrical bubble interaction. Shock Waves, 30(5), 169-184(2020)
[34] LIU, X. D., OSHER, S., and CHAN, T. Weighted essentially non-oscillatory schemes. Journal of Computational Physics, 115(1), 200-212(1994)
[35] SPITERI, R. J. and RUUTH, S. J. Non-linear evolution using optimal fourth-order strong-stability-preserving Runge-Kutta methods. Mathematics and Computers in Simulation, 62(1), 125-135(2003)
[36] VERWER, J. G., SOMMEIJER, B. P., and HUNDSDORFER, W. RKC time-stepping for advection-diffusion-reaction problems. Journal of Computational Physics, 20(1), 61-79(2004)
[37] NYBELEN, L. and PAOLI, R. Direct and large-eddy simulations of merging in corotating vortex system. AIAA Journal, 47(1), 157-167(2009)
[38] JACQUIN, L., FABRE, D., and GEFFROY, P. The properties of a transport aircraft wake in the extended near field: an experimental study. 39th Aerospace Sciences Meeting and Exhibit, American Institute of Aeronautics and Astronautics, Reno (2001)
[39] DAVIDE, V. and MADDALENA, L. A numerical method for the solution of supersonic streamwise vortex dynamics. Aerospace Science and Technology, 79, 310-317(2018)
[40] MEUNIER, P. and LEWEKE, T. Three-dimensional instability during vortex merging. Physics of Fluids, 13(10), 2747-2750(2001)
[41] MITCHELL, B. E., LELE, S. K., and MOIN, P. Direct computation of the sound from a compressible co-rotating vortex pair. Journal of Fluid Mechanics, 285, 181-202(1995)
[42] ZHENG, Z., ZHOU, F., and WANG, Z. A numerical study on compressibility effect on the evolution of vortex interaction (in Chinese). Acta Aeronautica et Astronautica Sinica, 41, 123295(2020)
[43] CHEN, A. L., JACOB, J. D., and SAVA, O. Dynamics of co-rotating vortex pairs in the wakes of flapped airfoils. Journal of Fluid Mechanics, 382, 155-193(1999)
[44] MARLES, D. and GURSUL, I. Effect of an axial jet on vortex merging. Physics of Fluids, 20(4), 047101(2008)
[45] SAFFMAN, P. G. Vortex Dynamics, Cambridge University Press, Cambridge (1995)
[46] HALLER, G. Lagrangian coherent structures. Annual Review of Fluid Mechanics, 47, 137-162(2015)
[47] SHADDEN, S. C., LEKIEN, F., and MARSDEN, J. E. Definition and properties of Lagrangian coherent structures from finite-time Lyapunov exponents in two-dimensional aperiodic flows. Physica D: Nonlinear Phenomena, 212(3), 271-304(2005)
[48] SHADDEN, S. C., DABIRI, J. O., and MARSDEN, J. E. Lagrangian analysis of fluid transport in empirical vortex ring flows. Physics of Fluids, 18(4), 047105(2006)
[49] HAN, S., ZHANG, S., and ZHANG, H. A Lagrangian criterion of unsteady flow separation for two-dimensional periodic flows. Applied Mathematics and Mechanics (English Edition), 39(7), 1007-1018(2018) https://doi.org/10.1007/s10483-018-2350-8
[50] HANG, H., YU, B., and XIANG, Y. An objective-adaptive refinement criterion based on modified ridge extraction method for finite-time Lyapunov exponent (FTLE) calculation. Journal of Visualization, 23(1), 81-95(2020)
[51] LIANG, G., YU, B., and ZHANG, B. Hidden flow structures in compressible mixing layer and a quantitative analysis of entrainment based on Lagrangian method. Journal of Hydrodynamics, 31(2), 256-265(2019)
[52] QIN, S., LIU, H., and XIANG, Y. Lagrangian flow visualization of multiple co-axial co-rotating vortex rings. Journal of Visualization, 21(1), 63-71(2018)
[53] XIANG, Y., LIN, H., and ZHANG, B. Quantitative analysis of vortex added-mass and impulse generation during vortex ring formation based on elliptic Lagrangian coherent structures. Experimental Thermal and Fluid Science, 94, 295-303(2018)
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