Numerical study of effect of pressure gradient on boundary-layer receptivity under localized wall blowing/suction

Lu Chang-Gen; Shen Lu-Yu; Zhu Xiao-Qing

doi:10.7498/aps.68.20190684

Abstract

Boundary-layer receptivity is the initial stage of the laminar-turbulent transition process, and plays a key role in predicting and controlling the transition. The present researches indicate that the boundary-layer receptivity is affected not only by the different sorts of free-stream disturbances or the size, shape and position of the wall localized roughness and blowing/suction, but also by the pressure gradient. Therefore, the local receptivity under the interaction between the free-stream turbulence and localized wall blowing/suction in the pressure-gradient boundary layer is studied in the present work, thus revealing the effect of the pressure gradient on the receptive process and the group speeds of the excited T-S wave packets under the interaction of the free-stream turbulence with localized wall blowing/suction in the boundary layer. High-order finite difference scheme is utilized to discretize the incompressible perturbation Navier-Stokes equation. A modified fourth-order Runge-Kutta scheme is used for time integration. The compact difference scheme based on non-uniform meshes is applied to the spatial discretization. The convective term is discretized by the fifth-order upwind compact scheme. The pressure gradient term is discretized by the sixth-order symmetric compact scheme. The viscosity term is discretized by the fifth-order symmetric compact scheme. Besides, the pressure Poisson equation is solved by the fourth-order scheme on the non-uniform meshes. The favorable or adverse pressure gradient promotes or suppresses the receptivity triggered by the interaction between free-stream turbulence and blowing/suction. And the blowing always induces a stronger receptivity than the suction in the same intensity. The initial amplitude of the T-S wave and wave packet excited in the adverse-pressure-gradient boundary layer are two orders larger than those excited in the favorable-pressure-gradient boundary layer. It is analyzed in detail that the favorable and adverse pressure gradient play a promoting or suppressing role in the growth of the excited T-S wave. Then the influences of the pressure gradient on the amplitudes, growth rates, wave numbers, phase speeds and shape functions of the excited T-S waves are investigated. The intensive research on receptivity in the pressure-gradient boundary layers provides a reference for designing the turbine machinery blades in the practical engineering.

Keywords:

Authors and contacts

School of Marine Sciences, Nanjing University of Information Science and Technology, Nanjing 210044, China

Corresponding author: Lu Chang-Gen, cglu@nuist.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 11472139)

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References

[1]	Goldstein M E 1983 J. Fluid. Mech. 127 59 Google Scholar
[2]	Ruban A I 1984 Fluid Dynam. 19 709
[3]	陆昌根, 沈露予 2015 物理学报 65 194701 Google Scholar Lu C G, Shen L Y 2015 Acta Phys. Sin. 65 194701 Google Scholar
[4]	Shen L, Lu C, Zhu X 2019 Appl. Math. Mech. 40 851 Google Scholar
[5]	Goldstein M E 1985 J. Fluid. Mech. 154 509 Google Scholar
[6]	Saric W S, Hoos J A, Radeztsky R H 1991 Proceedings of the Symposium and Joint Fluids Engineering Conference, 1st Portland, U.S.A, June 23−27, 1991 p17
[7]	Wiegel M, Wlezien R 1993 AIAA P. 3280
[8]	Dietz A J 1999 J. Fluid. Mech. 378 291 Google Scholar
[9]	Dietz A J 1998 AIAA J. 36 1171 Google Scholar
[10]	Dietz A J 1996 AIAA P. 2083
[11]	Wu X 2001 J. Fluid. Mech. 449 373 Google Scholar
[12]	Wu X 2001 J. Fluid. Mech. 431 91 Google Scholar
[13]	Shen L, Lu C 2016 Appl. Math. Mech. 37 929 Google Scholar
[14]	Shen L, Lu C 2016 Appl. Math. Mech. 37 349 Google Scholar
[15]	Würz W, Herr S, Wörner A, Rist U 2003 J. Fluid. Mech. 478 135 Google Scholar
[16]	Shen L, Lu C 2018 Adv. Appl. Math. Mech. 10 735 Google Scholar
[17]	陆昌根, 沈露予 2015 物理学报 64 224702 Google Scholar Lu C G, Shen L Y 2015 Acta Phys. Sin. 64 224702 Google Scholar
[18]	Johnson M W, Pinarbasi 2014 Flow Turbul. Combu. 93 1 Google Scholar
[19]	Jacobs R G 2001 J. Fluid. Mech. 428 185 Google Scholar

Cited By

图 1 数值计算区域示意图

Figure 1. The domain of numerical simulation.

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图 2 在压力梯度(a) β_H = 0.1, (b) β_H = 0和(c) β_H = –0.05情况下壁面局部吹入边界层内被激发出T-S波波包沿流向呈现增长的演化趋势

Figure 2. The streamwise evolutions of the excited T-S waves under the localized suction in the pressure-gradient boundary layers of (a) β_H = 0.1, (b) β_H = 0 and (c) β_H = –0.05.

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图 3 局部吹入和吸出边界层内被激发出T-S波包初始幅值A_R与压力梯度的关系　(a) 吹入强度; (b) 吸出强度

Figure 3. The relationships between the initial amplitudes of the excited T-S waves A_R and the pressure-gradients in the localized blowing and suction boundary layers: (a) Blowing intensity; (b) suction intensity

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图 4 不同压力梯度对壁面局部吹入边界层内被激发出的T-S波沿x向发展的影响　(a) F = 40; (b) F = 80

Figure 4. The effect of different pressure gradients on x-direction evolutions of the excited T-S waves in the localized blowing boundary layers. (a) F = 40; (b) F = 80

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图 5 壁面局部吹入边界层内被激发出T-S波的幅值A_T-S沿x向的演化(t = 2400)　(a) F = 40; (b) F = 80

Figure 5. The x-direction evolutions of the amplitude of the excited T-S waves in the local blowing boundary layers (t = 2400): (a) F = 40; (b) F = 80.

DownLoad: Full-Size Img PowerPoint

图 6 壁面局部吹入边界层内被激发出T-S波的增长率(–α_i)沿x向的演化(t = 2400)　(a) F = 40; (b) F = 80

Figure 6. The x-direction evolutions of the growth rate (–α_i) of the excited T-S waves in the local blowing boundary layers (t = 2400): (a) F = 40; (b) F = 80.

DownLoad: Full-Size Img PowerPoint

图 7 在不同压力梯度情况下壁面局部吹入和吸出边界层内被激发出T-S波波包的初始幅值A_R与局部吹吸强度q之间的关系

Figure 7. The relationships between the initial amplitudes of the excited T-S waves A_R and the localized blowing/suction intensity q in different pressure boundary layers

DownLoad: Full-Size Img PowerPoint

图 8 压力梯度对壁面局部吹入边界层内被激发出T-S波的特征形状函数的幅值沿y向演变的影响(x = 300)

Figure 8. The effects of different pressure gradients on y-direction amplitude profiles of the shape functions of the excited T-S waves in localized blowing boundary layers (x = 300).

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图 9 压力梯度对壁面局部吹入边界层内被激发出T-S波的特征形状函数的相位沿y向演变的影响(x = 300)

Figure 9. The effects of different pressure gradients on y-direction phase profiles of the shape functions of the excited T-S waves in localized blowing boundary layers (x = 300).

DownLoad: Full-Size Img PowerPoint

表 1 压力梯度对边界层内被激发出T-S波波包向前传播的群速度(C_g)的影响

Table 1. The group speeds (C_g) of the excited T-S wave packets in the pressure-gradient boundary layers.

β_H	0.3	0.1	0.05	0	–0.05	–0.1
C_g(吹入)	0.358	0.348	0.343	0.336	0.333	0.331
C_g(吸出)	0.356	0.347	0.341	0.334	0.332	0.329

DownLoad: CSV

表 2 压力梯度边界层被激发出的T-S波的流向波数和相速度(α_r, C)

Table 2. The streamwise wave numbers and phase speeds (α_r, C) of the excited T-S wave packets in the pressure-gradient boundary layers.

β_H	–0.1	–0.05	0	0.05	0.1
F = 30(吹)	(0.0977, 0.3071)	(0.0960, 0.3125)	(0.0949, 0.3161)	(0.0934, 0.3212)	(0.0915, 0.3279)
F = 30(吸)	(0.0984, 0.3049)	(0.0967, 0.3102)	(0.0956, 0.3138)	(0.0943, 0.3181)	(0.0923, 0.3250)
F = 40(吹)	(0.1262, 0.3169)	(0.1251, 0.3197)	(0.1240, 0.3226)	(0.1218, 0.3284)	(0.1204, 0.3322)
F = 40(吸)	(0.1269, 0.3152)	(0.1257, 0.3182)	(0.1248, 0.3205)	(0.1226, 0.3263)	(0.1210, 0.3306)
F = 50(吹)	(0.1533, 0.3262)	(0.1522, 0.3285)	(0.1514, 0.3303)	(0.1489, 0.3357)	(0.1470, 0.3401)
F = 50(吸)	(0.1541, 0.3245)	(0.1531, 0.3266)	(0.1521, 0.3287)	(0.1497, 0.3340)	(0.1477, 0.3385)
F = 60(吹)	(0.1792, 0.3348)	(0.1784, 0.3363)	(0.1772, 0.3386)	(0.1755, 0.3419)	(0.1735, 0.3458)
F = 60(吸)	(0.1799, 0.3335)	(0.1792, 0.3348)	(0.1780, 0.3371)	(0.1763, 0.3403)	(0.1744, 0.3440)
F = 70(吹)	(0.2047, 0.3419)	(0.2036, 0.3438)	(0.2020, 0.3465)	(0.2004, 0.3493)	(0.1985, 0.3526)
F = 70(吸)	(0.2055, 0.3406)	(0.2043, 0.3426)	(0.2028, 0.3451)	(0.2012, 0.3479)	(0.1993, 0.3512)
F = 80(吹)	(0.2287, 0.3498)	(0.2279, 0.3510)	(0.2267, 0.3529)	(0.2249, 0.3557)	(0.2234, 0.3581)
F = 80(吸)	(0.2295, 0.3486)	(0.2286, 0.3500)	(0.2276, 0.3515)	(0.2261, 0.3538)	(0.2244, 0.3565)

DownLoad: CSV

[1]	Goldstein M E 1983 J. Fluid. Mech. 127 59 Google Scholar
[2]	Ruban A I 1984 Fluid Dynam. 19 709
[3]	陆昌根, 沈露予 2015 物理学报 65 194701 Google Scholar Lu C G, Shen L Y 2015 Acta Phys. Sin. 65 194701 Google Scholar
[4]	Shen L, Lu C, Zhu X 2019 Appl. Math. Mech. 40 851 Google Scholar
[5]	Goldstein M E 1985 J. Fluid. Mech. 154 509 Google Scholar
[6]	Saric W S, Hoos J A, Radeztsky R H 1991 Proceedings of the Symposium and Joint Fluids Engineering Conference, 1st Portland, U.S.A, June 23−27, 1991 p17
[7]	Wiegel M, Wlezien R 1993 AIAA P. 3280
[8]	Dietz A J 1999 J. Fluid. Mech. 378 291 Google Scholar
[9]	Dietz A J 1998 AIAA J. 36 1171 Google Scholar
[10]	Dietz A J 1996 AIAA P. 2083
[11]	Wu X 2001 J. Fluid. Mech. 449 373 Google Scholar
[12]	Wu X 2001 J. Fluid. Mech. 431 91 Google Scholar
[13]	Shen L, Lu C 2016 Appl. Math. Mech. 37 929 Google Scholar
[14]	Shen L, Lu C 2016 Appl. Math. Mech. 37 349 Google Scholar
[15]	Würz W, Herr S, Wörner A, Rist U 2003 J. Fluid. Mech. 478 135 Google Scholar
[16]	Shen L, Lu C 2018 Adv. Appl. Math. Mech. 10 735 Google Scholar
[17]	陆昌根, 沈露予 2015 物理学报 64 224702 Google Scholar Lu C G, Shen L Y 2015 Acta Phys. Sin. 64 224702 Google Scholar
[18]	Johnson M W, Pinarbasi 2014 Flow Turbul. Combu. 93 1 Google Scholar
[19]	Jacobs R G 2001 J. Fluid. Mech. 428 185 Google Scholar

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Vol. 68, Issue 22 - 2019-11-20

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