高超声速条件下凸曲率壁面混合层的流动演化

张震; 易仕和; 刘小林; 陈世康; 张臻

doi:10.7498/aps.73.20240128

摘要

随着高超声速飞行器的不断更新换代, 对成像窗口提出了新的设计要求, 即共形窗口以提高气动特性, 这要求在超声速气膜和光学窗口需要与飞行器机身保持相同的曲率外形. 在马赫数Ma = 6高超声速静风洞中开展了凸曲率壁面(CV)混合层稳定性研究. 采用基于纳米粒子的平面激光散射技术捕获到混合层流场结构, 结合分形维数对混合层失稳规律进行研究. 使用数值模拟技术得到了压力、压缩冲量(I_p)沿流向演化结果. 结果表明: 随着来流总压(P₀)的增大, 静压比(RSP)减小, 混合层失稳位置延迟, 典型涡结构移动速度增大. CV壁面由于顺压梯度的存在使得压力沿流向下降, 沿壁面切向的超声速气膜处于工作状态时, 可以提升壁面压力, 随着P₀增大, RSP随之降低, 提升效果下降; 流动受到CV的膨胀效应影响, I_p沿流向下降, 超声速气膜可以削弱CV上的膨胀效应从而抑制I_p的下降; 压缩冲量的变化率ΔI_p受P₀影响显著, 在弯曲冲量|I_Φ| = 0.191—3.624内, 当P₀ = 0.5 MPa, ΔI_p从178.67%降至12.02%; 当P₀ = 1.0 MPa, ΔI_p从40.38%降至5.64%. ΔI_p随|I_Φ|增大而降低, 随着P₀增大, 降低幅度减小. 结果揭示凸曲率影响下的高超声速混合层流动演化规律, 对高超声速飞行器实现气动减阻与防热特性的外形设计提供一定参考.

关键词:

Abstract

With the continuous upgrading of hypersonic vehicles, a new requirement for designing imaging window i.e. conformal window for improving aerodynamic characteristics, is put forward, in which the supersonic cooling film and optical window are required to maintain the same curvature shape as the aircraft body. In this work, the mixed-layer flow evolution on a convex wall (CV) is investigated. A nanoparticle-based planar laser scattering technique is used to design the flow field structure of the mixed layer in Ma = 6 hypersonic static wind tunnel, and the location of the mixed-layer instability is studied by combing fractal dimension. The results of pressure, and impulse of compression (I_p) evolution along the flow direction are obtained by numerical simulation, showing that the total incoming pressure (P₀) has a significant effect on the flow evolution of the mixed layer: as P₀ increases, the ratio of static pressure (RSP) decreases, that the position of the mixed-layer instability is delayed, and that the flow velocity of the typical vortex structure increases. The favorable gradient existing at the CV wallleads the pressure to drop along the flow direction, and the pressure is enhanced when the supersonic air film along the tangential direction of the wall is under the operating condition. However, as P₀ increases, the RSP decreases, and the lifting effect of the pressure on the CV decreases. The flow field is affected by the expansion effect of the CV, and I_p decreases along the flow direction. The supersonic air film can weaken the expansion effect on the CV and thus suppressing the decrease of I_p. The change rate of I_p (ΔI_p) is significantly affected by P₀, in a range of bending impulse |I_Φ| = 0.191–3.62, ΔI_p decreases from 178.67% to 12.02% when P₀ = 0.5 MPa, and ΔI_p decreases from 40.38% to 5.64% when P₀ = 1.0 MPa. ΔI_p decreases as |I_Φ| increases, but the decrease becomes less as P₀ increases. The results reveal the flow evolution law of hypersonic mixed layer under the influence of convex curvature, and provide a certain reference for designing the shape of hypersonic vehicle to achieve aerodynamic drag reduction and thermal protection characteristics.

Keywords:

作者及机构信息

国防科技大学空天科学学院, 长沙　410073

通信作者: 易仕和, yishihe@nudt.edu.cn ; 刘小林, liuxiaolin09@nudt.edu.cn ;

基金项目: 国家自然科学基金(批准号: 92271203)资助的课题.

Authors and contacts

College of Aerospace Science and Engineering, National University of Defense Technology, Changsha 410073, China

Corresponding author: Yi Shi-He, yishihe@nudt.edu.cn ; Liu Xiao-Lin, liuxiaolin09@nudt.edu.cn ;

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 92271203).

文章全文 : translate this paragraph

参考文献

[1]	Ko S Y, Xu J Z, Yao Y Q, Tsou F K 1984 Int. J. Heat Mass Transfer 27 1551 Google Scholar
[2]	Gibson M M, Verriopoulos C A 1984 Exp. Fluids 2 73 Google Scholar
[3]	Humble R A, Peltier S J, Bowersox R D W 2012 Phys. Fluids 24 106103 Google Scholar
[4]	Mayle R E, Kopper F C, Blair M F, Bailey D A 1977 J. Eng. Power 99 77 Google Scholar
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[9]	Pu J, Zhang T, Wang J H 2022 Int. Commun. Heat Mass Transfer 130 105834 Google Scholar
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[16]	Ifti H S, Hermann T, Ewenz Rocher M, Doherty L, Hambidge C, McGilvray M, Vandeperre L 2022 Exp. Fluids 63 102 Google Scholar
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[23]	牛海波, 易仕和, 刘小林, 霍俊杰, 冈敦殿 2021 物理学报 70 134701 Google Scholar Niu H B, Yi S H, Liu X L, Huo J J, Gang D D 2021 Acta Phys. Sin. 70 134701 Google Scholar
[24]	刘小林, 易仕和, 牛海波, 陆小革 2018 物理学报 67 214701 Google Scholar Liu X L, Yi S H, Niu H B, Lu X G 2018 Acta Phys. Sin. 67 214701 Google Scholar
[25]	刘小林, 易仕和, 牛海波, 陆小革, 赵鑫海 2018 物理学报 67 174701 Google Scholar Liu X L, Yi S H, Niu H B, Lu X G, Zhao X H 2018 Acta Phys. Sin. 67 174701 Google Scholar
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施引文献

图 1 高超声速静风洞

Fig. 1. Hypersonic static wind tunnel.

下载: 全尺寸图片幻灯片

图 2 实验模型示意图

Fig. 2. Experimental model diagram.

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图 3 超声速气膜喷管马赫数校准结果

Fig. 3. Mach number calibration results for supersonic air-film nozzles.

下载: 全尺寸图片幻灯片

图 4 不同P₀下的流场NPLS图像　(a) 0.3 MPa; (b) 0.5 MPa; (c) 0.6 MPa; (d) 0.65 MPa; (e) 1.0 MPa

Fig. 4. NPLS images of the flow field at different P₀: (a) 0.3 MPa; (b) 0.5 MPa; (c) 0.6 MPa; (d) 0.65 MPa; (e) 1.0 MPa.

下载: 全尺寸图片幻灯片

图 5 边缘检测结果　(a) P₀ = 0.3 MPa; (b) P₀ = 0.5 MPa; (c) P₀ = 0.6 MPa; (d) P₀ = 0.65 MPa; (e) P₀ = 1.0 MPa

Fig. 5. Edge detection result: (a) P₀ = 0.3 MPa; (b) P₀ = 0.5 MPa; (c) P₀ = 0.6 MPa; (d) P₀ = 0.65 MPa; (e) P₀ = 1.0 MPa.

下载: 全尺寸图片幻灯片

图 6 分形分析结果

Fig. 6. Results of fractal analysis.

下载: 全尺寸图片幻灯片

图 7 不同P₀下时序间隔5 μs的NPLS结果　(a) P₀ = 0.3 MPa, t₁; (b) P₀ = 0.3 MPa, t₁+5 μs; (c) P₀ = 0.5 MPa, t₂; (d) P₀ = 0.5 MPa, t₂+5 μs; (e) P₀ = 0.6 MPa, t₃; (f) P₀ = 0.6 MPa, t₃+5 μs; (g) P₀ = 0.65 MPa, t₄; (h) P₀ = 0.65 MPa, t₄+5 μs; (i) P₀ = 1.0 MPa, t₅; (j) P₀ = 1.0 MPa, t₅+5 μs.

Fig. 7. NPLS results for timing intervals of 5 μs at different P₀: (a) P₀ = 0.3 MPa, t₁; (b) P₀ = 0.3 MPa, t₁+5 μs; (c) P₀ = 0.5 MPa, t₂; (d) P₀ = 0.5 MPa, t₂+5 μs; (e) P₀ = 0.6 MPa, t₃; (f) P₀ = 0.6 MPa, t₃+5 μs; (g) P₀ = 0.65 MPa, t₄; (h) P₀ = 0.65 MPa, t₄+5 μs; (i) P₀ = 1.0 MPa, t₅; (j) P₀ = 1.0 MPa, t₅+5 μs.

下载: 全尺寸图片幻灯片

图 8 不同来流总压下超声速气膜对P/P_in的影响　(a) P₀ = 0.3 MPa; (b) P₀ = 0.5 MPa; (c) P₀ = 0.6 MPa; (d) P₀ = 0.65 MPa; (e) P₀ = 1.0 MPa; (f) 不同P₀下, P_j= 10 kPa

Fig. 8. Effect of supersonic air film on P/P_in at different incoming total pressures: (a) P₀ = 0.3 MPa; (b) P₀ = 0.5 MPa; (c) P₀ = 0.6 MPa; (d) P₀ = 0.65 MPa; (e) P₀ = 1.0 MPa; (f) P_j= 10 kPa with different P₀.

下载: 全尺寸图片幻灯片

图 9 不同来流总压下超声速气膜对I_p的影响　(a) P₀ = 0.3 MPa; (b) P₀ = 0.5 MPa; (c) P₀ = 0.6 MPa; (d) P₀ = 0.65 MPa; (e) P₀ = 1.0 MPa; (f)不同P₀下, P_j= 10 kPa

Fig. 9. Effect of supersonic air film on I_p at different incoming total pressures: (a) P₀ = 0.3 MPa; (b) P₀ = 0.5 MPa; (c) P₀ = 0.6 MPa; (d) P₀ = 0.65 MPa; (e) P₀ = 1.0 MPa; (f) P_j= 10 kPa with different P₀.

下载: 全尺寸图片幻灯片

图 10 不同P₀下超声速气膜对I_p的增长作用

Fig. 10. Effect of supersonic air film on the growth of I_p at different P₀.

下载: 全尺寸图片幻灯片

[1]	Ko S Y, Xu J Z, Yao Y Q, Tsou F K 1984 Int. J. Heat Mass Transfer 27 1551 Google Scholar
[2]	Gibson M M, Verriopoulos C A 1984 Exp. Fluids 2 73 Google Scholar
[3]	Humble R A, Peltier S J, Bowersox R D W 2012 Phys. Fluids 24 106103 Google Scholar
[4]	Mayle R E, Kopper F C, Blair M F, Bailey D A 1977 J. Eng. Power 99 77 Google Scholar
[5]	Wang Q C, Wang Z G, Zhao Y X 2017 Phys. Fluids 29 116106 Google Scholar
[6]	Thara-Reshma I V, Vinoth P, Rajesh G, Ben-Dor G 2021 J. Fluid Mech. 924 A37 Google Scholar
[7]	Kokkinakis I W, Drikakis D, Spottswood S M, Brouwer K R, Riley Z B 2023 Phys. Fluids 35 106109 Google Scholar
[8]	Zhang T, Pu J, Zhou W L, Wang J H, Wu W L, Chen Y 2021 Int. J. Heat Mass Transfer 175 121384 Google Scholar
[9]	Pu J, Zhang T, Wang J H 2022 Int. Commun. Heat Mass Transfer 130 105834 Google Scholar
[10]	Su C H 2019 AIAA J 57 2840 Google Scholar
[11]	Zhao X H, Yi S H, Mi Q, Ding H L, He L 2022 AIAA J. 60 1262 Google Scholar
[12]	Sun X B, Ding H L, Liu M X, Yi S H, Zhao Y X 2023 Aerosp. Sci. Technol. 140 108488 Google Scholar
[13]	Lin J X, Wang Q C, Zhao Y X, Lu X G 2023 Phys. Fluids 35 056107 Google Scholar
[14]	Marquardt P, Klaas M, Schröder W 2020 Exp. Fluids 61 160 Google Scholar
[15]	Sun X K, Ni H, Peng W, Jiang P X, Zhu Y H 2021 Chin. J. Aeronaut. 34 452 Google Scholar
[16]	Ifti H S, Hermann T, Ewenz Rocher M, Doherty L, Hambidge C, McGilvray M, Vandeperre L 2022 Exp. Fluids 63 102 Google Scholar
[17]	Singh K, Udayraj 2022 Appl. Therm. Eng. 208 118224 Google Scholar
[18]	Qin Y M, Li X Y, Ren J, Jiang H D 2015 Int. J. Heat Mass Transfer 86 482 Google Scholar
[19]	Peter J M F, Kloker M J 2022 Phys. Fluids 34 025125 Google Scholar
[20]	Zhao X H, Yi S H, Mi Q, Ding H L, Niu H B 2022 Aerosp. Sci. Technol. 123 107457 Google Scholar
[21]	Zhao Y X, Yi S H, Tian L F, Cheng Z 2009 Sci. China, Ser. E: Technol. Sci. 52 3640 Google Scholar
[22]	郑文鹏, 易仕和, 牛海波, 霍俊杰 2021 物理学报 70 244702 Google Scholar Zheng W P, Yi S H, Niu H B, Huo J J 2021 Acta Phys. Sin. 70 244702 Google Scholar
[23]	牛海波, 易仕和, 刘小林, 霍俊杰, 冈敦殿 2021 物理学报 70 134701 Google Scholar Niu H B, Yi S H, Liu X L, Huo J J, Gang D D 2021 Acta Phys. Sin. 70 134701 Google Scholar
[24]	刘小林, 易仕和, 牛海波, 陆小革 2018 物理学报 67 214701 Google Scholar Liu X L, Yi S H, Niu H B, Lu X G 2018 Acta Phys. Sin. 67 214701 Google Scholar
[25]	刘小林, 易仕和, 牛海波, 陆小革, 赵鑫海 2018 物理学报 67 174701 Google Scholar Liu X L, Yi S H, Niu H B, Lu X G, Zhao X H 2018 Acta Phys. Sin. 67 174701 Google Scholar
[26]	Tichenor N R, Humble R A, Bowersox R D W 2013 J. Fluid Mech. 722 187 Google Scholar
[27]	Wang Q C, Wang Z G 2016 Appl. Phys. Lett. 108 114102 Google Scholar
[28]	Zhang Z, Yi S, Liu X L, Hu Y F, Chen S K 2024 Phys. Fluids 36 036127 Google Scholar
[29]	Bradshaw P 2006 J. Fluid Mech. 52 113 Google Scholar
[30]	Bradshaw P 1974 J. Fluid Mech. 63 449 Google Scholar

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高超声速条件下凸曲率壁面混合层的流动演化