Aero-Optical Mitigation of Shocks Around Turrets at Transonic Speeds Using Passive Flow Control

Gordeyev, Stanislav; Burns, Robert E.; Jumper, Eric J.; Gogineni, Sivaram; Paul, Michael; Wittich, Donald J.; Afb, Kirtland

doi:10.2514/6.2013-717

Cited by 18 publications

(11 citation statements)

References 16 publications

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“…The shock creates unsteady density gradients in the flow and promotes an earlier separation of the flow off the turret. All these shock-related features add additional strong aero-optical distortions to the outgoing beam [5,9,10].…”

Section: Introductionmentioning

confidence: 99%

“…One approach is to manipulate the flow using the flow control. The passive flow control utilizes a porous screen, which introduces total pressure losses near the surface of the turret and, as a result, slows the flow down to subsonic speeds, thus eliminating the unsteady shock [10]. The active flow control shows some promise in directly manipulating the shock [11].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Estimation of Aero-Optical Wavefronts Using Optical and Non-Optical Measurements

Burns

Gordeyev

Jumper

et al. 2014

52nd Aerospace Sciences Meeting

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In this paper we present two algorithms for estimating the aero-optical aberration of a transonic flow around a 2-D turret based on Malley probe signals or pressure signals from few selected points. These two algorithms use Artificial Neural Networks and Linear Stochastic Estimation of varying model orders to estimate Proper Orthogonal Decomposition modal coefficients. These estimated coefficients are then used to reconstruct an estimated wavefront. This estimated wavefront is subtracted from the true wavefront to obtain a simulated reduction in the overall level of optical aberration. Reductions of up to 48% are achieved for both models. A robustness analysis is also performed, in which it is found that the algorithm is not sufficiently robust to changing flow conditions. Solutions are proposed for further investigation.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Estimation of Aero-Optical Wavefronts Using Optical and Non-Optical Measurements

Burns

Gordeyev

Jumper

et al. 2014

52nd Aerospace Sciences Meeting

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“…Thus, in order to find a Machnumber-independent POD modes, it is necessary to repeat PSP experiments at a higher Mach number of at least 0.4. Also, the outlined approach to analyze the unsteady pressure fields can be highly-useful at transonic speeds, where additional effects from a local shock on the separated flow from the turret are present [1,28].…”

Section: Conclusion and Discussionmentioning

confidence: 99%

The Comparison of Unsteady Pressure Field over Flat- and Conformal-Window Turrets using Pressure Sensitive Paint

Gordeyev

Lucca

Jumper

et al. 2013

44th AIAA Plasmadynamics and Lasers Conference

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Spatially-temporally-resolved unsteady pressure fields on a surface of a hemisphere-oncylinder turret with either a flat-or a conformal-window were characterized using fastresponse pressure sensitive paint at M = 0.33 for several window viewing angles. Various statistical properties of pressure fields were computed and geometry effects on unsteady pressure, including an effect of either flat-or conformal-window, were analyzed and discussed. Proper orthogonal decomposition were also used to extract dominant pressure modes and corresponding temporal coefficients and to analyze and compare instantaneous pressure structures for different turret geometries and viewing angles. In addition, the effects of gaps and 'smile' cut-outs present on the turret were investigated.

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“…34 In terms of interaction of aeroptics with shock waves, the study by Gordeyev et al 31 placed a wedge in the windtunnel and measured through a weak mach wave. A more recent work by Gordeyev et al 35 looked at passive flow control devices to eliminate shock formation on a turret in transonic flow. Burns et al 36 investigated Artificial Neural Networks and Linear Stochastic Estimation to attempt to construct an estimated wavefront.…”

Section: Introductionmentioning

confidence: 98%

Investigation of turbulent shock boundary interaction unsteadiness and its effects on aero-optics in a Mach 2 ramp flow

White

Visbal

2014

45th AIAA Plasmadynamics and Lasers Conference

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Unsteady shock effects are investigated in a Mach 2 compression ramp in order to better understand the effects of shock motion on optical propagation. A shock surface is constructed from instantaneous flow data and used to determine the shock motion. This shock surface is then compared to the differential tip in the optical propagation in order to separate out the effects of the shock and the non-equilibrium boundary layer between the shock and ramp wall. The results show that even for a low Reynolds number (Re θ = 1375), the low frequency oscillations still show a characteristic Strouhal number of 0.03 which has been observed over a large range of Mach numbers at higher Reynolds numbers. Despite a marginal correlation between the wall pressure and the shock displacement, it is shown that using the wall pressure to drive Plotkin's simplified model of the shock motion [AIAA J., 13:8, 1975] has a much better correlation with the actual motion.

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Aero-Optical Mitigation of Shocks Around Turrets at Transonic Speeds Using Passive Flow Control

Cited by 18 publications

References 16 publications

Estimation of Aero-Optical Wavefronts Using Optical and Non-Optical Measurements

Estimation of Aero-Optical Wavefronts Using Optical and Non-Optical Measurements

The Comparison of Unsteady Pressure Field over Flat- and Conformal-Window Turrets using Pressure Sensitive Paint

Investigation of turbulent shock boundary interaction unsteadiness and its effects on aero-optics in a Mach 2 ramp flow

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