Head-on collision of shock wave induced vortices with solid and perforated walls

Kontis, Konstantinos; An, R.; Zare‐Behtash, Hossein; Kounadis, Diamantis

doi:10.1063/1.2837172

Cited by 44 publications

(20 citation statements)

References 28 publications

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“…1, where γ is the specific heat ratio, ρ is the density, M is the Mach number and subscripts 0 and jet refer to freestream and jet conditions. Schlieren photography [40][41][42][43][44] was employed to visualize the flow field around the cavity in a standard Z-type optical arrangement. A pair of 203.3 mm diameter parabolic mirrors with 1016 mm focal length and a 150W Hamamatsu Xenon continuous light source were used.…”

Section: Methodsmentioning

confidence: 99%

Effectiveness of jet location on mixing characteristics inside a cavity in supersonic flow

Ukai

Zare‐Behtash

Erdem

et al. 2014

Experimental Thermal and Fluid Science

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Section: Methodsmentioning

confidence: 99%

Effectiveness of jet location on mixing characteristics inside a cavity in supersonic flow

Ukai

Zare‐Behtash

Erdem

et al. 2014

Experimental Thermal and Fluid Science

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“…This produces a pulsed upstream condition where the duration and magnitude of the pulse can be controlled up to the nozzles' inlet. [11][12][13] The length of the circular driven section (baseline) was 1310.5mm, with each nozzle 300mm in length.…”

Section: Experimental Setup a Shock Tubementioning

confidence: 99%

Effect of primary jet geometry on ejector performance: A cold-flow investigation

Zare‐Behtash

Gongora-Orozco

Kontis

2011

International Journal of Heat and Fluid Flow

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The following cold-flow study examines the interaction of the diffracted shock wave pattern and the resulting vortex loop emitted from a shock tube of various geometries, with an ejector having a round bell-shaped inlet. The focus of the study is to examine the performance of the ejector when using different jet geometries (primary flow) to entrain secondary flow through the ejector. These include two circular nozzles with internal diameters of 15mm and 30mm, two elliptical nozzles with minor to major axis ratios of a/b = 0.4 and 0.6 with b = 30mm, a square nozzle with side lengths of 30mm, and two exotic nozzles resembling a pair of lips with axis ratios of a/b = 0.2 and 0.5 with b = 30mm. Shock tube driver pressures of P 4 = 4, 8, and 12bar were studied, with the pressure of the shock tube driven section P 1 being atmospheric. High-speed schlieren photography using the Shimadzu Hypervision camera along with detailed pressure measurements along the ejector and the impulse created by the ejector were conducted. * Hossein. Zare-Behtash@glasgow.ac.uk

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“…The bursting of the diaphragm was initiated manually with a plunger. The shock tube setup was identical to that used by Kontis et al (2008).…”

Section: Shock Tubementioning

confidence: 99%

“…In order to better compare the vortex loop behavior at various Mach numbers, it is desirable to eliminate these distortions. A means of doing so is by changing the length of the driver section so that the incident shock and the initial reflected rarefaction wave arrive at the shock tube exit at approximately the same time (Kontis et al, 2008, Arakeri et al, 2004, Brouillette and Hebert, 1997.…”

Section: Introductionmentioning

confidence: 99%

Global visualization and quantification of compressible vortex loops

Zare‐Behtash

Gongora-Orozco

Kontis

2009

J Vis

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Abstract:The physics of compressible vortex loops generated due to the rolling up of the shear layer upon the diffraction of a shock wave from a shock tube is far from being understood, especially when shock-vortex interactions are involved. This is mainly due to the lack of global quantitative data available which characterizes the flow. The present study involves the usage of the PIV technique to characterize the velocity and vorticity of compressible vortex loops formed at incident shock Mach numbers of M=1.54 and 1.66. Another perk of the PIV technique over purely qualitative methods, which has been demonstrated in the current study, is that at the same time the results also provide a clear image of the various flow features. Techniques such as schlieren and shadowgraph rely on density gradients present in the flow and fail to capture regions of the flow influenced by the primary flow structure which would have relatively lower pressure and density. Various vortex loops, namely, square, elliptic and circular, were generated using different shape adaptors fitted to the end of the shock tube. The formation of a coaxial vortex loop with opposite circulation along with the generation of a third stronger vortex loop ahead of the primary with same circulation direction are of the interesting findings of the current study.

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Head-on collision of shock wave induced vortices with solid and perforated walls

Cited by 44 publications

References 28 publications

Effectiveness of jet location on mixing characteristics inside a cavity in supersonic flow

Effectiveness of jet location on mixing characteristics inside a cavity in supersonic flow

Effect of primary jet geometry on ejector performance: A cold-flow investigation

Global visualization and quantification of compressible vortex loops

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