Characteristics of shock tube generated compressible vortex rings at very high shock Mach numbers

Poudel, Sajag; Chandrala, Lakshmana; Das, Debopam; De, Ashoke

doi:10.1063/5.0063164

Cited by 11 publications

(2 citation statements)

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“…Compressible vortex rings, as a common phenomenon in aerospace engineering, have been studied intensively for decades, both experimentally and numerically, in the atmosphere (Elder and De Haas 1952;Baird 1987;Hillier 1991;Brouillette and Hebert 1997;Kontis et al 2006;Murugan et al 2012;Dora et al 2014;Zhang et al 2014;Poudel et al 2021). Understanding compressible vortex ring evolution is fundamental to thrust control improvement (Cao et al 2021) and avoiding contamination and impingement on sensitive surfaces (Martinez and Worthy 2020).…”

Section: Introductionmentioning

confidence: 99%

Vortex Ring Formation Following Shock Wave Diffraction in Low-Pressure Environments

Cao,

Kontis,

Hosano

et al. 2023

Flow Turbulence Combust

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Compressible vortex rings have been widely investigated for decades under ambient atmospheric conditions, and understanding this transient phenomenon is important for improving the thrust vector and avoiding surface impingement and contamination. However, how the vortex ring behaves in a reduced pressure environment remains unknown. This work provides schlieren imaging and pressure measurement results of the vortex ring when the environmental pressure is lower than 1 atm. The basic structure of the compressible vortex ring in low-pressure environments has been captured. The reduced environmental pressure will degenerate the internal flow structure, including the shock wave, the CRVRs, and the vortices due to the Kelvin–Helmholtz instability, which is consistent with the conclusion of previous numerical work. The vortex ring is confirmed to exist when the environmental pressure is approximately 1.0 kPa.

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Section: Introductionmentioning

confidence: 99%

Vortex Ring Formation Following Shock Wave Diffraction in Low-Pressure Environments

Cao,

Kontis,

Hosano

et al. 2023

Flow Turbulence Combust

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“…Vortex rings can form not only in air, such as in rocket nozzles and wing tips of airplanes or out the end of a shock tube, but also in water in cavitation bubbles, the wake of a boat and waterspouts 1 , 2 . Cavitation bubbles can turn into vortices as they travel, and upon impact with the propeller or wall of a ship, break and create shock waves that damage the vessel 14 .…”

Section: Introductionmentioning

confidence: 99%

Shock wave formation from head-on collision of two subsonic vortex rings

Bauer

Thomas

Baker

et al. 2022

Sci Rep

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Vortex ring collisions have attracted intense interest in both water and air studies (Baird in Proc R Soc Lond Ser Math Phys Sci 409:59–65, 1987, Poudel et al. in Phys Fluids 33:096105, 2021, Lim and Nickels in Nature 357:225, 1992, New et al. in Exp Fluids 57:109, 2016, Suzuki et al. in Geophys Res Lett 34, 2007, Yan et al. in J Fluids Eng 140:054502, 2018, New et al. in J Fluid Mech 899, 2020, Cheng et al. in Phys Fluids 31:067107, 2019, Hernández and Reyes in 29:103604, 2017, Mishra et al. in Phys Rev Fluids, 2021, Zednikova et al. in Chem Eng Technol 42:843–850, 2019, Kwon et al. in Nature 600:64–69, 2021). These toroidal structures spin around a central axis and travel in the original direction of impulse while spinning around the core until inertial forces become predominant causing the vortex flow to spontaneously decay to turbulence (Vortex Rings, https://projects.iq.harvard.edu/smrlab/vortex-rings). Previous studies have shown the collision of subsonic vortex rings resulting in reconnected vortex rings, but the production of a shock wave from the collision has not been demonstrated visibly (Lim and Nickels in Nature 357:225, 1992, Cheng et al. in Phys Fluids 31:067107, 2019). Here we present the formation of a shock wave due to the collision of explosively formed subsonic vortex rings. As the vortex rings travel at Mach 0.66 toward the collision point, they begin to trap high pressure air between them. Upon collision, high pressure air was imploded and released radially away from the axis of the collision, generating a visible shock wave traveling through and away from the colliding vortices at Mach 1.22. Our results demonstrate a pressure gradient with high pressure release creating a shock wave. We anticipate our study to be a starting point for more explosively formed vortex collisions. For example, explosives with different velocities of detonation could be tested to produce vortex rings of varying velocities.

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Numerical simulation of high peak overpressure blast wave through shock tube and its interaction with a rectangular object

Thangadurai

Kundu²,

Sandhu³

et al. 2023

European Journal of Mechanics - B/Fluids

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Characteristics of shock tube generated compressible vortex rings at very high shock Mach numbers

Cited by 11 publications

References 50 publications

Vortex Ring Formation Following Shock Wave Diffraction in Low-Pressure Environments

Vortex Ring Formation Following Shock Wave Diffraction in Low-Pressure Environments

Shock wave formation from head-on collision of two subsonic vortex rings

Numerical simulation of high peak overpressure blast wave through shock tube and its interaction with a rectangular object

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