Physics of Fluids

2018

DOI: 10.1063/1.5012122

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Simulating particle inertia for velocimetry measurements of a flow behind an expanding shock wave

E. Yu. Koroteeva

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I. V. Mursenkova

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Abstract: When particle-based velocimetry techniques are applied to complex high-speed flows, the non-ideal tracing capability of seeding particles becomes most prominent. Here, we present a numerical particle tracking methodology to predict the bias errors associated with particle image velocimetry (PIV) of flows with moving shocks. The methodology involves performing computational fluid dynamics simulations that yield time-varying flow fields, which are then used to compute the actual paths and velocities of the seedi… Show more

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Cited by 11 publications

References 19 publications

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Evolution and fluid dynamic effects of pulsed column-shaped plasma

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et al. 2019

Experimental Thermal and Fluid Science

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No abstract

Evolution and fluid dynamic effects of pulsed column-shaped plasma

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et al. 2019

Experimental Thermal and Fluid Science

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Experimental and numerical investigation of a flow induced by a pulsed plasma column

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2018

Physics of Fluids

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The paper studies, both experimentally and numerically, a high-speed transient flow induced by a pulsed volume discharge in still air at low pressure. It is shown that, in the constricted mode, the discharge is capable of producing uniform deposition of the electrical energy into a long (24 mm in length), thin (less than 2 mm in radius) plasma column. Flow visualization experiments using particle image velocimetry (PIV) and high-speed shadow imaging indicate that this pulsed localized energy deposition generates a highly symmetrical cylindrical shock wave expanding at an average speed of 550 m/s within the first 40 μs after the discharge. Three-dimensional computational fluid dynamics (CFD) simulations successfully reproduce the experimentally observed flow structures and provide better insight into the complex discharge-induced flow. Modeling the trajectories of “virtual” particles within the CFD-predicted flow yields excellent agreement between numerical and PIV flow velocity profiles, and this comparison is used to quantify the rates of “rapid” energy thermalization in the pulsed discharge.

Experimental investigation of the flow dynamics and boundary layer in a shock tube with discharge section based on digital panoramic methods

et al. 2018

AIP Conference Proceedings

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