B R Ziganshin scite author profile

B R Ziganshin

3Publications

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Kazan State Technical University named after A. N. Tupolev

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Comparison of initial pressure distributions in shock wave simulation of optical breakdown on surface

Sattarov

Sochnev

Ziganshin

2021

J. Phys.: Conf. Ser.

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In this work we investigated the velocity of propagation of a shock wave after optical breakdown on the surface, depending on various initial pressure distributions which are simulated in Ansys Fluent. When setting of the shock wave energy of the order of 10 … 20% of the laser pulse energy, results are in satisfactory agreement with experiments. An analysis of the experimental data showed an effect when the velocities of shock waves propagation are comparable but energies of laser pulses differ by two orders of magnitude between each other, which leads to significant deviations from the theory of a point explosion.

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Numerical simulation of gas propagation process behind a shock wave during optical breakdown of air in a cylindrical channel

Sattarov

Ziganshin

Sochnev

et al. 2020

J. Phys.: Conf. Ser.

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This paper substantiates the need to study processes during nanosecond optical breakdown inside a cylindrical channel, and gives an analogy between L. Sedov’s theory of point explosion and an optical breakdown. A variant of the evolution of a shock wave inside a cylindrical channel is proposed. Based on the solution of the problem of a point explosion with backpressure, a preliminary estimate of the gas pressure and velocity behind the shock front was obtained to set the initial conditions in Ansys Fluent. As a result of numerical simulation, the characteristics of the shock wave were calculated, and the distributions of the velocity, density and pressure of the gas behind the shock front were obtained. According to comparison of the experiments and results of numerical simulation, an estimate of the shock wave energy is given, which is from 8 to 16% of the energy of a nanosecond laser pulse. The results of the proposed method of numerical calculation are consistent with the experimental data for measuring the time of the shock wave exits from the channel and the target momentum at atmospheric pressure.

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Study of the Aerodynamic Drag Coefficient of a Conical Thin-Walled Target Body at Low Reynolds Numbers

2021

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B R Ziganshin

Comparison of initial pressure distributions in shock wave simulation of optical breakdown on surface

Numerical simulation of gas propagation process behind a shock wave during optical breakdown of air in a cylindrical channel

Study of the Aerodynamic Drag Coefficient of a Conical Thin-Walled Target Body at Low Reynolds Numbers

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