Investigation of the interaction with a high-speed flow of an underexpanded gas jet injected out of the body


DOI: 10.34759/trd-2021-119-05

Аuthors

Snazin A. A., Shevchenko A. V.*, Panfilov E. B.**, Prilytskiy I. K.

Mlitary spaсe Aсademy named after A.F. Mozhaisky, Saint Petersburg, Russia

*e-mail: artnetru@yandex.ru
**e-mail: vka@mil.ru

Abstract

The interaction of injected gas jets with an incoming high-speed flow is one of the most pressing issues today. The use of injected jets for motion control has a significant advantage over mechanical controls, especially with regard to high maneuverability.

Calculations of the gas-dynamic parameters of a high-speed flow near a conical surface at Mach number M=10-17 were carried out with the characteristics of the incoming flow P=79.8 Pa, T=270 K and the parameters of the injected jets Tj=293 K and J=4.95 — the coefficient of penetration of the gas jet into the incoming flow [1,2].

The object of study is a conical surface with gas injection holes located along the generatrix at a distance x/l=0.3, 0.6, 0.9 from the toe.

When analyzing the distribution of the zones of increased pressure in front of the place of injection of the jet and low pressure behind it, it was found that the value of the pressure coefficient with an increase in the Mach number proportionally increases both in the zone of increased and decreased pressure, regardless of the place of injection. The maximum pressure coefficient difference between the zones of high and low pressure is observed during injection at a distance x/l=0.3. In this case, the injected jet interacts with the head shock wave, locally pushing it away from the model. As a result, the p ̅ on the surface before and after the jets is much higher than in other locations of the injection holes.

It was found that an increase in the oncoming velocity leads to an increase in pressure before and after the injected jet. In this case, in front of the injected jet, the pressure increases more significantly than downstream of it. With an increase in the Mach number, the maximum p ̅  shifts closer to the injection site.

The analysis of the efficiency of the action of jets with different variants of arrangement in high-speed flow is carried out. He showed that, while maintaining the parameters of the injected jets constant, an increase in the incoming flow velocity leads to a decrease in the J coefficient, since the pressure gradient at the shock wave increases.

It was found that the magnitude of the Ky increases with an increase in the incoming flow velocity. The maximum is observed when the injected jet is displaced closer to the nose of the model (at М=17), since in this place the injection of the jet is as close as possible to the head shock wave.

The results of numerical experiments correlate well with the results of field experimental studies [2, 19, 20], carried out using the aerodynamic laboratory of the A.F. Mozhaisky MSA and contribute to a more complete study of the effect of high-speed flow on the elements of aircraft.


Keywords:

gas injection, high-speed flow, pressure coefficient, amplification factor

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