|
Теплофизика высоких температур, 2020, том 58, выпуск 6, статья опубликована в англоязычной версии журнала
(Mi tvt11302)
|
|
|
|
Эта публикация цитируется в 4 научных статьях (всего в 4 статьях)
Статьи, опубликованные в английской версии журнала
Тепломассообмен и физическая газодинамика
Experimental research of gasdynamic liquid drops breakup in the supersonic flow with an oblique shock wave
K. J. Arefyevabc, O. V. Gus'kovab, A. N. Prokhorovab, A. S. Savel'evad, E. E. Sonad, K. Gauthame, D. Same, K. T. Sonue, T. M. Muruganandame a Moscow Institute of Physics and Technology
b Central Institute of Aviation Motors, State Scientific Center of Russian Federation, Moscow
c Bauman Moscow State Technical University
d Joint Institute for High Temperatures, Russian Academy of Sciences, Moscow
e Indian Institute of Technology Madras
Аннотация:
This paper is devoted to understanding gasdynamic liquid drops breakup in a supersonic flow with presence of an oblique shock wave. An experimental facility, diagnostic tools and an experimental methodology are presented as well as numerical simulations results. Computations and experiments were used to get flow parameters in the duct with supersonic flow at Mach numbers $2.0$, $2.5$, and $3.0$. The droplets were made to interact with a single oblique shock wave generated by a wedge in the test section. Experimental data are obtained for the change in diameter of the droplets and the change in speed of droplets in a supersonic flow at the three Mach numbers. The data are presented for an initial Weber number over the range of $16$–$115$. It is shown that the mass loss rate of droplets are quadratically related to the Weber number, irrespective of the presence of oblique shock.
Поступила в редакцию: 03.12.2019 Исправленный вариант: 05.03.2020 Принята в печать: 10.03.2020
Образец цитирования:
K. J. Arefyev, O. V. Gus'kov, A. N. Prokhorov, A. S. Savel'ev, E. E. Son, K. Gautham, D. Sam, K. T. Sonu, T. M. Muruganandam, “Experimental research of gasdynamic liquid drops breakup in the supersonic flow with an oblique shock wave”, High Temperature, 58:6 (2020), 884–892
Образцы ссылок на эту страницу:
https://www.mathnet.ru/rus/tvt11302
|
|