Search Results for “Smolenskyi D. E.” – Collected book of scientific-technical articles https://journal.yuzhnoye.com Space technology. Missile armaments Tue, 02 Apr 2024 12:34:00 +0000 en-GB hourly 1 https://journal.yuzhnoye.com/wp-content/uploads/2020/11/logo_1.svg Search Results for “Smolenskyi D. E.” – Collected book of scientific-technical articles https://journal.yuzhnoye.com 32 32 10.2.2017 Analysis Method of Hydraulic Parameters of Circular Intake Device in Limit Operating Modes https://journal.yuzhnoye.com/content_2017_2/annot_10_2_2017-en/ Fri, 21 Jun 2024 08:45:59 +0000 https://journal.yuzhnoye.com/?page_id=29771
, Smolenskyi D. М., Smolenskyi D. М., Smolenskyi D. М., Smolenskyi D. М., Smolenskyi D. М., Smolenskyi D. М., Smolenskyi D.
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10. Analysis Method of Hydraulic Parameters of Circular Intake Device in Limit Operating Modes

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2017 (2); 53-56

Language: Russian

Annotation: The paper presents the experiment-calculated data on hydraulic parameters of ring intake device in different operation modes. The method of their calculation is proposed taking into account limit deviations of influencing factors. Satisfactory convergence of calculated and experiment data is shown.

Key words:

Bibliography:
1. Il’in G. I., Demchenko S. A., Smolensky D. E. Experimental Investigation of Toroidal Tank Intake Device at High-Flowrate Flow Lab. Space Technology. Missile Armaments: Collection of scientific–technical articles. 2013. Issue 1. Dnepropetrovsk. P. 54–59.
2. Vasilina V. G. et al. Autonomous Development Testing of LRPS Pneumatic System Units and Subsystems: Tutorial / V. G. Vasilina, G. I. Il’in, V. F. Nesvit, V. I. Perlik. Kharkiv, 2005. 130 p.
3. Voloshina M. A. et al. On Measurement of Liquid Flow Discontinuity during Development Testing of Flying Vehicle Propellant Tanks Intake Devices. Space Technology. Missile Armaments: Collection of scientific-technical articles. 2010. Issue 2. P. 122–135.
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10.2.2017 Analysis Method of Hydraulic Parameters of Circular Intake Device in Limit Operating Modes
10.2.2017 Analysis Method of Hydraulic Parameters of Circular Intake Device in Limit Operating Modes
10.2.2017 Analysis Method of Hydraulic Parameters of Circular Intake Device in Limit Operating Modes
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5.2.2019 Features of the development testing of the propellants deposition inside the tanks of launch vehicles https://journal.yuzhnoye.com/content_2019_2-en/annot_5_2_2019-en/ Mon, 15 May 2023 15:45:40 +0000 https://journal.yuzhnoye.com/?page_id=27207
, Smolenskyi D. S., Smolenskyi D. S., Smolenskyi D. S., Smolenskyi D. S., Smolenskyi D. S., Smolenskyi D. S., Smolenskyi D.
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5. Features of the development testing of the propellants deposition inside the tanks of launch vehicles

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2019, (2); 35-41

DOI: https://doi.org/10.33136/stma2019.02.035

Language: Russian

Annotation: When accomplishing the task of spacecraft orbital injection, the necessity arises of main engine multiple ignitions and consequently, long pauses between the ignitions are possible. As the propellant during pauses between ignitions is in the conditions of practically full absence of gravitation and can freely move over entire tank volume taking practically any spatial position, to ensure main engine guaranteed ignition the necessity arises to move the propellant into pre-start position. The propellant is moved to the supply lines by way of creating longitudinal acceleration which is done using inertial continuity ensuring means (thrusters). The time of full liquid displacement from one position into another is the most important parameter having an impact on propellant amount in the tanks and accordingly, on power characteristics of a stage. The theoretical calculations of hydrodynamic processes are connected with considerable mathematical difficulties caused by complexity of solving hydrodynamic problems of determination of liquid flowing with free surface taking into account surface tension of the liquid and many other geometrical, kinematic, and dynamic factors. Therefore, the most reliable data from solving these problems are currently obtained only on model hydrodynamic stands where it is possible to model liquid behavior in tanks in the conditions of variable gravitation. The paper presents the authors-developed procedure of calculating the full time required for propellant components deposition during rocket’s apogee stage flight and the procedure of selecting the modeling parameters (scale, time, and acсeleration) to ensure development testing in the conditions of limited test stand base. The use of the proposed procedure allows (in initial phase of launch vehicle development) determining the full time required to perform deposition with sufficient accuracy and thus optimizing the propellant mass required for operation of inertial continuity ensuring system, which in its turn, will allow increasing the payload mass to be injected.

Key words: propellant deposition, zero-gravity stand, hydrodynamic similarity, damping and separation

Bibliography:
1. Masica W. J., Petrash D. A. Motion of liquid-vapor interface in response to imposed acceleration. Lewis Research Center. NASA TN D-3005. 1965. 24 р.
2. Masica W. J., Petrash D. A., Otto E. W. Hydrostatic stability of liquid-vapor interface in the gravitational field. Lewis Research Center. NASA TN D-2267. 1964. 18 р.
3. Glyuk D. F., Jill D. P. Hydromechanika podachi topliva v dvigatelnoy systeme kosmicheskogo korablya v sostoyanii nevesomosti. Konstruirovanie i technologiya machinostroeniya. 1965. T. 87. S. 1–10.
4. Birdge G. V., Blackmon J. B. et al. Analiticheskiy podkhod k proektirovaniyusystem povtornoy zapravke na orbite. Sbornik perevodov. GONTI-4. 1970. S. 56–111.
5. Woss D. E., Hattis P. D. Problema upravleniya istecheniem v processe zapravki bakov Space Shuttle zhidkimi komponentami na okolozemnoy orbite. Astronavtika i raketodynamika. 1986. № 7. S. 8–19.
6. Sedykh I. V., Smolenskiy D. E. Eksperimentalnoe podtverzhdenie rabotosposobnosti capillyrnogo zabornogo ustroistva pri otdelenii kosmicheskogo apparata. Mekhanika gyroskopicheskikh system. 2017. № 33. S. 105–114.
7. Sedykh I. V., Smolenskiy D. E., Nazarenko D. S. Eksperimentalnoe podtverzhdenie rabotosposobnosti capillyrnogo zabornogo ustroistva (setchatogo razdelitelya) pri programmnom razvorote. Visn. Dnipr. un-tu. Ser.: Raketno-kosmichna tekhnika. 2018. Vyp. 21. T. 26. S. 112–119.
8. Garkusha V. A., Shevchenko B. A., Rada N. A., Prilukova L. V. Eksperimentalnaya otrabotka sredstv obespecheniya sploshnosti komponentov topliva kosmicheskykh letatelnykh apparatov: Obzor po materialam otkrytoy zarubezhnoy pechati za 1963–1983. Seria UP. № 235. GONTI-3. 1984. 38 s.
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5.2.2019 Features of the development testing of the propellants deposition inside the tanks of launch vehicles
5.2.2019 Features of the development testing of the propellants deposition inside the tanks of launch vehicles
5.2.2019 Features of the development testing of the propellants deposition inside the tanks of launch vehicles

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