Mathematical modelling of liquid rocket engine flow regulator in frequency and time domains

Aeronautical and Space-Rocket Engineering

Thermal engines, electric propulsion and power plants for flying vehicles


DOI: 10.34759/vst-2021-1-96-106

Аuthors

Aung K. M.*, Kolomentsev A. I.**, Martirosov D. S.***

Moscow Aviation Institute (National Research University), 4, Volokolamskoe shosse, Moscow, А-80, GSP-3, 125993, Russia

*e-mail: aungkhinemyint22@gmail.com
**e-mail: a.i.kolomentsev@yandex.ru
***e-mail: mrtsv@mail.ru

Abstract

The article presents mathematical model of the liquid propellant rocket engine (LPRE) flow regulator and the study of its static characteristics, such as fuel component consumption dependence on the pressure difference, and dynamic characteristics, such as regulator amplitude-frequency response. The study was performed by the developed mathematical model, which unlike the well-known domestic and foreign counterparts ensures the most complete description of the fuel consumption regulation processes. It demonstrates that dynamic characteristics in technical systems are being determined by the areas of its movable part (slide-valve) and differential orifices.

The liquid flow regulator is one of the main units of any LPRE. These regulators are designate for maintaining the fuel components consumption keeping with the specified accuracy, or its varying according to the certain law under conditions of internal and external disturbing factors varying.

They are being employed in the modern multimode engines such as RD-253, RD-120, RD-170, RD-180, SSME, RL-10 as actuating elements.

The flow regulators employed in the LPRE are being separated into the two groups: direct- and indirect-acting regulators. The direct-acting regulators found wide application in modern LPRE. The direct-acting regulators are being applied as a rule at a flow rate m*g ≤0.2 kg/s, though they can be employed at greater flow rates, if high performance ensuring is necessary.

A feature of all flow regulators is their ability to control the flow rate and maintain the flow rate only at relatively slow changes of control and disturbing impacts in time.

The article presents a system of equations, describing working processes at the fuel components regulator normal functioning. Mathematical model of the improved direct-acting thrust regulator design for the LPRE with oxidizing gaz afterburning, allowing substantially increase effectiveness of automated for engine control and diagnostics systems. As the result of modelling, the dependencies of flow rate through the regulator on the angular position of the actuator and pressure difference at the regulator were obtained.

Recommendations on flow rate regulations modernization for the engines of the RD-170 family were given based on the obtained results. The results can be used while flow regulators designing and their state diagnostics while testing.

Keywords:

liquid rocket engine, mathematical model of the regulator, static and dynamic characteristics, regulator tuning and load characteristics, regulator amplitude-frequency and phase-frequency characteristics

References

  1. Aung K.M., Kolomentsev A.I. Materialy XLV Mezhdunarodnoi molodezhnoi nauchnoi konferentsii (16–19 April 2019; Moskva, MAI) «Gagarinskie chteniya — 2019», Moscow, MAI, 2019, pp. 150-151.

  2. Aung K.M., Kolomentsev A.I. Materialy XVIII Mezhdunarodnoi konferentsii (18-22 November 2019; Moskva, MAI) «Aviatsiya i kosmonavtika — 2019», Moscow, Logotip, 2019, pp. 39-40.

  3. Aung K.M., Kolomentsev A.I. Materialy XVIII Mezhdunarodnoi konferentsii (23-27 November 2020; Moskva, MAI) «Aviatsiya i kosmonavtika — 2019», Moscow, Pero, 2019, pp. 132- 133.

  4. Belyaev E.N., Chvanov V.K., Chervakov V.V. Matematicheskoe modelirovanie rabochego protsessa zhidkostnykh raketnykh dvigatelei (Mathematical modelling of liquid rocket engines working process), Moscow, MAI, 1999, 228 p.

  5. Belyaev E.N., Kolomentsev A.I., Nasimento L.B., Nazarov V.P. Vestnik Sibirskogo gosudarstvennogo aerokosmicheskogo universiteta im. akademika M.F. Reshetneva, 2014, no. 1(53), pp. 109–113.

  6. Belyaev E.N., Chervakov V.V. Matematicheskoe modelirovanie ZhRD (Mathematical modelling of LRE), Moscow, MAI-PRINT, 2009, 280 p.

  7. Vasil’ev A.P., Kudryavtsev V.M., Kuznetsov V.A., etc. Osnovy teorii i rascheta zhidkostnykh raketnykh dvigatelei. V 2 knigakh (Fundamentals of theory and calculation of liquid rocket engines. In two books). Moscow, Vysshaya shkola, 1993, (384 + 368) p.

  8. Vasyutin Yu.I., Smirnov I.A., Yagodnikov D.A., Deryagin Yu.A., Gostev V.A. Agregaty regulirovaniya zhidkostnykh raketnykh dvigatel’nykh ustanovok (Aggregates for liquid rocket propulsion systems regulation), Moscow, MGTU im. N. E. Baumana, 2015, 223 p.

  9. Gakhun G.G., Baulin V.I., Volodin V.A., etc. Konstruktsiya i proektirovanie zhidkostnykh raketnykh dvigatelei (Structure and design of liquid rocket engines), Moscow, Mashinostroenie, 1989, 424 p.

  10. Gimadiev A.G. Avtomatika i regulirovanie dvigatel’nykh ustanovok raketnykh i kosmicheskikh system (Automatics and regulation of propulsion systems of rocket and space systems), Samara, SGAU, 2010, 201 p.

  11. Glikman B.F. Avtomaticheskoe regulirovanie zhidkostnykh raketnykh dvigatelei (Automatic regulation of liquid rocket engines), Moscow, Mashinostroenie, 1989, 296 p.

  12. Gimadiev A.G. Vybor parametrov, raschet staticheskikh i dinamicheskikh kharakteristik regulyatora raskhoda topliva (Parameters selection, static and dynamic characteristics calculation of flow regulator), Samara, SGAU, 2007, 65 p.

  13. Goryachkin A.A., Zhukovskii A.E., Ignachkov S.M., Shorin V.P. Regulyatory raskhoda dlya toplivnykh sistem letatel’nykh apparatov (Flow regulators for aircraft fuel systems), Moscow, Mashinostroenie, 2000, 208 p.

  14. Dobrovol’skii M.V. Zhidkostnye raketnye dvigateli. Osnovy proektirovaniya (Liquid-propellant rocket engines. Design fundamentals), Moscow, MGTU im. N.E. Baumana, 2016, 461 p.

  15. Dolgopolov S.I., Nikolaev A.D. Tekhnicheskaya mekhanika, 2017, no. 1, pp. 15-25.

  16. Zenin E.S., Men’shikova O.M., Fedotchev V.A. Polet, 2013, no. 5, pp. 20-24.

  17. Kamenskii S.S., Martirosov D.S., Kolomentsev A.I. Similarity theory methods application for lpre steady-flow working procedures analysis. Aerospace MAI Journal, 2016, vol. 23, no. 1, pp. 32-37.

  18. Lebedinskii E.V., Zaitsev B.V., Sobolev A.A. Mnogourovnevoe matematicheskoe modelirovanie regulyatora raskhoda dlya ZhRD, 2011. URL: http://www.kerc.msk.ru/ipg/papers/model2.pdf

  19. Levochkin P.S., Martirosov D.S., Kamenskii S.S., Kozlov A.A., Borovik I.N., Belyaeva N.V., Rumyantsev D.S. Liquid rocket engines functional diagnostics system in real-time mode. Aerospace MAI Journal, 2019, vol. 26, no. 2, pp. 147-154.

  20. Likhachev V.A., Vasin A.S., Glikman B.F. Tekhnicheskaya diagnostika pnevmogidravlicheskikh sistem ZhRD (Technical diagnostics of pneumo-hydraulic systems of liquid-propellant engines), Moscow, Mashinostroenie, 1983, 207 p.

  21. Tsyganova E.V. Materialy Mezhregional’nogo molodezhnogo konkursa nauchno-tekhnicheskikh rabot i proektov «Molodezh’ i budushchee aviatsii i kosmonavtiki- 2013», pp. 140-141.

  22. Wynn J.A. Pressure regulator including a fixed valve ball and method of assembling the same. Patent US 7040344 B2, 09.05.2006.

  23. Dranovsky M. Combustion Instabilities in Liquid Rocket Engines. Testing and Development Practices in Russia. American Institute of Aeronautics and Astronautics, 2007, vol. 221, 285 p. DOI: 10.2514/4.866906

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