Research of supersonic flow in shortened nozzles of rocket engines with a bell-shaped tip

1Pryadko, NS, 1Strelnikov, HO, 1Ternova, KV
1Institute of Technical Mechanics of the National Academy of Sciences of Ukraine and State Space Agency of Ukraine, Dnipro, Ukraine
Space Sci. & Technol. 2024, 30 ;(1):03-13
https://doi.org/10.15407/knit2024.01.003
Publication Language: English
Abstract: 
The flow in a shortened nozzle with a bell-shaped tip is considered. A comparison of the wave structures of the supersonic gas flow in shortened nozzles with short and long tips formed by compression and stretching of the original bell-shaped nozzle for connection, respectively, with the long and short conical part of the base nozzle at the same nozzle length was carried out. Under operation conditions at sea level and low pressure at the nozzle inlet (P0<50·105 Ра), a large-scale vortex structure, starting from the corner point of the nozzle inlet, is observed in both nozzles. In addition, in the long tip, a small-scale vortex is observed on the wall near its cut. A barrel-shaped wave structure of hanging jumps with a closing Mach disc is formed in the flow in both nozzles, inside which a "saddle-shaped" wave structure of low intensity is noticed. In the separation flow in the tip (when Р0<50·105 Ра and Рн = 1·105 Ра), the pressure on the wall in the separation zone is slightly lower (by ≈ 5-10%) than the external pressure Рн.
         When the engine is operating in the upper layers of the atmosphere, the static pressure on the section of both tips is proportional to the pressure at the entrance of the nozzle. In the cross-section, starting from the axis of the nozzle to ~0.89 R/Ra (the ratio of the current value of the radius R to the radius of the nozzle wall at the outlet Ra), the pressure decreases to a value proportional to the pressure at the nozzle inlet. Then, it increases linearly to the value of the pressure on the tip wall, which is proportional to the pressure at the nozzle inlet. This is due to the wave structure of the flow inside the nozzle. It was established that with a decrease in the length of the nozzle conical part, the impulse coefficient of the nozzle decreases significantly for operating at sea level and slightly decreases for operating in the upper layers of the atmosphere. The results of calculations correlate satisfactorily with the experimental study results of the flows in shortened nozzles with a bell-shaped tip.
Keywords: impulse, pressure, shortened nozzle, supersonic flow, tip, wave structure
References: 

1. Arora R., Vaidyanathan A. (2015). Experimental investigation of flow through planar double divergent nozzles. Acta Astronomica, 112, 200-216.
https://doi.org/10.1016/j.actaastro.2015.03.020

2. Asha G., Naga Mohana D., Sai Priyanka K., Govardhan D. (2021). Design of minimum length nozzle using method of characteristics. Int. J. Engineering Res. and Technology (IJERT), 10, No. 5, 490-495.

3. Emelyanov V. N., Volkov K. N., Yakovchuk M. S. (2022). Unsteady flow in a dual-bell nozzle with displacement of an extendible section from the initial to working position. Fluid Dynamics, 57 (Suppl. 1), 35-45.
https://doi.org/10.1134/S0015462822601267

4. Genin C., Stark R., Haidn O., Quering K., Frey M. (2013). Experimental and numerical study of dual bell nozzle flow. Progr. Flight Phys., 5, 363-376.
https://doi.org/10.1051/eucass/201305363

5. Génin Ch., Stark R. (2010). Experimental study on flow transition in dual bell nozzles. J. Propulsion and Power, 26, 497-502.
https://doi.org/10.2514/1.47282

6. Gogish L. V. (1966). Investigation of short supersonic nozzles. Izvestiya Akademii nauk SSSR. Mehanika zhidkosti i gaza, No. 2, 175-180 [in Russian]

7. Hagemann G., Frey M., Koschel W. (2002). Appearance of restricted shock separation in rocket nozzles. J. Propulsion and Power, 18, 577-584.
https://doi.org/10.2514/2.5971

8. Hamitouche T., Sellam M., Kbab H., Bergheul S. (2019). Design and Wall Fluid Parameters Evaluation of the Dual-Bell Nozzle. Int. J. Engineering Res. and Technology, 12, No. 7, 1064-1074.

9. Hunter C. A. (2004). Experimental, theoretical and computational investigation of separated nozzle flows. Proc. 34th AIAA/ASME/SAE/ASEE Joint Propulsion Conf. and Exhibition (Cleveland, 2004). Paper No. 1998-3107, 1-10.
https://doi.org/10.2514/6.1998-3107

10. Ihnatiev O. D., Pryadko N. S., Strelnikov G. O., Ternova K. V. (2022). Gas flow in a shortened Laval nozzle with a bell-shaped nozzle. Technical mechanics, No. 2, 39-46.
https://doi.org/10.15407/itm2022.02.039

11. Ihnatiev O. D., Pryadko N. S., Strelnikov G. O., Ternova K. V. (2022). Thrust characteristics of a truncated Laval nozzle with a bell-shaped tip. Technical mechanics, No. 3, 35-46.
https://doi.org/10.15407/itm2022.03.035

12. Kovalenko N. D., Strelnikov G. A., Gora Yu. V., Grebenyuk L. Z. (1993). Gas dynamics of supersonic shortened nozzles. Kyiv: Naukova dumka, 223 p. [in Russian]

13. Kumar M., Fernando D., Kumar R. (2013). Design and optimization of de Lavel nozzle to prevent shock induced flow separation. Advs in Aerospace Sci. and Applications, 3, No. 2, 119-124.

14. Narayan A., Panneerselvam S. (2012). Study of the effect of over-expansion factor on the flow transition in dual bell nozzles. Int. J. Mech. AerospaceInd. Mechatron. Manuf. Eng., 6, No. 8, 1591-1595.

15. Nasuti F., Onofri M., Martelli E. (2005). Role of wall shape on the transition in axisymmetric dual-bell nozzles. J. Propul. Power, 21, No.. 2, 243-250.
https://doi.org/10.2514/1.6524

16. Rao G. V. R. (1958). Exhaust Nozzle Contour for Optimum Flight. Jet Propulsion, 28, No. 6, 377-382.
https://doi.org/10.2514/8.7324

17. Sergienko A. A., Sobachkin A. A. (1990). Profiling of short supersonic round nozzles. Izd. vuzov. Aviats. Tehnika, № 2, 62-64 [in Russian]

18. Sreenath K. R., Mubarak A. K. (2016). Design and analysis of contour bell nozzle and comparison with dual bell nozzle. Int. J. Res. Eng., 3, No. 6, 52-56.

19. Stark R., Genin C., Wagner B., Koschel W. (2012). The altitude adaptive dual bell nozzle. Proc. 16th Int. Conf. On the Methods of Aerophys. Res. (ICMAR 2012), 1-8.

20. Strelnikov G. A. (1993). Adjustable short supersonic nozzles. Dnepropetrovsk: DGU, 191 р. [in Russian]

21. Strelnikov G., Pryadko N., Ihnatiev O., Ternova K. (2022). Choice of a turbulence model for modeling complex flows in rocket engine nozzles. Novel Res. in Sci., 10, No. 5, 1-4.

22. Strelnikov G. A., Pryadko N. S., Ternova K. V. (2023). Wave structure of the gas flow in a shortened nozzle with a long bell-shaped tip. Technical mechanics, No,. 1, 14 - 23.
https://doi.org/10.15407/itm2023.01.040

23. Taylor N., Steelant J., Bond R. (2011). Experimental comparison of dual bell and expansion deflection nozzles. Proc. 47th AIAA/ASME/SAE/ASEE Joint Propulsion Conf. & Exhibition (SanDiego. 2011). Paper No. 2011-5688, 1-13.
https://doi.org/10.2514/6.2011-5688

24. Vermaa S. B., Haidnb O. (2014). Unsteady shock motions in an over-expanded parabolic rocket nozzle. Aerospace Sci. and Technology, 39, 48-71.
https://doi.org/10.1016/j.ast.2014.08.003

25. Wilcox D. (2006) Turbulence Modeling for CFD. California : DCW Industries, Inc., 536 р.