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Design of A 3-DOF Thrust Control System for Rocket Engines

Year 2022, Volume: 3 Issue: 1, 30 - 48, 29.06.2022

Abstract

Within the scope of this project, a system that can direct the thrust of solid propellant rocket engines will be built. This method will provide high mobility for hybrid and liquid propellant rocket engines. The rocket will react to external effects (wind, etc.) that may occur while cruising. Sensors such as GYRO and IMU on the system are called TVC (Propulsion Vector Control), which provides the balance of the rocket by directing the thrust in the opposite direction of the rocket's trajectory. It also meets the requirements for angular speed control, route linearity and immediate response to emergencies. The design of the system has been created according to geometric properties, kinematics and forces, energy requirements, safety, cost, control methods requirements. Regarding the management of TVC, a literature review on TVC system design has been made first. Analyzes will be made taking into account the thrust and combustion time of the engine used. The system will be designed according to mechanical and avionic design principles. All of this is filtered out by focusing on the relevance, adaptability, economy and consistency of production. It is aimed to solve and support the software and algorithms to be created (differentiated design), thrust vector angular position and other motion problems through flow charts. With the possible design we mentioned in the report, we aim to solve similar examples of our project and to eliminate the question mark in our minds to some extent. Our project management will be carried out in accordance with work schedules, risk management and research facilities. We aim to work on projects such as literature research, system conceptual design, system visual design, preparation of the final design and the final report of the system.

Supporting Institution

Sakarya University of Applied Sciences and TÜBİTAK

Thanks

Authors; they would like to thank Sakarya University of Applied Sciences, the SKYLINE Team and TÜBİTAK for their support in their studies.

References

  • Buschek, H. (2003). Design and flight test of a robust autopilot for the IRIS-T air-to-air missile. Control Engineering Practice, 11(5), 551–558.
  • https://arc.aiaa.org/doi/abs/10.2514/3.1597?journalCode=aiaaj , Erişim Tarihi: 10.07.2021.
  • https://en.wikipedia.org/wiki/Thrust_vectoring , Erişim Tarihi: 15. 07.2021.
  • https://dergipark.org.tr/tr/download/article-file/438514 , Erişim Tarihi: 15. 07.2021.
  • https://core.ac.uk/download/pdf/19143575.pdf , Erişim Tarihi: 20. 07.2021.
  • https://www.researchgate.net/publication/323685633_Design_and_Implementation_of_a_Thrust_Vector_Control_TVC_Test_System , Erişim Tarihi: 20. 07.2021
  • Lazic´, D. V., & Ristanovic´, M. R. (2004). Thrust vector control of twin nozzle engine. Proceedings of the VIII triennial international SAUM conference (pp. 94–97). Belgrade, Serbia, November 2004.
  • Schinstock, D. E., & Haskew, T. A. (2001). Transient force reduction in electromechanical actuators for thrust-vector control. Journal of Propulsion and Power, 17(1), 65–72.
  • Skogestad, S., & Postlethwaite, I. (1996). Multivariabile feedback control. England: Wiley.
  • Ünal A., Yaman K., Okur E. ve Adlı M.A., “Design and implementation of a Thrust Vector Control (TVC) test system”, Politeknik Dergisi, 21(2): 497-505, (2018).
  • Song, C., Kim, S. J., & Kim, S. H. (2006). Robust control of the missile attitude based on quaternion feedback. Control Engineering Practice, 14(7), 811–818.
  • Zipfel, P. H. (2000). Modeling and simulation of aerospace vehicle dynamics. Reston, VA: American Institute of Aeronautics and Astronautics, Inc.
  • https://www.esa.int/ESA_Multimedia/Images/2008/11/The_thrust_vector_control_system_of_the_Zefiro_23_engine_part_of_the_Vega_launcher_was_developed_under_GSTP
  • Wie, Bong. "Thrust vector control analysis and design for solar-sail spacecraft." Journal of Spacecraft and Rockets 44.3 (2007): 545-557.
Year 2022, Volume: 3 Issue: 1, 30 - 48, 29.06.2022

Abstract

References

  • Buschek, H. (2003). Design and flight test of a robust autopilot for the IRIS-T air-to-air missile. Control Engineering Practice, 11(5), 551–558.
  • https://arc.aiaa.org/doi/abs/10.2514/3.1597?journalCode=aiaaj , Erişim Tarihi: 10.07.2021.
  • https://en.wikipedia.org/wiki/Thrust_vectoring , Erişim Tarihi: 15. 07.2021.
  • https://dergipark.org.tr/tr/download/article-file/438514 , Erişim Tarihi: 15. 07.2021.
  • https://core.ac.uk/download/pdf/19143575.pdf , Erişim Tarihi: 20. 07.2021.
  • https://www.researchgate.net/publication/323685633_Design_and_Implementation_of_a_Thrust_Vector_Control_TVC_Test_System , Erişim Tarihi: 20. 07.2021
  • Lazic´, D. V., & Ristanovic´, M. R. (2004). Thrust vector control of twin nozzle engine. Proceedings of the VIII triennial international SAUM conference (pp. 94–97). Belgrade, Serbia, November 2004.
  • Schinstock, D. E., & Haskew, T. A. (2001). Transient force reduction in electromechanical actuators for thrust-vector control. Journal of Propulsion and Power, 17(1), 65–72.
  • Skogestad, S., & Postlethwaite, I. (1996). Multivariabile feedback control. England: Wiley.
  • Ünal A., Yaman K., Okur E. ve Adlı M.A., “Design and implementation of a Thrust Vector Control (TVC) test system”, Politeknik Dergisi, 21(2): 497-505, (2018).
  • Song, C., Kim, S. J., & Kim, S. H. (2006). Robust control of the missile attitude based on quaternion feedback. Control Engineering Practice, 14(7), 811–818.
  • Zipfel, P. H. (2000). Modeling and simulation of aerospace vehicle dynamics. Reston, VA: American Institute of Aeronautics and Astronautics, Inc.
  • https://www.esa.int/ESA_Multimedia/Images/2008/11/The_thrust_vector_control_system_of_the_Zefiro_23_engine_part_of_the_Vega_launcher_was_developed_under_GSTP
  • Wie, Bong. "Thrust vector control analysis and design for solar-sail spacecraft." Journal of Spacecraft and Rockets 44.3 (2007): 545-557.
There are 14 citations in total.

Details

Primary Language English
Subjects Artificial Intelligence
Journal Section Research Articles
Authors

Haktan Yağmur

Sinan Şen 0000-0001-6576-5520

Can Bayar 0000-0001-9650-274X

Kasım Serbest 0000-0002-0064-4020

Publication Date June 29, 2022
Published in Issue Year 2022 Volume: 3 Issue: 1

Cite

APA Yağmur, H., Şen, S., Bayar, C., Serbest, K. (2022). Design of A 3-DOF Thrust Control System for Rocket Engines. Journal of Smart Systems Research, 3(1), 30-48.
AMA Yağmur H, Şen S, Bayar C, Serbest K. Design of A 3-DOF Thrust Control System for Rocket Engines. JoinSSR. June 2022;3(1):30-48.
Chicago Yağmur, Haktan, Sinan Şen, Can Bayar, and Kasım Serbest. “Design of A 3-DOF Thrust Control System for Rocket Engines”. Journal of Smart Systems Research 3, no. 1 (June 2022): 30-48.
EndNote Yağmur H, Şen S, Bayar C, Serbest K (June 1, 2022) Design of A 3-DOF Thrust Control System for Rocket Engines. Journal of Smart Systems Research 3 1 30–48.
IEEE H. Yağmur, S. Şen, C. Bayar, and K. Serbest, “Design of A 3-DOF Thrust Control System for Rocket Engines”, JoinSSR, vol. 3, no. 1, pp. 30–48, 2022.
ISNAD Yağmur, Haktan et al. “Design of A 3-DOF Thrust Control System for Rocket Engines”. Journal of Smart Systems Research 3/1 (June 2022), 30-48.
JAMA Yağmur H, Şen S, Bayar C, Serbest K. Design of A 3-DOF Thrust Control System for Rocket Engines. JoinSSR. 2022;3:30–48.
MLA Yağmur, Haktan et al. “Design of A 3-DOF Thrust Control System for Rocket Engines”. Journal of Smart Systems Research, vol. 3, no. 1, 2022, pp. 30-48.
Vancouver Yağmur H, Şen S, Bayar C, Serbest K. Design of A 3-DOF Thrust Control System for Rocket Engines. JoinSSR. 2022;3(1):30-48.