Evaluating the Structural Integrity of Spacecraft Aeroshell Designs under Severe Re-Entry Conditions

Open Access

Issue		EPJ Web Conf. Volume 343, 2025 1^st International Conference on Advances and Innovations in Mechanical, Aerospace, and Civil Engineering (AIMACE-2025)


Article Number		02006
Number of page(s)		9
Section		Aerospace Engineering & Aerodynamics
DOI		https://doi.org/10.1051/epjconf/202534302006
Published online		19 December 2025

Allen, H. J., & Eggers, A. J. (1957). A study of the motion and aerodynamics of a blunt body in a hypersonic flow. NACA Technical Report, 1381, 1–36. [Google Scholar]
Knacke, T. W. (1991). Design of aerodynamic decelerators. American Institute of Aeronautics and Astronautics ( AIAA). [Google Scholar]
Braun, R. D., & Manning, R. M. (2007). Mars exploration entry, descent, and landing challenges. Journal of Spacecraft and Rockets, 44(2), 310–323. [Google Scholar]
Heppenheimer, T. A. (2006). Facing the heat barrier: A history of hypersonics. NASA SP-4232. NASA [Google Scholar]
Anderson, J. D. (2016). Fundamentals of aerodynamics (6th ed.). McGraw-Hill. [Google Scholar]
Davis, M. E. (2019). Hypersonic and high-temperature gas dynamics (3rd ed.). AIAA. [Google Scholar]
Bond, E. J. (2020). A comparison of aeroshell designs for Mars entry systems. International Conference on Aerospace and Mechanical Engineering, 12(3), 456–163 [Google Scholar]
Schetz, J. A. (2022). Aerodynamics of high-speed trains, vehicles, and spacecraft. Cambridge University Press. [Google Scholar]
Singh, M. K. (2019). Numerical modeling of drag coefficients for blunt-body reentry vehicles. International Journal of Aerodynamics, 15(3), 87–101. [Google Scholar]
ANSYS. (2023). Best practices for structural and thermal analysis of aerospace components. ANSYS Workbench Documentation. [Google Scholar]
Blanchard, C., & Austin, M. (2021). Finite element analysis in aerospace structural engineering. AIAA Journal, 58(7), 1423–1436. [Google Scholar]
Ahmed, K., & Sharma, N. (2020). Thermal protection and aerodynamic design of reentry vehicles. Aerospace Research Journal, 33(4), 199–210. [Google Scholar]
Srivastava, V., et al. (2023). Materials for hypersonic reentry vehicles: A comprehensive review. Materials Science and Engineering, 23, 321–343. [Google Scholar]
Yoshida, H., & Matsuo, T. (2022). Strain analysis and stress distribution in composite materials for aerospace applications. Composite Structures Journal, 98, 120–129. [Google Scholar]
Park, G. A. (2021). Introduction to space vehicle design and analysis (2nd ed.). Springer. [Google Scholar]
He, B., Sun, H., & Zhang, T. (2021). Optimization of reentry vehicle nose shapes using computational fluid dynamics. Computational Mechanics in Aerospace Engineering, 47(2), 209–222. [Google Scholar]
NASA. (n.d.). Entry, descent, and landing systems. NASA Engineering Design Handbook. Retrieved from https://www.nasa.gov [Google Scholar]
Karman, T. (2020). Aerodynamic heating and reentry physics. Journal of Spacecraft and Rockets, 45(2), 123–134. [Google Scholar]
NASA. (2021, October). NASA's 2020 planetary science research: Overview and highlights (NP-2020-02-2805-HQ). https://www.nasa.gov/wp-content/uploads/2021/10/np-2020-02-2805-hq.pdf [Google Scholar]
Padhye, R. P., & Joshi, S. C. (2023). CFD analysis of drag coefficient and heat transfer for blunt body configurations. Journal of Thermophysics and Heat Transfer, 36(1), 102–110. [Google Scholar]
Ali, A. (2023). Finite element modeling techniques for aerospace applications. Advances in Structural Engineering, 29(5), 1204–1217 [Google Scholar]

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