Derivation of Aerodynamic Characteristics of a Ribbon Parachute by Truck Tow Test

Salimi, Mohammad Reza; Farajollahi, Amir Hamzeh; Mohseni, Amir Hosein; Ayoobi, Mahmood

doi:10.22067/jacsm.2023.76405.1116

Derivation of Aerodynamic Characteristics of a Ribbon Parachute by Truck Tow Test

Document Type : Original Article

Authors

¹ Assistant professor, Aerospace Research Institute, Tehran, Iran

² Department of Engineering, Imam Ali University

³ Department of Aerospace Engineering, Sharif University of Technology, Tehran, Iran

⁴ Department of Aerospace Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran

10.22067/jacsm.2023.76405.1116

Abstract

Ribbon parachutes are used for speed reduction and stabilization of high-speed payloads and aircraft. The high porosity and their different geometrical shape are due to the performance of these parachutes at high speeds. In this paper, a ribbon parachute for recovery of a 350 kg spatial consignment has been designed, and by means of a set of tools, the aerodynamic and structural loads are calculated. The canopy is made from nylon 66; its deployed diameter is equal to 1.2 m. First, the types of parachute test methods are introduced. After the initial parachute design, the output of the design is modeled and simulated. Finally, to evaluate the design brake parachute, the vehicle's parachute traction test was used for validation. Comparing the results of simulations and experimental data obtained from the truck tow test are in acceptable agreement with each other, which shows the effectiveness of the truck tow test as a low-cost method for approximate measurement of drag coefficient and parachute stability at low speeds.

Keywords

Main Subjects

Aerodynamics

References

[1] A. Taylor, P., Sinclair, R., J., and Allamby, R., D., “Design and Testing of the Kistler Landing System Parachutes,” 15th Aerodynamic Decelerator Systems Technology Conference, vol. 1, pp. 1–9, (1999).

[2] “Crew Systems Deployable Aerodynamic Decelerator (DAD)”, Specification Guide Handbook, Department of Defense Joint Service Specification Guide, (1998).

[3] R.E. Meyerson, and W. Kent, “Space Shuttle Orbiter Drag Parachute Design,” 2001.

[4] K. Takizawa and T. E. Tezduyar, “Computational Methods for Parachute Fluid-Structure Interactions,” Archives of Computational Methods in Engineering, vol. 19, no. 1, pp. 125–169, (2012), doi: 10.1007/s11831-012-9070-4.

[5] D. Z. Huang, P. Avery, C. Farhat, J. Rabinovitch, A. Derkevorkian, and L. D. Peterson, “Modeling, Simulation and Validation of Supersonic Parachute Inflation Dynamics during Mars Landing,” in AIAA Scitech 2020 Forum, Orlando, FL, 01062020, (2020).

[6] X. Yang, L. Yu, S. Nie, and S. Zhang, “Aerodynamic performance of the supersonic parachute with material permeability,” Journal of Industrial Textiles, vol. 50, no. 6, pp. 812–829, (2021), doi: 10.1177/1528083719844605.

[7] L. Jiang, H. Jia, X. Xu, W. Rong, W., Jiang, Q. Wang, Q., C. Gang, and X. Xue, “Numerical Study on Aerodynamic Performance of Mars Parachute Models with Geometric Porosities,” Space Sci Technol, vol. 2022, (2022), doi: 34133/2022/9851982.

[8] J. Fan, J. Hao, C.-Y. Wen, and X. Xue, “Numerical investigation of supersonic flow over a parachute-like configuration including turbulent flow effects,” Aerospace Science and Technology, vol. 121, p. 107330, (2022), doi: 10.1016/j.ast.2022.107330.

[9] M. Dawoodian, A. Dadvand, and A. Hassanzadeh, “A Numerical and Experimental Study of the Aerodynamics and Stability of a Horizontal Parachute,” ISRN Aerospace Engineering, vol. 2013, pp. 1–8, (2013), doi: 10.1155/2013/320563.

[10] I. Laraibi, F. R. Marz-abadi, and F. Eatemadi, “Experimental and numerical investigation of fabric permeability on drag of conventional parachute,” Amirkabir Journal of Mechanical Engineering, vol. 49, no. 1, pp. 17–20, (2017). In Persian.

[11] Z. Gao, Charles, R., D., and L. Xiaolin, “Numerical Modeling of Flow Through Porous Fabric Surface in Parachute Simulation,” AIAA Journal, vol. 55, no. 2, pp. 686–690, (2017).

[12] M. Pratap, A. K. Agrawal, S. C. Sati, and V. Kumar, “Forebody Wake Effects on Parachute Performance for Re-entry Space Application,” Defence Science Journal, vol. 70, no. 3, pp. 223–230, (2020).

[13] Salimi, MR., Farajolahi, A. H., Mohseni Kafshgar Kolahi, A. H., Rostami, M. Aerodynamic, “Analysis of Cargo Speed Reduction Parachutes using Numerical Simulation”. Fluid Mechanics & Aerodynamics Journal, vol. 10, no. 2, pp. 1-17. (2022).

[14] Salimi, MR. Farajollahi, AH, Mohsenikafshgarkolaei, AH, M. Ebrahimi, and M. Ayoobi, “Numerical Analysis of Loads and Stresses Exerting on a Ribbon Type Parachute,” Journal of Advanced Defense Science & Technology, vol. 13, no. 4, pp. 271-282, (2023).

[15] M. Mcquilling and J. Potvin, “Forebody Wake Effects on the Aerodynamics of an Annular Parachute,” 42nd AIAA Fluid Dynamics Conference and Exhibit., (2012).

[16] Day, B. P., Field, M. N., & Gelito, J. P. (2006). An Experimental Investigation of Aerodynamic Drag on a Round Parachute Canopy. Worcester Polytechnic Institute, 117.

[17] K. Joung-Dong, L. Yan, and L. Xiaolin, “Simulation of Parachute FSI Using the Front Tracking Method,” Journal of Fluids and Structures, vol. 37, pp. 100–119, (2013).

[18] K.R. Stein, R.J. Benney, T.E. Tezduyar, J.W. Leonard, and M.L. Accorsi, “Fluid-Structure Interactions of a Round Parachute: Modeling and Simulation Techniques,” Journal of Aircraft, vol. 38, no. 5, pp. 800–808, (2001).

[19] E. Ortega, and R. Flores, “Aeroelastic Analysis of Parachute Deceleration Systems with Empirical Aerodynamics,” Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, vol. 234, no. 3, pp. 729–741, (2019).

[20] M. Pruett, M. Accorsi, and M. Kandis, “Stress Analysis of the Parachute System for the Mars Science Laboratory Mission,” AIAA Journal, pp. 1–19, (2009).

[21] S. V. Leonov, V. I. Morozov, and A. T. Ponomarev, “Shape Modeling and Strength Analysis of Parachutes,” Mechanics of Solids, vol. 46, no. 2, pp. 311–324, (2011).

[22] Xing-long, G., Qing-bin, Z., Qian-gang, T., & Tao, Y. (2013). Fluid-Structure Interaction Simulation of Parachute in Low Speed. Hong Kong: IAENG.

[23] X. Gao, Q. Zhang, and Q. Tang, “Fluid-Structure Interaction Analysis of Parachute Finite Mass Inflation,” International Journal of Aerospace Engineering, vol. 2016, (2016).

[24] G. Xinglong, Z. Qingbin, and T. Qiangang, “Parachute Dynamics and Perturbation Analysis of Precision Airdrop System,” Chinese Journal of Aeronautics, vol. 29, no. 3, pp. 596–607, (2016).

[25] R. Jamison L., “A Method for Calculating Parachute Opening Forces for General Deployment Conditions,” NASA Office of Advanced Research and Technology, vol. 4, no. 4, pp. 498–502, (1966).

[26] NASA, “NASA Orion Parachute Test: The Mars Generation Reports,” (2017). [Online]. Available: https://themarsgeneration.org.

[27] B. Gupta, “Aerial delivery systems and technologies,” Defence Science Journal, vol. 60, no. 2, pp. 124–136, (2010), doi: 10.14429/dsj.60.326.

[28] “Exprimental wind tunnel test for landing on Mars Report,” NASA.