De-spinning Wing Design and Aerodynamic Characteristics Analysis of High-Spinning Flight Body with Aft Control Kit

Xinrui Luo; Meng Zhang; Kai Shen; Zhihong Deng; Lijuan Wang

doi:10.1007/978-981-96-2220-7_41

De-spinning Wing Design and Aerodynamic Characteristics Analysis of High-Spinning Flight Body with Aft Control Kit

Xinrui Luo, Meng Zhang, Kai Shen, Zhihong Deng^*, Lijuan Wang

^*Corresponding author for this work

School of Automation

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

To enhance the controllability of the spin-stabilized projectile, this paper proposes a new projectile model. The model achieves spin reduction by installing a de-spinning wing in the aft control kit, which reduces the rotation speed from high to low. This maintains a stable rotation speed during subsequent flights, providing a favourable working environment for the measurement and actuation structures. The projectile’s aerodynamic design sets it apart from traditional spin-stabilized projectiles and displays unique aerodynamic characteristics. Numerical simulation methods were used to calculate the lift coefficient, drag coefficient, chamfered moment, and rolling moment at various Mach numbers. A seven-degree-of-freedom ballistic simulation with a de-spinning wing is established to delineate the de-spinning process and analyze the effects of the chamfered moment and rolling moment at different stages. The conclusion demonstrates that the design of the de-spinning wing proposed in this paper can effectively decrease the rotation speed of the aft control kit from 300 r/s to 10 r/s within 8 s and maintain it below 10 r/s in subsequent flights. This paper provides a basis for future research into the control and navigation of spin-stabilized projectile.

Original language	English
Title of host publication	Advances in Guidance, Navigation and Control - Proceedings of 2024 International Conference on Guidance, Navigation and Control Volume 6
Editors	Liang Yan, Haibin Duan, Yimin Deng
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	414-426
Number of pages	13
ISBN (Print)	9789819622191
DOIs	http://doi.org/10.1007/978-981-96-2220-7_41
Publication status	Published - 2025
Event	International Conference on Guidance, Navigation and Control, ICGNC 2024 - Changsha, China Duration: 9 Aug 2024 → 11 Aug 2024

Publication series

Name	Lecture Notes in Electrical Engineering
Volume	1342 LNEE
ISSN (Print)	1876-1100
ISSN (Electronic)	1876-1119

Conference

Conference	International Conference on Guidance, Navigation and Control, ICGNC 2024
Country/Territory	China
City	Changsha
Period	9/08/24 → 11/08/24

Keywords

Aerodynamic Characteristics
De-Spinning Wing
Finite Element Simulation
High-Spinning Flight Body
Outflow Field Analysis

Access to Document

10.1007/978-981-96-2220-7_41

Cite this

Luo, X., Zhang, M., Shen, K., Deng, Z., & Wang, L. (2025). De-spinning Wing Design and Aerodynamic Characteristics Analysis of High-Spinning Flight Body with Aft Control Kit. In L. Yan, H. Duan, & Y. Deng (Eds.), Advances in Guidance, Navigation and Control - Proceedings of 2024 International Conference on Guidance, Navigation and Control Volume 6 (pp. 414-426). (Lecture Notes in Electrical Engineering; Vol. 1342 LNEE). Springer Science and Business Media Deutschland GmbH. http://doi.org/10.1007/978-981-96-2220-7_41

Luo, Xinrui ; Zhang, Meng ; Shen, Kai et al. / De-spinning Wing Design and Aerodynamic Characteristics Analysis of High-Spinning Flight Body with Aft Control Kit. Advances in Guidance, Navigation and Control - Proceedings of 2024 International Conference on Guidance, Navigation and Control Volume 6. editor / Liang Yan ; Haibin Duan ; Yimin Deng. Springer Science and Business Media Deutschland GmbH, 2025. pp. 414-426 (Lecture Notes in Electrical Engineering).

@inproceedings{0da99cde5c164267adbfe54fee992ba1,

title = "De-spinning Wing Design and Aerodynamic Characteristics Analysis of High-Spinning Flight Body with Aft Control Kit",

abstract = "To enhance the controllability of the spin-stabilized projectile, this paper proposes a new projectile model. The model achieves spin reduction by installing a de-spinning wing in the aft control kit, which reduces the rotation speed from high to low. This maintains a stable rotation speed during subsequent flights, providing a favourable working environment for the measurement and actuation structures. The projectile{\textquoteright}s aerodynamic design sets it apart from traditional spin-stabilized projectiles and displays unique aerodynamic characteristics. Numerical simulation methods were used to calculate the lift coefficient, drag coefficient, chamfered moment, and rolling moment at various Mach numbers. A seven-degree-of-freedom ballistic simulation with a de-spinning wing is established to delineate the de-spinning process and analyze the effects of the chamfered moment and rolling moment at different stages. The conclusion demonstrates that the design of the de-spinning wing proposed in this paper can effectively decrease the rotation speed of the aft control kit from 300 r/s to 10 r/s within 8 s and maintain it below 10 r/s in subsequent flights. This paper provides a basis for future research into the control and navigation of spin-stabilized projectile.",

keywords = "Aerodynamic Characteristics, De-Spinning Wing, Finite Element Simulation, High-Spinning Flight Body, Outflow Field Analysis",

author = "Xinrui Luo and Meng Zhang and Kai Shen and Zhihong Deng and Lijuan Wang",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2025.; International Conference on Guidance, Navigation and Control, ICGNC 2024 ; Conference date: 09-08-2024 Through 11-08-2024",

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Luo, X, Zhang, M, Shen, K , Deng, Z & Wang, L 2025, De-spinning Wing Design and Aerodynamic Characteristics Analysis of High-Spinning Flight Body with Aft Control Kit. in L Yan, H Duan & Y Deng (eds), Advances in Guidance, Navigation and Control - Proceedings of 2024 International Conference on Guidance, Navigation and Control Volume 6. Lecture Notes in Electrical Engineering, vol. 1342 LNEE, Springer Science and Business Media Deutschland GmbH, pp. 414-426, International Conference on Guidance, Navigation and Control, ICGNC 2024, Changsha, China, 9/08/24. http://doi.org/10.1007/978-981-96-2220-7_41

De-spinning Wing Design and Aerodynamic Characteristics Analysis of High-Spinning Flight Body with Aft Control Kit. / Luo, Xinrui; Zhang, Meng; Shen, Kai et al.
Advances in Guidance, Navigation and Control - Proceedings of 2024 International Conference on Guidance, Navigation and Control Volume 6. ed. / Liang Yan; Haibin Duan; Yimin Deng. Springer Science and Business Media Deutschland GmbH, 2025. p. 414-426 (Lecture Notes in Electrical Engineering; Vol. 1342 LNEE).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Luo, Xinrui

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AU - Wang, Lijuan

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2025.

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N2 - To enhance the controllability of the spin-stabilized projectile, this paper proposes a new projectile model. The model achieves spin reduction by installing a de-spinning wing in the aft control kit, which reduces the rotation speed from high to low. This maintains a stable rotation speed during subsequent flights, providing a favourable working environment for the measurement and actuation structures. The projectile’s aerodynamic design sets it apart from traditional spin-stabilized projectiles and displays unique aerodynamic characteristics. Numerical simulation methods were used to calculate the lift coefficient, drag coefficient, chamfered moment, and rolling moment at various Mach numbers. A seven-degree-of-freedom ballistic simulation with a de-spinning wing is established to delineate the de-spinning process and analyze the effects of the chamfered moment and rolling moment at different stages. The conclusion demonstrates that the design of the de-spinning wing proposed in this paper can effectively decrease the rotation speed of the aft control kit from 300 r/s to 10 r/s within 8 s and maintain it below 10 r/s in subsequent flights. This paper provides a basis for future research into the control and navigation of spin-stabilized projectile.

AB - To enhance the controllability of the spin-stabilized projectile, this paper proposes a new projectile model. The model achieves spin reduction by installing a de-spinning wing in the aft control kit, which reduces the rotation speed from high to low. This maintains a stable rotation speed during subsequent flights, providing a favourable working environment for the measurement and actuation structures. The projectile’s aerodynamic design sets it apart from traditional spin-stabilized projectiles and displays unique aerodynamic characteristics. Numerical simulation methods were used to calculate the lift coefficient, drag coefficient, chamfered moment, and rolling moment at various Mach numbers. A seven-degree-of-freedom ballistic simulation with a de-spinning wing is established to delineate the de-spinning process and analyze the effects of the chamfered moment and rolling moment at different stages. The conclusion demonstrates that the design of the de-spinning wing proposed in this paper can effectively decrease the rotation speed of the aft control kit from 300 r/s to 10 r/s within 8 s and maintain it below 10 r/s in subsequent flights. This paper provides a basis for future research into the control and navigation of spin-stabilized projectile.

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Luo X, Zhang M, Shen K , Deng Z, Wang L. De-spinning Wing Design and Aerodynamic Characteristics Analysis of High-Spinning Flight Body with Aft Control Kit. In Yan L, Duan H, Deng Y, editors, Advances in Guidance, Navigation and Control - Proceedings of 2024 International Conference on Guidance, Navigation and Control Volume 6. Springer Science and Business Media Deutschland GmbH. 2025. p. 414-426. (Lecture Notes in Electrical Engineering). doi: 10.1007/978-981-96-2220-7_41