Article: Flow control for the steering of supersonic fin-stabilised projectiles using pin-based micro-actuators Journal: International Journal of Theoretical and Applied Multiscale Mechanics (IJTAMM) 2022 Vol.4 No.1 pp.27 - 57 Abstract: This study focuses on a novel steering method for supersonic fin-stabilised projectiles using pin-based mechanical micro-actuators implanted at the rear of the ammunition. When supersonic cross-flows and aerodynamic structures generated by the neighbouring tail fins are acting on the projectile, complex interactions between the boundary layer and the pin-induced shockwaves will occur around the actuator. To understand the underlying physical phenomena and to determine how these flow structures could be simulated with steady-state CFD simulations, fundamental wind tunnel investigations have first been performed on a flat plate by means of pressure sensitive paints (PSPs) and particle image velocimetry (PIV) measurements. The resulting conclusions have then been applied to the controlled ammunition. Parametric CFD calculations determined the optimal area where the actuator should be implanted. Six degrees of freedom (6DoF) simulations provided the resulting trajectory. These predictions have finally been compared to free-flight deviation measurements to validate the steering methodology and to quantify the prediction error resulting from successive aerodynamics and flight mechanics simulations. Inderscience Publishers - linking academia, business and industry through research

Title: Flow control for the steering of supersonic fin-stabilised projectiles using pin-based micro-actuators

Authors: Michel Libsig; Bastien Martinez

Addresses: Aerodynamics, Measurements and Simulations Department, French-German Research Institute of Saint-Louis (ISL), Saint-Louis, 68300, France ' Aerodynamics and Exterior Ballistics Department, French-German Research Institute of Saint-Louis (ISL), Saint-Louis, 68300, France

Abstract: This study focuses on a novel steering method for supersonic fin-stabilised projectiles using pin-based mechanical micro-actuators implanted at the rear of the ammunition. When supersonic cross-flows and aerodynamic structures generated by the neighbouring tail fins are acting on the projectile, complex interactions between the boundary layer and the pin-induced shockwaves will occur around the actuator. To understand the underlying physical phenomena and to determine how these flow structures could be simulated with steady-state CFD simulations, fundamental wind tunnel investigations have first been performed on a flat plate by means of pressure sensitive paints (PSPs) and particle image velocimetry (PIV) measurements. The resulting conclusions have then been applied to the controlled ammunition. Parametric CFD calculations determined the optimal area where the actuator should be implanted. Six degrees of freedom (6DoF) simulations provided the resulting trajectory. These predictions have finally been compared to free-flight deviation measurements to validate the steering methodology and to quantify the prediction error resulting from successive aerodynamics and flight mechanics simulations.

Keywords: supersonic projectile; micro-actuator; pin; basic finner; fin-stabilised; lambda-shock; separation region; wind-tunnel; CFD; turbulence model; pressure sensitive paint; PSP; particle image velocimetry; PIV; 6DoF; free-flight.

DOI: 10.1504/IJTAMM.2022.122885

International Journal of Theoretical and Applied Multiscale Mechanics, 2022 Vol.4 No.1, pp.27 - 57

Received: 02 Sep 2020
Accepted: 05 Jun 2021
Published online: 16 May 2022 *

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Title: Flow control for the steering of supersonic fin-stabilised projectiles using pin-based micro-actuators

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