Numerical Study of Fluidic Thrust Vector Control Using Dual Throat Nozzle

doi:10.47176/jafm.14.01.31690

Cited by 6 publications

(1 citation statement)

References 30 publications

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“…To realize the mechanical actuation of TVC, several technological methods could be used: gimbaled engines, Vernier thrusters, jet vanes, axial plates, movable nozzles, etc. There exists various kinds of fluidic thrust vectoring [9]: shock wave TVC, bypass shock wave TVC, coflowing TVC, counterflowing TVC, dual throat nozzle TVC and bypass dual throat nozzle TVC.…”

Section: Introductionmentioning

confidence: 99%

Path-Following Control for Thrust-Vectored Hypersonic Aircraft

et al. 2023

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Thrust vector control (TVC) might be used to control aircraft at large altitudes and in post-stall conditions when aerodynamic control surfaces are ineffective. This study demonstrated that the implementation of the TVC on high-speed aircraft is a reasonable solution and might be an alternative when compared to the complicated reaction control system or large aerodynamic control surfaces. The numerical flight dynamics model of the X-15 experimental aircraft was developed and implemented in MATLAB/Simulink and then used to investigate the proposed solution. The obtained results indicate that the aircraft, equipped with full 3D thrust vectoring and two independent horizontal stabilizers to control the roll angle, was able to achieve flight along the path that was defined by a set of waypoints. This paper also highlights the potential benefits and challenges of using TVC as a control method for aircraft. The results of this study contribute to the growing body of research on aircraft control and simulation. Future work can explore the use of TVC for other aircraft with unique configurations and low maneuverability features.

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Section: Introductionmentioning

confidence: 99%

Path-Following Control for Thrust-Vectored Hypersonic Aircraft

et al. 2023

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Experimental investigation on the transient process of jet deflection controlled by passive secondary flow

Shi

Zhou

et al. 2022

J Vis

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Mechanism of hysteresis and uncontrolled deflection in jet vectoring control based on Coanda effect

Shi

Zhou

et al. 2022

Physics of Fluids

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We investigated the mechanism of hysteresis and uncontrolled deflection in jet vectoring control based on Coanda effect. Thrust vectoring control based on the Coanda effect are highly applicable in the field of fluid dynamics because they can achieve jet deflection control with simple geometric structure and low energy consumption. However, the hysteresis and uncontrolled deflection phenomena considerably hinder the practical application of these technologies. We designed a new passive fluidic thrust vectoring control model to analyze the mechanism of these disadvantages. We developed a synchronous pressure, force, and flow field measurement system to investigate the evolutions of flow structures and their effects on wall pressure distribution and vectoring force. The characteristics of the key flow structures including the separation bubble, the secondary flow, and the backflow were investigated. The transient features of jet attachment and jet detachment were researched to identify the transition of near-wall flow structures and wall pressure distribution during jet uncontrolled deflection. The mechanism of uncontrolled deflection is that the formation/breakdown of the separation bubble changes the flow state of the backflow and the near-wall mass flux balance is collapsed. This causes a dramatic change in the jet vectoring angle which is out of the valve's control. During attachment, the shear layer first touches the wall and forms a separation bubble, then the bubble shrinks. During detachment, the bubble first enlarges and then breaks down. Therefore, the formation and breakdown of the separation bubble correspond to different valve positions, which is the mechanism of hysteresis.

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Numerical Study of Fluidic Thrust Vector Control Using Dual Throat Nozzle

Cited by 6 publications

References 30 publications

Path-Following Control for Thrust-Vectored Hypersonic Aircraft

Path-Following Control for Thrust-Vectored Hypersonic Aircraft

Experimental investigation on the transient process of jet deflection controlled by passive secondary flow

Mechanism of hysteresis and uncontrolled deflection in jet vectoring control based on Coanda effect

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