Numerical Study on Rod Thrust Vector Control for Physical Applications

Mechanical thrust vector control is a classical and significant branch in the thrust vector control field, offering an extremely reliable control effect. In this article, steady-state and unsteady-state aerodynamic characteristics of the rod thrust vector control technology are numerically investiga...

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Bibliographic Details
Published inInternational Journal of Aerospace Engineering Vol. 2021; pp. 1 - 15
Main Authors Li, Dong, Wu, Kexin
Format Journal Article
LanguageEnglish
Published New York Hindawi 2021
John Wiley & Sons, Inc
Hindawi Limited
Subjects
Aerodynamic characteristics
Aerodynamics
Aerospace engineering
Aircraft
Boundary conditions
Computational fluid dynamics
Control rods
Control systems
Flow control
Flow velocity
Forecasts and trends
Geometry
Mathematical analysis
Penetration
Pressure effects
Pressure oscillations
Steady state
Supersonic nozzles
Technology application
Thrust vector control
Topology
Two dimensional flow
Upstream
Vortices
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Summary:Mechanical thrust vector control is a classical and significant branch in the thrust vector control field, offering an extremely reliable control effect. In this article, steady-state and unsteady-state aerodynamic characteristics of the rod thrust vector control technology are numerically investigated in a two-dimensional supersonic nozzle. Complex flow phenomena caused by the penetrating rod in the diverging part of the supersonic nozzle are elucidated with the purpose of a profound understanding of this simple flow control technique for physical applications. Published experimental data are used to validate the dependability of current computational fluid dynamics results. A grid sensitivity study is carried through and analyzed. The result section discusses the impacts of two important factors on steady-state aerodynamic features, involving the rod penetration height and the rod location. Furthermore, unsteady-state flow features are analyzed under various rod penetration heights for the first time. Significant vectoring performance variations and flow topology descriptions are illuminated in full detail. While the rod penetration height increases, the vectoring angle increases, whereas the thrust coefficient decreases. As the rod location moves downstream close to the nozzle exit, the vectoring angle and thrust coefficient increase. In terms of unsteady-state aerodynamic effects, certain pressure oscillations occur upstream of the rod, which resulted from the expanding and shrinking of the upstream anticlockwise separation bubbles.
ISSN:1687-5966
1687-5974
DOI:10.1155/2021/6963728