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Numerical study of a trapezoidal bypass dual throat nozzle

Shuai Huang, Jinglei Xu, Kaikai Yu, Yangsheng Wang, Ruifeng Pan, Kuangshi CHEN, Yuqi ZHANG

2022Chinese Journal of Aeronautics28 citationsDOIOpen Access PDF

Abstract

Bypass Dual Throat Nozzle (BDTN) is a novel type of fluidic thrust vectoring nozzle. To improve the infrared stealth performance of BDTN, a nozzle based on BDTN is proposed and numerically simulated. Each cross-section along the x-axis of the novel nozzle becomes a trapezoid, which is named “BDTN-TRA.” The main numerical simulation results show that BDTN-TRA can produce a thrust vectoring angle when the upper or lower bypass valve is open. The angle difference between the two conditions mentioned above is usually approximately 1°–2°. Even if the two bypasses are closed, BDTN-TRA can produce a small thrust vectoring angle at around 3°–5°. When the sidewall angle increases from 60° to 90°, the thrust coefficient and thrust vectoring angle under each work condition usually decrease. A larger aspect ratio indicates better performance. As the aspect ratio increases over 7.2, the performance of BDTN-TRA is quite close to that of BDTN with rectangular cross-sections at the same aspect ratio. These features will benefit the control and trimming for future aircraft design, especially for the flying wing layout aircraft. Last but not least, BDTN-TRA has a more extraordinary mixing performance compared with BDTN. The distributions of static temperature and axial velocity along the x-axis of BDTN-TRA with sidewall angle of 60° decrease faster than those of BDTN. When the total temperature of the inlet equals 1600 K, the static temperature difference between BDTN-TRA with sidewall angles of 60° and 90° is over 360 K at twice the length of the nozzle downstream of the nozzle exit, which is the reflection for excellent infrared stealth for the fighter.

Topics & Concepts

Dual (grammatical number)NozzleThroatMechanicsComputer sciencePhysicsMedicineMechanical engineeringEngineeringSurgeryArtLiteratureRocket and propulsion systems researchComputational Fluid Dynamics and AerodynamicsGas Dynamics and Kinetic Theory
Numerical study of a trapezoidal bypass dual throat nozzle | Litcius