利用科恩达喷嘴对几何和流体可压缩湍流推力矢量进行计算研究

IF 4.1 2区 工程技术 Q1 MECHANICS
Alireza Nayebi, Mohammad Taeibi Rahni
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引用次数: 0

摘要

本研究针对提高飞机机动性(尤其是垂直起降)的挑战,重点研究了利用科恩达效应实现推力矢量的流体航空科恩达高效定向喷嘴。这项研究加深了人们对推力矢量中几何因素和流体因素之间相互作用的理解。假定流动条件为静止、湍流和可压缩流动,采用法夫尔平均雷诺平均纳维-斯托克斯方法和标准 k-ε 模型。使用基于压力的有限体积法和结构化计算网格获得了计算结果。主要发现包括由于总质量流量、隔膜位置(无冲击波相关问题时)和雷诺数的增加而导致的推力矢量增强。此外,冲击波的形成(在特定的质量流量和隔膜位置)对推力矢量有很大影响。这些见解对于优化先进推进系统(包括无人驾驶飞行器)中基于科恩达喷嘴的设计至关重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Computational investigation of both geometric and fluidic compressible turbulent thrust vectoring, using a Coanda based nozzle
This study addresses the challenge of enhancing aircraft maneuverability, particularly for vertical landing and takeoff, focusing on the fluidic aerial Coanda high efficiency orienting jet nozzle that employs the Coanda effect to achieve thrust vectoring. This research advances understanding of the interplay between geometric and fluidic factors in thrust vectoring. Stationary, turbulent, and compressible flow conditions are assumed, employing Favre-averaged Reynolds-averaged Navier–Stokes approach with the standard k-ε model. Computational solutions were obtained using a pressure-based finite volume method and a structured computational grid. The key findings include thrust vectoring enhancement due to an increase in the total mass flow rate, septum position (at no shock wave-related issues), and Reynolds number. In addition, shock wave formation (at specific mass flow rates and septum positions) considerably affects thrust vectoring. These insights are crucial for optimizing Coanda-based nozzle design in advanced propulsion systems, including in unmanned aircraft vehicles.
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来源期刊
Physics of Fluids
Physics of Fluids 物理-力学
CiteScore
6.50
自引率
41.30%
发文量
2063
审稿时长
2.6 months
期刊介绍: Physics of Fluids (PoF) is a preeminent journal devoted to publishing original theoretical, computational, and experimental contributions to the understanding of the dynamics of gases, liquids, and complex or multiphase fluids. Topics published in PoF are diverse and reflect the most important subjects in fluid dynamics, including, but not limited to: -Acoustics -Aerospace and aeronautical flow -Astrophysical flow -Biofluid mechanics -Cavitation and cavitating flows -Combustion flows -Complex fluids -Compressible flow -Computational fluid dynamics -Contact lines -Continuum mechanics -Convection -Cryogenic flow -Droplets -Electrical and magnetic effects in fluid flow -Foam, bubble, and film mechanics -Flow control -Flow instability and transition -Flow orientation and anisotropy -Flows with other transport phenomena -Flows with complex boundary conditions -Flow visualization -Fluid mechanics -Fluid physical properties -Fluid–structure interactions -Free surface flows -Geophysical flow -Interfacial flow -Knudsen flow -Laminar flow -Liquid crystals -Mathematics of fluids -Micro- and nanofluid mechanics -Mixing -Molecular theory -Nanofluidics -Particulate, multiphase, and granular flow -Processing flows -Relativistic fluid mechanics -Rotating flows -Shock wave phenomena -Soft matter -Stratified flows -Supercritical fluids -Superfluidity -Thermodynamics of flow systems -Transonic flow -Turbulent flow -Viscous and non-Newtonian flow -Viscoelasticity -Vortex dynamics -Waves
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