涡轮轴发动机进气颗粒分离器的三维非稳态流动数值建模

IF 1.3 Q2 ENGINEERING, AEROSPACE
Marco Castaldi, Ignacio Mayo, Jacques Demolis, Frank Eulitz
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引用次数: 0

摘要

直升机和涡轮螺旋桨发动机很容易吸入碎片和其他异物,特别是在起飞、降落和悬停时。为了避免有害影响,可以安装过滤器,如进口颗粒分离器(IPS)。然而,这些系统的性能和局限性必须在实际设备可以安装在飞机动力装置之前进行调查。在本文中,我们提出了不同的数值方法,随着分辨率的增加,以提供一个气动特性的IPS,即从简单的半经验模型到三维大涡模拟。我们利用实验数据验证了这些数值工具,这些工具可以在分离效率和压力损失等全局参数方面帮助IPS设计。对于这些工具,我们强调了它们在行业实践中的弱点和潜在的好处。非定常流动分析表明,分离涡流模拟是一种权衡选择,它使设计人员能够最有效地规划实验活动并降低风险。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Numerical Modelling of the 3D Unsteady Flow of an Inlet Particle Separator for Turboshaft Engines
Helicopter and turboprop engines are susceptible to the ingestion of debris and other foreign objects, especially during take-off, landing, and hover. To avoid deleterious effects, filters such as Inlet Particle Separators (IPS) can be installed. However, the performance and limitations of these systems have to be investigated before the actual equipment can be installed in the aircraft powerplant. In this paper, we propose different numerical methods with increasing resolution in order to provide an aerodynamic characterization of the IPS, i.e., from a simple semi-empirical model to 3D large eddy simulation. We validate these numerical tools that could aid IPS design using experimental data in terms of global parameters such as separation efficiency and pressure losses. For each of those tools, we underline weaknesses and potential benefits in industry practices. Unsteady flow analysis reveals that detached eddy simulation is the trade-off choice that allows designers to most effectively plan experimental campaigns and mitigate risks.
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来源期刊
CiteScore
2.30
自引率
21.40%
发文量
29
审稿时长
11 weeks
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