低雷诺数风机试验的边界层控制

IF 1.1 Q4 ENGINEERING, MECHANICAL
Alejandro Castillo Pardo, Tim Williams, Christopher Clark, Nick Atkins, Cesare Hall, Mark Wilson, Raul Vazquez Diaz
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引用次数: 0

摘要

超高涵道比涡扇发动机由于其更高的推进效率,大大减少了燃油和污染。短进气可能会导致更强的风扇进气相互作用,这在非设计条件下的稳定性产生不确定性。由于全尺寸实验测试的成本过高,在风洞中进行亚尺寸测试来了解这种行为。亚尺度模型的低雷诺数导致层流激波-边界层相互作用不具有代表性。因此,边界层状态需要经过调节才能更好地表示全尺寸跨音速风扇。本文提出了一种廉价且可靠的风机叶片吸力侧流量控制方法。给出了用于控制边界层状态的离散粗糙度单元的位置和高度的设计准则。本文还提出了一种快速实验验证方法,以确保并降低边界层起下钻在3D钻机叶片上的应用风险。实验方法应用于一个通用的翼型代表一个风扇尖端部分。实验方法证明了在1/10亚比例尺模型上再现全尺寸风扇叶片的边界层和压力分布是可能的。结果证实,边界层行程法成功地促进了全尺寸叶片代表性位置的转捩,避免了非代表性层流激波边界层相互作用。这突出了在低雷诺数风机试验中调节边界层的重要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Boundary layer control for low Reynolds number fan rig testing
Ultra-high bypass ratio turbofans offer significant reductions in fuel and pollution due to their higher propulsive efficiency. Short intakes might lead to a stronger fan-intake interaction, which creates uncertainty in stability at off-design conditions. Due to the prohibitive cost of full-scale experimental testing, subscale testing in wind tunnels is used to understand this behaviour. The low Reynolds number of subscale models results in unrepresentative laminar shock-boundary layer interactions. The boundary layer state thus needs to be conditioned to better represent full-scale transonic fans. This paper proposes the use of an inexpensive and robust flow control method for the suction side of a fan blade. Design guidelines are given for the location and height of the discrete roughness elements used to control the boundary layer state. This paper also presents a rapid experimental validation methodology to ensure and de-risk the application of the boundary layer trip to 3D rig blades. The experimental methodology is applied to a generic aerofoil representative of a fan tip section. The experimental method proves that it is possible to reproduce boundary layers and pressure distributions of a full-scale fan blade on a 1/10 subscale model. The results obtained confirm that the boundary layer trip method successfully promotes transition at the location representative of full-scale blades, avoiding unrepresentative laminar shock wave boundary layer interactions. This highlights the importance of conditioning boundary layers in low Reynolds number fan rig testing.
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来源期刊
Journal of the Global Power and Propulsion Society
Journal of the Global Power and Propulsion Society Engineering-Industrial and Manufacturing Engineering
CiteScore
2.10
自引率
0.00%
发文量
21
审稿时长
8 weeks
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