脉动流动条件下涡轮增压器径向涡轮大涡模拟

R. Mosca, S. Lim, M. Mihăescu
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引用次数: 0

摘要

涡轮增压器所处的脉动流动条件与稳定流动条件相比,会造成涡轮气动性能的重大偏差。实际上,涡轮内二次流的发展是由流入气动条件决定的,而流入气动条件在脉冲周期内变化很大。本文采用高分辨率大涡模拟方法,研究了涡轮增压器径向涡轮在脉冲周期内的流场演化。首先,根据气站流动条件下的实验结果对模型进行了验证。然后,将转子跨中段瞬时流场与等效循环平均稳态流场进行了比较。结果突出了五个不同的流动特征。在低质量流量下,当相对流入角为负值时,流动在叶片压力侧分离,形成由两个直径与叶片通道相当的反向旋转涡组成的二次流。随着质量流量的增加,第一个涡持续存在于叶顶,而第二个涡向叶后缘靠近。这对应于第二个特征流场。随着相对来流角的增大,第三个特征流动特征只表现出叶片前缘的再循环,其尺寸逐渐减小。对于第四个特征流动特征,在相对来流角为中等负值时,流场与叶片型线对齐良好,没有二次流。然后,随着相对入流角逐渐趋于较大的正值,流动在叶片吸力侧分离,导致该流动与前一叶片压力侧流动的气流混合。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Large Eddy Simulations of a Turbocharger Radial Turbine Under Pulsating Flow Conditions
The pulsating flow conditions which a turbocharger turbine is exposed cause important deviations of the turbine aerodynamic performance when compared to steady flow conditions. Indeed, the secondary flows developing in the turbine are determined by the inflow aerodynamic conditions, which largely vary during the pulse cycle. In this paper, a high-resolved Large Eddy Simulation is performed to investigate and characterize the flow field evolution in a turbocharger radial turbine over the pulse cycle. At first, the model is validated against experimental results obtained in gas-stand flow conditions. Then, the instantaneous flow field at the rotor mid-span section is compared to the one given by the equivalent cycle-averaged steady flow conditions. The results highlight five distinct flow features. At low mass flow rates, when the relative inflow angle assumes large negative values, the flow separates at the blade pressure side, causing a secondary flow consisting in two counter-rotating vortices characterized by a diameter comparable to the blade passage. As the mass flow rate increases, the first vortex persists at the blade tip while the second one moves closer to the blade trailing edge. This corresponds to the second characteristic flow field. With increasing relative inflow angle, for the third characteristic flow feature, only the recirculation at the blade leading edge is displayed and its size gradually reduces. For the fourth characteristic flow feature, at moderate negative values of the relative inflow angle, the flow field is well aligned with the blade profile and free of secondary flows. Then, as the relative inflow angle gradually grows towards large positive values, the flow separates on the blade suction side causing the mixing of the flow with the stream flowing on the pressure side of the previous blade.
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