带空腔放气的跨音速高压压缩机转子的非均匀流动特性和旋转不稳定性

Chen Xu, Shaowen Chen, Yun Gong
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引用次数: 0

摘要

航空发动机压气机中存在的排气会严重影响其流动特性,并导致旋转不稳定。本研究的重点是典型空腔渗流结构对压气机内部流动特性的影响,特别是其圆周不均匀性和气动稳定性。考虑到 E3 压缩机的典型放气结构,对其跨音速高压转子进行了涉及多个流动通道的数值模拟。该研究深入探讨了压缩机流场中的非均匀流动特性及其产生机制。此外,通过比较均匀和非均匀流场条件下压缩机不稳定性和绝热效率的变化,探讨了放气对压缩机旋转不稳定性的影响。研究结果表明,空腔放气结构的轴向位置对转子失速裕度、峰值效率和近失速条件下的总压比等关键参数起着至关重要的影响作用。空腔排气导致的圆周不均匀性随着排气流量的增加而加剧。对于转子的上游排气配置,总排气率为 5%,不同转子通道入口处绝对流角的最大变化可达 1°。此外,入口流量系数的最大差异可达 0.0392。这些发现表明,与均匀流场方案相比,典型放气结构造成的不均匀性会导致转子失速裕度的损失。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Non-uniform flow characteristics and rotating instability of a transonic high-pressure compressor rotor with cavity bleed
The presence of bleed in an aero engine’s compressor can significantly impact its flow characteristics and contribute to rotating instability. This study focuses on the impact of a typical cavity bleed structure on the internal flow characteristics of a compressor, specifically its circumferential non-uniformity and aerodynamic stability. A numerical simulation involving multiple flow passages was conducted on the transonic high-pressure rotor of the E3 compressor, considering its typical bleed structure. The study delves deep into the non-uniform flow characteristics and the mechanisms behind their generation in the compressor flow field. Furthermore, the influence of bleed on the rotating instability of the compressor is explored by comparing changes in compressor instability and adiabatic efficiency under uniform and non-uniform flow field conditions. The findings indicate that the axial position of the cavity bleed structure plays a crucial role in influencing key parameters such as rotor stall margin, peak efficiency, and total pressure ratio under near-stall conditions. The circumferential non-uniformity, resulting from the presence of the cavity bleed, intensifies with higher bleed air flow rates. For the upstream bleed configuration applied to the rotor, with a total bleed rate of 5%, the maximum variation in absolute flow angle at the inlet of different rotor channels can reach up to 1°. Additionally, the maximum difference in inlet flow coefficient can reach 0.0392. These findings demonstrate that the non-uniformity caused by the typical bleed structure leads to a loss in stall margin for the rotor when compared to a uniform flow field scheme.
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