Flow physics during durge of an axial-centrifugal compressor

IF 1.1 Q4 ENGINEERING, MECHANICAL Journal of the Global Power and Propulsion Society Pub Date : 2024-03-18 DOI:10.33737/jgpps/183914

Jiaan Li, Weihan Kong, Xueqi Zou, Xiwu Liu, Baotong Wang, Xinqian Zheng

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引用次数: 1

Abstract

Aerodynamic instability design is one of the crucial elements when designing a compressor. Unstable phenomenon such as surge harms the compressor in both performance and structure integrity. The complex unsteady flow process during instability strongly relates to the compressor design. This paper investigates the transient instability process using URANS on a three-stage-axial and one-stage-centrifugal combined compressor under its off-design conditions. Results show that the compressor suffers two surge patterns. The mild surge happens first, with a higher frequency than the traditional mild surge. Then, with the decrease of valve opening, the deep surge is initiated, and the axial stages work at the peak pressure ratio because the mass flow rate is limited by the choked radial diffuser. Moreover, analysis of aerodynamic loads reveals that IGV and the first rotor have the largest unsteady force among all blade rows. According to the flow field, the rotor root and stator tip suffer the most serious impulse caused by reversed flow during surge conditions.

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轴向离心式压缩机停机时的流动物理特性

空气动力不稳定性设计是压缩机设计的关键要素之一。浪涌等不稳定现象会损害压缩机的性能和结构完整性。失稳过程中复杂的非稳态流动过程与压缩机的设计密切相关。本文使用 URANS 对三阶段轴向和一阶段离心式组合压缩机在非设计条件下的瞬态不稳定过程进行了研究。结果表明，压缩机会出现两种浪涌模式。首先出现的是轻度喘振，频率高于传统的轻度喘振。然后，随着气阀开度的减小，深度喘振开始，由于质量流量受阻于径向扩散器，轴向级以峰值压力比工作。此外，气动载荷分析表明，在所有叶片排中，IGV 和第一转子的不稳定力最大。根据流场分析，转子根部和定子顶端在浪涌条件下受到的反向流冲击最为严重。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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