Observations of the Growth and Decay of Stall Cells during Stall and Surge in an Axial Compressor

IF 0.9 Q4 ENGINEERING, MECHANICAL

International Journal of Rotating Machinery Pub Date : 2017-09-13 DOI:10.1155/2017/6329382

Adam R. Hickman, S. Morris

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引用次数: 1

Abstract

This research investigated unsteady events such as stall inception, stall-cell development, and surge. Stall is characterized by a decrease in overall pressure rise and nonaxisymmetric throughflow. Compressor stall can lead to surge which is characterized by quasi-axisymmetric fluctuations in mass flow and pressure. Unsteady measurements of the flow field around the compressor rotor are examined. During the stall inception process, initial disturbances were found within the rotor passage near the tip region. As the stall cell develops, blade lift and pressure ratio decrease within the stall cell and increase ahead of the stall cell. The stall inception event, stall-cell development, and stall recovery event were found to be nearly identical for stable rotating stall and surge cases. As the stall cell grows, the leading edge of the cell will rotate at a higher rate than the trailing edge in the rotor frame. The opposite occurs during stall recovery. The trailing edge of the stall cell will rotate at the approximate speed as the fully developed stall cell, while the leading edge decreases in rotational speed in the rotor frame.

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轴流压气机失速和喘振过程中失速细胞生长和衰减的观察

这项研究调查了非定常事件，如失速开始、失速细胞发展和喘振。失速的特点是整体压力上升和非轴对称通流减小。压缩机失速可导致喘振，其特征是质量流量和压力的准轴对称波动。对压缩机转子周围流场的非稳态测量进行了检查。在失速起始过程中，在叶尖区域附近的转子通道内发现了初始扰动。随着失速单元的发展，叶片升力和压力比在失速单元内减小，并在失速单元之前增加。对于稳定旋转失速和喘振情况，失速起始事件、失速单元发展和失速恢复事件几乎相同。随着失速单元的增长，单元的前缘将以比转子框架中的后缘更高的速率旋转。在失速恢复期间，情况正好相反。失速单元的后缘将以与完全展开的失速单元近似的速度旋转，而前缘在转子框架中的旋转速度降低。

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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来源期刊

International Journal of Rotating Machinery ENGINEERING, MECHANICAL-

CiteScore

2.40

自引率

0.00%

发文量

审稿时长

25 weeks

期刊介绍： This comprehensive journal provides the latest information on rotating machines and machine elements. This technology has become essential to many industrial processes, including gas-, steam-, water-, or wind-driven turbines at power generation systems, and in food processing, automobile and airplane engines, heating, refrigeration, air conditioning, and chemical or petroleum refining. In spite of the importance of rotating machinery and the huge financial resources involved in the industry, only a few publications distribute research and development information on the prime movers. This journal is the first source to combine the technology, as it applies to all of these specialties, previously scattered throughout literature.