某风扇增压级发生了一次振动故障,基频振动瞬间突增,之后快速下降,但仍超限制值,停机检查发现试验件损伤较为严重。为排查故障原因,进行了转速分析,确定了故障分析的振动信号时段,对该时段振动信号进行了小波分析、快速傅里叶变换(fast fourier transform,FFT)分段对比分析,推断出异常振动的频率;结合试验件分解后发现的磨痕特征,推断出异常振动的振型;再结合静子机匣模态试验、转子鼓筒模态分析、轴心轨迹分析等多种信息后,提出了故障机理——转静子碰磨激发了转子鼓筒3节径后行波共振;根据故障机理提出了整改措施,经试验验证,措施有效。本文对该次的振动故障特征、故障诊断方法进行了总结,对类似振动故障的排除具有重要的参考价值。
关键词:行波共振;转速分析;故障频率;故障振型;小波分析
Abstract
A vibration fault occurred on a fan booster stage: fundamental frequency vibration increased suddenly and reduced soon, but it exceeded limit value yet; serious damages were found in the checking after stopped running. In order to find out the reasons for this fault, analysis on rotating speed was conducted, and a period of vibration signal was locked for fault analysis. Wavelet analysis and fast fourier transform(FFT) segmented contrast analysis were finished to infer the abnormal vibration frequency. A fault mechanism was presumed based on comprehensive information including stator case modal experiment, rotor drum modal analysis and orbit analysis, which was the resonance of the 3-nodal-diameter backward travelling wave of rotor drum due to friction between stator and rotor. Rectification measures were made according to fault mechanism, which were proven being effective through experiment. The characteristics of vibration fault and the method of fault diagnosis in this vibration fault event were summarized, which have an important reference value on similar fault diagnosis.
Key words: Travelling wave resonance; rotating speed analysis; abnormal frequency; abnormal shape; wavelet analysis
关键词
行波共振 /
转速分析 /
故障频率 /
故障振型 /
小波分析
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Key words
Travelling wave resonance /
rotating speed analysis /
abnormal frequency /
abnormal shape /
wavelet analysis
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