基于VSG-CNN的往复式压缩机故障诊断方法

doi:10.16731/j.cnki.1671-3133.2025.10.015

摘要/Abstract

摘要： 针对现有往复式压缩机故障诊断方法在缺乏故障样本时难以构建高精度诊断模型的问题,提出一种结合故障机理驱动的虚拟样本生成(Virtual Sample Generation,VSG)和卷积神经网络(Convolutional Neural Networks,CNN)的往复式压缩机故障诊断方法。首先依据往复式压缩机故障机理与源域数据集对故障共性特征参数进行建模;然后通过共性特征参数和目标域正常角域数据计算得到故障特征,在此基础上将故障特征与目标域正常角域数据结合,生成个性化故障虚拟样本;最后根据目标域正常样本和故障虚拟样本,构建无需目标域往复式压缩机真实故障样本的故障诊断模型。通过往复式压缩机故障模拟实验台数据和某石化企业生产现场数据验证提出方法。研究结果显示,提出方法平均准确率达到88.92 %,相较于对比方法TCA-BPNN、LMD-SDAE、WKCL、RSTRN分别提升49.19 %、22.09 %、18.99 %、14.59 %,证明提出方法在性能上有明显的提升。

关键词: 往复式压缩机, 故障诊断, 虚拟样本生成, 故障机理, 卷积神经网络, 角域分析

Abstract: Aimed at the problem that existing fault diagnosis methods for reciprocating compressors were faced with difficulties in constructing a high precision diagnosis model when fault samples were lacked,a fault diagnosis method for reciprocating compressors was proposed. This method combined fault mechanism driven Virtual Sample Generation (VSG) and Convolutional Neural Networks (CNN). First,a fault common parameter distribution model was established based on the fault mechanism of reciprocating compressors and the source domain data set. Next,fault features were calculated through common parameters and the normal angular domain data of the target domain. By combining the fault features with the normal angular domain data of the target domain,personalized fault virtual samples were generated. Finally,a fault diagnosis model that did not require real fault samples of the target domain reciprocating compressors was constructed using fault virtual samples and target domain normal samples. In the comparative analysis,the data from the reciprocating compressor fault simulation test bench and the production site data of a petrochemical enterprise were used to verify the proposed method. The results indicated that the average accuracy of the proposed method reached 88.92 %. This was 49.19 %,22.09 %,18.99 %,14.59 % higher than the comparative methods TCA-BPNN,LMD-SDAE,WKCL and RSTRN respectively,proving that the proposed method had a significant improvement in performance.

Key words: reciprocating compressor, fault diagnosis, virtual sample generation, fault mechanism, convolutional neural network, angular domain analysis

中图分类号:

TH457
TH17

李远, 胡明辉, 马波. 基于VSG-CNN的往复式压缩机故障诊断方法[J]. 现代制造工程, 2025, 541(10): 138-147.

LI Yuan, HU Minghui, MA Bo. Fault diagnosis method for reciprocating compressors based on VSG-CNN[J]. Modern Manufacturing Engineering, 2025, 541(10): 138-147.

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