无转速计下变工况滚动轴承故障特征量化表征提取

无转速计下变工况滚动轴承振动信号中各信号分量来源难以确定以及瞬时转频准确估计困难,而现有大多数研究依赖于已知转速并关注于时变冲击带来的频谱畸变,鲜有在无转速计变工况下开展轴承故障特征提取探究。提出无转速计下变工况滚动轴承故障特征量化表征提取方法,从振动信号希尔伯特包络中提取轴承故障特征,为定量描述各振动包络分量间关系,提出基于来源假设的特征模型与量化表征方法,利用同步压缩小波变换的时频重排与可重构特性,基于最大能量与最小曲率准则依次估计多时频脊瞬时频率,为降低广义解调后振动包络中干扰分量对量化结果的影响,提出基于选择性重构与广义解调的变工况下干扰抑制与平稳化重置方法。将所提方法用于仿真信号以及轴承振动数据分析,10 k长度信号包络分量在不同来源假设下的特征提取用时约为3 s,同时在无转速计下实现了对2 s内转速变化分别约为300 r/min和200 r/min的内圈故障轴承以及复合故障轴承的特征提取。     

基于时变零相位滤波的变转速滚动轴承故障诊断

针对变转速下齿轮箱中滚动轴承故障调制特征的提取与分离,提出了基于时变零相位滤波的变转速滚动轴承故障诊断方法。该方法先用线调频小波路径追踪(CPP)算法从齿轮箱滚动轴承故障振动信号中估计出齿轮啮合频率,由啮合频率除以齿数得到齿轮箱的转速,同时,采用Hilbert包络解调方法获取轴承故障振动信号的包络信号;然后根据获取的转速信息设计各阶时变零相位滤波器;再采用各时变零相位滤波器对包络信号进行分析,获取各调制信号;最后,利用转速信号对求取的各调制信号进行阶次分析,并根据各阶次谱来诊断滚动轴承故障。算法仿真和应用实例分析表明,该方法可有效提取和分离变速齿轮箱中滚动轴承的各阶故障调制特征。     

基于ALE的自适应滤波在轴承故障诊断中的应用

提出了一种基于谱线增强的变步长自适应滤波方法,从滚动轴承的振动信号中分离出故障冲击信号,便于包络分析获取故障特征频率.介绍了该方法的原理及算法实现,并对未知高频固有振动的滚动轴承进行了故障诊断,效果明显优于传统带通滤波方法.     

POVMD与包络阶次谱的变工况滚动轴承故障诊断

针对变转速滚动轴承故障特征提取较难的问题,提出一种基于参数优化变分模态分解(parameter optimized variational mode decomposition,简称POVMD)与包络阶次谱的变工况滚动轴承故障诊断方法。首先,采用POVMD对变转速滚动轴承振动信号进行分解,得到若干个本征模态函数之和;其次,对各个分量的时域信号进行角域重采样,将时变信号转化为平稳信号处理,再利用Hilbert变换估计重采样后的平稳信号的包络;最后,对得到的包络信号进行阶比分析,从谱图中读取故障特征信息。将POVMD方法与经验模态分解进行了对比,仿真信号分析结果表明了POVMD方法的优越性。将提出的变转速滚动轴承故障诊断方法应用于试验数据分析,分析结果表明,所提出的方法能够实现变转速滚动轴承的故障诊断,而且诊断效果优于现有方法。     

基于角域AR模型滤波的滚动轴承故障诊断

在齿轮噪源存在的变转速滚动轴承故障诊断过程中,因混合信号中转频分量相对较小,使得基于时频表达的阶比跟踪技术受到限制。虽然基于故障特征频率的角域重采样能提取轴承的故障特征,但这种算法不能确定故障位置,而且可能会出现误判。针对这一问题,提出了基于角域自回归(auto regressive,简称AR)模型滤波的处理方法。该方法利用线调频小波路径追踪算法从降采样处理的混合信号中提取齿轮瞬时啮合频率趋势线并估计转速,根据估计转速信息对原混合信号进行等角度重采样,获得了角域信号。利用角域信号中齿轮啮合振动成分具有周期性的特点,使用AR模型对其滤波,并且对滤波后信号进行包络阶比分析,完成故障判断。通过处理仿真信号和实验信号,验证了该方法不仅能有效地去除齿轮噪声,并且可以判断轴承故障位置。     

Weak fault feature extraction of rolling bearing under strong poisson noise and variable speed conditions

Fault feature extraction of the rolling bearing under strong background noise is always a difficult problem in bearing fault diagnosis. At present, most of the research focuses on weak signal extraction under Gaussian white noise and has certain practical significance. However, the noise in engineering is often complex and changeable, Gaussian white noise cannot fully simulate the actual strong background noise. Poisson white noise is a type of typical non-Gaussian noise, which widely exists in complex mechanical impact. It is of great significance to study the weak fault feature extraction of a faulty bearing under this type of noise. At the same time, variable speed conditions occupy most rotating machinery speed conditions. Non-stationary vibration signals make it difficult to extract fault features, and the frequency spectrum ambiguity will occur because of speed fluctuation. To solve the above problems, a method of weak feature extraction of a faulty bearing based on computed order analysis (COA) and adaptive stochastic resonance (SR) is proposed. Firstly, by numerical simulation, the non-stationary fault characteristic signal corrupted with strong Poisson noise is transformed into a stationary signal in the angle domain by COA. Secondly, the influence of the parameters of the pulse arrival rate and noise intensity of Poisson white noise on the optimal SR response in the angle domain are studied, and the influence of the parameters of Poisson white noise on the fault feature extraction is given. Then, adaptive SR method is used to extract and enhance fault feature information. Finally, the effectiveness of this method in weak fault characteristic signal extraction under strong Poisson noise is verified by experiments. Numerical simulation and experimental results verify the effectiveness of the proposed method in bearing fault diagnosis under strong Poisson noise and variable speed conditions.

     

基于改进EMD和谱峭度法滚动轴承故障特征提取

针对滚动轴承故障信号的强背景噪声特点,提出一种基于改进经验模态分解(empirical mode decomposition,简称EMD)与谱峭度法的滚动轴承故障特征提取方法.首先,利用EMD方法对原故障信号进行分解,得到若干平稳固有模态分量(intrinsic mode function,简称IMF);然后,采用灰色关联度与互信息相结合方法剔除传统EMD分解结果中存在的虚假分量;最后,运用谱峭度法和包络解调方法对真实IMF分量进行分析,提取故障特征频率.通过对实际滚动轴承故障信号的应用表明,该方法可有效地提取滚动轴承故障特征,且能够取得比传统包络解调分析更好的效果.     

IEWT和FSK在齿轮与滚动轴承故障诊断中的应用

改进的经验小波变换方法(improved empirical wavelet transform,简称IEWT)是一种新的自适应性信号处理方法,将这种方法和快速谱峭度(fast spectral kurtosis,简称FSK)相结合,进行齿轮与滚动轴承的故障诊断。首先,采用IEWT对信号进行分解,筛选出故障特征最为明显的2个分量并重构信号;其次,对重构信号进行快速谱峭度滤波;最后,对滤波后的信号进行包络谱分析,提取出信号的故障特征。分析齿轮断齿及滚动轴承故障信号,与直接包络谱和基于EMD经验模态分解(empirical mode decomposition,简称EMD)方法的FSK滤波包络谱分析方法相比可知,采用IEWT处理后再进行FSK滤波的信号进行包络谱分析更具有区分性,可有效识别齿轮和滚动轴承的故障特征。     

盲解卷积和频域压缩感知在轴承复合故障声学诊断的应用

针对时域盲解卷积算法对单一故障机械声信号有效,及传统稀疏分量分析对声信号分析失效等问题,提出一种盲解卷积、形态滤波和频域压缩感知重构的稀疏分量分析相结合的轴承复合故障声学诊断方法。通过时域盲解卷积算法优选分量结果,提取声信号的冲击成分。使用形态滤波滤除背景噪声。使用模糊C均值聚类估计混合矩阵,重构传感矩阵,并运用稀疏度自适应匹配追踪基算法(Sparsity adaptive matching pursuit,SAMP)的频域压缩感知重构分离信号。双通道滚动轴承故障声信号分析结果表明该方法能够有效分离和提取滚动轴承故障特征。     

基于本征模态函数包络谱的滚动轴承故障诊断

针对滚动轴承故障振动信号非平稳的特征,以及传统傅里叶变换不能反映信号细节的缺陷,引入了一种基于本征模态函数包络谱的方法。首先,采用经验模态分解（empirical mode decomposition,EMD）将滚动轴承故障振动信号分解成若干个本征模态函数（intrinsic mode function,IMF）之和;然后,求出包含主要信息成分的IMF分量的Hilbert包络谱;最后,对照滚动轴承故障特征频率,进而判定故障类型。通过对滚动轴承内圈、外圈故障振动信号的分析处理,表明该方法能有效地提取滚动轴承的故障特征。     

基于自适应最优Morlet小波的滚动轴承故障诊断

滚动轴承早期故障信号中故障信息比较微弱常常被强噪声所掩盖,增加了对滚动轴承故障诊断的难度。针对这一问题,笔者提出了基于自适应最优Morlet小波变换的滚动轴承故障诊断方法。首先,利用粒子群优化算法对Morlet小波变换的核心参数进行自适应寻优,在获得最优Morlet小波的同时保证了良好的带通滤波性能;然后,将最优Morlet小波对滚动轴承早期故障信号进行滤波去噪,提高信号的信噪比;最后,对最优Morlet小波滤波信号进行包络谱分析,通过包络谱中的主导频率成分与滚动轴承各元件的故障特征频率对比从而判断轴承的故障位置。仿真数据和实测数据分析结果证明,笔者所提方法能够有效提取故障信号中的特征信息,具有一定的有效性。     

改进ILoG算子的故障检测方法

针对强背景噪声干扰下轮对轴承故障特征微弱、难以准确检测的问题,提出了一种自适应改进高斯拉普拉斯(improved Laplacian of Gaussian,简称ILoG)算子的微弱故障检测方法。ILoG算子滤波器具有优良的信号突变特征检测能力,将其用于轮对轴承故障信号的冲击特征检测,同时利用水循环算法(water cycle algorithm,简称WCA)的寻优特性,并行搜寻筛选最佳的ILoG算子影响参数,通过对参数优化后ILoG算子滤波后信号做进一步包络解调分析,提取出轮对轴承微弱的故障特征信息。对实际轮对轴承外圈和内圈故障信号分析的结果表明,该方法可以有效检测出轴承微弱故障特征频率,故障检测效果优于小波阈值和多尺度形态学差值滤波方法。     

基于短时傅里叶变换和独立分量分析的滚动轴承包络分析

滚动轴承的早期故障信号能量小,频带分布广泛;而传统包络谱分析技术直接在强干扰影响下对滚动轴承的故障特征提取经常失效.提出一种基于短时傅里叶变换(short time Fourier transform,STFT)的能量谱和独立分量分析( independent component analysis,ICA)的抗干扰滚动轴承包络分析新方法.该方法首先对获取的滚动轴承振动信号进行STFT能量谱分析,获取信号采样频带下的能量分布,采用带通滤波器获得高频带能量信号,并提取该包络波形,再通过ICA实现包络波形按源分离去噪,最后通过比较各独立分量的包络频谱与滚动轴承理论计算故障特征频率的匹配性,实现滚动轴承故障的精确诊断.仿真数据和试验验证该方法的可行性.     

Early fault detection method for rolling bearing based on multiscale morphological filtering of information-entropy threshold

The scale of structure element is especially important to obtain good filtering results in multiscale morphological filtering (MMF) method. In general, the optimal scale of structure element is set to be a fixed value in traditional morphological filter, therefore it is difficult to extract the fault feature from rolling bearing vibration signal effectively. A novel multiscale morphological filtering algorithm is proposed based on information-entropy threshold (IET-MMF) for early fault detection of rolling bearing. Compared with traditional MMF method, several optimal scales of structure elements are achieved according to the energy distribution characteristic of different vibration signals. The information entropy theory is applied to quantify the analyzed signals, and the optimal threshold of information entropy is obtained by iterative algorithm to ensure integrity of useful information. The simulation and rolling bearing experimental analysis results show that the IET-MMF method can extract fault features of vibration signals effectively.

     

Adaptive combined HOEO based fault feature extraction method for rolling element bearing under variable speed condition

It is still a challenge for condition monitoring and fault diagnosis for rolling element bearings working under variable speed, while some conventional diagnostic methods are useless. Order tracking is commonly used as an effective tool of the non-stationary vibration analysis for rotating machinery and tacho-less order tracking may be more applicable for practical situations, while the key point is to obtain more accurate instantaneous rotating speed. What’s more, the collected bearing fault vibration signals always contain strong background noise that greatly affects the result of fault feature extraction. To solve these problems, a fault feature extraction method is proposed in this study. The Chirplet-based approach was used to estimate some obvious harmonics of instantaneous rotating speed and the average value of these components was regarded as the final instantaneous rotating speed to reduce the estimation error. Since the higher order energy operator (HOEO) can not only improve the signal-to-noise ratio and signal-to-interference ratio, but is also easily applied, an adaptive combined HOEO method based on hybrid particle swarm optimizer with sine cosine acceleration coefficients (H-PSO-SCAC) was constructed to enhance the impulse components, and then, the fault features were extracted by the order spectrum analysis. Simulation and experimental results indicate that the proposed algorithm is effective for rolling element bearings’ fault diagnosis under variable speed condition.     

变转速下滚动轴承阶比峭度图法故障特征提取

结合传统阶比分析和峭度图算法的优势,利用计算阶比跟踪方法将时域非平稳信号转换为角域平稳信号,并利用峭度指标准确表征滚动轴承振动信号中的故障瞬态冲击大小,提出了阶比峭度图算法。仿真故障信号及实测滚动轴承外圈故障信号分析结果表明,阶比峭度图算法能够有效识别阶比域内的最优包络解调频带参数,显著提高了变转速工况下滚动轴承故障特征提取的准确性。     

基于平稳工况数据截取的RV减速器故障诊断方法

旋转矢量（Rotary Vector, RV）减速器广泛应用在工业机器人重载关节处,直接影响着工业机器人的工作精度和稳定性。与一般旋转机械设备不同,工业机器人完成各项工作任务时,关节处RV减速器做往复变转速转动,转速的变化会使特征频率、统计指标等产生时变效应,导致故障信息难以提取,为故障诊断带来挑战。文中结合工业机器人RV减速器的运动特点,提出基于平稳工况数据截取的RV减速器故障诊断方法。首先通过引入压缩范围限制因子获取清晰的时频谱图;然后进行基于快速路径优化的脊线提取,并利用构建的滑动窗峰–峰值和均值指标截取脊线平稳段,获取所需的平稳工况数据;最后通过对平稳工况数据进行包络谱分析实现故障诊断。利用RV减速器往复运动振动数据对提出的诊断方法进行验证。结果表明,该方法可实现对平稳工况数据的准确截取,克服了转速变化的影响,成功提取了故障信息。     

基于包络分析的滚动轴承故障诊断研究

在研究滚动轴承振动机理的基础上,提出了利用对振动信号进行包络分析,以及特征提取的方法来进行故障类型的判断。在QPZZ-Ⅱ型故障模拟实验台上进行了滚动轴承实验,对振动信号进行包络分析和特征提取,准确地判断出了滚动轴承的故障类型,证明了该方法是有效的。     

基于平方包络谱相关峭度的最优共振解调诊断滚动轴承故障

利用峭度指标识别滚动轴承共振频带,结合包络分析解调故障特征,是滚动轴承故障诊断的常用方法。峭度指标虽然能够表征瞬态冲击特征的强弱,却无法利用瞬态冲击特征循环发生的特点,导致其难以区分脉冲噪声和循环瞬态冲击,无法准确识别共振频带,进而容易导致错误的故障诊断结果。受峭度和信号自相关的启发,重新定义相关峭度,提出平方包络谱相关峭度新指标;并结合Morlet小波滤波和粒子群优化算法,提出一种滚动轴承最优共振解调方法。通过与峭度、谱峭度等进行对比,仿真和试验分析结果表明平方包络谱相关峭度能够准确识别循环瞬态冲击;最优共振解调能够稳健确定共振频带的最优中心频率和带宽,准确解调诊断滚动轴承故障,验证了平方包络谱相关峭度在检测循环瞬态冲击和识别最优共振频带中的有效性和优越性。     

基于最优 IMF 分量和 K-SVD 的滚动轴承故障声音信号特征提取

针对滚动轴承声音信号中周期性冲击故障特征难提取的问题,提出了基于最优 IMF 分量与 K-SVD 字典学习相结合的轴承故障特征提取方法。首先,利用 VMD 分解原始信号获得一系列 IMF 分量;其次,利用 SAF 指标自适应选取最优 IMF 分量,并作为训练信号;最后,利用 K-SVD 字典学习方法训练出字典库,通过正交匹配追踪算法( OMP )对原始信号处理得到稀疏信号,并对稀疏信号进行包络谱分析。仿真及实验结果表明,对比传统 K-SVD 字典学习方法,该方法得到的稀疏信号信噪比( SNR )更高,能更准确地提取滚动轴承周期性冲击,增强了轴承故障特征。