Comparison Study On Pinch-Hitting Vibration Signal Analysis for Automotive Bearing: I-KazTM and I-Kaz 3D

IF 0.4 Q4 ENGINEERING, MULTIDISCIPLINARY

International Journal of Integrated Engineering Pub Date : 2023-10-19 DOI:10.30880/ijie.2023.15.05.027

A. Othman, H. Hamid, M. A. F. Ahmad, M. Z. Nuawi

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引用次数: 0

Abstract

Rotating machines are now an essential part of the automotive industry. Meanwhile, a bearing is playing the most important component of rotating machinery. To sustain the system's smooth running, maintenance methods such as preventive maintenance, breakdown maintenance, and predictive maintenance are used. Under preventive maintenance, vibration analysis is used to diagnose machines bearing faults. The main objective is to recognize bearing defects in a mechanical device by acquiring signals from the bearing using data acquisition hardware. This analysis is conducted under various load torque conditions, speeds, and defect types. A modular hardware configuration consisting of an accelerometer acquires the vibration signal. The signals are analyzed by using I-kazTM and I-kaz 3D signal analysis and its main objective is to observe the degree of dispersion data from its mean point. This analysis resolves the issues associated with time domain analysis. This pinch-hitting analysis research was conducted in two stages. The first stage is an experimental process that uses 3 types of bearings, the healthy (BL), inner race fault (IRF), and defect at outer race (ORF) bearing on the Machine Fault Simulator and forces with a different type of speed (1000, 1500 and 2500 rpm) and load variation (0.0564, 0.564 and 1.1298 N-m). In the second stage, computing the coefficient value and plots of signal’s I-kazTM and I-kaz 3D based on the bearings type were done accordingly. As a result, the analysis for detecting inner race fault, the deviation percentage averages calculation obtained the I-kazTM coefficient shows a better result with 96.86% by comparing to the I-kaz 3D that achieves 94.20%. Similarly, for the outer race defect, I-kazTM lead with 65.40% compared to I-kaz 3D with only 54.82%.

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汽车轴承夹击振动信号分析的比较研究:I-KazTM和I-Kaz 3D

旋转机械现在是汽车工业的重要组成部分。同时，轴承是旋转机械中最重要的部件。为了保证系统的正常运行，需要采用预防性维护、故障维护和预测性维护等维护方法。在预防性维修中，振动分析是诊断机械轴承故障的常用方法。主要目标是通过使用数据采集硬件从轴承获取信号来识别机械设备中的轴承缺陷。该分析是在各种负载、扭矩条件、速度和缺陷类型下进行的。由加速度计组成的模块化硬件配置获取振动信号。利用I-kazTM和I-kaz三维信号分析对信号进行分析，其主要目的是观察数据离其均值的色散程度。这种分析解决了与时域分析相关的问题。本次捏击分析研究分两个阶段进行。第一阶段是一个实验过程，在机器故障模拟器上使用3种类型的轴承，健康(BL)，内圈故障(IRF)和外圈(ORF)轴承缺陷，以及不同类型速度(1000,1500和2500 rpm)和负载变化(0.0564,0.564和1.1298 N-m)的力。第二阶段，根据轴承类型计算信号的I-kazTM和I-kaz 3D的系数值和图。结果，对检测内圈故障的分析，偏差百分比平均计算得到的I-kazTM系数为96.86%，优于I-kaz 3D的94.20%。同样，对于外圈缺陷，I-kazTM的领先率为65.40%，而I-kaz 3D的领先率仅为54.82%。

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来源期刊

International Journal of Integrated Engineering ENGINEERING, MULTIDISCIPLINARY-

CiteScore

1.40

自引率

0.00%

发文量

期刊介绍： The International Journal of Integrated Engineering (IJIE) is a single blind peer reviewed journal which publishes 3 times a year since 2009. The journal is dedicated to various issues focusing on 3 different fields which are:- Civil and Environmental Engineering. Original contributions for civil and environmental engineering related practices will be publishing under this category and as the nucleus of the journal contents. The journal publishes a wide range of research and application papers which describe laboratory and numerical investigations or report on full scale projects. Electrical and Electronic Engineering. It stands as a international medium for the publication of original papers concerned with the electrical and electronic engineering. The journal aims to present to the international community important results of work in this field, whether in the form of research, development, application or design. Mechanical, Materials and Manufacturing Engineering. It is a platform for the publication and dissemination of original work which contributes to the understanding of the main disciplines underpinning the mechanical, materials and manufacturing engineering. Original contributions giving insight into engineering practices related to mechanical, materials and manufacturing engineering form the core of the journal contents.