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基于低成本振动的干草旋转摊晒机机器监测系统的设计与评估。

Design and Evaluation of Low-Cost Vibration-Based Machine Monitoring System for Hay Rotary Tedder.

机构信息

Faculty of Electrical Engineering, Bialystok University of Technology, Wiejska St. 45D, 15351 Bialystok, Poland.

出版信息

Sensors (Basel). 2022 May 27;22(11):4072. doi: 10.3390/s22114072.

DOI:10.3390/s22114072
PMID:35684692
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9185525/
Abstract

Vibration monitoring provides a good-quality source of information about the health condition of machines, and it is often based on the use of accelerometers. This article focuses on the use of accelerometer sensors in fabricating a low-cost system for monitoring vibrations in agricultural machines, such as rotary tedders. The aim of the study is to provide useful data on equipment health for improving the durability of such machinery. The electronic prototype, based on the low-cost AVR microcontroller ATmega128 with 10-bit ADC performing a 12-bit measurement, is able to acquire data from an accelerometer weighing up to 10 g. Three sensors were exposed to low accelerations with the use of an exciter, and their static characteristics were presented. Standard experimental tests were used to evaluate the constructed machine monitoring system. The self-contained prototype system was calibrated in a laboratory test rig, and sinusoidal and multisinusoidal excitations were used. Measurements in time and frequency domains were carried out. The amplitude characteristic of the preformed system differed by no more than 15% within a frequency range of 10 Hz-10 kHz, compared to the AVM4000 commercial product. Finally, the system was experimentally tested to measure acceleration at three characteristic points in a rotational tedder, i.e., the solid grease gearbox, the drive shaft bearing and the main frame. The RMS amplitude values of the shaft vibrations on the bearing in relation to the change in the drive shaft speed of two tedders of the same type were evaluated and compared. Additionally, the parameters of kurtosis and crest factor were compared to ascertain the bearing condition.

摘要

振动监测为机器的健康状况提供了高质量的信息来源,它通常基于加速度计的使用。本文专注于使用加速度计传感器制造用于监测农业机械(如旋转式搂草机)振动的低成本系统。研究的目的是提供有关设备健康状况的有用数据,以提高此类机械的耐用性。基于低成本 AVR 微控制器 ATmega128 的电子原型,该微控制器具有执行 12 位测量的 10 位 ADC,能够从重达 10g 的加速度计获取数据。三个传感器使用激振器暴露于低加速度下,并展示了它们的静态特性。标准实验测试用于评估所构建的机器监测系统。独立的原型系统在实验室测试台上进行了校准,并使用了正弦和多正弦激励。进行了时域和频域的测量。与 AVM4000 商业产品相比,在 10Hz-10kHz 的频率范围内,预成型系统的幅度特性差异不超过 15%。最后,对系统进行了实验测试,以测量旋转式搂草机三个特征点的加速度,即固体润滑脂齿轮箱、传动轴轴承和主机架。评估并比较了两个相同类型的搂草机的传动轴速度变化时,轴承上轴振动的 RMS 幅度值。此外,还比较了峭度和峰度系数的参数,以确定轴承的状况。

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