Abstract
In the current work, magnetoelastic material ribbons are used as vibration sensors to monitor, in real time and non-destructively, the mechanical health state of rotating beam blades. The magnetoelastic material has the form of a thin ribbon and is composed of Metglas alloy 2826 MB. The study was conducted in two stages. In the first stage, an experiment was performed to test the ability of the ribbon to detect and transmit the vibration behavior of four rotating blades, while the second stage was the same as the first but with minor damages introduced to the blades. As far as the first stage is concerned, the results show that the sensor can detect and transmit with great accuracy the vibratory behavior of the rotating blades, through which important information about the mechanical health state of the blade can be extracted. Specifically, the fast Fourier transform (FFT) spectrum of the recorded signal revealed five dominant peaks in the frequency range 0–3 kHz, corresponding to the first five bending modes of the blades. The identification process was accomplished using ANSYS modal analysis, and the comparison results showed deviation values of less than 1% between ANSYS and the experimental values. In the second stage, two types of damages were introduced to the rotating blades, an edge cut and a hole. The damages were scaled in number from one blade to another, with the first blade having only one side cut while the last blade had two side cuts and two holes. The results, as was expected, show a measurable shifting on the frequency values of the bending modes, thus proving the ability of the proposed magnetoelastic sensors to detect and transmit changes of the mechanical state of rotating blades in real time.
Highlights
IntroductionThe equipment is maintained after a major failure so it is unable to continue its operation
Ribbons of magnetoelastic material known as Metglas 2826 MB are used in this work as vibration sensors in order to detect and transmit the vibration state of the rotating beams
The measurements were performed on rotating blades without damages, and the results were verified using the ANSYS software program, while in the second stage, the measurements were performed by inserting damages to the rotating blades
Summary
The equipment is maintained after a major failure so it is unable to continue its operation. This method generally necessitates high maintenance costs and poses a risk to personal safety. The second case (preventive failure) is based on the wear law of equipment parts and treats the part failure as a function of time. While this method is planned and preventative in certain aspects, it can be fairly costly when the parts are free of faults. Health monitoring with advanced measurement techniques is typical of this method, and the advantages are numerous (improved machine efficiency, dependability, availability, durability, reduced maintenance costs, programs to improve safety and the environment, etc.)
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