Abstract
Accurate and reliable measurement of rotational speed is desirable in a variety of industries. This paper presents a rotational speed measurement system based on a low-cost imaging device with a simple marker on the rotor. Sequential images are pre-processed through denoising, histogram equalization, and circle Hough transform, and then processed by similarity evaluation methods to obtain the similarity level of images. Finally, the rotational speed is obtained through the Chirp-Z transform on the restructured signals. The measurement principle, structure design, and performance assessment of the proposed system are presented. The effects of different influence factors, including frame rate, marker shape and size, an algorithm for image similarity evaluation, illumination conditions, shooting angle and photographic distance, on the performance of the measurement system are quantified and discussed through a series of experimental tests on a laboratory test rig. Experimental results suggest that the system is capable of providing constant rotational speed measurement with a maximum relative error of ±0.6% and a repeatability of less than 0.6% over a speed range from 100 to 900 RPM. Under varying speed conditions the proposed system can achieve valid measurement with a relative error within ±1% over the speed range of 300 to 900 RPM.
Highlights
Rotating machineries such as generators, electromotors and centrifuges play an important role in a wide range of industries
The imaging device is placed immediately opposite to the cross section of the rotor, the shooting angle is controlled by a cradle hand and the distance between the rotor and the imaging device is adjustable
In order to obtain an independent reference speed to assess the accuracy of the measured speed from the proposed system, a non-contact laser tachometer (UNI-T, model UT372) with a maximum relative error of ±0.04% is used in this study
Summary
Rotating machineries such as generators, electromotors and centrifuges play an important role in a wide range of industries. The operation of a magnetic tachometer requires a ferromagnet to be installed on the rotor and the system performance is susceptible to electromagnetic interference. Photoelectric tachometers do not perform well under dusty, harsh and extreme conditions. Such instruments should be placed adjacent to the rotors being measured, which results in limited portability and flexibility in installation. Vibration signal processing techniques have been combined with accelerometers to estimate the rotational speed of rotating equipment [7]. Such systems are difficult to obtain accurate measurements in a harsh industrial environment. When significant noise exists in the vibration signal, it will generate severe spectral interference and have an adverse effect on the rotational speed measurement [8]
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