Novelty Sensor for Detection of Wear Particles in Oil Using Integrated Microwave Metamaterial Resonators With Neodymium Magnets

Sensors for detecting wear particles in fluid lubricants have been widely studied owing to their ability to diagnose mechanical machine conditions and to help in preventing mechanical failures caused by wear particles or contamination particles. The proposed novelty sensor was fabricated using photo...

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Veröffentlicht in:	IEEE sensors journal 2022-06, Vol.22 (11), p.10508-10514
Hauptverfasser:	Chuma, Euclides Lourenco, Iano, Yuzo, Roger, Leonardo Lorenzo Bravo, de Oliveira, Gabriel Gomes, Vaz, Gabriel Caumo
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Sprache:	eng
Schlagworte:	CSRR Low cost Lubricants Magnetic analysis Magnetic flux Magnetic resonance Magnetic sensors magnets metamaterial Metamaterials Monitoring Neodymium oil monitoring Oils Permanent magnets Photolithography Predictive maintenance Resonators Sensor Sensors wear debris Wear particles
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creator	Chuma, Euclides Lourenco Iano, Yuzo Roger, Leonardo Lorenzo Bravo de Oliveira, Gabriel Gomes Vaz, Gabriel Caumo
description	Sensors for detecting wear particles in fluid lubricants have been widely studied owing to their ability to diagnose mechanical machine conditions and to help in preventing mechanical failures caused by wear particles or contamination particles. The proposed novelty sensor was fabricated using photolithography to make the complementary split ring resonator (CSSR) on PCB and it utilized neodymium magnets at the center of the CSRR structure to attract ferrous wear particles. The proposed sensor was tested, and we found that it is highly sensitive and could detect 50 ppm of ferrous wear particles larger than 10 \mu \text{m} dissolved in mineral white oil ISO VG 15. The sensor of this article has a low-cost and can be used in different situations to measure the ferrous wear particles while monitoring the real-time mechanical equipment wear, as it can be easily integrated into them. The sensor offers good accuracy, and is insensitive to fluid transparency and bubble formation, unlike other sensors for detection of wear particles. Therefore, the proposed novelty sensor of this work is in line with Industry 4.0, which requires many low-cost sensors for continuous monitoring to apply predictive maintenance techniques for extending the lifespan of infrastructures.
doi_str_mv	10.1109/JSEN.2022.3168228
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The proposed novelty sensor was fabricated using photolithography to make the complementary split ring resonator (CSSR) on PCB and it utilized neodymium magnets at the center of the CSRR structure to attract ferrous wear particles. The proposed sensor was tested, and we found that it is highly sensitive and could detect 50 ppm of ferrous wear particles larger than <inline-formula> <tex-math notation="LaTeX">10 \mu \text{m} </tex-math></inline-formula> dissolved in mineral white oil ISO VG 15. The sensor of this article has a low-cost and can be used in different situations to measure the ferrous wear particles while monitoring the real-time mechanical equipment wear, as it can be easily integrated into them. The sensor offers good accuracy, and is insensitive to fluid transparency and bubble formation, unlike other sensors for detection of wear particles. 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subjects	CSRR Low cost Lubricants Magnetic analysis Magnetic flux Magnetic resonance Magnetic sensors magnets metamaterial Metamaterials Monitoring Neodymium oil monitoring Oils Permanent magnets Photolithography Predictive maintenance Resonators Sensor Sensors wear debris Wear particles
title	Novelty Sensor for Detection of Wear Particles in Oil Using Integrated Microwave Metamaterial Resonators With Neodymium Magnets
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