Autors: Mateev, V. M., Marinova, I. Y.
Title: Magnetic elastomer sensor for dynamic torque measurements in magnetic gears
Keywords: Experimental test, High rotational speed, Magnetic elastomer

Abstract: In this paper is proposed a dynamic torque sensor for precise measurement of torque changes at high rotational speeds. Sensor is based on magnetic elastomer material deformation and corresponding change in magnetic field amplitude and direction. Proposed sensor design is simple and acquire reliable readings for a wide range of rotational speeds. Sensor construction consists of magnetic elastomer coating with nanoparticles which is used for a sensing convertor, magneto-resistive linear field sensor, microprocessor unit for calibration and control. Numerical and experimental test results are demonstrated and analyzed. Sensor implementation aims magnetic gear mechatronic system specific requirements

References

  1. Nemori, H., Saito, Y., Marinova, I., 2014, Harmonic balance for magnetization characteristics exhibiting hysteretic property, 18th International Symposium on Electrical Apparatus and Technologies, SIELA 2014 - Proceedings, art. no. 6871877, 29-31 May 2014, <Bourgas, Bulgaria>, IEEE
  2. Maruyama, K., Marinova, I., Saito, Y., 2013, Enhance the Sensibility of the Resonance Type Eddy Current Sensor, Eighth Japanese-Mediterranean Workshop on Applied Electromagnetic Engineering for Magnetic, Superconducting, Multifunctional and Nano Materials (JAPMED'8), 23-26 June 2013, Athens, Greece, Volume June 2013, pp. pp. 130-131
  3. Kikuchihara, H., Marinova, I., Saito, Y., 1950, Development of a New High Sensitive Eddy Current Sensor, Eighth Japanese-Mediterranean Workshop on Applied Electromagnetic Engineering for Magnetic, Superconducting, Multifunctional and Nano Materials (JAPMED'8), 23-26 June 2013, Athens, Greece, Volume June 2013, pp. p. 128
  4. (2008) Magnetic Field Sensors-General. Philips Semiconductors
  5. Dapino, M., Smith, R., Calkins, F., Flatau, A., 2002, A Magnetoelastic Model for Villari-Effect Magnetostrictive Sensors, Technical report, July, 2002, e-book, Raleigh, North Carolina, North Carolina State University, <https://projects.ncsu.edu/crsc//reports/ftp/pdf/crsc-tr02-20.pdf>, Дата на последен преглед (Last accessed on): 03.12.2019
  6. Lacheisserie, T., 1993, Magnetostriction Theory and Applications of Magnetoelasticity, Boca Raton, CRC Press, Inc
  7. Morón, C., Cabrera, C., Morón, A., García, A., González, M., 2015, Magnetic sensors based on amorphous ferromagnetic materials: A review (Open Access), Sensors (Switzerland), Volume 15 (11), pp. pp. 28340-28366
  8. Ausanio, G., Iannotti, V., Ricciardi, E., Lanotte, L., Lanotte, L., 2014, Magneto-piezoresistance in Magnetorheological elastomers for magnetic induction gradient or position sensors (Open Access), Sensors and Actuators, A: Physical, Volume 205, pp. pp. 235-239

Issue

13th International Conference on Sensing Technology,Proceedings of the International Conference on Sensing Technology, ICST, vol. ICST 2019, issue 13, pp. Article number 9047694, 2019, Australia, IEEE Computer Society, DOI 10.1109/ICST46873.2019.9047694

Copyright IEEE

Цитирания (Citation/s):
1. N. J. Kumar et al., "A Flexible Inductive Sensor for Non-Invasive Arterial Pulse Measurement," 2023 IEEE SENSORS, Vienna, Austria, 2023, pp. 1-4, doi: 10.1109/SENSORS56945.2023.10324884. - 2023 - в издания, индексирани в Scopus или Web of Science

Вид: пленарен доклад в международен форум, публикация в реферирано издание, индексирана в Scopus