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Control system and measurements of coil actuators parameters for magnetomotive micropump concept

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
This paper presents an approach to the construction and measurements of electrodynamic and reluctance actuators. Executive elements were used as drives in a novel concept of a magnetomotive micropump. The paper discusses various aspects concerning the designation of parameters, control system, the explanation of physical phenomena, and the optimization of the basic elements for coil units. The conducted work describes the measurement system and the analysis of the derived values. The actuators were compared and the pros/cons of building the conceptual device were highlighted. The best solution to be used in the upcoming work concerning the construction of a magnetomotive micropump was chosen based on measurements, engineering aspects, layout control, and key parameters such as the piston velocity, energy stored in capacitors, and efficiencies.
Rocznik
Strony
893--901
Opis fizyczny
Bibliogr. 22 poz., rys., tab.
Twórcy
autor
  • Institute of Electrical Power Engineering, Warsaw University of Technology, 75 Koszykowa Street, 00-662 Warsaw, Poland
  • Astronika Sp. z o.o., 18 Bartycka Street, 00-716 Warsaw, Poland
  • Institute of Electrical Power Engineering, Warsaw University of Technology, 75 Koszykowa Street, 00-662 Warsaw, Poland
  • Institute of Electrical Power Engineering, Warsaw University of Technology, 75 Koszykowa Street, 00-662 Warsaw, Poland
autor
  • ILF Consulting Engineers sp. z o.o., 12 Osmańska Street, 02-823 Warsaw, Poland
autor
  • ILF Consulting Engineers sp. z o.o., 12 Osmańska Street, 02-823 Warsaw, Poland
Bibliografia
  • [1] W.F. Gauster, “Somerbasic concepts for magnet coil design”, Conference paper, Illionois, pp. 1–17, 1959.
  • [2] J. Liu and T. Koseki, “3 degrees of freedom control of semi-zero-power magnetic levitation suitable for two-dimensional linear motor”, Proceedings of the Fifth International Conference on Electrical Machines and Systems, Shenyang, China, pp. 976 –981, 2001.
  • [3] Y. An, G. Liu, P. Wang, H. Wen, and Z. Meng, “Magnetic force analysis and experiment of novel permanent magnet axial thrust balance structure in canned motor pump”, IEEE 2nd International Conference on Advanced Computer Control, Shenyang, China, vol. 1, pp. 1–8, 2010.
  • [4] J. Cai and Y. Deng, “Initial Rotor Position Estimation and Sensorless Control of SRM Based on Coordinate Transformation”, IEEE Trans. Instrum. Meas. 64 (4), 1004–1018 (2015).
  • [5] A. Masi, A. Danisi, R. Losito, and R. Perriard, “Characterization of magnetic immunity of an ironless inductive position sensor”, IEEE Sens. J. 13 (3), 941–948 (2013).
  • [6] K. Yongdae, H.Y. Choi, and Y.CH. Lee, “Design and preliminary evaluation of high-temperature position sensors for aerospace applications”, IEEE Sens. J. 14 (11), 4018–4025 (2014).
  • [7] F. Khoshnoud, and C.W. Silva, “Recent advances in MEMS sensor technology-mechanical applications”, IEEE Trans. Instrum. Meas. 15 (2), 14–24 (2012).
  • [8] G. Loussert, “An Efficient and Optimal Moving Magnet Actuator for Active Vibration Control”, 15 th International Conference on New Actuators, Bremen, Germany, pp. 1390–1420, 2016.
  • [9] C. Paulitsch, P. Gardonio, S.J. Elliott, P. Sas, and R. Boonen, “Design of a Lightweight, Electrodynamic, Inertial Actuator with Integrated Velocity Sensor for Active Vibration Control of a Thin Lightly-Damped Panel”, Proceedings of ISMA, pp. 239–251, 2004.
  • [10] C. Paulitsch, P. Gardonio, and S.J. Elliott, “Active vibration damping using an interial, electrodynamic actuator”, J. Vib. Acoust. 129, 39-47 (2007).
  • [11] X. Li, K. Tian, and Y. Zhou, “Linear Electromagnetic Oil Pumping Unit Based on the Principle of Coil Gun”, IEEE Conference, China, 2008.
  • [12] P. Fang, F. Ding, and Q. Li, “Novel High-Response Electromagnetic Actuator for Electronic Engraving System”, IEEE Trans. Magn. 42 (3), 460–464 (2006).
  • [13] Y. Nakanishi, T. Honda, K. Kasamura, Y. Nakashima, K. Nakano, K. Kondo, and H. Higaki, “Bio-inspired shaft seal in coolant pump for electric vehicles”, IEEE International Conference on Renewable Energy Research and Applications (ICRERA), 2016.
  • [14] R.E. Clark, G.W. Jewell, S.J. Forrest, J. Rens, and J. Maerky, “Design Features for Enhancing the Performance of Electromagnetic Valve Actuation Systems”, IEEE Trans. Magn. 41 (3), 692–696 (2005).
  • [15] H. Hoshi, T. Shinshi, and S. Takatani, “Third-generation blood pumps with mechanical noncontact magnetic bearings”, Artif. Organs 30 (5), 324–338 (2006).
  • [16] J.F. Antaki, B. Paden, G. Burgreen, and N.J. Groom, “Blood pump having a magnetically suspended rotor”, US Patent, No: 6447266 B2, 2002.
  • [17] J. Albert, R. Banucu, W. Hafla, and W.M. Rucker, “Simulation based development of a valve actuator for alternative drives using BEM-FEM code”, IEEE Trans. Magn. 45 (3), 1744–1747 (2009).
  • [18] M.P. Goldowsky, “Magnetic suspension blood pump”, US Patent, No: 6527699 B1, 2003.
  • [19] D. Elata, “On the static and dynamic response of electrostatic actuators”, Bull. Pol. Ac.: Tech. 53 (4), 373–384 (2005).
  • [20] S.M. Yang and M.S. Huang, “Design and Implementation of a Magnetically Levitated Single- Axis Controlled Axial Blood Pump”, IEEE Trans. Ind. Electron. 56 (6), 2213–2219 (2009).
  • [21] M.B. Khamesee and E. Shameli, “Pole piece effect on improvement of magnetic controllability for noncontact micromanipulation”, IEEE Trans. Magn. 43 (2), 533–542 (2007).
  • [22] B. Ozdalyan and O. Dogan, “Effect of a semi electro-mechanical engine valve on performance and emissions in a single cylinder spark ignited engine”, J. Zhejiang Univ., Sci. A. 11 (2), 106–114 (2010).
Uwagi
PL
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-fe437d38-b650-4011-8030-1be2cd1a50a9
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