ENG> Vol.6 No.9, August 2014

A New Type of a Magnetic Plane Motor Coupled Mechanical Vibration with Electromagnetic Force

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This paper proposes a new magnetic plane motor capable of rotation by the resonance energy of double-cantilever beam model excited by an electromagnetic force. This magnetic plane motor has two double-cantilever models, and the rotational direction is able to change by changing of the vibration mode. Basic characteristics of a prototype for the magnetic plane motor, such as rotational speed, output torque and efficiency were determined experimentally. Experimental results demonstrated that the rotational speed of 8.1 rpm was obtained with output torque of 0.07 Ncm for the magnetic plane motor having double-cantilever model. The output torque characteristics of the magnetic plane motor with two double-cantilever models improved 200 percent compared with double-cantilever model.

Cite this paper

Yaguchi, H. , Iino, K. and Eguchi, T. (2014) A New Type of a Magnetic Plane Motor Coupled Mechanical Vibration with Electromagnetic Force. Engineering, 6, 491-499. doi: 10.4236/eng.2014.69051.


[1] Yamamoto, A., Nishijima, T. and Higuchi, T. (2005) High-Power Double-Sided Drive Type Electrostatic Motor with Stacked-Film Structure. The Japan Society for Precision Engineering, 71, 1245-1249.
[2] Kurosawa, M. (2003) Surface Acoustic Wave Linear Motor. Advanced Robotics, 21, 736-739.
[3] Niino, T., Higuchi, T. and Egawa, T. (1997) AC Dual Excitation Multiphase Electrostatic Drive. Advanced Robotics, 15, 1147-1155.
[4] Fan, L.S., Tai, Y.C. and Muller, R.S. (1988) IC-Processed Electrostatic Micro-Motors. Proceedings of IEEE International Electron Devices Meeting, San Francisco, 11 December 1988, 666-669.
[5] Jacobsen, S.C., Price, R.H. and Wood, J.E. (1989) The Wobble Motor: An Electrostatic, Planetary-Armature, Miroactuator. Proceedings of IEEE Micro Electro Mechanical Systems Workshop ’89, Solt Lake City, 20 February 1989, 17-24.
[6] Yokota, S., Kuwajima, S., Kondo, Y. and Edamura, K. (2004) Realization of a Higher Integrated Multi-Layered DP-RE Type ECF Micro-Motor. Transactions of Japan Society of Mechanical Engineers, 70, 1463-1469.
[7] Sharma, S.V., Nayak, M.M. and Dinesh, N.S. (2008) Shape Memory Alloy Based Motor. Sadhana, 33, 699-712.
[8] Reynaerts, D. and Brussel, H.V. (1998) Design Aspects of Shape Memory Actuators. Mechatronics, 8, 635-656.
[9] Vranish, J.M., Naik, D.P., Restorff, J.B. and Teter, J.P. (1991) Magnetostrictive Direct Drive Rotary Motor Development. IEEE Transaction on Magnetics, 27, 5355-5357.
[10] Claeyssen, F., Lhermet, N., Letty, R. and Bouchilloux, P. (1996) Design and Construction of a Resonant Magnetostrictive Motor. IEEE Transaction on Magnetics, 32, 4749-4751.
[11] Pack, I.S., Oh, O.K., Pack, Y.W. and Wereley, N.M. (2013) A Nobel Concept and Proof of Magnetostrictive Motor. IEEE Transaction on Magnetics, 49, 3379-3382.
[12] Maruno, T., Honda, T. and Yamasaki, J. (2000) Considerations on Increase in the Torque of an Electromagnetic Friction-Drive Micro-Motor. Transaction IEE of Japan, 120-A, 289-294.

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