Journal of Engineering and Applied Sciences

Year: 2019
Volume: 14
Issue: 16
Page No. 5670 - 5677

Mathematical Modeling of Magnetic Fields of Actuators with Hape Memory Effect by a Combined Finite Element Method and Fundamental Solutions with Point Magnetic Moments

Authors : A.L. Balaban, Yu. A. Bakhvalov and V.V. Grechikhin

References

Asua, E., J. Feuchtwanger, A.G. Arribas, V. Etxebarria and I. Orue et al., 2009. Ferromagnetic shape memory alloy actuator for micro-and nano-positioning. Sens. Lett., 7: 348-350.
Direct Link  |  

Bahvalov, Y.A., N.N. Gorbatenko, V.V. Grechikhin, 2014. Inverse Problems of Electrical Equipment. Magazine Russian Electromechanics, Novocherkassk, Russia, Pages: 211.

Bakhvalov, Y.A., V.V. Grechikhin and A.L. Yufanova, 2015. Mathematical modeling of magnetic fields by the combined method of fundamental solutions and finite elements in problems of diagnosis of systems with shape memory effect. Russ. Electromechanics, 6: 22-31.

Bakhvalov, Y.A., V.V. Grechikhin and A.L. Yufanova, 2016. The method of fundamental solutions using the vector magnetic dipoles for calculation of the magnetic fields in the diagnostic problems based on full-scale modelling experiment. Mater. Sci. Eng., 127: 1-10.
CrossRef  |  Direct Link  |  

Cao, C. and Q.H. Qin, 2015. Hybrid fundamental solution based finite element method: Theory and applications. Adv. Math. Phys., 2015: 1-38.
CrossRef  |  Direct Link  |  

Chen, C.S., A. Karageorghis and Y.S. Smyrlis, 2008. The Method of Fundamental Solutions: A Meshless Method. Dynamic Publishers, Atlanta, Georgia, ISBN:1890888-04-4, Pages: 329.

Gorbatenko, N.I., V.V. Grechikhin and D.V. Shaikhutdinov, 2015. Measuring and actuating devices based on shape memory ferromagnets. Met. Sci. Heat Treat., 56: 609-613.

Hubert, A., N. Calchand, Y.L. Gorrec and J.Y. Gauthier, 2012. Magnetic shape memory alloys as smart materials for micro-positioning devices. Adv. Electromagnet., 1: 75-84.
Direct Link  |  

Riccardi, L., D. Naso, H. Janocha and B. Turchiano, 2012. A precise positioning actuator based on feedback-controlled magnetic shape memory alloys. Mechatron., 22: 568-576.
CrossRef  |  Direct Link  |  

Shimoni, K., 1964. Theoretical Electrical Engineering. Mir Publishers, Moscow, Russia, Pages: 775.

Tozoni, O.V. and I.D. Maergoyz, 1974. Analysis of Three-Dimensional Electromagnetic Fields. Tekhnika Publisher, Kiew, Ukraine, Pages: 352.

Vasil’ev, A.N., V.D. Buchel’nikov, T. Takagi, V.V. Khovailo and E.I. Estrin, 2003. Shape memory ferromagnets. Phy.Usp., 46: 559-588.
CrossRef  |  Direct Link  |  

Wang, F.X., W.J. Li, Q.X. Zhang, X.J. Wu and C. Ge, 2005. Design and control of linear actuators made by magnetically controlled shape memory alloy. Proceedings of the IEEE International Conference on Mechatronics (ICM'05), July10-12, 2005, IEEE, Taipei, Taiwan, ISBN:0-7803-8998-0, pp: 583-586.

Wilson, S.A., R.P. Jourdain, Q. Zhang, R.A. Dorey and C.R. Bowen et al., 2007. New materials for micro-scale sensors and actuators: An engineering review. Mater. Sci. Eng. R. Rep., 56: 1-129.
Direct Link  |  

Yavorskiy, B.M. and A.A. Detlaf, 1974. Handbook of Physics for Engineers and University Students. Nauka Publishers, Moscow, Russia, Pages: 943.

Design and power by Medwell Web Development Team. © Medwell Publishing 2022 All Rights Reserved