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American Journal of Electrical and Electronic Engineering. 2019, 7(2), 26-33
DOI: 10.12691/AJEEE-7-2-1
Original Research

How Choosing Precisely the Secondary Length of an Electromagnetic Catapult Could Prevent Vibrations

Jean-Pierre Pascal1,

1Ex. Institut de Recherche des Transports (French Ministry of Transportation) 75007 Paris

Pub. Date: June 21, 2019
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Cite this paper

Jean-Pierre Pascal. How Choosing Precisely the Secondary Length of an Electromagnetic Catapult Could Prevent Vibrations. American Journal of Electrical and Electronic Engineering. 2019; 7(2):26-33. doi: 10.12691/AJEEE-7-2-1

Abstract

Dealing with electromagnetic catapults, using a simplified numerical approach discretizing the secondary into small parallelepipeds, we demonstrate that short secondary linear induction motors usually produce superimposed periodic force modulations (large ripple). The paper begins with analyzing force modulations in the simple case of an aluminum sheet moving at constant speed inside a stationary sinusoidal magnetic field. The second part extends the analysis to the motor case when both the magnetic field and the sheet are moving at different speeds with an algorithm controlling accelerations through the motor slip. The third part presents an application of the calculation method simulating vibrations of a suspended mass elastically linked to a launching aircraft. The paper concludes that the linear motor thrust is modulated at a variable frequency which depends upon the motor control strategy. The frequency of this modulation is the ratio of the speed difference, between the field velocity minus the motor velocity, divided by the motor pole pitch. The thrust modulation could induce strong vibrations on heavy parts, such as fuel tanks, suspended onto aircraft wings, when meeting their resonance frequency. It is demonstrated how this modulation is avoided completely when the secondary motor length is an exact multiple of the stator pole pitch.

Keywords

electromagnetic launching, induction motors, vibration control, resonance, catapults

Copyright

Creative CommonsThis work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

References

[1]  Westinghouse ‘Electropult’, 1946, in: “A History of Linear Electric Motors”, E. R. Laithwaite, pp.46-47, Macmillan, London, 1987
 
[2]  J. P. Pascal, «Rapport des essais du prototype du moteur linéaire à induit en U», Rapport de Recherche IRT, Paris, 1976, ed. IFSTTAR F 77447 Marne la Vallée, France https://filez.ifsttar.fr/jl3tds.
 
[3]  J. L. Giovachini, « Evaluation par la Similitude des Systèmes de propulsion et freinage électromagnétiques », Revue Générale des Chemins de Fer, Dunod, Paris, juin 1977.
 
[4]  EMALS, Kaman Electromagnetics corp., in: “Linear motor outperforms steam-piston catapults”, Automation & Motion Control, Oct. 23 1995 (www.designnews.com/automation-motion-control).
 
[5]  S. Gallagher, “Navy’s newest carrier has problems getting planes up”, ars Technica, 6/15/2017 (https://arstechnica.com/tech-policy/2017/06/uss-ford-is-ready-for-service-except-for-the-plane-launching-part/).
 
[6]  H. W. Beaty & J. L. Kirtley Jr., “Electric Motor Handbook”, Mc Graw Hill, NY, 1998.
 
[7]  G. Seguier & F. Notelet, « Electromagnétique Industrielle », 3rd ed. Lavoisier, Paris, 2006.
 
[8]  S. Yamamura, “Theory of linear induction Motors”, John Whiley & Sons, 1972.
 
[9]  E. R. Laithwaite, “Adapting a linear induction motor for the acceleration of large masses to high velocities”, IEE Proceedings, July 1995.
 
[10]  A.H. Selcuk, Hasan Kurum, "Investigation of End Effects in Linear Induction Motors by Using the Finite-Element Method", IEEE Trans. on Magn., vol. 44, no. 7, pp. 1791-1795, Jul 2008.
 
[11]  G. Kang, K. Nam, "Field-Oriented Control Scheme for Linear Induction Motor with the End-Effect", IEE Proc. on Elect. Pwr. Appl., vol. 152, no. 6, pp. 1565-1572, Nov 2005.
 
[12]  A. Majumdar & T. K. Bhattacharya, “Field simulation of linear induction machines illustrating the peak to peak ripple in propulsive force and its dependence on the length of the primary”, 2017 International Conference on Power and Embedded Drive Control (ICPEDC), Chennai, India, Publisher: IEEE
 
[13]  R. Feynman, “The Feynman Lectures on Physics”, California Institute of Technology, 2010 ed. (www.BasicFeynman.com).
 
[14]  A. Johnson, “High speed Linear Induction Motor Efficiency Optimization”, Dissertation Thesis, MIT, June 2005.