DocumentCode
1460998
Title
Thermal and mechanical stress in induction coilguns
Author
Becherini, G. ; Raugi, M. ; Tellini, A.
Author_Institution
Gruppo Elettrotecnica Naval Acad., Livorno, Italy
Volume
35
Issue
1
fYear
1999
fDate
1/1/1999 12:00:00 AM
Firstpage
130
Lastpage
135
Abstract
The aim of this paper is to define a procedure for the design of induction coilguns in order to obtain thermal and mechanical stress that do not exceed the allowed values in the sleeve. The magnetic vector potential is determined considering a cylindrical sheet current model both for the barrel and the sleeve and solving the related modified Bessel equation. Then the flux, the current density and the propulsive force for each section are determined. By considering the constraints due to mechanical and thermal stress, the maximum muzzle velocity for a one-section launcher is determined. Supposing that the muzzle velocities in the first and in the last section are established, and assuming that all sections, from the second to the last, work with the same mean slip and the same relative velocity, the number of sections and their length are determined. Moreover the surface current density in the barrel is calculated. The design criterion is compared with other criteria, and then used to design an 8 km/s muzzle velocity launcher
Keywords
Bessel functions; current density; electromagnetic induction; electromagnetic launchers; stress analysis; thermal analysis; thermal stresses; 8 km/s; current density; cylindrical sheet current model; induction coilguns; magnetic vector potential; maximum muzzle velocity; mechanical stress; modified Bessel equation; one-section launcher; propulsive force; surface current density; thermal stress; Capacitors; Coilguns; Current density; Equations; Frequency; Induction motors; Magnetic flux; Occupational stress; Projectiles; Thermal stresses;
fLanguage
English
Journal_Title
Magnetics, IEEE Transactions on
Publisher
ieee
ISSN
0018-9464
Type
jour
DOI
10.1109/20.738390
Filename
738390
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