Title :
Mechanics of composite rotating machines for pulsed power applications
Author :
Tzeng, Jerome T.
Author_Institution :
US Army Res. Lab., Aberdeen Proving Ground, MD, USA
fDate :
1/1/2001 12:00:00 AM
Abstract :
Composite rotating machines are currently used in pulsed power generators, which convert kinetic energy stored in the rotor into electrical current. The rotor could be constructed from a series of concentric press-fitted field coils and composite cylinders. Radial compressive stresses are “built-in” to compensate for the centripetal force resulting from high-speed rotation, and to enhance the shear and radial strength at the interfaces. This paper discusses mechanical concerns at the interfaces of the rotor including press-fit, rotor dynamics, preload relaxation, and a potential rotor failure mechanism. Models and analyzes were then developed for the rotor structural optimization based on these critical parameters, in particular, the concerns about prestress loss attributed to the creep and stress relaxation in the composite materials. Stresses induced by centripetal and magnetic forces might initiate delamination at the interfaces that could eventually propagate causing rotor failure
Keywords :
composite materials; electric machines; electromagnetic forces; electromagnetic launchers; flywheels; machine theory; pulsed power supplies; rotors; EM launchers; centripetal force compensation; composite cylinders; composite rotating machines mechanics; concentric press-fitted field coils; interface delamination; kinetic energy conversion; magnetic forces; preload relaxation; press-fit; pulsed power applications; radial compressive stresses; radial strength enhancement; rotor dynamics; rotor failure mechanism; shear enhancement; Coils; Compressive stress; Creep; Failure analysis; Kinetic energy; Magnetic analysis; Power generation; Pulse generation; Rotating machines; Rotors;
Journal_Title :
Magnetics, IEEE Transactions on
