Title :
Fracture identification and prevention of a high-speed optical disk with a crack
Author :
Chung, Jintai ; Kim, Wonsuk
Author_Institution :
Dept. of Mech. Eng., Hanyang Univ., Ansan, South Korea
fDate :
5/1/2002 12:00:00 AM
Abstract :
A fracture mechanism of an optical disk with a crack is identified and methods to prevent the disk fracture are proposed when the disk has a high spinning speed. Equations of motion for a flexible spinning disk with angular acceleration are discretized by the Galerkin approximate method and then the discretized equations are solved by the generalized-α time integration method. With the computed stress distributions, the maximum stress on a crack tip is obtained by using a commercial finite element analysis code. The critical crack length is then determined as a fracture criterion of the disk based on the maximum stress criterion. Furthermore, the fracture phenomenon is verified experimentally. The analysis and experiment show that fracture occurs at a crack on the inner circumference. In order to prevent the disk fracture, methods to reinforce the clamping area are suggested
Keywords :
Galerkin method; crack-edge stress field analysis; fatigue; finite element analysis; integration; optical disc storage; Galerkin approximate method; angular acceleration; clamping area reinforcement; crack tip; critical crack length; discretized equations; equations of motion; finite element analysis code; flexible spinning disk; fracture mechanism; generalized-α time integration; inner circumference; maximum stress criterion; optical disk; stress distributions; Acceleration; Disk drives; Distributed computing; Equations; High speed optical techniques; Mechanical engineering; Moment methods; Nonlinear optics; Spinning; Stress;
Journal_Title :
Consumer Electronics, IEEE Transactions on
DOI :
10.1109/TCE.2002.1010129
