Title :
PID control of laser surface hardening of steel
Author :
Hömberg, Dietmar ; Weiss, Wolf
Author_Institution :
Res. Group Nonlinear Optimization & Inverse Problems, Weierstrass Inst. for Appl. Anal. & Stochastics, Berlin
Abstract :
We discuss control strategies for the laser surface hardening of steel. The goal is to achieve a prescribed hardening depth avoiding surface melting. Our mathematical model consists of a system of ordinary differential equations (ODEs) for the phase volume fractions coupled with the heat equation. The system is solved semi-implicitely using the finite element method. To obtain a uniform hardening depth the first attempt is to use proportional integral differential (PID) control to achieve a constant temperature in the hot spot of the laser beam on the surface. However, the numerical results prove that this is not sufficient. We show that the best strategy is to control the temperature close to the lower boundary of the hardening zone. Then one can compute the optimal temperature in the hot spot of the beam and use it as the setpoint for the pyrometer control of the real process
Keywords :
differential equations; finite element analysis; laser hardening; steel industry; temperature control; three-term control; PID control; feedback control; finite element method; heat treatment; ordinary differential equations; phase volume fractions; proportional-integral-differential control; steel laser surface hardening; temperature control; Differential equations; Integral equations; Laser beams; Laser modes; Mathematical model; Optical control; Steel; Surface emitting lasers; Temperature control; Three-term control; Feedback control; heat conduction; heat treatment; laser material treatment; optimization; phase transitons; surface hardening;
Journal_Title :
Control Systems Technology, IEEE Transactions on
DOI :
10.1109/TCST.2006.879978
