Title :
In-process control in thermal rapid prototyping
Author :
Doumanidis, Charalabos C.
Author_Institution :
Dept. of Mech. Eng., Tufts Univ., Medford, MA, USA
fDate :
8/1/1997 12:00:00 AM
Abstract :
This article addresses thermal feedback control of distributed-parameter, dynamic nonlinear heat transfer phenomena involved in rapid prototyping processes. These mechanisms are captured in a numerical simulation of the thermal field generated during such operations. For the design of a multivariable controller, a linearized state-space model of lumped temperatures and heat inputs on a grid is established, and its parameters are identified in-process. The controller gains are adapted in real time through optimization of the closed-loop pole placement by a simplex method, minimizing the distance of the actual from the desired system eigenvalues. This control strategy is validated both by simulation and in the laboratory, where temperature feedback from an infrared camera is used to modulate the power and motion of a plasma-arc torch in laminated object manufacturing
Keywords :
adaptive control; closed loop systems; control system synthesis; distributed parameter systems; eigenvalues and eigenfunctions; feedback; heat transfer; linearisation techniques; minimisation; multivariable control systems; nonlinear control systems; parameter estimation; pole assignment; process control; state-space methods; thermal variables control; closed-loop pole placement optimization; controller gain adaptation; distributed-parameter dynamic nonlinear heat transfer phenomena; eigenvalues; heat inputs; in-process control; infrared camera; laminated object manufacturing; linearized state-space model; lumped temperatures; minimization; motion modulation; multivariable controller design; numerical simulation; parameter identification; plasma-arc torch; power modulation; simplex method; temperature feedback; thermal feedback control; thermal field; thermal rapid prototyping; Control systems; Feedback control; Heat transfer; Numerical simulation; Plasma simulation; Plasma temperature; Prototypes; Rapid thermal processing; Real time systems; Temperature control;
Journal_Title :
Control Systems, IEEE
