Direct drive linear motors have good potential for use as next generation machine tool feed drives since they can increase machining rates and improve servo accuracy by eliminating gear related mechanical problems. To exploit the high speed and high response direct drives for machining, the servo control must achieve as high as possible tracking performance while at the same time establishing as much as possible the dynamic stiffness in order to maintain machining stability and reduce the effect of machining disturbance forces on the tool position. This paper investigates the use of optimal H∞ control to design for large stiffness and closed-loop tracking performance. Position feedback alone is first considered, with cutting force feedback later added to augment closed loop stiffness. Optimal position feedback is experimentally seen to achieve up to a 46 percent stiffness improvement over that achievable with proportional-derivative control. The addition of force feedback to the servo-loop resulted in a further 70 to 100 percent stiffness improvement over the position feedback alone values.
[1]
G. Zames,et al.
Feedback, minimax sensitivity, and optimal robustness
,
1983
.
[2]
H. E. Merritt.
Theory of Self-Excited Machine-Tool Chatter: Contribution to Machine-Tool Chatter Research—1
,
1965
.
[3]
Tsu-Chin Tsao,et al.
Stability of Turning Processes with Actively Controlled Linear Motor Feed Drives
,
1994
.
[4]
K. Srinivasan,et al.
Analysis and Design of Machine Tool Chatter Control Systems Using the Regeneration Spectrum
,
1978
.
[5]
Gene F. Franklin,et al.
Digital control of dynamic systems
,
1980
.
[6]
Bruce A. Francis,et al.
Feedback Control Theory
,
1992
.
[7]
Maciejowsk.
Multivariable Feedback Design
,
1989
.
[8]
M. Vidyasagar.
Control System Synthesis : A Factorization Approach
,
1988
.