Disturbance compensation for DC motor mechanism low speed regulation: A feedforward and feedback implementation

Author

Wu, Wei

Author_Institution

Lexmark Int., Lexington, KY, USA

fYear

2011

fDate

12-15 Dec. 2011

Firstpage

1614

Lastpage

1619

Abstract

The disturbance torque in the DC motor drive of a scan unit was calculated using the known voltage input to the motor and the measured motor speed response. The cogging torque of the motor and the friction in the mechanism can then be estimated from the calculated disturbance torque. The calculated disturbance torque was further utilized to reduce the speed ripples in speed regulation applications. A combined feedforward and feedback configuration was used to reject the disturbance based on both the off-line calculated disturbance and the on-line estimated disturbance. This scheme was successfully implemented in commercial scan devices. Data obtained under real operating conditions demonstrated the effectiveness and robustness of this disturbance compensation scheme.

Keywords

DC motor drives; angular velocity control; compensation; feedback; feedforward; machine control; DC motor drive; DC motor mechanism low speed regulation; cogging torque; commercial scan devices; disturbance compensation scheme; disturbance torque; feedback implementation; feedforward implementation; motor speed response; offline calculated disturbance; online estimated disturbance; speed ripples reduction; voltage input; DC motors; Feedforward neural networks; Forging; Friction; Steady-state; Torque; Voltage control;

fLanguage

English

Publisher

ieee

Conference_Titel

Decision and Control and European Control Conference (CDC-ECC), 2011 50th IEEE Conference on

Conference_Location

Orlando, FL

ISSN

0743-1546

Print_ISBN

978-1-61284-800-6

Electronic_ISBN

0743-1546

Type

conf

DOI

10.1109/CDC.2011.6160408

Filename

6160408