Braking Scheme for Vector-Controlled Induction Motor Drives Equipped With Diode Rectifier Without Braking Resistor

Author

Hinkkanen, Marko ; Luomi, Jorma

Author_Institution

Power Electron. Lab., Helsinki Univ. of Technol., Espoo

Volume

42

Issue

5

fYear

2006

Firstpage

1257

Lastpage

1263

Abstract

This paper deals with sensorless vector control of pulsewidth-modulated inverter-fed induction motor drives equipped with a three-phase diode rectifier. An electronically controlled braking resistor across the dc link is not used. Instead, the power regenerated during braking is dissipated in the motor while a dc-link overvoltage controller limits the braking torque. Losses in the motor are increased by an optimum flux-braking controller, maximizing either the stator voltage or the stator current depending on the speed. Below the rated speed, the braking times are comparable to those achieved using a braking resistor. The proposed braking scheme is very simple and causes no additional torque ripple. Experimental results obtained using a 2.2-kW induction motor drive show that the proposed scheme works well

Keywords

braking; induction motor drives; machine vector control; optimal control; overvoltage; rectifying circuits; stators; torque; 2.2 kW; DC-link overvoltage controller; braking resistor; braking scheme; induction motor drive; optimum flux-braking controller; pulse width modulated inverter-fed motor; sensorless vector control; stators; three-phase diode rectifier; Diodes; Induction motor drives; Machine vector control; Pulse inverters; Rectifiers; Resistors; Sensorless control; Stators; Torque control; Voltage control; DC-link capacitor; field weakening; flux braking; overvoltage;

fLanguage

English

Journal_Title

Industry Applications, IEEE Transactions on

Publisher

ieee

ISSN

0093-9994

Type

jour

DOI

10.1109/TIA.2006.880852

Filename

1703719