Reduction of DC bus capacitor ripple current with PAM/PWM converter

Electrolytic capacitors are used in nearly all adjustable speed drives (ASD) and they are one of the components most prone to failure. The main failure mechanisms include the loss of electrolyte through outgassing and chemical changes to the oxide layer. All the degradation mechanisms are exacerbate...

Full description

Saved in:
Bibliographic Details
Main Authors: Kieferndorf, F.D., Forster, M., Lipo, T.A.
Format: Conference Proceeding
Language:English
Subjects:
Capacitors
Chemicals
Degradation
Failure analysis
Frequency
Heating
Paramagnetic resonance
Pulse width modulation
Pulse width modulation converters
Variable speed drives
Online Access:Request full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Electrolytic capacitors are used in nearly all adjustable speed drives (ASD) and they are one of the components most prone to failure. The main failure mechanisms include the loss of electrolyte through outgassing and chemical changes to the oxide layer. All the degradation mechanisms are exacerbated by ripple current heating. Since the equivalent series resistance (ESR) of electrolytic capacitors is a very strong function of frequency, it must be properly modeled to accurately calculate the power loss. In this paper, a method to reduce the ripple current in a constant Volts/Hertz (V/f) pulse amplitude modulation (PAM/PWM) converter driving an induction motor is investigated. The DC bus voltage amplitude is reduced in proportion to speed by a buck or current source rectifier (CSR) and the PWM modulation index is increased to achieve a reduced ripple current below base speed. It is shown that this mode of operation can lead to a significant reduction in capacitor power loss leading to increased capacitor lifetime or decreased capacitor size. The capacitor heating is analyzed using numerical and analytical techniques. Experimental results are provided to verify the analytical results.
ISSN:0197-2618
2576-702X
DOI:10.1109/IAS.2002.1042777