A new method of damping harmonic resonance at the DC link in a large-capacity rectifier-inverter system

Toshihiko Tanaka, Shinji Fujikawa, Shigeyuki Funabiki

Research output: Contribution to journalArticle

1 Citation (Scopus)

Abstract

This paper proposes a new method of damping harmonic resonance in the DC link of a large-capacity rectifier-inverter system, such as in rapid-transit railways. A voltage-source PWM converter is connected in series to the DC capacitor of the rectifier through a matching transformer, acting as a damping resistor to the DC capacitor current. No filters are needed to extract harmonic components from the DC capacitor current. This results in a quick response and highly stable damping. The relationship between the control gain of the PWM converter and the required rating is theoretically discussed. We show that the required rating is less than one-thousandth of that previously proposed. In particular, regenerating the power consumed by the PWM converter is very important because of the large power in practical systems. Normally, an additional PWM inverter is connected to the DC bus of the PWM converter to regenerate the consumed power. The additional inverter regenerates the DC power to the AC source through a transformer. This method, however, makes the damping circuit complex, thus the proposed method for the DC-link harmonic resonance is less practicable. In this paper, a simple and novel scheme that utilizes the DC-link voltage of the rectifier as a DC source for the PWM converter is proposed. The excellent practicability of the proposed damping method with the novel regenerating scheme is confirmed using digital computer simulation.

Original languageEnglish
Pages (from-to)53-62
Number of pages10
JournalElectrical Engineering in Japan (English translation of Denki Gakkai Ronbunshi)
Volume144
Issue number2
DOIs
Publication statusPublished - Jul 30 2003

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Keywords

  • Highly stable and quick response
  • Large-capacity inverter system
  • Regeneration of the consumed active power
  • Resonance damping at the main DC circuit

ASJC Scopus subject areas

  • Energy Engineering and Power Technology
  • Electrical and Electronic Engineering

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