Integrating PWM Amplifier with the Design of Mechatronic Systems for Energy-efficient Precision Motion
Integrating PWM Amplifier with the Design of Mechatronic Systems for Energy-efficient Precision Motion
カテゴリ: 論文誌(論文単位)
グループ名: 【D】産業応用部門(英文)
発行日: 2021/03/01
タイトル(英語): Integrating PWM Amplifier with the Design of Mechatronic Systems for Energy-efficient Precision Motion
著者名: Shingo Ito (Christian Doppler Laboratory for Precision Engineering for Automated In-Line Metrology, Automation and Control Institute (ACIN), TU Wien), Stefan Pirker (Automation and Control Institute (ACIN), TU Wien), Georg Schitter (Christian Doppler Labo
著者名(英語): Shingo Ito (Christian Doppler Laboratory for Precision Engineering for Automated In-Line Metrology, Automation and Control Institute (ACIN), TU Wien), Stefan Pirker (Automation and Control Institute (ACIN), TU Wien), Georg Schitter (Christian Doppler Labo
キーワード: nanopositioner,motion control,PWM amplifier,mechatronics
要約(英語): This paper proposes an integrated mechatronic system design to realize insensitivity to the current ripple of a switching current amplifier that drives electromagnetic actuators in high-precision motion systems. Switching current amplifiers are desirable for high energy efficiency with a concern that the resulting current ripple impairs the achievable positioning resolution. To eliminate this concern, a motion system is developed based on a flexure-guided voice coil actuator, which is driven by a switching current amplifier. A resonator is mounted onto the mover, creating an antiresonance at 11.3kHz. This antiresonance is used to absorb the mover vibrations stemming from the current ripple. For this purpose, pulse width modulation (PWM) is used in the current amplifier such that the switching frequency is accurately tuned to the antiresonant frequency. Experiments reveal that the developed switching current amplifier reduces the power loss by a factor of 5.6 in comparison with a linear current amplifier. However, the switching current amplifier creates a current ripple of 0.77A and oscillates the mover, resulting in a parasitic vibration of 5.1nm. The use of the antiresonance successfully eliminates this vibration, decreasing the positioning error by a factor of three to 1.6nm.
本誌掲載ページ: 134-141 p
原稿種別: 論文/英語
電子版へのリンク: https://www.jstage.jst.go.jp/article/ieejjia/10/2/10_20004386/_article/-char/ja/
受取状況を読み込めませんでした
