Simulation of Active Suppression of Boring Bar Vibrations by Means of Boring Bar’s ”1-D” Finite Element Model

Article

Simulation of Active Suppression of Boring Bar Vibrations by Means of Boring Bar’s ”1-D” Finite Element Model

Tatiana Smirnova,Henrik Åkesson,Lars Håkansson,Ingvar Claesson,Thomas L Lagö-2009-01-01

0

TL;DRAbstract

In metal cutting active control is one method that may be used to attenuate vibration of a boring bar during an internal turning operation. It is based on the utilization of an active boring bar with an embedded piezoceramic actuator and a suitable controller, etc. In this case, the primary boring bar vibrations originating from the material deformation process may be suppressed with secondary anti- vibrations induced by the actuator. The design of an active boring bar is usually a tedious and costly procedure, which involves decision making concerning the selection of the actuator characteristics, its position inside the boring bar as well as production and testing of several active boring bar prototypes. Therefore accurate mathematical modeling of the active control system; including the active boring and controller, etc. is of importance. In this paper a simple “1-D” finite element model of a boring bar is utilized to simulate its dynamic response and as controller an adaptive digit

Chat with Paper

AI Agents for this Paper

In metal cutting active control is one method that may be used to attenuate vibration of a boring bar during an internal turning operation. It is based on the utilization of an active boring bar with an embedded piezoceramic actuator and a suitable controller, etc. In this case, the primary boring bar vibrations originating from the material deformation process may be suppressed with secondary anti- vibrations induced by the actuator. The design of an active boring bar is usually a tedious and costly procedure, which involves decision making concerning the selection of the actuator characteristics, its position inside the boring bar as well as production and testing of several active boring bar prototypes. Therefore accurate mathematical modeling of the active control system; including the active boring and controller, etc. is of importance. In this paper a simple “1-D” finite element model of a boring bar is utilized to simulate its dynamic response and as controller an adaptive digit

Keywords

Bar (unit)ActuatorFinite element methodController (irrigation)VibrationEngineeringActive vibration controlProcess (computing)

Chat

Click to start Chat