Predicting regenerative chatter in turning using operational modal analysis

Kim, Sooyong

23 April 2019

Chatter, unstable vibration during machining, damages the tool and workpiece. A proper selection of spindle speed and depth of cut are required to prevent chatter during machining. Such proper cutting conditions are usually determined using vibration models of the machining process. Nonetheless, uncertainties in modeling or changes in dynamics during the machining operations can lead to unstable machining vibrations, and chatter may arise even when stable cutting conditions are used in the process planning stage. As a result, online chatter monitoring systems are key to ensuring chatter-free machining operations. Although various chatter monitoring systems are described in the literature, most of the existing methods are suitable for detecting chatter after vibrations become unstable. In order to prevent poor surface finish resulting from chatter marks during the finishing stages of machining, a new monitoring system that is capable of predicting the occurrence of chatter while vibrations are still stable is required. In this thesis, a new approach for predicting the loss of stability during stable turning operations is developed. The new method is based on the identification of the dynamics of self-excited vibrations during turning operations using Operational Modal Analysis (OMA). The numerical simulations and experimental results presented in this thesis confirm the possibility of using Operational Modal Analysis as an online chatter prediction method during stable machining operations. / Graduate

Chatter

Regenerative chatter

Turning

Operational Modal Analysis

Chatter detection

Stability

Vibration

Unstable vibration

不連続ばね特性を利用した回転機械の不安定領域の除去

石田, 幸男, ISHIDA, Yukio, 劉, 軍, LIU, Jun

03 1900

No description available.

Unstable Vibration

Nonlinear Vibration

Vibration Control

Discontinuous Spring Characteristics

Roter Containing Liquid