Prediction of chatter stability for enhanced productivity in parallel orthogonal turn-milling

To increase productivity and the material removal rate, an increasing number of factories have been employing multiple tools for simultaneous cutting. Among these tools is parallel orthogonal turn-milling, which is an important parallel-processing method. However, a dynamic interaction occurs during...

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Veröffentlicht in:	International journal of advanced manufacturing technology 2020-10, Vol.110 (9-10), p.2377-2388
Hauptverfasser:	Zheng, Zhongpeng, Jin, Xin, Sun, Yewang, Zhang, Zhijing, Sun, Hongchang, Li, Qiming
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Sprache:	eng
Schlagworte:	CAE) and Design Chatter Computer-Aided Engineering (CAD Engineering Extreme values Industrial and Production Engineering Industrial plants Machine tools Material removal rate (machining) Mechanical Engineering Media Management Milling machines Original Article Parameters Productivity Stability Vibration Waviness
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container_end_page	2388
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container_title	International journal of advanced manufacturing technology
container_volume	110
creator	Zheng, Zhongpeng Jin, Xin Sun, Yewang Zhang, Zhijing Sun, Hongchang Li, Qiming
description	To increase productivity and the material removal rate, an increasing number of factories have been employing multiple tools for simultaneous cutting. Among these tools is parallel orthogonal turn-milling, which is an important parallel-processing method. However, a dynamic interaction occurs during the cutting processes due to the waviness induced on the shared cutting surface and the dynamic coupling through the machine structure, creating machining vibrations, or chatter, which affect the quality of the machined surface. Therefore, to reduce or avoid the vibration problem during the cutting process, chatter stability of parallel orthogonal turn-milling was examined in this study. Initially, a chatter mechanism model of parallel orthogonal turn-milling was designed, and the limit-critical axial depth of the cut formula was obtained. Next, the model parameters of the machine tool were obtained based on the hammer test method. A parallel orthogonal turn-milling stability lobe diagram (SLD) with tool tip runout was constructed. Finally, the experimental results were verified on a high-efficiency turn-milling machine tool. The results showed that chatter can be predicted for parallel orthogonal turn-milling and an SLD can provide a reference for the selection of machining parameters. In addition, the SLD can also guide the formulation of processing technology specifications. Our results are extremely significant for ongoing research in the field of machining methods.
doi_str_mv	10.1007/s00170-020-06015-0
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title	Prediction of chatter stability for enhanced productivity in parallel orthogonal turn-milling
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