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Study on the combination of virtual machine tools and wearable vibration devices for operators experiencing cutting forces in the milling process
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Study on the combination of virtual machine tools and wearable vibration devices for operators experiencing cutting forces in the milling process
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Journal Article
Study on the combination of virtual machine tools and wearable vibration devices for operators experiencing cutting forces in the milling process
2024
Overview
The primary goal of this study is to develop a wearable system for providing CNC machine operators with visual and tactile perception of triaxial cutting forces, thereby assisting operators in industrial environments to enhance work efficiency and prevent mechanical failures. To achieve this goal, we successfully integrated a virtual machining tool simulator with the remote-control wearable system (RCWS). Using the ‘King Path’ milling parameters, we employed the simulation software developed by the AIM-HI team to calculate static and dynamic cutting forces, converting this data into vibrational commands for the RCWS to generate corresponding tactile feedback. Furthermore, we conducted extensive experiments, testing various data conversion methods, including three sampling techniques and two data compression strategies, aiming to provide accurate tactile feedback related to cutting forces under different operating conditions.
