Journal of the Korean Society for Precision Engineering

Techniques for Tool Life Prediction and Autonomous Tool Change Using Real-time Process Monitoring Data: Seong Hun Ha, Min-Suk Park, Hoon-Hee Lee; J. Korean Soc. Precis. Eng. 2025;42(11):949-958.
Published online November 1, 2025; DOI: https://doi.org/10.7736/JKSPE.025.077

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Materials such as titanium alloys, nickel alloys, and stainless steels are difficult to machine due to low thermal conductivity, work hardening, and built-up edge formation, which accelerate tool wear. Frequent tool changes are required, often relying on operator experience, leading to inefficient tool use. While modern machine tools include intelligent tool replacement systems, many legacy machines remain in service, creating a need for practical alternatives. This study proposes a method to autonomously determine tool replacement timing by monitoring machining process signals in real time, enabling automatic tool changes even on conventional machines. Tool wear is evaluated using current and vibration sensors, with the replacement threshold estimated from the maximum current observed in an initial user-defined interval. When real-time signals exceed this threshold, the system updates controller variables to trigger tool changes. Results show vibration data are more sensitive to wear, whereas current data provide greater stability. These findings indicate that a hybrid strategy combining both sensors can enhance accuracy and reliability of tool change decisions, improving machining efficiency for difficult-to-cut materials.

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Robotic Abrasive Waterjet System for Cutting of Carbon Fiber Reinforced Plastic (CFRP): Jong Min Ko, Dong Hun Kim, Sung Ryul Kim, Seok Woo Lee; J. Korean Soc. Precis. Eng. 2019;36(1):37-43.
Published online January 1, 2019; DOI: https://doi.org/10.7736/KSPE.2019.36.1.37

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Carbon Fiber Reinforced Plastic (CFRP) materials which are superlight in weight and have high strength have recently been applied in the automobile and aerospace industry, etc. to achieve high fuel efficiency. CFRP is termed as ‘difficult to cut material’ due to its unique material properties. It’s considered to be highly sensitive in processing due to its laminated structure which would pose some challenges such as delamination, Pull-out, Burr and Uncut. Due to this, it’s maintenance and treatment costs are high. There are also limitations in the conventional Gantry Machine in 3D shape cutting of CFRP materials. To counter this challenge, a robotic abrasive waterjet system with the following features has been developed and installed on site; a high-pressure pump, monitoring system and a catcher for 3D Shape cutting., It’s performance has been successfully proved. Based on the result, we discovered that a 6 axes robot could execute 3D shape cutting of car hood due to its high movement flexibility. In the future it is projected to fulfill more kinds of CFRP materials cutting test on many car brands.

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A Study on the Effect of Gas Flow Rate and Power in Plasma Assisted Machining: Choon-Man Lee, Young Hun Lee; J. Korean Soc. Precis. Eng. 2018;35(6):603-608.
Published online June 1, 2018; DOI: https://doi.org/10.7736/KSPE.2018.35.6.603

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Recently, demands for difficult-to-cut materials with high mechanical properties have been increased in various industrial fields, such as the aerospace and automobile industries. Because difficult-to-cut materials have high mechanical properties, it is difficult to achieve conventional machining. Therefore, many researchers have been studying the machining methods for difficult-to-cut materials. One of the many studies of how to cut difficult-to-cut materials involves plasma-assisted machining (PAM) is a machining method that softens difficult-to-cut materials by a plasma heat source to remove by the cutting tool. PAM has various machining conditions, and it is very important to determine the optimal conditions to improve machining accuracy and efficiency. In this study, the cutting force was analyzed by using a gas flow rate and power which are the easiest to control in the PAM system. The results of this study can be applied to PAM data under optimum conditions.

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A Study on Optimal Machining Conditions and Energy Efficiency in Plasma Assisted Machining of Ti-6Al-4V
Young-Hun Lee, Choon-Man Lee
Materials.2019; 12(16): 2590. CrossRef

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Improvement of the Quality of Cryogenic Machining by Stabilization of Liquid Nitrogen Jet Pressure: Myeong Gu Gang, Byung-Kwon Min, Tae-Gon Kim, Seok-Woo Lee; J. Korean Soc. Precis. Eng. 2017;34(4):247-251.
Published online April 1, 2017; DOI: https://doi.org/10.7736/KSPE.2017.34.4.247

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Titanium alloy has been widely used in the aerospace industry because of its high strength and good corrosion resistance. During cutting, the low thermal conductivity and high chemical reactivity of titanium generate a high cutting temperature and accelerates tool wear. To improve cutting tool life, cryogenic machining by using a liquid nitrogen (LN2) jet is suggested. In cryogenic jet cooling, evaporation of LN2 in the tank and transfer tube could cause pressure fluctuation and change the cooling rate. In this work, cooling uniformity is investigated in terms of liquid nitrogen jet pressure in cryogenic jet cooling during titanium alloy turning. Fluctuation of jet spraying pressure causes tool temperature to fluctuate. It is possible to suppress the fluctuation of the jet pressure and improve cooling by using a phase separator. Measuring tool temperature shows that consistent LN2 jet pressure improves cryogenic cooling uniformity.