Abstract
Machining is the traditional product shaping process by removing materials from a block of original materials. Practically, the machining process itself has not changed much in the last couple of centuries but the accessories around the process have improved significantly, like data logging features in modern computer numerically controlled machines. The machining process is a system, the components of which should be considered as independent units which work harmonously with other systems in the enterprise. In this chapter a systems approach is adopted to examine methods and techniques that can improve five key performance indicators of the machining system, i.e. sustainability, accuracy, efficiency, precision and reliability. In particular, High Speed Machining, tool breakage prevention, thin wall deflection, tool geometry and chatter monitoring are studied in relation to the five performance indicators, respectively. Application of these techniques has produced good machining outcomes showing strategic development direction leading to better performance of the machining system.
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Mo, J.P.T., Ding, S. (2019). Systems Engineering for Machining. In: Stjepandić, J., Wognum, N., J. C. Verhagen, W. (eds) Systems Engineering in Research and Industrial Practice. Springer, Cham. https://doi.org/10.1007/978-3-030-33312-6_11
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