Investigations of tool wear of coated carbide tool while machining X-750 nickel alloy

Abstract

Modern advanced structures and machinery rely heavily on advanced materials. Ni-based superalloys have applications in nuclear power plants, gas engines, airplane engines, turbines, etc. All these environments have high temperatures, thus; the material is selected such that it demonstrates sufficient strength at high temperatures. Ni-based superalloys present this characteristic due to their “high strength temperature resistant” (HSTR) nature. In the present work, an attempt has been made to machine X-750 nickel alloy on conventional machining considering rotational speed (TRS), feed (F) and depth of cut (DoC) as input machining variables. The coated carbide insert has been used at different machining cutting of input machining variables. The tool wear is assumed as an output parameter and the effect of input of parameters on the tool wear has been investigated. It has been observed that with the increase in rotational speed, feed and depth of cut the value of flank wear increases. The main mechanisms of tool wear exist in the present study are abrasion, adhesion and chipping, which are observed after the analysis of tool inserts by optical as well as scanning electron microscopy. The optimized setting for minimum TW (0.2716 mm) is TRS: 1362RPM; DoC: 01 mm and F: 0.07 mm/rev.