Abstract
Due to their high-temperature resistance, nickel-based super alloys are used in many fields, especially in the aviation and aerospace industries. In addition to these advantages, there are some machining difficulties. Some cooling methods are used to minimize the machining difficulties of these materials. For this purpose, in this study, tool life, tool wear, surface roughness (Ra), cutting forces (Fc), and cutting zone temperature (T) were investigated in turning Inconel 625 super alloys under different cooling conditions. Experiments were carried out under three different cutting conditions (dry, minimum quantity lubrication [MQL], and vortex cooling methods). Three feed rates (0.08, 0.1, and 0.12 mm/rev) and three cutting speeds (60, 80, and 100 m/min) were used. Tool wear tests were conducted at average cutting speed and feed rate (80 m/min and 0.1 mm/rev). After the experiments, it was found out that the cooling application positively affects in terms of tool life, cutting zone temperature, and surface roughness. The lowest wear occurred as 0.136 mm in experiments with MQL. The best values for cutting forces, surface roughness, and cutting zone temperatures were also obtained with MQL.
Highlights
Super alloys are generally used in situations where high mechanical properties and strength must be maintained at operating temperatures
It was concluded that the cooling application affects positively in terms of tool life, cutting zone temperature and surface roughness
The aim of this study is to investigate, the effects of MQL and vortex on tool life, surface quality, cutting force and cutting zone temperature in turning of Ni-based Inconel 625 by taking the dry cutting conditions as reference
Summary
Super alloys are generally used in situations where high mechanical properties and strength must be maintained at operating temperatures. They concluded that MQL cooling method gives better results compared to traditional cooling methods in terms of tool wear [3]. Chetan at et al compared the effect of cryogenic cooling and Al2O3 nanoparticle based MQL cooling method in the machining of a nickel-based alloy. Paturi et al investigated the effect of MQL on surface roughness in turning of Inconel 718 After the study, they determined that using solid lubricant-assisted MQL improved the surface quality approximately 35% [6]. Investigated the effects of minimum quantity lubrication on tool life and surface quality in turning of titanium alloys. They concluded that the usage of MQL has a positive effect on tool life. They concluded that the usage of MQL has a positive effect on tool life. [7]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
