Abstract:
tMinimum quantity lubrication machining has been actively researched by scientists as a viable alternativeto the use of cutting fluids used in metal cutting, a source known for their operator’s health and ecologicalconcerns. MQL machining assumes significance due to the very low volumes of the lubricants used,which are often consumed in the machining processes itself. The quest for greener lubricants has leadthe researchers towards vegetable oils. Ionic liquids are a relatively new family of green chemicals whichhave the advantage that their physical and chemical properties can be designed for specific applications.Previous work by researchers has demonstrated that ionic liquids can be used as promising lubricants invarious engineering applications.This paper presents the results of a detailed study carried out to evaluate the performance of fluorinecontaining oil non-miscible ionic liquids and phosphonium ion based oil miscible ionic liquids, addedto canola oil or polyethylene glycol in small volumes in interrupted MQL machining of a plain mediumcarbon steel under different cutting parameters. The result of the studies demonstrated that fluorine con-taining ionic liquids showed improved results at higher cutting speeds and load and could be a candidatefor high speed machining applications, where the cutting zone temperatures rise above the decomposi-tion temperatures of the ionic liquids prompting the liberation of fluorine which readily binds with thefreshly produced chip under-surface and reduces the severity of the tool-chip adhesion.The phosphonium ion based ionic liquids and polyethylene glycol showed better results at lower cuttingspeeds where the tool-chip interface temperature stayed below the decomposition temperature of thelubricants, suggesting a strong influence of the lubricant viscosity on the cutting performance. The use oflubricants with higher viscosity resulted in improved surface roughness. The results of the study can beused as a starting guideline for the design of ionic liquids with specific chemical and physical propertiesfor different machining applications.
