Abstract
The significance of the micro-geometries on the cutting edge is known from numerous studies conducted in the past. However, the effect of micro-geometry on the wiper facet (also called the wiper edge) is not known. Hence, this paper investigates the effect of different micro-geometries with a focus on geometry variation on the wiper edge of a milling insert on surface roughness and forces in face milling of SAE1070 high-carbon steel. Milling inserts with sharp, rounded, chamfered edges and their combinations were manufactured on the cutting edge and wiper edge for the study. Critical surface quality parameters such as the average surface roughness (Ra), mean depth of surface roughness (Rz), and force components such as radial force (Fx), cutting force (Fy), and axial force (Fz) were evaluated. Metal cutting tests were performed at three different cutting speeds and three different feed rates to study the influence of cutting parameters and the effect of edge geometries on surface roughness. The results were correlated with the force values to understand the machining dynamics. Finite element analysis was performed to evaluate the high and low-stress zones on the insert, workpiece, and chip to understand the metal cutting mechanism of different micro-geometries. The novel finding from the study is that having identical micro-geometries on the cutting and wiper edge is the preferred combination, whereas dissimilar micro-geometries result in reduced surface quality, increased forces, and high stress on the workpiece and chip.
Highlights
The surface roughness of materials formed in machining is determined by the microgeometry of the tool, nose radius, cutting parameters, tool wear, and thermal properties of the work material
The first part elaborates the experimental results showing the effect of different micro-geometries on surface roughness, Analysis of Variance (ANOVA) study, and numerical simulations to understand the mechanism that is responsible for the variation in surface roughness
The analysis shows that the stress concentration on Insert B with a sharp chamfer on the cutting and wiper edge is high followed by Insert D with an edge radius, whereas Insert C with a radiused chamfer on the cutting and wiper edge shows the least stress concentration, which is a sign of superior edge stability
Summary
The surface roughness of materials formed in machining is determined by the microgeometry of the tool, nose radius, cutting parameters, tool wear, and thermal properties of the work material The knowledge of these variables and understanding of their interactions is imperative to get a superior finish on the final product. The first part elaborates the experimental results showing the effect of different micro-geometries on surface roughness, ANOVA study, and numerical simulations to understand the mechanism that is responsible for the variation in surface roughness.
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
