Three multilayer-coated carbides [two trigon-shaped inserts: Ti(C,N)/TiC/ A
l2O3 (T1), Ti(C,N)/Al2O3/TiN (T2) and one 80 degrees -rhomboid shaped inser
t: TiC/Al2O3/TiN (T3)] were used to machine a martensitic stainless steel a
t various combinations of cutting speed and feed rate without coolant to as
sess their wear performance. Significant nose wear and chipping/fracture of
the cutting edge were the predominant failure modes affecting tool perform
ance at higher speed conditions. Plucking of tool materials was the main ra
ke face wear phenomenon observed on T1 grade insert with alumina as the top
-layer coating when machining at the lower speed conditions. Attrition and
plastic flow were the main wear mechanisms observed on the ceramic coating
layers, with dissolution-diffusion being the probable wear mechanism of the
tool grades where tungsten carbide substrate had direct contact with the f
lowing chip. The fitted statistical wear models revealed T3 grade insert wi
th 80 degrees -rhomboid shape as having the highest speed-feed capability,
resulting in the highest material removal rate relative to T1 and T2 grade
inserts with trigon shapes.