The ARC Premium branded range of end mills are made from a traceable grade of material. They are precision manufactured for consistency, quality and accuracy.
Uncoated Carbide End Mills
Arc Premium Uncoated end mills are specially ground for milling aluminium. Sharper cutting edges are possible with uncoated end mills. Also, where indicated, the higher helix angle of 45° helps to evacuate the chips quickly thus reducing the amount of heat generated and producing a good surface finish. Arc Premium Uncoated end mills are ideal for machining aluminium, brass, plastics and other non-ferrous materials.
TiAlN Coated Carbide End Mills
Arc Premium TiAlN coated end mills are coated with the highly regarded Balzers Balinit® Futura Nano TiAlN (titanium aluminium nitride) coating offering high-performance machining and long tool life. Depending upon machine limitations, TiAlN coated end mills can operate at speeds up to 100% higher than uncoated end mills. Arc Premium TiAlN coated end mills are recommended for machining steel, cast iron and stainless steel.
In general, TiAlN is a high-performance coating of about same hardness as TiCN but will maintain it's hardness at much higher cutting temperatures.
When the cutter is working hard, the aluminium content in the coating forms a gaseous aluminium oxide layer at the cutting edge where the temperature could reach more than 800°C. This helps to protect the carbide substrate from the damaging effects of heat and is what makes this coating ideal for high speed machining, especially when dry cutting. Depending upon the limitations of your machine, TiAlN coated end mills can be operated at speeds up to 100% higher than uncoated end mills.
The Balzers Balinit® Futura Nano coating offers outstanding properties enabling high-performance machining and long tool life. In fact Balzers Balinit® Futura Nano not only out-performs uncoated cutters, TiN and TiCN coated cutters but also many other TiAlN coated cutters as well.
|TiAlN Coating||Balzers BALINIT® FUTURA NANO|
|Microhardness||3,300 HV 0.05|
|Coefficient of Friction
|0.30 – 0.35
|Compressive Stress||- 1.3 / - 1.5GPa|
|Maximum Service Temperature||900°C|
|Coating Structure||Nano Structured|
Greater wear resistance
Better coefficient of friction due to higher surface quality
Greater thermal and chemical resistance
Optimised hardness:residual compressive stress ratio