Wear mechanisms of uncoated and coated cemented carbide tools in machining lead-free silicon brass

Free-machining brass containing 2–3% of lead is a preferred industrial material as it shows excellent machinability where low cutting forces, short chips and reduced tool wear are attained. However this addition of lead, a highly toxic and hazardous material, leads to health and environmental issues. Alternative lead-free brasses are known for poor chip control and accelerated tool wear. The current study focuses on wear mechanisms of uncoated and coated cemented carbide tools when high-speed machining lead-free CuZn21Si3P silicon brass. The study shows that severe crater formation on the rake is the dominant tool failure mode. Microscopy observations indicate the diffusion wear mechanism to be driven by diffusion of cobalt binder into the chips and minor cross-diffusion of copper and zinc. Loss of the binder in cemented carbide is accompanied by adhesive pluck-out of WC grains. As a way to hinder the loss of Co, the diffusion preventing capacity of a-C:H diamond like carbon and (Ti,V,Zr,Nb,Hf,Ta)N nitride coating were tested. SEM, EDX and TEM data show that formation of amorphous SiO2 and stoichiometric β-SiAlON stable layers was observed on the nitride coating, thus preventing diffusional tool wear. O-rich and N-rich glassy amorphous layers in Si-Al-O-N system with ZnS inclusions were found on the DLC coating. Partial delamination of the DLC coating and removal of the glassy phases resulted in localized crater formation associated with diffusional wear.

[1]  S. Hampshire Oxynitride glasses, their properties and crystallisation – a review , 2003 .

[2]  L. Nyborg,et al.  Machinability of CuZn21Si3P brass , 2016 .

[3]  O. Ivasishin,et al.  Irradiation resistance, microstructure and mechanical properties of nanostructured (TiZrHfVNbTa)N coatings , 2016 .

[4]  W. Chapman Metal cutting , 2019, Workshop technology.

[5]  N. Gane The effect of lead on the friction and machining of brass , 1981 .

[6]  J. Davim,et al.  Influence of the chemical composition on the machinability of brasses , 2005 .

[7]  D. Vaughan Handbook of Mineralogy: Volume I; Elements, Sulfides, Sulfosalts , 1991, Mineralogical Magazine.

[8]  C. Charitidis,et al.  Nanomechanical and nanotribological properties of carbon-based thin films: A review , 2010 .

[9]  George Pantazopoulos,et al.  Leaded brass rods C 38500 for automatic machining operations: A technical report , 2002 .

[10]  R. M. Hamouda,et al.  Microstructure and castability of lead‐free silicon brass alloys , 2012 .

[11]  J. Belzunce,et al.  Comparative study of the parameters influencing the machinability of leaded brasses , 2010 .

[12]  G. Pantazopoulos A review of defects and failures in brass rods and related components , 2003 .

[13]  F. Klocke,et al.  Experimental investigation of chip formation, flow, and breakage in free orthogonal cutting of copper-zinc alloys , 2015 .

[14]  F. Klocke,et al.  Influence of Tool Coating, Tool Material, and Cutting Speed on the Machinability of Low-Leaded Brass Alloys in Turning , 2016 .

[15]  E. Trent Metal cutting and the tribology of seizure: III temperatures in metal cutting , 1988 .

[16]  Fritz Klocke,et al.  Machinability Enhancement of Lead-free Brass Alloys , 2014 .

[17]  K. Jack,et al.  α′-Sialon ceramics , 1978, Nature.

[18]  Lucille A. Giannuzzi,et al.  Focused Ion Beam Milling and Micromanipulation Lift-Out for Site Specific Cross-Section Tem Specimen Preparation , 1997 .

[19]  Jan-Eric Ståhl,et al.  Comparative study on the machinability of lead-free brass , 2017 .

[20]  P. Cochat,et al.  Et al , 2008, Archives de pediatrie : organe officiel de la Societe francaise de pediatrie.

[21]  F. Klocke,et al.  Application of a new, severe-condition friction test method to understand the machining characteristics of Cu–Zn alloys using coated cutting tools , 2015 .

[22]  Jan-Eric Ståhl,et al.  Residual stress analysis of machined lead-free and lead-containing brasses , 2016 .