A new model for initial chip curl in continuous cutting

“…Instead of being broken, the chip formation tends to be continuous and curly when micro-milling PC/CNT nanocomposites for the entire range of feed rates. It is possibly due to the good rake face lubrication [47] that could attain from reducing the friction coefficient of CNT along the rake face in comparison with plain PC [48]. In addition, the presence of showed higher cutting forces when micro-milling PC/MWCNT nanocomposite than plain PC only when the feed rate (2 µm) was lower than edge radius (~ 3µm) as a result of ploughing dominance in cutting mechanism due to MUCT effects.…”

A Review on Nanocomposites. Part 2: Micromachining

“…Instead of being broken, the chip formation tends to be continuous and curly when micro-milling PC/CNT nanocomposites for the entire range of feed rates. It is possibly due to the good rake face lubrication [47] that could attain from reducing the friction coefficient of CNT along the rake face in comparison with plain PC [48]. In addition, the presence of showed higher cutting forces when micro-milling PC/MWCNT nanocomposite than plain PC only when the feed rate (2 µm) was lower than edge radius (~ 3µm) as a result of ploughing dominance in cutting mechanism due to MUCT effects.…”

A Review on Nanocomposites. Part 2: Micromachining

A survey and future predictions for the use of chip breaking in unmanned systems

Indentation as the basis for metal cutting