Numerical and experimental study of dry cutting for an aeronautic aluminium alloy (A2024-T351)

Abstract In the present contribution, numerical and experimental methodologies concerning orthogonal cutting are proposed in order to study the dry cutting of an aeronautic aluminium alloy (A2024-T351). The global aim concerns the comprehension of physical phenomena accompanying chip formation according to cutting velocity variation. For the numerical model, material behaviour and its failure criterion are based on the Johnson–Cook law. The model proposes a coupling between material damage evolution and its fracture energy. A high-speed camera was used to capture the chip formation sequences. The numerical results show that the chip–workpiece contact and the tool advancement induce bending loads on the chip. Consequently, a fragmentation phenomenon takes place above the rake face when the chip begins to curl up. The computed results corroborate with experimental ones. The numerical results predict the residual stress distribution and show high values, along the cutting direction, on the machined workpiece surface.

[1]  M. Nouari,et al.  Experimental analysis and optimisation of tool wear in dry machining of aluminium alloys , 2003 .

[2]  G. R. Johnson,et al.  Fracture characteristics of three metals subjected to various strains, strain rates, temperatures and pressures , 1985 .

[3]  William D. Callister,et al.  Materials Science and Engineering: An Introduction , 1985 .

[4]  Tarek Mabrouki,et al.  Experimental and numerical study of chip formation during straight turning of hardened AISI 4340 steel , 2005 .

[5]  J. J. Mason,et al.  Experimental study of the temperature field generated during orthogonal machining of an aluminum alloy , 2002 .

[6]  Deborah L Thurston,et al.  Machining Quality and Cost: Estimation and Tradeoffs , 2002 .

[7]  Tarek Mabrouki,et al.  A contribution to a qualitative understanding of thermo-mechanical effects during chip formation in hard turning , 2006 .

[8]  T. Wierzbicki,et al.  Evaluation of six fracture models in high velocity perforation , 2006 .

[9]  J. Lemaître,et al.  Engineering Damage Mechanics: Ductile, Creep, Fatigue and Brittle Failures , 2005 .

[10]  P. Sreejith,et al.  Dry machining: Machining of the future , 2000 .

[11]  Martin Howarth,et al.  TiAlN/VN superlattice structured PVD coatings: A new alternative in machining of aluminium alloys for aerospace and automotive components , 2006 .

[12]  N. Fang,et al.  The effects of chamfered and honed tool edge geometry in machining of three aluminum alloys , 2005 .

[13]  Mohammed Nouari,et al.  Wear behaviour of cemented carbide tools in dry machining of aluminium alloy , 2005 .

[14]  A. Hillerborg,et al.  Analysis of crack formation and crack growth in concrete by means of fracture mechanics and finite elements , 1976 .

[15]  J. Sutherland,et al.  Finite element simulation of the orthogonal metal cutting process for qualitative understanding of the effects of crater wear on the chip formation process , 2002 .

[16]  Tuğrul Özel,et al.  Predictive Analytical and Thermal Modeling of Orthogonal Cutting Process—Part II: Effect of Tool Flank Wear on Tool Forces, Stresses, and Temperature Distributions , 2006 .

[17]  Tuğrul Özel,et al.  Predictive Analytical and Thermal Modeling of Orthogonal Cutting Process—Part I: Predictions of Tool Forces, Stresses, and Temperature Distributions , 2006 .

[18]  Luis Ricardo Castro,et al.  Correction of dynamic effects on force measurements made with piezoelectric dynamometers , 2006 .