论文信息 - Perforation of welded aluminum extrusions - Numerical prediction and experimental validation

Perforation of welded aluminum extrusions - Numerical prediction and experimental validation

A purely numerical procedure for predicting the perforation resistance of welded extruded AA6082-T6 aluminum profiles is presented in this study. The numerical work was conducted completely independent of the experimental tests that were only used for validation purposes. The outline of the three-step numerical procedure is as follows: (1) the temperature development due to a specified welding process is predicted by a thermal solver, (2) based on the chemical composition of the alloy, the temperature-time history during aging and the welding analysis, the yield strength and flow stress of the material were determined; and (3) the ballistic limit velocity is found using explicit finite element simulations. The experimental validation program is described and it shows that the ballistic limit velocities found from the impact experiments correlate closely with the numerically predicted values obtained without any physical material or component tests. Further, welding of the 10 mm thick extrusions gives a 10% degradation of the capacity in terms of ballistic limit velocity compared to the unaffected material.

[1] Øystein Grong,et al. Modelling of the age hardening behaviour of Al–Mg–Si alloys , 2001 .

[2] D. Agard,et al. Microtubule nucleation by γ-tubulin complexes , 2011, Nature Reviews Molecular Cell Biology.

[3] Paolo Ruggerone,et al. Computational Materials Science X , 2002 .

[4] T. Børvik,et al. A computational model of viscoplasticity and ductile damage for impact and penetration , 2001 .

[5] T. W. Ipson,et al. Ballistic Perforation Dynamics , 1963 .

[6] Tore Børvik,et al. A nano-scale material model applied in finite element analysis of aluminium plates under impact loading , 2013 .

[7] Tore Børvik,et al. Effects of heat treatment on the ballistic properties of AA6070 aluminium alloy , 2013 .

[8] Øystein Grong,et al. A Combined Precipitation, Yield Strength, and Work Hardening Model for Al-Mg-Si Alloys , 2010 .

[9] T. Børvik,et al. Perforation resistance of five different high-strength steel plates subjected to small-arms projectiles , 2009 .

[10] C. S. Smith,et al. Metallurgical and Materials Transactions a Volume 41a, May 2010—1063 , 2010 .

[11] A. Karimi,et al. Master‟s thesis , 2011 .

[12] T. L. Warren,et al. Perforation of 7075-T651 Aluminum Armor Plates with 7.62 mm APM2 Bullets , 2010 .