Dynamic response and microstructure evolution of the finite steel target subjected to high velocity impact by copper explosively formed projectile

Abstract: The dynamic deformation of the finite steel target subjected to high velocity impact of copper explosively formed projectile is investigated by optical, scanning, and transmission electron microscopy. Morphology analysis of fracture surfaces indicates that the copper remainder plated to the crater wall shows extremely plastic deformation, which consists of elongated parabolic dimples, and the mild carbon steel target exhibits excellent brittle features that material fails mainly along the cleavage facets on th… Show more

“…However, as a chemical energy projectile, which is one of the most common weapons used to defeat the armors in the military applications (Weickert and Gallagher, 1993; Wu et al, 2007; Yu et al, 1999), EFP (explosively formed projectile) will experience essentially plastic strains up to 300%, at strain rates of the order of 10 4 s −1 (Pappu, 2000; Sui and Wang, 2000) during the formation and penetration process and the projectile cannot be treated as a rigid body anymore (Senthil and Iqbal, 2013; Sui and Wang, 2000). Actually, the main body of EFP will be fragmented or eroded during the penetration process of semi-infinite or infinite targets (with thickness orders of magnitude greater than the projectile dimensions) at high-velocity impact, only leaving some fractional mass in the crater wall (Li et al, 2010; Liu et al, 2017) and crater bottom. As the appearance of projectile is stable, the EFP is in a long rod-shaped with a high kinetic energy (Cardoso and Teixeira-Dias, 2016; Wu et al, 2007).…”

Ballistic performance study on the finite steel target subjected to normal and oblique impact by copper explosively formed projectile

“…However, as a chemical energy projectile, which is one of the most common weapons used to defeat the armors in the military applications (Weickert and Gallagher, 1993; Wu et al, 2007; Yu et al, 1999), EFP (explosively formed projectile) will experience essentially plastic strains up to 300%, at strain rates of the order of 10 4 s −1 (Pappu, 2000; Sui and Wang, 2000) during the formation and penetration process and the projectile cannot be treated as a rigid body anymore (Senthil and Iqbal, 2013; Sui and Wang, 2000). Actually, the main body of EFP will be fragmented or eroded during the penetration process of semi-infinite or infinite targets (with thickness orders of magnitude greater than the projectile dimensions) at high-velocity impact, only leaving some fractional mass in the crater wall (Li et al, 2010; Liu et al, 2017) and crater bottom. As the appearance of projectile is stable, the EFP is in a long rod-shaped with a high kinetic energy (Cardoso and Teixeira-Dias, 2016; Wu et al, 2007).…”

Ballistic performance study on the finite steel target subjected to normal and oblique impact by copper explosively formed projectile

Study on the Effect of Impact on the Macro- and Micro-structure of Q345 Steel Plate

Ballistic performance study on the composite structures of multi-layered targets subjected to high velocity impact by copper EFP