Experimental Investigation on the Failure Mechanism of Grooved Steel Plate Impacted by Projectile with Different Nose Shapes

In order to study the penetration performance of the tandem warhead composed of a front circular shaped charge and a rear penetration projectile, a grooved steel plate was processed to simulate the effect of circular shaped jets on metal plate, then the failure mechanism of the grooved steel plate i...

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Bibliographic Details
Published in:Key engineering materials 2020-06, Vol.846, p.162-166
Main Authors: Tong, Zong Bao, Tang, Song Ze, Zhou, Nan, Wang, Jin Xiang
Format: Article
Language:English
Subjects:
Failure analysis
Failure mechanisms
Grooves
Impact damage
Metal plates
Noses (forebodies)
Penetration
Projectiles
Shape effects
Splitting
Steel plates
Tensile deformation
Terminal ballistics
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Summary:In order to study the penetration performance of the tandem warhead composed of a front circular shaped charge and a rear penetration projectile, a grooved steel plate was processed to simulate the effect of circular shaped jets on metal plate, then the failure mechanism of the grooved steel plate impacted by rear projectile was investigated by ballistic experiment, meanwhile, the effect of projectile nose shape on the failure mechanism was also analyzed. The results show that the main failure mechanism of grooved steel plate is ductile tensile deformation or damage when the projectile impacted on the inner plate body and the depth of the pre-splitting groove is not big enough (usually more than 4mm), on the other hand, the circumferential sheared fracture of the bottom of the groove occurred when the depth of the pre-splitting groove is not less than 4mm. The oval projectile body has much greater erosion damage than rod-shaped projectile during the penetration process.
ISSN:1013-9826
1662-9795
1662-9795
DOI:10.4028/www.scientific.net/KEM.846.162