Physical experiments were performed to investigate the enhanced lethality of reactive materials (RMs) shaped charge liner against concrete target. The results show that the shaped charge with RMs liner left a funnel shaped hole on the pure concrete target front surfaces, whereas the Cu liner just left a slender penetration hole and produced less damage in comparison. The damage events were recorded by high‐speed photography with the frame rate up to 10,000 frames/s, and the results indicate that deflagration reaction of RMs has occurred inside the target after the detonation of main charge. By comparison of damage effects between RMs and inert Cu liners, we conclude that the gaseous products of the deflagration are the main inducement of catastrophic damage. For multi‐layered concrete targets, a cavity inside the target and several cracks on the targets front surfaces were formed, and the formation mechanisms are deeply discussed in this paper. Based on the isentropic expansion and crack growth theories, the computational formula for crack length was developed, and the influences of the mass of RMs and initiation depth on crack effects are achieved.
During the firing process, the gun barrel bears the thermal and chemical erosion of high‐temperature gunpowder gas and the wear of the rotation band. The forced cone tended to the most severely worn part of the barrel, which directly affects the life of the barrel. Combined with the erosion test and wear test of gun steel materials, this research studied the forcing cone of a medium caliber naval gun barrel. With the commercial finite element software ABAQUS as the platform, we took advanced adaptive mesh method combined with secondary development technology. This method used in our study in order to better realize the numerical simulation of the radial erosion wear of the forced projectile cone in the continuous firing environment. At the same time, we compared the numerical simulation with the actual firing test data, and proposed a new calculation method of barrel life. In conclusion, the results of this study showed that this method can better calculate the radial erosion wear of the forced cone, and provide guidance for improving the life of the gun barrel in the future.
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