A naval electromagnetic railgun would be a considerable asset against a littoral environment. By accelerating projectiles to 3 km/s, a naval railgun would be capable of reaching 300-400 nautical miles. Problems such as rail erosion, energy storage and fire control prevent the railgun from becoming a weapon to date. At the Naval Postgraduate School, the Physics Department continues to investigate and develop concepts to overcome these challenges. As part of the methodology, previous students built a one-meter railgun system for experimentation. The existing 1.6 mF power supply is insufficient to fire this railgun effectively. To design a sufficient power supply a MATLAB code was created to simulate a generated current pulse and to predict the subsequent railgun performance. Interrelated factors such as railgun geometry, muzzle velocity, current density and contact surface area were taken into consideration. Also, tradeoffs in capacitance, projectile mass and residual current were weighed against one another to achieve desired railgun performances. From numerous simulations, this study determined that the one-meter railgun with a 21.5 mF power supply could fire a 0.158-kg projectile at a velocity of 1 km/s, and leave a residual current of only 4% of the initial energy once the projectile exits the rails. v.
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机译:海军电磁炮在沿海环境中将是一笔可观的财富。通过将弹丸加速至3 km / s,海军的轨道炮将能够达到300-400海里。诸如轨道腐蚀,能量存储和火控之类的问题阻止了轨道炮成为一种武器。在海军研究生院,物理系继续研究和开发克服这些挑战的概念。作为该方法的一部分,以前的学生构建了一个用于测试的一米铁路炮系统。现有的1.6 mF电源不足以有效地发射这把电磁炮。为了设计足够的电源,创建了MATLAB代码以模拟生成的电流脉冲并预测随后的电磁炮性能。相互关联的因素,如轨道炮的几何形状,炮口速度,电流密度和接触表面积等都已考虑在内。同样,在电容,弹丸质量和剩余电流之间的权衡也要相互权衡,以实现所需的电磁炮性能。通过大量的模拟,这项研究确定了配备21.5 mF电源的一米轨道炮可以以1 km / s的速度发射0.158 kg的弹丸,而一旦发射,则剩余电流仅为初始能量的4%。弹丸退出铁轨。 v。
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