摘要:
磁驱动加载技术通过脉冲功率源将超大脉冲电流加载到实验负载区,从而形成随时间平滑上升的磁压力,实现对样品的准等熵压缩和超高速飞片发射.本文基于聚龙一号装置的输出特性参数,依次从负载结构、电极尺寸、电流波形和诊断系统等方面,分别设计完成了两种负载构型的超高速飞片发射实验.其中应用单侧带状负载发射尺寸Φ10 mm ×0.725 mm的LY12铝飞片速度达到11.5 km/s,磁驱动加载压力近0.9 Mbar.比较模拟计算与实验结果,飞片发射过程和最终速度基本一致.而进一步的模拟计算表明,优化的负载结构尺寸和电流波形调节方案下,将有望发射尺寸Φ8.5 mm ×1 mm的铝飞片速度超过15 km/s.从模拟设计到实验开展,已初步掌握了基于多支路脉冲功率发生器的超高速飞片发射实验技术.
Abstract:
Magnetically driven loading technology is to load the large pulse current to the test area through the pulsed power, which forms a smooth magnetic pressure rising over time to achieve a quasi-isentropic compression of sample and hyper-velocity flyer launch. Based on the output characteristics and parameters of PTS accelerator, two types of hyper-velocity flyer launch experiments with different load configurations, such as the load, flyer plates size, current waveform and diagnostic systems, etc, are designed and tested. LY12 aluminum flyer plates with dimensions of Φ10 mm × 0.725 mm was launched by single-sided stripline load configuration to 11.5 km/s while the magnetic drive load pressure is near 0.9 × 105 MPa. Simulation and experimental results agrees well with those of in the flyer launch process and the ultimate velocity. Further simulation shows that the launch velocity of aluminum flyer plates with dimensions of Φ8.5 mm × 1 mm is expected to exceed 15 km/s under the program of optimizing the structural parameters and regulation. The design and experiment technology of hyper-velocity flyer launch based on multi-branch pulsed power generator has been mastered during the designs and experiments.
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