Abstract :
Summary form only given. After evaluating the engineering requirements, costs, and performance simulations of various Capacitive and Inductive Energy Storage Pulsed Power Systems concepts, we have settled on some concise design capable of generating peak current pulse of 200 KA, with 6.36 mus rise-time, and di/dt of 139 kA/mus for the Lightning Direct Strike Test Facility at White Sands Missile Range, NM. Unlike the recently refurbished Sandia Lightning Simulator which uses YAG laser induced spark-gap triggering, our design relies on high-power diodes as crowbar switch that automatically shunts the peak current pulse at the desired point in time, and for the desired decay through RL sub-circuitry. Also discussed herein are the various aspects of engineering, performance, and reliability of the diodes, the crucial switching components, and evaluation of the key parameters, such as dynamic resistance during forward recovery transient, and high di/dt impact on modulation conductivity, all of which will eventually be resolved using advanced diffusion physics simulations.
Keywords :
RLC circuits; lightning; pulse modulation; pulsed power technology; spark gaps; RL subcircuitry; YAG laser induced spark-gap triggering; advanced diffusion physics simulations; automatic shunts; crowbar switch; current 200 kA; dynamic resistance; forward recovery transient; high-di-dt impact; high-power diodes; lightning direct strike test facility; modulation conductivity; peak current pulse; prototype design; refurbished Sandia lightning simulator; time 6.36 mus; Design engineering; Diodes; Lightning; Optical design; Optical pulse generation; Power system simulation; Prototypes; Pulse power systems; Switches; Test facilities;
