Genesis: A 5 MA programmable pulsed power driver for Isentropic Compression Experiments

Enabling technologies are being developed at Sandia National Laboratories to improve the performance and flexibility of compact pulsed power drivers for magnetically driven dynamic materials properties research. We have designed a modular system capable of precision current pulse shaping through the...

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Bibliographic Details
Main Authors: Glover, S.F., Schneider, L.X., Reed, K.W., Pena, G.E., Davis, J.-P., Hall, C.A., Hickman, R.J., Hodge, K.C., Lehr, J.M., Lucero, D.J., McDaniel, D.H., Puissant, J.G., Rudys, J.M., Sceiford, M.E., Tullar, S.J., Van De Valde, D.M., White, F.E.
Format: Conference Proceeding
Language:English
Subjects:
Current measurement
Dielectric measurements
Inductance
Laboratories
Material properties
Power transmission lines
Pulse compression methods
Pulse shaping methods
Shape
Strips
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Summary:Enabling technologies are being developed at Sandia National Laboratories to improve the performance and flexibility of compact pulsed power drivers for magnetically driven dynamic materials properties research. We have designed a modular system capable of precision current pulse shaping through the selective triggering of pulse forming components into a disk transmission line feeding a strip line load. The system is comprised of two hundred and forty 200 kV, 60 kA modules in a low inductance configuration capable of producing 250-350 kbar of magnetic pressure in a 1.75 nH, 20 mm wide strip line load. The system, called Genesis, measures approximately 5 meters in diameter and is capable of producing shaped currents greater than 5 MA. This performance is enabled through the use of a serviceable solid dielectric insulator system which minimizes the system inductance and reduces the stored energy and operating voltage requirements. Genesis can be programmed by the user to generate precision pulse shapes with rise times of 220-500 ns, allowing characterization of a range of materials from tungsten to polypropylene. This paper provides an overview of the Genesis design including the use of genetic optimization to shape currents through selective module triggering.
ISSN:2158-4915
2158-4923
DOI:10.1109/PPC.2009.5386357