Fast discharge energy storage development for improving X-ray simulators

Over the last two years there have been design studies to investigate the impact of improvements in fast energy storage systems on the design of simulator upgrades (Double-EAGLE and Decade Quad) and on larger future simulators (40-MA to 60-MA PRS machine). The fast energy storage systems investigate...

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Main Authors: Sincerny, Peter, Carboni, Vie, Childers, Kendall, Corcoran, Pat, Hammon, Jud, Lam, S. K., Miller, Richard, Naff, Tom, Smith, Ian, Tucker, Terry, Ennis, Joel, Cooper, Robert, Bell, David, Davis, Randy
Format: Conference Proceeding
Language:English
Online Access:Request full text
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Summary:Over the last two years there have been design studies to investigate the impact of improvements in fast energy storage systems on the design of simulator upgrades (Double-EAGLE and Decade Quad) and on larger future simulators (40-MA to 60-MA PRS machine). The fast energy storage systems investigated in these design studies included Fast Marx Generators (FMG with √LC = 200 ns and √LC = 300 ns) and Linear Transformer Drivers (LTD). A design sketch of a compact 20-MA PRS driver and a potential upgrade of Double-EAGLE using FMG technology will be presented. The first concept that will be discussed is a 16-MA driver for PRS (plasma radiation source) loads. This generator would consist of 48 eight-stage FMG units and 13 m diameter and would drive the PRS directly without further pulse compression. The second concept that will be presented is a potential upgrade of an operational simulator, Double-EAGLE. This concept would utilize the FMG to replace the existing slower Marx generator, transfer capacitor and triggered gas switch. The basic building blocks for these future FMG driven machines are a low- inductance Marx switch and a low-inductance capacitor designed to be integrated with the new switch. These components are configured in a low-inductance FMG stage and then stacked in series to form a unit for the voltage required and a number of units in parallel for the required system inductance and stored energy. A review of the FMG component requirements and the status of the FMG component testing in a single-stage FMG configuration will also be presented. A four-stage FMG unit is being built and tested to demonstrate the required stage voltage and inductance. Results of these initial tests will be presented.
DOI:10.1063/1.1530806