| Autor: |
L. J. Tabaka, Robert G. Watt, Joyce A. Guzik, Jeffrey R Griego, C. R. E. Reinovsky, D.T. Torres, Henn Oona, R. Menikoff, A. G. Sgro, David B. Holtkamp, P. Reardon, Thomas E. Tierney, G. Idzorek A. Kaul, James H. Goforth, L. Rousculp, R. K. Meyer, S. A. Colgate, Ronald C. Kirkpatrick, D.H. Herrera, Walter L. Atchison |
| Rok vydání: |
2009 |
| Předmět: |
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| Zdroj: |
2009 IEEE Pulsed Power Conference. |
| Popis: |
We are developing a new high explosive pulsed power (HEPP) system based on the 1.4 m long Ranchero generator which was developed in 1999 for driving solid density z-pinch loads. The new application requires approximately 40 MA to implode similar liners, but the liners cannot tolerate the 65µs, 3 MA current pulse associated with delivering the initial magnetic flux to the 200 nH generator. To circumvent this problem, we have designed a system with an internal start switch and four explosively formed fuse (EFF) opening switches. The integral start switch is installed between the output glide plane and the armature. It functions in the same manner as a standard input crowbar switch when armature motion begins, but initially isolates the load. The circuit is completed during the flux loading phase using post hole convolutes. Each convolute attaches the inner (coaxial output transmission line to the outside of the outer coax through a penetration of the outer coaxial line. The attachment is made with the conductor of an EFF at each location. The EFFs conduct 0.75 MA each, and are actuated just after the internal start switch connects to the load. EFFs operating at these parameters have been tested in the past. The post hole convolutes must withstand as much as 80 kV at peak dI/dt during the Ranchero load current pulse. We describe the design of this new HEPP system in detail, and give the experimental results available at conference time. In addition, we discuss the work we are doing to test the upper current limits of a single standard size Ranchero module. Calculations have suggested that the generator could function at up to ∼120 MA, the rule of thumb we follow (1 MA/cm) suggests 90 MA, and simple flux compression calculations, along with the ∼4 MA seed current available from our capacitor bank, suggests 118 MA is the currently available upper limit. |
| Databáze: |
OpenAIRE |
| Externí odkaz: |
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