55-TW magnetically insulated transmission-line system: Design, simulations, and performance

Stygar, W. A.; Corcoran, Patrick; Ives, H.C.; Spielman, R. B.; Douglas, J.; Whitney, B.; Mostrom, Michael A.; Wagoner, T. C.; Speas, Christopher; Gilliland, T. L.; Allshouse, G.O.; Clark, Robert E.; Donovan, G.L.; Hughes, T.P.; Humphreys, D. R.; Jaramillo, Deanna M.; Johnson, M.F.; Kellogg, J. W.; Leeper, R. J.; Long, F. W.; Martin, T. H.; Mulville, T. D.; Pelock, M.D.; Peyton, B. P.; Poukey, J. W.; Ramirez, J.J.; Reynolds, P.; Seamen, J. F.; Seidel, D. B.; Seth, A. P.; Sharpe, A. W.; Shoup, R.W.; Smith, James W.; Valde, D. M. Van De; Wavrik, Richard William

doi:10.1103/physrevstab.12.120401

Cited by 56 publications

(39 citation statements)

References 38 publications

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“…1. [11][12][13] Water transmission lines couple to a water/ vacuum insulator stack which drive four vacuum magnetically insulated transmission lines ͑MITL͒ ͑a͒. These lines are coupled together through a double post hole convolute ͑b͒ that connects to a short final transmission line feeding the wire array load region ͑c͒.…”

Section: B the Z Generatormentioning

confidence: 99%

Simulations of the implosion and stagnation of compact wire arrays

et al. 2010

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Wire array z-pinches have been used successfully for many years as a powerful x-ray source, as a dynamic hohlraum, and as an intense K-shell radiation source. Significant progress has been made in the effective modeling of these three-dimensional ͑3D͒ resistive plasmas. However, successful modeling also requires an accurate representation of the power delivered to these loads from the generator, which is an uncertainty potentially as large as the magnetohydrodynamic ͑MHD͒ implosion dynamics. We present 3D resistive MHD simulations of wire arrays that are coupled to transmission line equivalent models of the Z generator, driven by voltage sources derived directly from electrical measurements. Significant ͑multi-mega-ampère͒ current losses are shown to occur in both the convolute and the final feed. This limits the array performance and must be correctly accounted for to accurately represent the generator response to the load. Our simulations are validated against data for compact: 20 mm diameter, 10 mm long wire arrays that have produced the highest x-ray power densities on Z. This is one of the most comprehensive experimental data sets for single and nested wire arrays and includes voltage, current, x-ray power and energy, and multiple mass distribution measurements. These data tightly constrain our simulation results and allow us to describe in detail both the implosion and stagnation, and how energy is delivered to, and radiated from z-pinch loads. We show that the radiated power is consistent with the kinetic energy delivered to a distributed 3D mass profile over its implosion and stagnation. We also demonstrate how the local inductance of the transmission line connecting to the wire array is responsible for delivering more than 50% of the total radiated power. This makes the power output dependent on the design of specific elements of the generator, and their response to the imploding load, and not just on the peak current that can be delivered.

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Section: B the Z Generatormentioning

confidence: 99%

Simulations of the implosion and stagnation of compact wire arrays

et al. 2010

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“…The higher impedance of the load during the rising portion of the power pulse resulted in higher voltages in the MITLs and convolute. The higher voltages result in greater current losses between the outer-MITL and inner-MITL B-dot probes [29]. The actual nature of these current losses is the subject of considerable study [4,14,[23][24][25][26][27][28][29] with particular emphasis on the formation of electrode plasmas in the convolute that lead to gap closure.…”

Section: Resultsmentioning

confidence: 99%

“…The load-current B-dot probes on ZR are located 6 cm from the axis of the load, which is located at the center of the machine. Just upstream of these probes, electrical power that is transported by four radial MITLs is combined by a double-post-hole vacuum convolute [4,14,[20][21][22][23][24][25][26][27][28][29]. The four MITLs located upstream of the convolute are referred to as the outer MITLs.…”

Section: Introductionmentioning

confidence: 99%

107-A load-currentB-dot monitor: Simulations, design, and performance

Rose

Welch

Miller

et al. 2010

Phys. Rev. ST Accel. Beams

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A B-dot monitor that measures the current 6 cm from the axis of dynamic loads fielded on 10 7 -A multiterawatt pulsed-power accelerators has been developed. The monitor improves upon the multimegampere load-current gauge described in Phys. Rev. ST Accel. Beams 11, 100401 (2008). The design of the improved monitor was developed using three-dimensional particle-in-cell simulations that model vacuum electron flow in the transmission line near the monitor. The simulations include important geometric features of the B-dot probe and model the deposition of electron energy within the probe. The simulations show that the improved design reduces by as much as a factor of 5 the electron energy deposition to the interior of the monitor. Data taken on accelerator shots demonstrate that the improved monitor works as well as the original monitor on shots with low-impedance loads, and delivers superior performance on higher-impedance-load shots.

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“…Magnetically insulated transmission lines (MITLs) are commonly used in the final stages of pulsed power systems to transfer power at high voltage and current to the physics-package load. Areas such as the convolute and inner-MITL of the Z-Machine require MA/cm level currents to be transmitted with vacuum gaps of 1 cm or less [1]. Future pulsed power systems, which will deliver greater power to loads, will require MITLs to transfer power at greater power densities.…”

Section: Introductionmentioning

confidence: 99%

Millimeter-Gap Magnetically Insulated Transmission Line Power Flow Experiments

Hutsel

Stoltzfus

Breden

et al. 2014

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An experiment platform has been designed to study vacuum power flow in magnetically insulated transmission lines (MITLs). The platform is driven by the Mykonos-V LTD accelerator to drive a coaxial MITL with a millimeter-scale anode-cathode gap. The experiments conducted quantify the current loss in the MITL with respect to vacuum pumpdown time and vacuum pressure. MITL gaps between 1.0 mm and 1.3 mm were tested. The experiment results revealed large differences in performance for the 1.0 and 1.3 mm gaps. The 1.0 mm gap resulted in current losses of 40%-60% of the peak current. The 1.3 mm gap resulted in current losses of less than 5% of peak current. Classical MITL models that neglect plasma expansion predict that there should be zero current loss, after magnetic insulation is established, for both of these gaps.

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55-TW magnetically insulated transmission-line system: Design, simulations, and performance

Cited by 56 publications

References 38 publications

Simulations of the implosion and stagnation of compact wire arrays

Simulations of the implosion and stagnation of compact wire arrays

107-A load-currentB-dot monitor: Simulations, design, and performance

Millimeter-Gap Magnetically Insulated Transmission Line Power Flow Experiments

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