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Your search keyword '"Schaich, Charles R."' showing total 9 results
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9 results on '"Schaich, Charles R."'

1. ITER ECH Transmission Line System Design and Status.

Author

Hanson, Gregory R., Wolfe, Zachary C., Kaufman, Michael C., Casal, Natalia, Dukes, Carl L., Gandini, Franco, Goodman, Timothy P., Hale, Zackary P., Henderson, Mark A., Schaich, Charles R., Shanmugasundaram, Aravind, and Takahashi, Koji

Subjects
ELECTRON cyclotron resonance heating, ELECTRIC lines, ELECTROMAGNETIC waves, RADIO frequency
Abstract

The electron cyclotron (EC) heating & current drive (H&CD) system on ITER provides plasma heating by generating, transmitting, and launching high-intensity, high-frequency (170 GHz) electromagnetic wave energy steerable across the plasma cross-section. The transmission line (TL) subsystem connects the Matching Optics Unit (MOU) on each of the 24 gyrotrons to the 32 feed points in the four upper launchers and the 24 feed points in the equatorial launcher. Each TL must be able to operate at up to 1.2 MW of input power for up to 1 hour pulse lengths. The TL system contains 50 mm water-cooled corrugated waveguide, 90o miter bends, 140o miter bends, polarizer miter bend pairs, switches, expansion units, pumpouts, DC breaks, MOU-TL adapters, Radio Frequency (RF) loads, and isolation shutter valves. A detailed finite element analysis has been used to verify the thermo-mechanical performance of each component. The microwave performance has been analyzed using a 2-D electromagnetic code combined with a Monte Carlo code. This approach allows the impact of manufacturing and installation tolerances to be assessed and optimized to provide a high probability of achieving the system performance requirements. Prototypes of the waveguide and TL components have been fabricated and tested at high-power. Production contracts are now being issued for fabrication and delivery of the waveguide and components to ITER. [ABSTRACT FROM AUTHOR]

Published
2024
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6. A 6 MW/m2High Heat Flux Testing Facility of Irradiated Materials Using Infrared Plasma-Arc Lamps

Author

Sabau, Adrian S., Tokunaga, Kazutoshi, Littleton, Michael G., Kiggans, James O., Schaich, Charles R., Dinwiddie, Ralph B., Moore, Daniel T., Ueda, Yoshio, and Katoh, Yutai

Abstract

AbstractAssessing the effect of neutron irradiation of plasma-facing materials has been challenging due to both the technical and radiological challenges involved. In an effort to address the radiological challenges, a facility was developed to conduct high heat flux testing (HHFT) of inherently small samples of neutron-irradiated materials. A new line-focus reflector was designed and fabricated at Oak Ridge National Laboratory for a plasma-arc lamp (PAL) to attain a source heat flux of 12 MW/m2. The new reflector was fabricated with two ports for monitoring specimen condition during HHFT. At the same operational conditions for PAL, the absorbed heat flux in tungsten was increased from 1.39 MW/m2with the uniform irradiance reflector to 5.12 MW/m2for the line-focus reflector. This fourfold increase in the heat flux, at the same PAL electrode lifetimes, enabled cost-effective facility operation for a high number of cyclic high heat flux tests. Specifically, the test section is confined to a hemispherical dome, and specimens are bolted directly to a water-cooled copper alloy rod. Temperature measurement in the PAL facility was a main challenge due to a limited line of sight. For the first time in a PAL facility operating at high heat fluxes, the specimen surface temperature was directly measured during HHFT with a pyrometer. The HHFT data, which were obtained in this upgraded PAL facility, demonstrated the facility readiness for irradiated materials.

Published
2019
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