The design of the center core of a spherical tokamak

Richard J. Colchin; John D. Galambos; Paul L. Goranson; Steven P. Hirshman; Phillip H. Edmonds; John R. Uglum

doi:10.13182/FST97-A30838

The design of the center core of a spherical tokamak

Richard J. Colchin, John D. Galambos, Paul L. Goranson, Steven P. Hirshman, Phillip H. Edmonds, John R. Uglum

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Abstract

Recently, there have been several proposals to build low-aspect-ratio or spherical tokamaks with plasma currents in the range of 1 MA. These low-aspect-ratio toka-maks employ conventional engineering, except in the central core, which contains the central toroidal field conductors and an ohmic heating solenoid (if present). To achieve low aspect ratios, these components must be engineered to the limits of stress and thermal properties. Solutions are found for the steady-state cooling of the toroidal field conductors. The solenoid, which must be high performance to produce the flux swing required for a 1-MA plasma current, cannot be cooled steady state. The mathematics and procedures necessary to study these issues are given.

Original language	English
Pages (from-to)	350-369
Number of pages	20
Journal	Fusion Technology
Volume	31
Issue number	3
DOIs	https://doi.org/10.13182/FST97-A30838
State	Published - May 1997

Keywords

Central core
Central solenoid
Spherical tokamaks

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abstract = "Recently, there have been several proposals to build low-aspect-ratio or spherical tokamaks with plasma currents in the range of 1 MA. These low-aspect-ratio toka-maks employ conventional engineering, except in the central core, which contains the central toroidal field conductors and an ohmic heating solenoid (if present). To achieve low aspect ratios, these components must be engineered to the limits of stress and thermal properties. Solutions are found for the steady-state cooling of the toroidal field conductors. The solenoid, which must be high performance to produce the flux swing required for a 1-MA plasma current, cannot be cooled steady state. The mathematics and procedures necessary to study these issues are given.",

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AU - Galambos, John D.

AU - Goranson, Paul L.

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AU - Edmonds, Phillip H.

AU - Uglum, John R.

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AB - Recently, there have been several proposals to build low-aspect-ratio or spherical tokamaks with plasma currents in the range of 1 MA. These low-aspect-ratio toka-maks employ conventional engineering, except in the central core, which contains the central toroidal field conductors and an ohmic heating solenoid (if present). To achieve low aspect ratios, these components must be engineered to the limits of stress and thermal properties. Solutions are found for the steady-state cooling of the toroidal field conductors. The solenoid, which must be high performance to produce the flux swing required for a 1-MA plasma current, cannot be cooled steady state. The mathematics and procedures necessary to study these issues are given.

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The design of the center core of a spherical tokamak

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Keywords

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