THE USE OF AN ELECTROTHERMAL PLASMA GUN TO SIMULATE THE EXTREMELY HIGH HEAT-FLUX CONDITIONS OF A TOKAMAK DISRUPTION

被引：24

作者：

GILLIGAN, J

BOURHAM, M

机构：

[1] Department of Nuclear Engineering, North Carolina State University, Raleigh, 27695-7909, North Carolina

来源：

JOURNAL OF FUSION ENERGY | 1993年 / 12卷 / 03期

关键词：

TOKAMAK DISRUPTION; PLASMA-FACING COMPONENTS; DIVERTORS; VAPOR SHIELD; MATERIAL EROSION; MAGNETIC VAPOR SHIELD;

D O I：

10.1007/BF01079675

中图分类号：

TL [原子能技术]; O571 [原子核物理学];

学科分类号：

0827 ; 082701 ;

摘要：

Disruption damage conditions for future large tokamaks like ITER are nearly impossible to simulate on current tokamaks. The electrothermal plasma source SIRENS has been designed, constructed, and operated to produce high density(> 10(25)/m(3)), low temperature (1-3 eV) plasma formed by the ablation of the insulator with currents of up to 100 kA (100 mu s pulse length) and energies up to 15 kJ. The source heat fluence (variable from 0.2 to 7 MJ/m(2)) is adequate for simulation of the thermal quench phase of plasma disruption in future fusion tokamaks. Different materials have been exposed to the high heat flux in SIRENS, where comparative erosion behavior was obtained. Vapor shield phenomena has been characterized for different materials, and the energy transmission factor through the shielding layer is obtained. The device is also equipped with a magnet capable of producing a parallel magnetic field (up to 16 T) over a 8 msec pulse length. The magnetic field is produced to decrease the turbulent energy transport through the vapor shield, which provides further reduction of surface erosion (magnetic vapor shield effect).

引用

页码：311 / 316

页数：6

共 10 条

[1]

Sestero A., Protection of walls from hard disruption in large tokamaks, Nucl. Fusion, 17, (1977)

[2]

Hassanein A., Erosion and redeposition of divertor and wall materials during abnormal events, Fusion Technol., 19, (1991)

[3]

Gilligan J., Hahn D., The magnetic vapor shield (MVS) mechanism for protection of high-heat flux components in highfield tokamaks, Journal of Nuclear Materials, 145-147, (1987)

[4]

Bourham M., Hankins O., Auciello O., Stock J., Wehring B., Mohanti R., Gilligan J., Vapor shielding and erosion of surfaces exposed to high heat load in an electrothermal accelerator, IEEE Trans. Plasma Sci., 17, (1989)

[5]

Gilligan J., Mohanti R., Time dependent numerical simulation of ablation controlled arcs, IEEE Trans. Plasma Sci., 18, (1990)

[6]

Gilligan J., Hahn D., Mohanti R., Vapor shielding of surfaces subjected to high heat fluxes during a plasma disruption, Journal of Nuclear Materials, 162, (1989)

[7]

Mohanti R., Gilligan J., Bourham M., Time dependent simulation of weakly nonideal plasmas in electrothermal launchers, Physics Fluids B, 3, (1991)

[8]

Hankins O., Bourham M., Earnhart J., Gilligan J., Visible light emission measurements from a dense electrothermal launcher plasma, IEEE Transactions on Magnetics, 29, (1993)

[9]

Bolt H., Linke J., Nickel H., Wallura E., Akiba M., Araki M., Seki M., Performance of carbon materials under short and intense electron beam pulses in the JEBIS facility, Fusion Techol., 20, (1991)

[10]

Blu E., Mikhailov, Ozols R., Heat and Mass Transfer in MHD Flows, (1987)

← 1 →