Asymmetric vertical displacement event (AVDE) disruptions in ITER should produce a relatively small electromechanical force on the conducting structures surrounding the plasma, in contrast to previous predictions based on JET data. This is shown in simulations [1, 2] with theM3D 3DMHD code [3] and confirmed in JET experiments [4] in which the current was quenched with massive gas injection (MGI). In ITER the current quench (CQ) time tCQ is less than or equal to the resistive wall penetration time twall . JET is in a different param- eter regime, with tCQ/twall > 1. JET simulations were validated by comparison [1] to JET shot 71985 data and were in good agreement. The wall time twall was then artificially increased, keeping tCQ fixed, and it was found that the wall force decreased. The reduction of the asymmetric wall force was also found in analysis of experimental data of JET MGI mitigated disruption shots, although the published data only concerned the symmetric wall force [4]. Further simulations [2] were carried out of ITER AVDEs. For tCQ/twall 1, the force was 4MN, comparable to the force in JET. A fast CQ may cause production of runaway electrons (REs). Simulations using a modified version of M3D with a fluid RE model [5] will be presented.
Reduction of Asymmetric wall force in JET and ITER including Runaway Electrons
Paccagnella R;
2018
Abstract
Asymmetric vertical displacement event (AVDE) disruptions in ITER should produce a relatively small electromechanical force on the conducting structures surrounding the plasma, in contrast to previous predictions based on JET data. This is shown in simulations [1, 2] with theM3D 3DMHD code [3] and confirmed in JET experiments [4] in which the current was quenched with massive gas injection (MGI). In ITER the current quench (CQ) time tCQ is less than or equal to the resistive wall penetration time twall . JET is in a different param- eter regime, with tCQ/twall > 1. JET simulations were validated by comparison [1] to JET shot 71985 data and were in good agreement. The wall time twall was then artificially increased, keeping tCQ fixed, and it was found that the wall force decreased. The reduction of the asymmetric wall force was also found in analysis of experimental data of JET MGI mitigated disruption shots, although the published data only concerned the symmetric wall force [4]. Further simulations [2] were carried out of ITER AVDEs. For tCQ/twall 1, the force was 4MN, comparable to the force in JET. A fast CQ may cause production of runaway electrons (REs). Simulations using a modified version of M3D with a fluid RE model [5] will be presented.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
