TY - JOUR
T1 - Comparative studies on the control algorithm for the high-density ignition regime in FFHR-d1
AU - Mitarai, Osamu
AU - Sugiyama, Shota
AU - Yanagi, Nagato
AU - Narushima, Yoshiro
AU - Sakamoto, Ryuichi
AU - Goto, Takuya
AU - Matsuura, Hideaki
AU - Sagara, Akio
N1 - Publisher Copyright:
© 2020 The Japan Society of Plasma Science and Nuclear Fusion Research.
PY - 2020
Y1 - 2020
N2 - In the Force Free Helical Reactor FFHR-d1 (R~15.7m, a~2.5m, Bo ~4.5 T, 〈〉 ~5% and the fusion power of 3 GW) [1, 2], it is demonstrated that the thermally unstable operation is better to achieve the higher density and lower temperature plasma (n(0)~ 9 x 1020 m-3 and T(0)~7 keV) than the impurity injection method. One drawback of the thermally unstable operation is a possibility of the thermal runaway when fueling systems have failures. However, we have found that the inherently safe function exists owing to the plasma outward shift during the thermal runaway. Thus we continue to pursue this high-density operation scenario for FFHR-d1. Preliminary estimation of the alpha energy loss fraction of ~3% is obtained for a broad density profile in the high-density ignition regime.
AB - In the Force Free Helical Reactor FFHR-d1 (R~15.7m, a~2.5m, Bo ~4.5 T, 〈〉 ~5% and the fusion power of 3 GW) [1, 2], it is demonstrated that the thermally unstable operation is better to achieve the higher density and lower temperature plasma (n(0)~ 9 x 1020 m-3 and T(0)~7 keV) than the impurity injection method. One drawback of the thermally unstable operation is a possibility of the thermal runaway when fueling systems have failures. However, we have found that the inherently safe function exists owing to the plasma outward shift during the thermal runaway. Thus we continue to pursue this high-density operation scenario for FFHR-d1. Preliminary estimation of the alpha energy loss fraction of ~3% is obtained for a broad density profile in the high-density ignition regime.
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U2 - 10.1585/PFR.15.2405059
DO - 10.1585/PFR.15.2405059
M3 - Article
AN - SCOPUS:85090281699
SN - 1880-6821
VL - 15
JO - Plasma and Fusion Research
JF - Plasma and Fusion Research
M1 - 5059
ER -