The Helias reactor is an upgraded version of the Wendelstein 7-X experiment.
A straightforward extrapolation of Wendelstein 7-X leads to HSR5/22, which has
5 field periods and a major radius of 22 m. HSR4/18 is a more compact Helias reactor
with 4 field periods and an 18 m major radius. Stability limit and energy
confinement times are nearly the same as in HSR5/22, thus the same fusion power (3000 MW) is expected in
both configurations. Neoclassical transport in HSR4/18 is very low, and the effective helical
ripple is below 1%. The article describes the power balance of the Helias reactor, and the blanket
and maintenance concepts. The coil system of HSR4/18 comprises 40 modular coils with NbTi
superconducting cables. The reduction from 5 to 4 field periods
and the concomitant reduction in size will also reduce the cost of the Helias reactor.
The Helias ignition experiment is an upgraded version of the Wendelstein 7-X experiment. The magnetic configuration is a four-period Helias configuration (major radius 18 m, plasma radius 2.0 m, B = 4.5 T), which presents a more compact option than the five-period configuration. Much effort has been focused on two versions of the four-period configuration. One option is the power reactor HSR4/18 providing at least 3 GW of fusion power and the second is the ignition experiment HSR 4/18i aiming at a minimum of fusion power and the demonstration of self-sustaining burn. The design criteria of the ignition experiment HSR 4/18i are the following: The experiment should demonstrate a safe and reliable route to ignition; self-sustained burn without external heating; steady-state operation during several hundred seconds; reliability of the technical components and tritium breeding in a test blanket. The paper discusses the technical issues of the coil system and describes the vacuum vessel and the shielding blanket. The power balance will be modelled with a transport code and the ignition conditions will be investigated using current scaling laws of energy confinement in stellarators. The plasma parameters of the ignition experiment are: peak density 2–3×1020 m−3, peak temperature 11–15 keV, average beta 3.6% and fusion power 1500–1700 MW.
The dispersion relation for gravitational instability has been given within the framework of a two-fluid theory. It has been shown that the Jeans criterion is changed by finite Larmor radius and by collisions for waves propagating perpendicular to the magnetic field. The critical wavenumber for instability decreases with increasing Alfvén velocity and with increasing gyroviscosity. Instability does not set in with overstabiity.
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