This should allow sustainable stability in the larger Tokamaks.
Yet i never had much faith in the whole design concept and it is a money pig that has gone on for fifty years. At least now a wide range of alternatives are been funded as well. Unfortunately they all seem to get close, but never a tomato.
My own work is way to soon to address all this easily. Yet our knowledge of the additional states available in elements is powerfully suggestive of resonance solutions been possible...
Railguns Stabiliize ITER Nuclear Fusion Plasma Three Times Faster than Gas Guns
| January 26, 2019
One
of the problems preventing the Multi-billion dollar ITER nuclear fusion
project from scaling to provide commercial energy are disruptions of
the plasma. Disruptions are sudden events that can halt fusion reactions and damage the tokamaks.
Princeton has developed an electromagnetic particle injector (EPI)
which is a type of railgun that fires a high-velocity projectile from a
pair of electrified rails into a plasma on the verge of disruption.
The
projectile, called a “sabot,” releases a payload of material into the
center of the plasma that radiates, or spreads out, the energy stored in
the plasma, reducing its impact on the interior of the tokamak.
Current systems release pressurized gas or gas-propelled shattered
pellets using a gas valve into the plasma, but with velocity limited by
the mass of the gas particles.
The risk of disruptions is particularly great for ITER, the large
international tokamak under construction in France to demonstrate the
feasibility of fusion power. ITER’s dense, high-power discharges of
plasma, the state of matter that fuels fusion reactions, will make it
difficult for current gas-propelled methods of mitigation to penetrate
deeply enough into the highly energetic ITER plasma to take good effect.
On ITER, mitigation is desired in less than 20 milliseconds, or
thousands of a second, from the warning of a disruption, with 10
milliseconds as ideal. Tests of the EPI prototype show that it can
deliver a payload of correctly sized particles in fewer than 10
milliseconds, compared with 30 milliseconds for gas-propelled systems.
Nuclear Fusion Journal – Electromagnetic particle injector for fast time response disruption mitigation in tokamaks
Abstract
A novel, rapid time-response, disruption mitigation system referred to as the electromagnetic particle injector (EPI) is described. This method can accurately deliver the radiative payload to the plasma center on a less than 10 ms time scale, much faster, and deeper, than what can be achieved using conventional methods. The EPI system accelerates a sabot electromagnetically. The sabot is a metallic capsule that can be accelerated to desired velocities by an electromagnetic impeller.
A novel, rapid time-response, disruption mitigation system referred to as the electromagnetic particle injector (EPI) is described. This method can accurately deliver the radiative payload to the plasma center on a less than 10 ms time scale, much faster, and deeper, than what can be achieved using conventional methods. The EPI system accelerates a sabot electromagnetically. The sabot is a metallic capsule that can be accelerated to desired velocities by an electromagnetic impeller.
At the
end of its acceleration, within 2 ms, the sabot will release a
radiative payload, which is
composed of low-z granules, or a shell
pellet containing smaller pellets. The primary advantage of the EPI
concept over gas propelled systems is its potential to meet short
warning time scales, while accurately delivering the required particle
size and materials at the velocities needed for achieving the required
penetration depth in high power ITER-scale discharges for thermal and
runaway current disruption mitigation. The present experimental tests
from a prototype system have demonstrated the acceleration of a 3.2 g
sabot to over 150 m s−1 within 1.5 ms, consistent with the calculations,
giving some degree of confidence that larger ITER-scale injector can be
developed.
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