Author_Institution :
45 Village Rd., Sea Bright, NJ, USA
Abstract :
The plasma kinetic temperature and density changes, each per an injected fuel density rate increment, control the energy supplied by a thermonuclear fusion reactor in a power production cycle. This could include simultaneously coupled control objectives for plasma current, horizontal and vertical position, shape and burn control. The minimum number of measurements required, use of indirect (not plasma parameters) system measurements, and distributed control procedures for burn control are to be verifiable in a time dependent systems code. The International Thermonuclear Experimental Reactor (ITER) has the need to feedback control both the fusion output power and the driven plasma current, while avoiding damage to diverter plates. The system engineering of fusion reactors must be performed to assure their development expeditiously and effectively by considering reliability, availability, maintainability, environmental impact, health and safety, and cost
Keywords :
Tokamak devices; distributed control; feedback; fusion reactor design; fusion reactors; position control; shape control; ITER; International Thermonuclear Experimental Reactor; availability; burn control; distributed control procedures; diverter plates; driven plasma current; feedback control; fusion output power; fusion reactor control; horizontal position control; injected fuel density rate increment; plasma current control; plasma density; plasma kinetic temperature; power production cycle; reliability; shape control; simultaneously coupled control objectives; thermonuclear fusion reactor; time dependent systems code; vertical position control; Fuels; Fusion reactors; Inductors; Kinetic theory; Plasma density; Plasma measurements; Plasma temperature; Shape control; Temperature control; Time measurement;
