论文信息 - Design concept of K-DEMO for near-term implementation

Design concept of K-DEMO for near-term implementation

A Korean fusion energy development promotion law (FEDPL) was enacted in 2007. As a following step, a conceptual design study for a steady-state Korean fusion demonstration reactor (K-DEMO) was initiated in 2012. After the thorough 0D system analysis, the parameters of the main machine characterized by the major and minor radii of 6.8 and 2.1 m, respectively, were chosen for further study. The analyses of heating and current drives were performed for the development of the plasma operation scenarios. Preliminary results on lower hybrid and neutral beam current drive are included herein. A high performance Nb3Sn-based superconducting conductor is adopted, providing a peak magnetic field approaching 16 T with the magnetic field at the plasma centre above 7 T. Pressurized water is the prominent choice for the main coolant of K-DEMO when the balance of plant development details is considered. The blanket system adopts a ceramic pebble type breeder. Considering plasma performance, a double-null divertor is the reference configuration choice of K-DEMO. For a high availability operation, K-DEMO incorporates a design with vertical maintenance. A design concept for K-DEMO is presented together with the preliminary design parameters.

[1] S. Ide,et al. Compact DEMO, SlimCS: design progress and issues , 2009 .

[2] Yican Wu,et al. CAD-based interface programs for fusion neutron transport simulation , 2009 .

[3] X. Litaudon,et al. Conceptual study of a reflector waveguide array for launching lower hybrid waves in reactor grade plasmas , 1995 .

[4] C. Kessel,et al. Simulation of the hybrid and steady state advanced operating modes in ITER , 2007 .

[5] W. M. Tang. Microinstability-based model for anomalous thermal confinement in tokamaks , 1986 .

[6] E. Fable,et al. Particle transport in tokamak plasmas, theory and experiment , 2009 .

[7] H. R. Wilson,et al. A first-principles predictive model of the pedestal height and width: development, testing and ITER optimization with the EPED model , 2011 .

[8] S. Jardin,et al. Dynamic modeling of transport and positional control of tokamaks , 1986 .

[9] R. S. Hemsworth,et al. Status of the ITER heating neutral beam system , 2009 .

[10] X. Litaudon,et al. Steady state long pulse tokamak operation using Lower Hybrid Current Drive , 2011 .

[11] D. Dietderich,et al. Characterization of High Current RRP Wires as a Function of Magnetic Field, Temperature, and Strain , 2009, IEEE Transactions on Applied Superconductivity.