Title :
Thermal and structural analysis of the ITER ELM coils
Author :
Brooks, A.W. ; Zhai, Yujia ; Daly, Eamonn ; Kalish, M. ; Pillsbury, R. ; Khodak, Andrei
Author_Institution :
Princeton Plasma Phys. Lab., Princeton, NJ, USA
Abstract :
A thermal and structural analysis of the ELM Coil design for ITER is presented. The ELM Coils are constructed using a jacketed mineral insulated conductor of CuCrZr, MgO and Inconel 625, rigidly mounted to the vacuum vessel inner shell, behind the Blanket Modules. Since the coils are not designed to be remotely maintained, a major issue is demonstrating the structural integrity against fatigue and crack propagation over an estimated 100 million cycles arising from operation at 5 hz in a high magnetic field. The temperature rises from ohmic and nuclear heating produce mean thermal stresses that further limit the allowable alternating stresses. Thermal growth also imparts large forces which must be reacted by the Vacuum Vessel. This paper presents the analysis and results with particular attention to the design criteria which is unique to the In-Vessel Coils.
Keywords :
Tokamak devices; coils; cracks; fatigue; fusion reactor blankets; fusion reactor design; plasma instability; plasma toroidal confinement; thermal analysis; thermal stresses; CuCrZr; ITER ELM coil design; Inconel 625; MgO; blanket modules; crack propagation; design criteria; fatigue; frequency 5 Hz; high magnetic field; in-vessel coils; jacketed mineral insulated conductor; mean thermal stresses; nuclear heating; ohmic heating; structural analysis; structural integrity; thermal analysis; thermal growth; vacuum vessel inner shell; Coils; Conductors; Finite element analysis; Rails; Stress; Water heating; Analysis; ELM Coil; ITER;
Conference_Titel :
Fusion Engineering (SOFE), 2013 IEEE 25th Symposium on
Conference_Location :
San Francisco, CA
Print_ISBN :
978-1-4799-0169-2
DOI :
10.1109/SOFE.2013.6635513
