Title :
Three-Dimensional Magnetic and Mechanical Finite-Element Analysis of the HTS Insert Coil
Author :
Pes, Chhon ; Devaux, Melanie ; Mayri, C. ; Rey, J.M.
Author_Institution :
DSM/IRFU, CEA Saclay, Gif-sur-Yvette, France
Abstract :
Future accelerator magnets will need to reach field in the 20-T range. Reaching such a magnetic field is a challenge only attainable using high-temperature superconductor (HTS) material. The high current densities and stress levels needed to satisfy the design criterion of such magnets make YBaCuO superconductor the most appropriate candidate. The HFM EUCARD program is aimed to design and manufacture a dipole insert made of HTS material generating 6 T inside a Nb3Sn dipole of 13 T at 4.2 K. In the HTS insert, engineering current densities higher than 250 A/mm2 under 19 T are required to reach the performances. This paper summarizes the results of magnetic and mechanical finite element analysis of the HTS dipole insert magnet. The nonlinearity of the ferromagnetic material is also taken into account. The mechanical analysis of the magnet is carried out under Lorentz forces.
Keywords :
accelerator magnets; barium compounds; ferromagnetic materials; finite element analysis; power engineering computing; superconducting magnets; yttrium compounds; 3D magnetic finite-element analysis; 3D mechanical finite-element analysis; HFM EUCARD program; HTS dipole insert magnet; HTS insert coil; HTS material; Lorentz forces; ferromagnetic material nonlinearity; future accelerator magnets; high current densities; high-temperature superconductor material; stress levels; temperature 4.2 K; yttrium barium copper oxide superconductor; Coils; High-temperature superconductors; Loading; Magnetomechanical effects; Stress; Superconducting magnets; $hbox{Nb}_{3} hbox{Sn}$ dipole; Finite-element analysis; HTS dipole insert; Lorentz forces; Von Mises stress; magnetic nonlinearity;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2013.2283015
