Title :
Thermal, electrical and mechanical response in Nb3Sn superconducting coils
Author :
Ferracin, P. ; Caspi, S. ; Chiesa, L. ; Gourlay, S.A. ; Hafalia, R.R. ; Imbasciati, L. ; Lietzke, A.F. ; Sabbi, G. ; Scanlan, R.M.
Author_Institution :
Lawrence Berkeley Nat. Lab., CA, USA
fDate :
6/1/2004 12:00:00 AM
Abstract :
During a quench, significant temperatures can arise as a magnet´s stored energy is dissipated in the normal zone. Temperature gradients during this process give rise to localized strains within the coil. Reactive forces in the magnet structure balance the electromagnetic and thermal forces and maintain on equilibrium. In this paper we present a complete 3D finite element analysis of a racetrack coil. Specifically, the analysis focuses on thermal, electrical and mechanical conditions in a 10 T Nb3Sn coil built and tested as part of LBNL´s Subscale Magnet Program. The study attempts to simulate time history of the temperature and voltage rise during quench propagation. The transient thermal stress after the quench is then evaluated and discussed.
Keywords :
finite element analysis; niobium alloys; quenching (thermal); superconducting coils; superconducting magnets; thermal analysis; 10 tesla; 3D finite element analysis; LBNL; Nb3Sn; Subscale Magnet Program; electrical response; electromagnetic forces; magnet stored energy; magnet structure; mechanical response; normal zone; quench propagation; racetrack coil; reactive forces; superconducting coils; temperature gradients; thermal forces; thermal response; transient thermal stress; Coils; Electromagnetic forces; Finite element methods; Magnetic analysis; Magnetic field induced strain; Niobium; Temperature; Thermal force; Thermal stresses; Tin; Quench propagation; stress analysis; superconducting magnets; thermal analysis;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2004.829130
