Title :
Performance test of a CuNb reinforced (Nb,Ti)3Sn coil fabricated by the react and wind method
Author :
Awaji, Satoshi ; Watanabe, Kazuo ; Nishijima, Gen ; Takahashi, Kohki ; Motokawa, Mitsuhiro ; Jikihara, Kazunori ; Sugizaki, Hiroyuki ; Sakuraba, Junji
Author_Institution :
High Field Lab. for Supercond. Mater., Tohoku Univ., Sendai, Japan
fDate :
3/1/2002 12:00:00 AM
Abstract :
In order to investigate the stress-strain and superconducting properties for a react and wind method under large electromagnetic stress states, a test coil with a large bore was fabricated using the highly strengthened CuNb/(Nb,Ti)3Sn wire. We found that the analysis on the basis of the bending and tensile strains successfully explains the obtained mechanical properties. The operation currents could be applied, until the electromagnetic stress and strain became about 340 MPa and 0.34%, respectively. This is mainly due to not only the strong mechanical property of CuNb/(Nb,Ti)3Sn wire but also the compression stress induced by the thermal contraction. As a result of the bending and tensile strain analysis for the critical current, the ratio of the quench current to the critical current was about 86% at 11 T and then decreased with decreasing magnetic fields.
Keywords :
bending; copper alloys; critical currents; multifilamentary superconductors; niobium alloys; stress-strain relations; superconducting coils; superconducting magnets; tin alloys; titanium alloys; winding (process); 11 T; CuNb-(NbTi)3Sn; bending strains; bronze processed multifilamentary wire; compression stress; critical current; high strength wire; highly strengthened wire; large bore; large electromagnetic stress states; operation currents; quench current; react and wind method; stress-strain properties; superconducting coils; superconducting magnets; superconducting properties; tensile strains; test coil; thermal contraction; Boring; Critical current; Mechanical factors; Superconducting coils; Superconducting filaments and wires; Tensile strain; Tensile stress; Testing; Thermal stresses; Tin;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2002.1018734
