Title :
Improvement of Ic by loading and unloading bending strain for high strength Nb3Sn wires
Author :
Awaji, Satoshi ; Oguro, Hidetoshi ; Nishijima, Gen ; Watanabe, Kazuo ; Katagiri, Kazumune ; Miyoshi, Kazutomi ; Meguro, Shin-ichiro
Author_Institution :
High Field Lab. for Supercond. Mater., Tohoku Univ., Sendai, Japan
fDate :
6/1/2004 12:00:00 AM
Abstract :
We investigated the influence of the repeated bending strain on the critical current properties. The bending strain was applied to the Ti-added high strength CuNb/Nb3Sn wires at room temperature and released. We define this loading and unloading bending strain at room temperature as a "pre-bending" treatment. We found that the critical current Ic is much enhanced by applying the pre-bending treatment. The maximum enhancement of Ic due to the pre-bending treatment is about twice at 17 T, for instance. The stress dependence of Ic shows that Ic is improved in low stress states by pre-bending treatment. This phenomenon can be described well by the uniaxial strain analysis on the basis of the strain distribution. In addition, the increase of the maximum critical current of the strain dependent Ic is also observed. This may be related to the reduction of the radial/tangential prestrain.
Keywords :
bending; copper alloys; critical current density (superconductivity); niobium alloys; stress effects; superconducting tapes; tin alloys; type II superconductors; 17 T; CuNb; CuNb/Nb3Sn wires; Ic improvement; Nb3Sn; Ti-added wire; bending strain; critical current properties; pre-bending treatment; radial prestrain reduction; room temperature; strain distribution; stress dependence; tangential prestrain reduction; uniaxial strain analysis; Capacitive sensors; Critical current; Niobium; Strain measurement; Stress; Superconducting coils; Superconducting filaments and wires; Temperature; Tin; Uniaxial strain; $hboxNb_; Bending strain; critical current; hboxSn$; tansile strain;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2004.830348
