Title :
Finite element analysis of drawing of multifilamentary wires
Author :
Peng, X. ; Sumption, M.D. ; Collings, E.W.
Author_Institution :
Ohio State Univ., Columbus, OH, USA
fDate :
6/1/2005 12:00:00 AM
Abstract :
Co-deformation and possible fracture during the drawing of internal tin multifilamentary superconductor wires was investigated by FEM simulation. A thermomechanical, elasto-plastic finite-element method was applied to simulate the drawing process. The experimental conditions and materials of interest to composite superconductor manufacture were assumed. In this 3D FEM model, the billet configuration was 6 around 1, with the subelement simulated as an assembly of Cu-clad Nb filaments array enclosing a pure Sn core. The outer sleeve was Cu. The initial state of the billet was assumed to be one without subelement-to-subelement bonding. A simple ductile fracture criterion was employed in this investigation to estimate the possible occurrence of fracture with different area reductions.
Keywords :
deformation; finite element analysis; fracture; mechanical stability; mechanical strength; multifilamentary superconductors; wire drawing; Nb filaments array; Nb-Cu; Nb3Sn; billet configuration; codeformation; composite superconductor; drawing process; ductile fracture criterion; elasto-plastic finite element method; finite element analysis; multifilamentary superconductor wires; subelement-to-subelement bonding; thermomechanical finite element method; Assembly; Billets; Composite materials; Finite element methods; Manufacturing; Multifilamentary superconductors; Superconducting filaments and wires; Superconducting materials; Thermomechanical processes; Tin; Drawing; FEM; multifilamentary wire;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2005.848955
