Title :
Thermal-Mechanical Properties of Epoxy-Impregnated Bi-2212/Ag Composite
Author :
Pei Li ; Yang Wang ; Godeke, Arno ; Liyang Ye ; Flanagan, Gene ; Tengming Shen
Author_Institution :
Magn. Syst. Dept., Fermi Nat. Accel. Lab., Batavia, IL, USA
Abstract :
Knowledge of the thermal-mechanical properties of epoxy/superconductor/insulation composite is important for designing, fabricating, and operating epoxy impregnated high field superconducting magnets near their ultimate potentials. We report measurements of the modulus of elasticity, Poisson´s ratio, and the coefficient of thermal contraction of epoxy-impregnated composite made from the state-of-the-art powder-in-tube multifilamentary Ag/Bi2Sr2CaCu2Ox round wire at room temperature and cryogenic temperatures. Stress-strain curves of samples made from single-strand and Rutherford cables were tested under both monotonic and cyclic compressive loads, with single strands insulated using a thin TiO2 insulation coating and the Rutherford cable insulated with a braided ceramic sleeve.
Keywords :
Poisson ratio; bismuth compounds; calcium compounds; composite superconductors; high-temperature superconductors; resins; silver; stress-strain relations; strontium compounds; superconducting magnets; Bi2Sr2CaCu2O-Ag; Poisson´s ratio; Rutherford cables; braided ceramic sleeve; cryogenic temperature; cyclic compressive load; elasticity modulus; epoxy impregnated composite; epoxy-superconductor-insulation composite; high field superconducting magnets; monotonic compressive load; powder-in-tube multifilamentary round wire; stress-strain curves; thermal contraction coefficient; thermal-mechanical properties; Cable insulation; Magnetomechanical effects; Strain; Stress; Superconducting magnets; Temperature measurement; Wires; Bi-2212/Ag; composite material modeling; mechanical property; strain; thermal contraction; thermal contraction, composite material modeling;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2014.2376178
