Effect of bronze on the compression of Nb3Sn in multifilamentary conductors

Short Jc samples and small coils wound from bronze-processed multifilamentary Nb3Sn wires were reacted at 700°C, both under vacuum and under 20 MPa argon pressure for various times and subsequently tested in an applied transverse magnetic field at 4.2 K. High pressure reaction enhanced the Nb3Sn lay

The critical current I c of Nb aSn conductors containing 1615 or 3721 filaments was measured in magnetic flux densities up to 18 7". The magnetic field was generated by a Bitter magnet. The overall current density of the conductor was 5 x 104 A cm-2 at 10 Tand 5 x 103 A cm -2 at 18 7". Values of up

Multifilamentary Nb3Sn composite conductors with 65 880 and 421 160 filaments have been fabricated in long lengths by the internal tin-diffusion method. Filament diameters are in the range from 31.1 nm to 274 nm. Conductors were heat treated for 1 to 53 days at various temperatures from 400°C to 700

A.c. losses for a practical bronze-processed Nb3Sn multifilamentary composite were measured over a wide range of amplitudes (0 ~ B m ~< 14 T, 0 ~Bdc <~ 1 0 T) in transverse magnetic field with trapezoidal wave forms. The composite had a Nb or Ta barrier for ptoecting the Cu stabilizer from Sn diffus

Reduced sized cable-in-conduit Nb3Sn conductors were fabricated with various void fractions as a parameter, before fabricating full size conductors. The relation between critical current and bending strain was investigated. The Nb3Sn conductors had a 6 x 3 strand cable in a conduit with 0.61 mm diam

Room temperature tensile testing has been carried out on a number of multifilamentary Nb3 Sn superconductivity wires. Metallographic studies of the tested wires suggest that filament cracking does not occur until strains approaching 1% have been reached. This conclusion has been confirmed for one of