AC losses in single-core superconducting composite conductors

The influence of dc transport currents on alternating-field hysteresis loss was investigated for a single core superconducting wire. The configuration of the sample coil simulates a tight solenoidal winding of superconducting magnets, and the field is a small transverse alternating field applied on

ac losses have been investigated experimentally as we# as theoretically in tapes having on the surface several normal conducting and/or superconducting layers. The superconducting layers under investigation have been Nb3Sn on a niobium substrate and Nb3Ge on a stainless steel substrate. It has been

I~q a previous paper 1 the author derived certain relationships connecting the size of a transformer and the acceptable core and leakage flux densities. Various simplifying assumptions were made, but all of these made the calculated size smaller than that of any transformer that could actually be co

A C losses have been measured in prototype tubular composite conductors of a design proposed for superconducting ac power transmission lines. The conductors were of 15 and 19 mm diameter, with a niobium surface layer bonded to a copper substrate either directly or via an intermediate layer of niobiu

The influence of oscillating magnetic fields on the dc transport current in a single core superconducting wire has been studied by observing the terminal voltage of the wire. The voltage versus oscillating field characteristics can be explained quantitatively by a theoretical analysis based on the c