Thermal stability of superconducting multifilamentary wire with multiply connected stabilizing regions

Experience in developing superconducting solenoids from multifilamentary niobium-tin wires without stabilizing copper is presented. Such wires are the components of the conductor of the Tokamak 15 magnetic system. The heat treatment of the wire was carried out after winding the solenoid. Tests showe

Using superconducting Nb Ti magnets it is possible to generate fields up to 12 T maximum, if intrinsica/ly stable material is used, at 1.5 K. The filament diameters required to ensure intrinsic stable behaviour and their dependence on temperature are presented. A t the highest current density so far

Bronze processed multifilamentary Nb3Sn superconducting wires, with a CuNb reinforcing stabilizer instead of the conventional Cu stabilizer, were fabricated. The mechanical properties and the strain dependence of the critical current Ic were evaluated at 4.2 K and a magnetic field of 15 T. A remarka

The stability of two kinds of conductors, CuNb/(Nb,Ti)~Sn and Cu/(Nb,Ti)~Sn has been studied in order to obtain basic information for the future compact design of high field superconducting magnets using a (Nb,TiI,Sn conductor stabilized with a high strength-high conductivity CuNb in-situ composite.

A quench in modern multifilament conductors with voltag~current characteristics, broadened due to a longitudinal inhomogeneity of a critical current, occurs at electric fields high enough to be easily registered. It provides an opportunity to control superconducting solenoids made of such conductors

The eects of niobium content in the Cu±Nb microcomposite on the mechanical property and the axial tensile or transverse compressive stress/strain characteristics of the critical current I c in a bronze processed Nb 3 Sn multi®lament superconducting wire with the Cu±Nb microcomposite were evaluated a