Litcius/Paper detail

Fatigue behaviors and damage mechanisms for Nb3Sn triple-helical structure at liquid nitrogen temperature

Lang Jiang, Zhiwei Zhang, Zhen Yu, Jun Zhou, Huadong Yong, Xingyi Zhang

2023Superconductivity12 citationsDOIOpen Access PDF

Abstract

Nb3Sn triple-helical structure is the elementary structure in the superconducting cable of ITER magnets and undergoes prolonged fatigue loading in extreme environments leading to serious damage degradation. In this paper, the fatigue behaviors of the Nb3Sn triple-helical structure have been investigated by the strain cycling fatigue experiments at liquid nitrogen temperature. The results indicate that Nb3Sn triple-helical structures with short twist-pitches possess excellent fatigue damage resistance than that of long twist-pitches, such as longer fatigue life, slower damage degradation, and smaller energy dissipation. Meanwhile, a theoretical model of damage evolution has been established to reveal the effects of twist-pitches on fatigue properties for triple-helical structures, which is also validated by the present experimental data. Furthermore, one can see that the Nb3Sn superconducting wires in a triple-helical structure with the shorter twist-pitches have a larger elongation of helical structure and less cyclic deformation, which can be considered as the main mechanism of better fatigue damage properties for the triple-helical structures during the strain cycling processes. These findings provide a better understanding of the fatigue properties and damage mechanisms for Nb3Sn triple-helical structures in superconducting cables of ITER magnets.

Topics & Concepts

Materials scienceTwistLiquid nitrogenDeformation (meteorology)SuperconductivityDegradation (telecommunications)DissipationTriple junctionStrain (injury)ElongationComposite materialCondensed matter physicsPhysicsUltimate tensile strengthMedicineInternal medicineOptoelectronicsGeometryTelecommunicationsQuantum mechanicsComputer scienceMathematicsThermodynamicsSuperconducting Materials and ApplicationsMechanical stress and fatigue analysisElectromagnetic Launch and Propulsion Technology