Feasibility Evaluation of Cu-Nb Microcomposite Joints Formed by Magnetic Field Pressing for Pulsed Power Applications

Nikolaj Višniakov; Gediminas Mikalauskas; Raimonda Lukauskaitė; Jelena Škamat; Olegas Černašėjus; Vitalij Novickij

doi:10.17559/TV-20161222114409

Tehnički Vjesnik (Jan 2018)

Feasibility Evaluation of Cu-Nb Microcomposite Joints Formed by Magnetic Field Pressing for Pulsed Power Applications

Nikolaj Višniakov,
Gediminas Mikalauskas,
Raimonda Lukauskaitė,
Jelena Škamat,
Olegas Černašėjus,
Vitalij Novickij

Affiliations

Nikolaj Višniakov: Vilnius Gediminas Technical University, Faculty of Mechanics, Welding Research and Diagnostics Laboratory, Basanavičiaus str. 28, LT-03227, Vilnius, Lithuania
Gediminas Mikalauskas: Vilnius Gediminas Technical University, Faculty of Mechanics, Department of Material Science and Welding, Basanavičiaus str. 28, LT-03227, Vilnius, Lithuania
Raimonda Lukauskaitė: Vilnius Gediminas Technical University, Faculty of Mechanics, Welding Research and Diagnostics Laboratory, Basanavičiaus str. 28, LT-03227, Vilnius, Lithuania
Jelena Škamat: Vilnius Gediminas Technical University, Institute of Thermal Insulation, Linkmenų str. 28, LT-08217, Vilnius, Lithuania
Olegas Černašėjus: Vilnius Gediminas Technical University, Faculty of Mechanics, Department of Material Science and Welding, Basanavičiaus str. 28, LT-03227, Vilnius, Lithuania
Vitalij Novickij: Vilnius Gediminas Technical University, Faculty of Electronics, Institute of High Magnetic Fields, Naugarduko str. 41, LT-03227, Vilnius, Lithuania

DOI: https://doi.org/10.17559/TV-20161222114409
Journal volume & issue: Vol. 25, no. Supplement 2
pp. 326 – 329

Abstract

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In this work we have evaluated the feasibility of the magnetic field pressing technology for formation of Cu-Nb joints for further pulsed power applications. The electrical and mechanical properties of joints have been investigated. The structure of Cu-Nb conductors joints was investigated using optical and scanning electron microscopy. The mechanical characteristics have been evaluated using tensile tests. It has been determined that the maximum tensile strength of 350 MPa could be achieved, which is 30,4 % of a Cu-Nb wire strength. The applied pressing technology allowed minimizing the defects in the microcomposite structure due to solid-state joining process, however the resultant decrease of conductivity by 10 % influenced an increase of the Joule heating. After a 2 min 200 A current flow the difference of 54,4 °C between the conductor and the joint area was observed. It was concluded that the Cu-Nb joints formed by magnetic field pressing are applicable for pulsed magnet setups where non-destructive joints are required.

Published in Tehnički Vjesnik

ISSN: 1330-3651 (Print); 1848-6339 (Online)
Publisher: Faculty of Mechanical Engineering in Slavonski Brod, Faculty of Electrical Engineering in Osijek, Faculty of Civil Engineering in Osijek
Country of publisher: Croatia
LCC subjects: Technology: Engineering (General). Civil engineering (General)
Website: http://hrcak.srce.hr/tehnicki-vjesnik

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