MEASUREMENT OF ELECTRICAL CONDUCTIVITY AND RESISTIVITY OF CU-NB18% MICROCOMPOSITE CONDUCTOR AND ITS WELDED JOINT

Mokslas - Lietuvos ateitis Pub Date : 2024-01-17 DOI:10.3846/mla.2024.19110

Paulius Beinoras, Nikolaj Višniakov

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Abstract

Systems generating strong magnetic fields are widely used in modern fundamental and applied research as well as in the most innovative industrial processes. These devices generate magnetic fields that reach 5–100 T and the conductors are subjected to a huge Lorentz force, so the conductor material must be extremely strong (UTS ≥ 700 MPa) and have a good specific electrical conductivity (IACS ≥ 60%). Since traditional conductors such as copper, aluminum, gold, and silver cannot withstand such loads, microcomposite materials have been developed that are characterized by such high strength and good specific electrical conductivity. This paper reviews the specific electrical conductivity and specific electrical resistance characteristics of conductor and factors affecting them, methods of measuring these electrical characteristics as well as properties of Cu-Nb18% microcomposite conductor. This paper also describes the methodology for measuring the specific electrical conductivity and specific electrical resistance of the Cu-Nb18% microcomposite conductor solid and with welded joint (welded by using butt welding). The comparison of application possibilities of used methodologies and obtained characteristics was carried out.

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测量铜铌 18%微复合导体及其焊接接头的导电率和电阻率

产生强磁场的系统广泛应用于现代基础研究和应用研究以及最具创新性的工业流程中。这些设备会产生高达 5-100 T 的磁场，导体会承受巨大的洛伦兹力，因此导体材料必须非常坚固（UTS ≥ 700 MPa），并具有良好的比电导率（IACS ≥ 60%）。由于铜、铝、金和银等传统导体无法承受这样的负荷，因此人们开发出了具有高强度和良好比电导率的微复合材料。本文回顾了导体的比电导率和比电阻特性及其影响因素、测量这些电气特性的方法以及铜铌 18% 微复合导体的特性。本文还介绍了测量固态和带焊接接头（通过对接焊焊接）的 Cu-Nb18% 微复合导体的比电导率和比电阻的方法。对所使用方法的应用可能性和所获得的特性进行了比较。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Mokslas - Lietuvos ateitis

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