MgB 2 cables made of thin wires manufactured by IMD process

Self Cite

Up to now, the highest current densities of MgB2 superconducting wires have been obtained by the internal magnesium diffusion (IMD) method. MgB2 superconductors are especially suitable for DC or AC windings generating low or medium magnetic fields, where thermal stability and low AC losses are important issues. Mechanical, thermal and electrical parameters of the wires are strongly influenced by metallic materials used for the outer sheath. While highly electrical conductive sheath material is beneficial for thermally stable behaviour, it has a great effect on the generation of high eddy current losses. To minimize the contribution of eddy current losses, multi-core MgB2 wires with low purity Cu and Al sheaths were prepared by the IMD process and characterized in detail. Results of low temperature measurements are analysed and discussed in the present work.

Section: Resultssupporting

confidence: 73%

Low‐purity Cu and Al sheathed multi‐core MgB₂ wires made by IMD process

Kòváč

Kováč

Pérez

et al. 2021

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“…While area of boron is larger than Mg in as-drawn wire 7CuD (Mg/B = 0.81-0.87, see figure 10(a)), it is in opposite ratio in as-rolled wire 7CuR (Mg/B = 1.21-1.38, see figure 10(b)). It is due to more densified boron powder by rolling deformation in comparison to drawing [22].…”

Section: Uniformity Of Multi-core Wiresmentioning

confidence: 99%

Longitudinal uniformity of MgB₂ wires made by an internal magnesium diffusion process

Kòváč¹,

Hušek²,

Hain³

et al. 2021

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Single- and multi-core MgB2 wires have been fabricated by an internal Mg diffusion (IMD) process. Wires uniformity after drawing and/or rolling deformation has been studied by optical microscopy and x-ray micro-tomography. Several short samples taken lengthwise between both ends of the wire were annealed and their critical current measured. It was found that I c of the single-core barrier-free MgB2/Fe wire with high fill factor (32.5% of MgB2) vary by 100% towards the averaged I c. Multi-core wire having ∼15.0% of MgB2 and Cu outer sheath shows better uniformity with 25% deviation of I c over the 10 m length, which is still quite low and needs some improvements. It is expected, that improved in-length uniformity can be reached only for filamentary IMD wires with optimized deforming process and mechanically stronger outer sheath.

“…The core uniformity is also challenging in the production of long IMD wires due to the variations in the packing density of boron powder along the IMD wire, leading to changes in the superconducting properties after heat treatment. Therefore, improving the longitudinal uniformity and J e in IMD wires is essential for large-scale applications [11,[16][17][18][19][20][21].…”

Section: Introductionmentioning

confidence: 99%

Transport and structural properties of MgB₂/Fe wires produced by redesigning internal Mg diffusion process

Yetiş¹,

Avcı²,

Karaboğa³

et al. 2022

Self Cite

We report transport, electromechanical, and structural properties of single core MgB2/Fe wire produced using a new fabrication method, called designed IMD process, which relies on the use of non-stoichiometric Mg + B pellets with excess Mg in place of a central Mg rod used in the standard internal Mg diffusion (IMD) method. Structural analysis revealed the successful formation of a porous MgB2 structure in the center and a dense circular MgB2 layer surrounding this structure in the designed-IMD wire. Fast transport I –V measurements showed that the designed IMD method increased engineering critical current density (Je) up to twice that of the IMD wires in self-field. The central porous MgB2 structure shared the applied current and indirectly behaved as an internal stabilizer against quench damage at high applied currents.