Abstract
The nature of alternating current transfer via metallic materials is specific, since the current density tends to be inhomogeneous across the cross-section of the conductor and the skin effect tends to occur. However, the influence of this effect on the behaviour of the conductor can be optimized via the design and fabrication procedures. The study presents innovative design of an Al–Cu clad conductor, which is supposed to affect favourably the influence of the skin effect. The clad conductors of various diameters (20 mm, 15 mm, and 10 mm) were fabricated via rotary swaging at room temperature, and their electric characteristics were subsequently examined both experimentally and via numerical simulations. Structure analyses performed to document the effects of the swaging technology on the development of substructure and characteristic structural features were carried out by scanning electron microscopy (electron backscatter diffraction analyses), and transmission electron microscopy. The results showed that the design of the composite has a favourable effect on decreasing the power losses during alternating current transfer and that the substructure development affected favourably the electric resistance of the conductor. The highest electric resistance was measured for the composite conductor with the diameter of 20 mm (1.8% increase compared to electric resistance during transfer of direct current). This value then decreased to 0.6%, and 0.1% after swaging down to the diameters of 15 mm, and 10 mm; the 10 mm composite featured the finest grains, partially restored structure, and texture randomization compared to the 20 mm and 15 mm composites. Manufacturing of the clad composite via rotary swaging imparted advantageous combinations of both the electric and mechanical properties, as swaging also introduced increased microhardness.
Highlights
Clad composites consisting of metallic components, sometimes denoted as metallic laminates, are gaining increasing attention throughout numerous industrial branches and typically consist of two or more elements, for example Al plus Mg [1], Ni [2], or Sn [3], Cu plus Ti [4], Ni [5], or steel [6], combinations of Al and Cu plus Mg [7], or Zn [8], and more
The highest electric resistance was measured for the composite conductor with the diameter of 20 mm (1.8% increase compared to electric resistance during transfer of direct current)
The study was focused on characterizing the structure development within innovative Al–Cu clad composite conductors with the diameters of 20 mm, 15 mm, and 10 mm prepared via room temperature rotary swaging, and correlating the occurring structural features with the behaviours of the conductors during transfer of alternating current (AC)
Summary
Clad composites consisting of metallic components, sometimes denoted as metallic laminates, are gaining increasing attention throughout numerous industrial branches (automotive, marine, aerospace, etc.) and typically consist of two or more elements, for example Al plus Mg [1], Ni [2], or Sn [3], Cu plus Ti [4], Ni [5], or steel [6], combinations of Al and Cu plus Mg [7], or Zn [8], and more. Most of the SPD methods are discontinuous and are designed to process small bulk samples For this reason, researchers advantageously use other processing methods based on imposing high shear strain into the processed materials leading to production of well-bonded composites featuring advantageous fine-grained structures (e.g., combinations of stir casting and cryorolling [22], or repeated press and rolling [23]). Materials 2022, 15, 650 reason, the presented study focuses on characterization of the electric conductivity of innovative self-designed Al–Cu clad conductors fabricated via room temperature rotary swaging during AC transfer. S0ws,whSaengreinaSgr0ed, ciSernso,asrrsee-sspceercocttsiisov-nesleaycl.tiaorneaalsaorefatshoef the Al–Cu composites Al–Cu composites at at inlet and outlet from inlet and outlet from swaging dies, respectively
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