Microstructure and Mechanical Properties of Rapidly Solidified Al-Fe-X Alloys

Milena Voděrová; Pavel Novák; Ivo Marek; Dalibor Vojtech

doi:10.4028/www.scientific.net/KEM.592-593.639

Paper Titles

Standing Contact Fatigue Analyse of Steels with Different Microstructures
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High Temperature Fatigue Strength and Quantitative Metallography of an Eutectic Al-Si Alloy for Piston Application
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Effects of Different Microstructure on Resistance of EA4T Railway Axle Steel of Equal Strength to Fatigue Crack Growth
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Investigation of the Microstructure Factors Affecting the Brittle Fracture Initiation of Pre-Cracked Charpy-Type Samples of VVER-1000 RPV Steel
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Microstructure and Mechanical Properties of Rapidly Solidified Al-Fe-X Alloys
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Heat Treatment Effects on Static and Dynamic Mechanical Properties of Sintered SINT D30 Powder Metal
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Influence of the Composition of Cement Mortars Modified by Lime or Polymers on the Mechanical Properties and Microstructure of Mortars
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Influence of Fly Ash on Abrasion Resistance of Concretes with their Additions
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Relation between Microstructure and Tribological Properties of High Density Polyethylene Hybrid Composites Filled with Untreated Glass Spheres, Talc and Calcium Carbonate
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Microstructure and Mechanical Properties of Rapidly Solidified Al-Fe-X Alloys

Abstract:

Rapidly solidified aluminium alloys have many interesting properties such as higher thermal stability and strength, when compared with conventional cast alloys. Due to these properties, RS alloys seem to be prospective for using in automotive or aircraft industry. Aim of this work was to compare the differences in microstructure of alloys containing Fe, Ni and Cr which were prepared by different solidification rate. Alloys were prepared by melt spinning, melting with follow-up quenching into the water and by conventional casting with pouring into brass mould. Microstructure of prepared alloys was investigated by scanning electron microscope; phase composition was determined by x-ray diffraction. In this experiment, microhardness was measured in the initial state of all types of alloys; rapidly solidified alloys were also annealed to determine thermal stability by microhardness measurement. Results indicate that higher solidification rate refines the microstructure which is composed of supersaturated solid solution of alloying elements in aluminium and stable and meta-stable intermetallic phases. Hardness of the alloys increases and microstructure refines with solidification rate.