The present work pertains to the improvement of high temperature stability of age hardenable AA2219 aluminium-copper (6.3%) alloy. Addition of scandium, magnesium and zirconium to the base metal AA2219 was adopted to improve this high temperature stability. These additions were systematically varied by preparing alloys of different composition using gas tungsten arc melting. Long time ageing studies and impression creep technique were used to study the high temperature stability of the alloys. These modified compositions of the alloy resulted in fine equiaxed grains, refined eutectics, large number of high temperature stable and finer precipitates. Among all the compositions, 0.8% Sc + 0.45% Mg + 0.2% Zr addition was found to be significant in improving the high temperature stability of AA2219 alloy. This may be attributed to the possible microstructural changes, solute enrichment of the matrix and pinning of the grain boundaries by the finer precipitates. © 2007.

M. Kamaraj

Department of Metallurgical and Materials Engineering

P. Naga Raju

Addition reactions

Age hardening

Grain boundaries

Metallographic microstructure

Precipitates

Zircon

GAS TUNGSTEN ARC MELTING

HIGH TEMPERATURE STABILITY

IMPRESSION CREEP TECHNIQUE

Aluminum alloys

IIT Madras is a public technical and research university located in Chennai, Tamil Nadu. Founded in 1959, it is recognised as an Institute of National Importance.

IIT Madras has been ranked as the top engineering institute in India for four years in a row by the National Institutional Ranking Framework of the MHRD

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IIT Madras

Materials Science and Engineering A

The effect of scandium additions to 2219 aluminium alloy weld metal has been investigated. At low levels (0.16%) of scandium, in spite of grain refinement in the weld metal, improvement in the mechanical properties has been nominal. At higher levels of scandium (0.37%), a substantial improvement in the tensile properties has been obtained. Further improvement in mechanical properties has been achieved by adding small amounts of magnesium. Transmission electron microscopy revealed the presence of fine precipitate particles in the scandium containing weld metals. Electron probe microanalysis (EPMA) and SEM-EDX revealed extensive copper segregation to grain and subgrain boundaries. The presence of scandium reduces the severity of segregation by producing fine equlaxed grains in the weld metals and also by refining the grain substructure. The morphology and size of the high copper eutectic phase at grain boundaries and sub-boundaries have been found to be finer and well distributed in the case of scandium containing weld metals. EPMA linescans and quantitative analyses proved that the depletion of copper in the matrix is minimised as a result of the fine grained structure. © 2005 Institute of Materials, Minerals and Mining.

Science and Technology of Welding and Joining

Improving mechanical properties of 2219 aluminium alloy GTA welds by scandium addition

Izvestiya Rossiiskoi Akademii Nauk. Seriya Geograficheskaya.

Materials Science and Engineering: A

A 2xxx aluminum alloy crept at medium temperature: role of thermal activation on dislocation mechanisms

Acta Materialia

Final cell distribution in a Zener pinned structure

Effect of Mg addition on the creep and yield behavior of an Al–Sc alloy

Microstructure and high temperature stability of age hardenable AA2219 aluminium alloy modified by Sc, Mg and Zr additions

Journal	Materials Science and Engineering A
ISSN	09215093
Open Access	No