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Friction-stir welding effects on microstructure and fatigue of aluminum alloy 7050-T7451

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Abstract

Aluminum alloy 7050 was friction-stir welded (FSW) in a T7451 temper to investigate the effects on the microstructure and mechanical properties. Results are discussed for the as-welded condition (as-FSW) and for a postweld heat-treated condition consisting of 121 °C for 24 hours (as-FSW + T6). Optical microscopy and transmission electron microscopy (TEM) examination of the weld-nugget region show that the FS welding process transforms the initial millimeter-sized pancake-shaped grains in the parent material to fine 1 to 5 µm dynamically recrystallized grains; also, the FS welding process redissolves the strengthening precipitates in the weld-nugget region. In the heat-affected zone (HAZ), the initial grain size is retained, while the size of the strengthening precipitates and of the precipitatefree zone (PFZ) is coarsened by a factor of 5. Tensile specimens tested transverse to the weld show that there is a 25 to 30 pct reduction in the strength level, a 60 pct reduction in the elongation in the as-FSW condition, and that the fracture path is in the HAZ. The postweld heat treatment of 121 °C for 24 hours did not result in an improvement either in the strength or the ductility of the welded material. Comparison of fatigue-crack growth rates (FCGRs) between the parent T7451 material and the as-FSW + T6 condition, at a stress ratio of R = 0.33, shows that the FCG resistance of the weldnugget region is decreased, while the FCG resistance of the HAZ is increased. Differences in FCGRs, however, are substantially reduced at a stress ratio of R = 0.70. Analysis of residual stresses, fatigue-crack closure, and fatigue fracture surfaces suggests that decrease in fatigue crack growth resistance in the weld-nugget region is due to an intergranular failure mechanism; in the HAZ region, residual stresses are more dominant than the microstructure improving the fatigue crack growth resistance.

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Authors and Affiliations

  1. the Materials and Manufacturing Directorate, Air Force Research Laboratory, AFRL/MLLM, 45433, Wright-Patterson Air Force Base, OH

    K. V. Jata (Senior Research materials Scientist)

  2. the Boeing Company, 63166, St. Louis, MO

    K. K. Sankaran (Technical Fellow)

  3. the Materials Engineering Division, University of Dayton Research Institute, 45469-0136, Dayton, OH

    J. J. Ruschau (Research Engineer)

Authors
  1. K. V. Jata
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  2. K. K. Sankaran
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  3. J. J. Ruschau
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Jata, K.V., Sankaran, K.K. & Ruschau, J.J. Friction-stir welding effects on microstructure and fatigue of aluminum alloy 7050-T7451. Metall Mater Trans A 31, 2181–2192 (2000). https://doi.org/10.1007/s11661-000-0136-9

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