Influence of ECAP temperature on the formability of a particle reinforced 2017 aluminum alloy (bibtex)

by S. Wagner, M. Härtel, P. Frint, M.F.-X. Wagner

Abstract:
Severe plastic deformation methods are commonly used to increase the strength of materials by generating ultrafine-grained microstructures. The application of these methods to Al-Cu alloys is, however, difficult because of their poor formability at room temperature. An additional reduction of formability of such alloys occurs when ceramic particles are added as reinforcement: this often triggers shear localization and crack initiation during ECAP. This is the main reason why equal-channel angular pressing (ECAP) of aluminum matrix composites (AMCs) can generally only be performed at elevated temperatures and using ECAP dies with a channel angle larger than 90° (e.g. 120°). In this study we present a brief first report on an alternative approach for the improvement of the formability of an AMC (AA2017, 10 % SiC): ECAP at low temperatures. We show that, using a temperature of -60 °C and a channel angle of 90° (corresponding to an equivalent strain of 1.1), ECAP of the AMC can be successfully performed without material failure. The mechanical properties of the strongly deformed AMC are analyzed by tensile testing. Our results indicate that the increased formability of the AMC at low temperatures can be attributed to the suppression of unstable plastic flow that affects formability at room temperature.
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Reference:
Wagner, S., Härtel, M., Frint, P., Wagner, M.F.-X.: Influence of ECAP temperature on the formability of a particle reinforced 2017 aluminum alloy, IOP Conference Series: Materials Science and Engineering 181, 012039, 2017.
Bibtex Entry:
@Article{Wagner2017,
  Title                    = {Influence of ECAP temperature on the formability of a particle reinforced 2017 aluminum alloy},
  Author                   = {Wagner, S. and Härtel, M. and Frint, P. and Wagner, M.F.-X.},
  Journal                  = {IOP Conference Series: Materials Science and Engineering},
  Year                     = {2017},

  Month                    = {Mar},
  Pages                    = {012039},
  Volume                   = {181},
  Abstract                 = {Severe plastic deformation methods are commonly used to increase the strength of materials by generating ultrafine-grained microstructures. The application of these methods to Al-Cu alloys is, however, difficult because of their poor formability at room temperature. An additional reduction of formability of such alloys occurs when ceramic particles are added as reinforcement: this often triggers shear localization and crack initiation during ECAP. This is the main reason why equal-channel angular pressing (ECAP) of aluminum matrix composites (AMCs) can generally only be performed at elevated temperatures and using ECAP dies with a channel angle larger than 90° (e.g. 120°). In this study we present a brief first report on an alternative approach for the improvement of the formability of an AMC (AA2017, 10 % SiC): ECAP at low temperatures. We show that, using a temperature of -60 °C and a channel angle of 90° (corresponding to an equivalent strain of 1.1), ECAP of the AMC can be successfully performed without material failure. The mechanical properties of the strongly deformed AMC are analyzed by tensile testing. Our results indicate that the increased formability of the AMC at low temperatures can be attributed to the suppression of unstable plastic flow that affects formability at room temperature.},
  Doi                      = {10.1088/1757-899x/181/1/012039},
  ISSN                     = {1757-899X},
  Publisher                = {IOP Publishing},
  Url                      = {http://dx.doi.org/10.1088/1757-899X/181/1/012039}
}
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