Magnesium - Einfluss der Textur auf das Umformverhalten /

Gehrmann, Robert.

January 2004

Zugl.: Aachen, Techn. Hochsch., Diss., 2003.

Magnesium AZ31

Strain localization in extruded AZ31 Magnesium alloy

Huang, Chao-Chun

06 August 2009

none

EBSD

Dynamic Recrystallization

AZ31

Zur thermischen Ermüdung der Magnesiumbasislegierungen AZ31 und AZ91

Krauss, Martin

January 2006

Zugl.: Kassel, Univ., Diss., 2006 / Download lizenzpflichtig

AZ91 Thermische Ermüdung AZ31

Zur thermischen Ermüdung der Magnesiumbasislegierungen AZ31 und AZ91

Krauss, Martin

January 2006

Zugl.: Kassel, Univ., Diss., 2006

AZ91 Thermische Ermüdung AZ31

Zur thermischen Ermüdung der Magnesiumbasislegierungen AZ31 und AZ91

Krauß, Martin.

January 2007

Zugl.: Kassel, Universiẗat, Diss., 2006. / Download lizenzpflichtig.

AZ91. Thermische Ermüdung. AZ31.

Hot working behavior of AZ31 Magnesium alloys

Suen, Der-Kai

12 August 2005

none

dynamic recrystallization

AZ31 magnesium alloys

Zum Verformungsverhalten der Magnesiumbasislegierungen AZ31 und AZ91 bei zyklischen und quasi-statischen Beanspruchungen im Temperaturbereich 20-300C

Noster, Ulf.

January 2003

Universiẗat, Diss., 2003--Kassel. / Lizenzpflichtig.

Einfluss von intermetallischen Phasen in der Magnesiumknetlegierung AZ31 auf Rekristallisation, Texturausbildung und mechanische Eigenschaften

Laser, Torsten

January 2008

Zugl.: Hamburg, Techn. Univ., Diss., 2008

Constitutive modeling of slip, twinning, and untwinning in AZ31B magnesium

Li, Min

05 January 2006

No description available.

Constitutive Model

Twinning

Untwinning

Slip

Magnesium

AZ31

Material Processing and Forming Approaches for Enhancing Room Temperature Formability of Automotive Mg Sheet

Habibnejad-korayem, Mahdi

11 1900

Automotive magnesium sheets typically exhibit poor room temperature ductility which makes them unsuitable for room temperature sheet stamping applications. This research involved aspects of re-processing and forming of AZ31 automotive magnesium sheet to improve its room temperature ductility and bendability (and, more generally, formability). The sheet re-processing studies for formability improvement were carried out by two different methods, (i) cyclic bending-unbending and annealing (or CBUA) and (ii) wire brushing and annealing (or WBA). These two processing methods led to a complex stress and strain distribution through the thickness and a multi-layered microstructure after annealing. The grain structure, micro-texture, and micro-hardness of each of the layers were studied by optical microscopy, electron back-scattered diffraction (EBSD) and indentation measurements, respectively. The through-thickness grain structure study indicated grain refinement and texture randomization in the surface layers for both CBUA and WBA processed materials. In addition, the as-received (and fully annealed) sheet as well as processed materials were subsequently deformed in uniaxial tension and bending by a process referred to in the literature as pre-strain annealing (or PSA). The PSA process was studied as a single step as well as multi-step process to assess its effect on formability improvement, underlying changes in microstructural and mechanical behavior, and to explore practical limitations and advantages of the process. The results from single-step PSA process were also used to develop a microstructure-based constitutive material model to capture and predict the observed mechanical and microstructural response of AZ31 sheet to PSA variables. This model explicitly considered the effect of recovery on recrystallization kinetics, and non-constant nucleation and growth rate. The model was extended to predict the grain size at the end of recrystallization and within the grain growth stage as well as post-PSA yield and work hardening characteristics. The mechanical property prediction was based on considering the microstructure as a composite of un-recrystallized, recrystallized and coarsened grain structure and by employing a rule of mixture. The processing and forming methods led to significantly increased cumulative uniaxial tensile ductility and plane strain cumulative bendability of AZ31 sheet at room temperature depending upon PSA process parameters. The experimental and modeling studies collectively helped correlate mechanical properties from various processing conditions and forming methods with microstructural parameters, and to explain the improvement in room temperature formability based on microstructural and textural considerations. / Dissertation / Doctor of Philosophy (PhD)