tubaf Experimental analysis and numerical fatigue modeling for magnesium sheet metals 2016-09-16 [Electronic ed.] Technische Universitaet Bergakademie Freiberg Universitaetsbibliothek "Georgius Agricola" prv Technische Universitaet Bergakademie Freiberg Universitaetsbibliothek "Georgius Agricola", Freiberg Werkstoffwissenschaft und Werkstofftechnologie Werkstofftechnologie Maschinenbau Leichtbau male Straubing male male male male male The desire for energy and resource savings brings magnesium alloys as lightweight materials with high specific strength more and more into the focus. Most structural components are subjected to cyclic loading. In the course of computer aided product development, a numerical prediction of the fatigue life under these conditions must be provided. For this reason, the mechanical properties of the considered material must be examined in detail. Wrought magnesium semifinished products, e.g. magnesium sheet metals, typically reveal strong basal textures and thus, the mechanical behavior considerably differs from that of the well-established magnesium die castings. Magnesium sheet metals reveal a distinct difference in the tensile and compressive yield stress, leading to non-symmetric sigmoidal hysteresis loops within the elasto-plastic load range. These unusual hysteresis shapes are caused by cyclic twinning and detwinning. Furthermore, wrought magnesium alloys reveal pseudoelastic behavior, leading to nonlinear unloading curves. Another interesting effect is the formation of local twin bands during compressive loading. Nevertheless, only little information can be found on the numerical fatigue analysis of wrought magnesium alloys up to now. The aim of this thesis is the investigation of the mechanical properties of wrought magnesium alloys and the development of an appropriate fatigue model. For this purpose, twin roll cast AM50 as well as AZ31B sheet metals and extruded ME21 sheet metals were used. Mechanical tests were carried out to present a comprehensive overview of the quasi-static and cyclic material behavior. The microstructure was captured on sheet metals before and after loading to evaluate the correlation between the microstructure, the texture, and the mechanical properties. Stress- and strain-controlled loading ratios and strain-controlled experiments with variable amplitudes were performed. Tests were carried out along and transverse to the manufacturing direction to consider the influence of the anisotropy. Special focus was given to sigmoidal hysteresis loops and their influence on the fatigue life. A detailed numerical description of hysteresis loops is necessary for numerical fatigue analyses. For this, a one-dimensional phenomenological model was developed for elasto-plastic strain-controlled constant and variable amplitude loading. This model consists of a three-component equation, which considers elastic, plastic, and pseudoelastic strain components. Considering different magnesium alloys, good correlation is reached between numerically and experimentally determined hysteresis loops by means of different constant and variable amplitude load-time functions. For a numerical fatigue life analysis, an energy based fatigue parameter has been developed. It is denoted by “combined strain energy density per cycle” and consists of a summation of the plastic strain energy density per cycle and the 25 % weighted tensile elastic strain energy density per cycle. The weighting represents the material specific mean stress sensitivity. Applying the energy based fatigue parameter on modeled hysteresis loops, the fatigue life is predicted adequately for constant and variable amplitude loading including mean strain and mean stress effects. The combined strain energy density per cycle achieves significantly better results in comparison to conventional fatigue models such as the Smith-Watson-Topper model. The developed phenomenological model in combination with the combined strain energy density per cycle is able to carry out numerical fatigue life analyses on magnesium sheet metals. 620 Blech, Magnesiumlegierung, Materialermüdung, Mittelspannung, Spannungs-Dehnungs-Beziehung, Numerisches Modell Magnesiumbleche, Ermüdungsmodell, AM50, AZ31, ME21, Mittelspannung, Variable Amplituden, Spannungs-Dehnungs-Modell, Dehnungsenergiedichte, Zwillingsbänder Magnesium sheet metals, Fatigue model, AM50, AZ31, ME21, Mean stress, Variable amplitude loading, Stress-strain model, Strain energy density, Twin bands urn:nbn:de:bsz:105-qucosa-209124 978-3-86012-531-1 TU Bergakademie Freiberg dgg TU Bergakademie Freiberg, Freiberg Hochschule Landshut dgg Hochschule Landshut, Landshut Johannes Dallmeier 1985-11-09 aut Klaus Eigenfeld Prof. Dr.-Ing. dgs rev Otto Huber Prof. Dr.-Ing. dgs rev Horst Biermann Prof. Dr.-Ing. rev eng 2016-01-06 2016-05-09 born digital Johannes Dallmeier 01704726731 Johannes-Dallmeier@t-online.de doctoral_thesis