Ulrich Fröbel scite author profile

For high-temperature applications, creep strength is of major concern, in addition to oxidation and corrosion resistance, and determines the application range of titanium aluminide alloys in competition with other structural materials. Thus, this work was aimed at identifying mechanisms of creep deformation and microstructural degradation and at developing alloying concepts with respect to an enhanced high-temperature capability. The analysis shows that dislocation climb controls deformation in the range of the intended operation temperatures. Further, complex processes of phase transformations, recrystallization, and microstructural coarsening were observed, which contribute to microstructural degradation and limit component life in long-term service. By alloying with high contents of Nb, both room-and high-temperature strength properties can be improved as Nb increases the activation energy of diffusion and increases the propensity for twinning at ambient temperature. For alloys with enhanced hightemperature capability, microalloying with carbon is also of particular use, because carbide precipitates effectively hinder dislocation motion and are thought to increase microstructural stability.

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Strain ageing in γ(TiAl)-based titanium aluminides due to antisite atoms

Fröbel¹,

Appel²

2002

Acta Materialia

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Hot-Workability of Gamma-Based TiAl Alloys during Severe Torsional Deformation

Fröbel¹,

Appel²

2007

Metall Mater Trans A

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Wrought TiAl products manufactured by conventional hot-working procedures, such as forging and extrusion, suffer from structural and chemical inhomogeneities, which are major concerns for the reliability of components. In an attempt to overcome these problems, TiAl alloys were hot worked by torsional deformation. Using this method, a much higher strain and mechanical work can be imparted, which triggers dynamic recrystallization. The metallurgical potential of this technique will be assessed. Particular emphasis is placed on shear localization processes, which often lead to premature failure of the workpiece.

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Strain ageing in γ(TiAl)-based and α2(Ti3Al) titanium aluminides

Fröbel¹,

Appel²

2006

Intermetallics

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Microstructural Evolution in Gamma Titanium Aluminides During Severe Hot-Working

Fröbel

Stark

2014

Metall Mater Trans A

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Ulrich Fröbel

Creep behavior of TiAl alloys with enhanced high-temperature capability

Strain ageing in γ(TiAl)-based titanium aluminides due to antisite atoms

Hot-Workability of Gamma-Based TiAl Alloys during Severe Torsional Deformation

Strain ageing in γ(TiAl)-based and α2(Ti3Al) titanium aluminides

Microstructural Evolution in Gamma Titanium Aluminides During Severe Hot-Working

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