Modelling the micromorphology of heat treated Ti6Al4V forgings by means of spatial tessellations feasible for FEM analyses of microscale residual stresses

B. Regener, C. Krempaszky, E. Werner, M. Stockinger

Publikation: Beitrag in FachzeitschriftArtikelBegutachtung

18 Zitate (Scopus)

Abstract

Due to finite thermal conductivity and the heterogeneous microstructure of Ti6Al4V, the temperature distribution within large components during thermal processing is highly heterogeneous on both, the macroscale and the microscale. To compute a spatial distribution of stresses at the microscale, a microdomain partition is prerequisite. By analysing representative micrographs, characteristic grain shapes are determined which serve as validation of numerically generated realistic microdomain partitions utilising the technique of spatial tessellations. By generalising the standard Voronoï tessellation, a more sophisticated tessellation, the Johnson-Mehl tessellation is introduced to capture these characteristics appropriately. The Johnson-Mehl cells grow isotropically around the kernels which result from an inhomogeneous Poisson point process, replicating the underlying phase evolution mechanism during thermal processing. In order to capture the anisotropy of the microstructure caused by preceding forging, a geometrical morphing is applied subsequently to the computation of the spatial tessellation. Comparison of the basic features of both, the experimentally derived micrographs and the numerically derived ones, reveals a good qualitative agreement.

OriginalspracheEnglisch
Seiten (von - bis)77-81
Seitenumfang5
FachzeitschriftComputational Materials Science
Jahrgang52
Ausgabenummer1
DOIs
PublikationsstatusVeröffentlicht - Feb. 2012

Fingerprint

Untersuchen Sie die Forschungsthemen von „Modelling the micromorphology of heat treated Ti6Al4V forgings by means of spatial tessellations feasible for FEM analyses of microscale residual stresses“. Zusammen bilden sie einen einzigartigen Fingerprint.

Dieses zitieren