Flow modelling of Ti6Al4V under large strains

Katharina Hogrefe, Ricardo Henrique Buzolin, M. C. Poletti*

*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceedingChapter

Abstract

This work uses flow stresses obtained experimentally at different strain rates and temperatures to validate flow modelling results. Flow curves of Ti6Al4V are measured via torsion experiments with a Gleeble® 3800 up to effective strains of 8. A physically based model that describes the evolutions of microstructure and the flow stress in the β-phase field was developed. A model of continuous dynamic recrystallization (CDRX) based on the work of Gourdet and Montheillet [1] for aluminium alloys is combined in this work with elements taken from Kocks and Mecking [2]. The model consists of a detailed description of the microstructure, based on different dislocation density populations and grain boundaries. All these internal variables evolve according to a production and a recovery term correlated mathematically with the temperature and the strain rate. The modelled output variables besides the flow stress are the total, the interior and the wall dislocation densities as well as the subgrain and grain sizes developed by continuous dynamic recrystallization. The model describes the softening occurring during large strain deformations, which is partly produced by the formation of new high angle grain boundaries (HAGB). The fraction of HAGB was used to determine the recrystallization grade, validated with microstructural characterization.
Original languageEnglish
Title of host publicationMATEC Web of Conferences
Number of pages6
Volume321
DOIs
Publication statusPublished - 12 Oct 2020
EventThe 14th World Conference on Titanium - Nantes, France
Duration: 10 Jun 201914 Jun 2019
https://www.titanium2019.com/

Conference

ConferenceThe 14th World Conference on Titanium
Abbreviated titleTi-2019
CountryFrance
CityNantes
Period10/06/1914/06/19
Internet address

Fingerprint Dive into the research topics of 'Flow modelling of Ti6Al4V under large strains'. Together they form a unique fingerprint.

Cite this