FEM study of process parameters in a novel superplastic forming of titanium alloy Ti-6Al-4V

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Liu, Jun and Parameswaran, Elangovan and Yakushina, Evgenia and Zuelli, Nicola and Milliken, David M. and Humphreys, Nick and Gill, Les and Greenough, Christopher; Szeliga, Danuta and Muszka, Krzysztof, eds. (2024) FEM study of process parameters in a novel superplastic forming of titanium alloy Ti-6Al-4V. In: Metal Forming - 2024. Materials Research Proceedings . Association of American Publishers, POL, pp. 209-217. ISBN 9781644903247 (https://doi.org/10.21741/9781644903254-23)

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Abstract

A novel hybrid forming process involving the use of hot drawing along with superplastic forming (SPF) is studied here. The hot drawing stage helps in enhancing the formability and in fast deforming the sheet metal into a hollow shape with desired amount of material draw-in. During the subsequent SPF stage, gas pressure was applied onto the pre-formed part to complete the forming process at a targeted strain rate. With the hybrid process, titanium alloy Ti-6Al-4V sheets have been successfully formed in lab-scaled conditions at 800°C in 16 min. In this paper, finite element modelling (FEM) was used to demonstrate the effects of each stage (hot drawing and SPF) during the process. A plasticity model based on tensile test data was adopted as a material model for simulation. The pressure cycle which was predicted from the simulation has been used in the process to maintain the sheet forming at an average strain rate (e.g. 10-3 and 5×10-4 s-1). Material draw-in and thickness distribution were used to compare and optimise the process parameters. The simulations have shown the capability of the model to be used for the hybrid superplastic forming process. The influences of varying process parameters, such as punch geometry, blank size, blankholder force, friction coefficient and pressure cycle, were investigated by the simulations. It was found that the punch geometry and blank size played significant roles on the thickness uniformity of the final part, from which an optimised hot-drawing system that could lead to minimum thinning has been designed by FEM method.

ORCID iDs

Liu, Jun ORCID logoORCID: https://orcid.org/0000-0002-1604-0539, Parameswaran, Elangovan, Yakushina, Evgenia ORCID logoORCID: https://orcid.org/0000-0001-6498-4502, Zuelli, Nicola, Milliken, David M., Humphreys, Nick, Gill, Les and Greenough, Christopher; Szeliga, Danuta and Muszka, Krzysztof
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