Phenomenological model of hardening and flow for Ti-6Al-4 V titanium alloy sheets under hot forming conditions

Fu, Kunning; Peng, Heli; Zheng, Kailun; Yuan, Shijian

doi:10.1007/s00170-022-10629-x

Cited by 4 publications

(1 citation statement)

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“…Concerning the behavior law of the Ti-6Al-4V at 725 • C, for this paper, the material data are sourced from Bylya et al [13] and Seshacharyulu et al [14] due to the confidential nature of the material parameters obtained from hot tensile tests in our lab during this study. To precisely determine the hot deformation characteristics of titanium alloy sheets, hot tensile uniaxial tests using a Gleeble thermomechanical simulator at various strain rates and temperatures must be performed as proposed by Fu et al [15]. This characterization can also include the evaluation of hot-forming limit diagrams of titanium alloy sheets as proposed by Fan et al [16] that can reflect the anisotropic hardening and the r-value evolution during the deformation.…”

Section: Materials Propertiesmentioning

confidence: 99%

Comparative Analysis of Finite Element Formulations for Simulating Hot Forming of Ti-6Al-4V Aerospace Components

Pantalé,

Rangasamy Mahendren,

Dalverny

2024

Eng

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This study presents a comprehensive finite element analysis to compare the performance of different element formulations (classic shell elements, solid elements, and continuum shell elements) in simulating the hot-forming process at 725 °C of a complex Ti-6Al-4V aerospace component with an initial blank thickness of 1.6 mm (0.063 inches). The Ti-6Al-4V blank is modeled as a deformable body exhibiting anisotropic plastic behavior, whereas the forming tools (matrix and punch) are assumed to be rigid bodies. The simulation accounts for temperature and strain rate effects on the material properties, incorporating phenomena such as friction and anisotropy. Three different element types are studied and compared: S4R and S4 (classic shells), C3D8R and C3D8 (solids), and SC8R (continuum shell with reduced integration). Finally, the model is validated by comparing the predicted final part geometry, especially the thickness distribution, against the experimental measurements. The model can also predict the springback effect on the final geometry. The SC8R continuum shell element provides the smoothest representation of thickness variations along critical regions of the final part. The study highlights the importance of selecting the appropriate element type for the accurate simulation of hot-forming processes involving large deformations and complex contact conditions. The ability of continuum shell elements to accurately capture the thickness variations makes them an ideal candidate for such applications.

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