Mechanical behaviour and strain rate sensitivity analysis of TA2 by the small punch test

•The strain rate sensitivity of TA2 is reflected well in the small punch test.•The effect of strain rate sensitivity is presented by characteristic parameters.•Deformation characteristics of TA2 at different strain rates is analysed by FEM.•A modified inverse method is proposed to identify the const...

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Bibliographic Details
Published in:Theoretical and applied fracture mechanics 2019-02, Vol.99, p.9-17
Main Authors: Xue, Lin, Ling, Xiang, Yang, Sisheng
Format: Article
Language:English
Subjects:
Algorithms
Computer simulation
Constitutive models
Displacement
Elastic bending
Elastic deformation
Exponential functions
Finite element method
Finite element simulation
Identification methods
Inverse identification
Material properties
Mechanical properties
Parameter identification
Plastic instability
Sensitivity analysis
Small punch test
Strain analysis
Strain rate sensitivity
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Summary:•The strain rate sensitivity of TA2 is reflected well in the small punch test.•The effect of strain rate sensitivity is presented by characteristic parameters.•Deformation characteristics of TA2 at different strain rates is analysed by FEM.•A modified inverse method is proposed to identify the constitutive parameters. In this study, small punch tests are conducted at various displacement rates (0.005–0.5 mm/min) to investigate the mechanical behaviour and strain rate sensitivity of commercial pure titanium TA2. The experimental results show that the yield load Py and the maximum load Pmax depend strongly on the displacement rate. An exponential function is established to describe the relationship between the material properties and the displacement rate. In order to describe the deformation characteristics of the specimen in the small punch tests at different strain rates, the Johnson–Cook constitutive model is applied in the finite element simulation. The influence of the constitutive parameters on the deformation behaviour is also analysed. The results indicate that the elastic bending region and plastic bending region are mainly affected by parameter A, whereas parameter B dominates the membrane stretching region and the plastic instability region of the curve. An improved inverse algorithm, combining the advance-and-retreat method with the golden section search method, is proposed. Based on characteristic analysis of the parameters, the one-dimensional and two-dimensional identification methods are used to identify the constitutive parameters from the load–displacement curve. Thus, the mechanical properties of materials can be calculated by inversion of the constitutive parameters.
ISSN:0167-8442
1872-7638
DOI:10.1016/j.tafmec.2018.11.002