Abstract
Background
Accelerated development of advanced metals and alloys requires validated relationships between the high throughput indentation measurements and standardized tensile test protocols.
Objective
The main objective of this paper is to critically evaluate the quantitative relationships between the yield strengths measured in standard tensile tests and the indentation yield strengths obtained from the recently developed spherical indentation stress-strain protocols for a broad range of steels with varying properties and microstructures. The tensile yield strengths for the tested steels varied from 300 to 1400 MPa, providing the broadest experimental evaluation to date for the spherical indentation stress-strain protocols.
Methods
Standardized tension tests, standardized hardness measurements, and the recently developed spherical microindentation stress-strain protocols were employed on all the steels included in this study. The indentation stress-strain protocols provide a suitably normalized characterization of the material’s intrinsic mechanical response, when compared to standardized hardness measurements.
Results
It was found that the yield strengths estimated using the spherical indentation stress-strain protocols were within a 10% error. Furthermore, it was found that the tensile strengths estimated from the conventional hardness measurements exhibited higher error compared to those estimated from the spherical indentation stress-strain protocols.
Conclusions
Spherical indentation stress-strain protocols were able to predict tensile yield strengths. The role of sample thickness on the indentation measurements was specifically investigated and quantified, resulting in specific recommendation for the minimum sample size for the indentation measurements.
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Acknowledgements
SM, NM, and SK acknowledge funding from ONR N00014-18-1-2879.
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Mohan, S., Millan-Espitia, N., Yao, M. et al. Critical Evaluation of Spherical Indentation Stress-Strain Protocols for the Estimation of the Yield Strengths of Steels. Exp Mech 61, 641–652 (2021). https://doi.org/10.1007/s11340-021-00689-7
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DOI: https://doi.org/10.1007/s11340-021-00689-7