Can ultrasound attenuation measurement be used to characterise grain statistics in castings?
Can ultrasound attenuation measurement be used to characterise grain statistics in castings?
Industrial inspection protocols are qualified using mock-ups manufactured according to the same procedure as the plant part. For coarse-grained castings, known for their low inspectability, relying on mock-ups becomes particularly challenging owing to the variability of grain properties among components. Consequently, there is a keen interest in the capability to verify whether the grain size of the component under test matches the qualification specification in-situ. This paper investigates the potential of an attenuation measurement for assessing the ultrasonic inspectability of coarse-grained components using qualified procedures in a practical setting. The experimental part of the study focuses on an industrial Inconel 600 mock-up with spatially varying attenuation, measured across the entire sample in an immersion tank. Three zones with distinctly different attenuations were examined using metallography, which allowed for calculating classical grain size histograms and two-point correlation functions. For one of the zones, we synthesised the microstructure with the same statistical properties numerically and simulated the propagation of ultrasound using a grain-scale finite element model. The results showed good agreement with the experiment, and lead to several suggestions for the reasons for the discrepancy, the varying grain size statistics being the most likely. A parametric study, which followed, depicted the effect of the mean and standard deviation-to-mean ratio of the log-normal grain size distribution on the attenuation of ultrasound and its frequency dependence. Most notably, we demonstrated the known non-uniqueness of the relationship between the log-normal grain size distribution parameters and the attenuation. We suggested that the correlation length calculated from a single exponential fit to the two-point correlation function is a more robust metric describing grain statistics for this context, which can be obtained from attenuation. The correlation lengths estimated from measured attenuation using the second-order approximation model for the three zones of the studied mock-up yielded results of acceptable accuracy. We concluded that this metric could replace the average grain size in practical settings, as it retains more statistical information than the mean grain size and allows for linking measurements to the established theoretical attenuation models which this paper demonstrates.
Grain size distribution, Material characterisation, Polycrystalline materials, Ultrasound Attenuation
Liu, Yuan
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Kalkowski, Michał K.
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Huang, Ming
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Lowe, Michael J.S.
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Samaitis, Vykintas
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Cicėnas, Vaidotas
6cf6e3d0-07a4-42eb-bc21-133b285981f4
Schumm, Andreas
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15 April 2021
Liu, Yuan
d7928fb1-a58e-45fd-b469-60343656d17f
Kalkowski, Michał K.
6f0d01ef-7f44-459c-82a2-03f9e1275eda
Huang, Ming
59c953c8-a5e4-4306-99a0-c9a761c0ea35
Lowe, Michael J.S.
3fe38792-9acf-4f3e-8067-78c8f50d933a
Samaitis, Vykintas
2d587fb5-8c22-40fd-b872-16dfee30ef32
Cicėnas, Vaidotas
6cf6e3d0-07a4-42eb-bc21-133b285981f4
Schumm, Andreas
c4fe1be7-4e7b-4d21-8d8b-ad9e967ae1aa
Liu, Yuan, Kalkowski, Michał K., Huang, Ming, Lowe, Michael J.S., Samaitis, Vykintas, Cicėnas, Vaidotas and Schumm, Andreas
(2021)
Can ultrasound attenuation measurement be used to characterise grain statistics in castings?
Ultrasonics, 115, [106441].
(doi:10.1016/j.ultras.2021.106441).
Abstract
Industrial inspection protocols are qualified using mock-ups manufactured according to the same procedure as the plant part. For coarse-grained castings, known for their low inspectability, relying on mock-ups becomes particularly challenging owing to the variability of grain properties among components. Consequently, there is a keen interest in the capability to verify whether the grain size of the component under test matches the qualification specification in-situ. This paper investigates the potential of an attenuation measurement for assessing the ultrasonic inspectability of coarse-grained components using qualified procedures in a practical setting. The experimental part of the study focuses on an industrial Inconel 600 mock-up with spatially varying attenuation, measured across the entire sample in an immersion tank. Three zones with distinctly different attenuations were examined using metallography, which allowed for calculating classical grain size histograms and two-point correlation functions. For one of the zones, we synthesised the microstructure with the same statistical properties numerically and simulated the propagation of ultrasound using a grain-scale finite element model. The results showed good agreement with the experiment, and lead to several suggestions for the reasons for the discrepancy, the varying grain size statistics being the most likely. A parametric study, which followed, depicted the effect of the mean and standard deviation-to-mean ratio of the log-normal grain size distribution on the attenuation of ultrasound and its frequency dependence. Most notably, we demonstrated the known non-uniqueness of the relationship between the log-normal grain size distribution parameters and the attenuation. We suggested that the correlation length calculated from a single exponential fit to the two-point correlation function is a more robust metric describing grain statistics for this context, which can be obtained from attenuation. The correlation lengths estimated from measured attenuation using the second-order approximation model for the three zones of the studied mock-up yielded results of acceptable accuracy. We concluded that this metric could replace the average grain size in practical settings, as it retains more statistical information than the mean grain size and allows for linking measurements to the established theoretical attenuation models which this paper demonstrates.
Text
Attenuation_in_polycrystals_accepted
- Accepted Manuscript
More information
Accepted/In Press date: 9 April 2021
Published date: 15 April 2021
Additional Information:
Funding Information:
This project has received funding from the Euratom research and training programme 2014–2018 under grant agreement No 755500 (ADVISE – www.advise-h2020.eu). The authors also acknowledge the invaluable contributions of Jerome Boulenger and Adrien Le Drou, technicians at EDF R&D, who performed the metallurgical analysis.
Funding Information:
This project has received funding from the Euratom research and training programme 2014?2018 under grant agreement No 755500 (ADVISE ? www.advise-h2020.eu). The authors also acknowledge the invaluable contributions of Jerome Boulenger and Adrien Le Drou, technicians at EDF R&D, who performed the metallurgical analysis.
Publisher Copyright:
© 2021
Keywords:
Grain size distribution, Material characterisation, Polycrystalline materials, Ultrasound Attenuation
Identifiers
Local EPrints ID: 469500
URI: http://eprints.soton.ac.uk/id/eprint/469500
ISSN: 0041-624X
PURE UUID: a4e8eba9-8ac5-4f37-88b0-61f00c1e498e
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Date deposited: 16 Sep 2022 16:36
Last modified: 18 Mar 2024 05:29
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Contributors
Author:
Yuan Liu
Author:
Ming Huang
Author:
Michael J.S. Lowe
Author:
Vykintas Samaitis
Author:
Vaidotas Cicėnas
Author:
Andreas Schumm
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