Profilometry‐Based Inverse Finite Element Method Indentation Plastometry

Clyne, T.W.; Campbell, James E.; Burley, Max; Dean, James

doi:10.1002/adem.202100437

Cited by 52 publications

(59 citation statements)

References 74 publications

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“…These steps are described in detail in a recent review paper. [8] Samples for indentation were in the form of 8 mm thick plates with lateral dimensions of about 45 by 20 mm. (As the preferred spacing between indents made with a 1 mm radius ball is at least about 4 mm, this allowed up to about 20 indents to be produced on each sample.)…”

Section: Indentation Plastometrymentioning

confidence: 99%

“…Its emergence is the outcome of an extended period of research and development. [1][2][3][4][5][6][7][8] The superior reliability of PIP to the (instrumented indentation technique) methodology of converting a load-displacement plot to a stress-strain curve via analytic relationships has been clearly demonstrated. [9] It has already been applied to a thin plasma-sprayed layer [10] and (anisotropic) additively manufactured material, [11] both Ni-based superalloys.…”

Section: Introductionmentioning

confidence: 99%

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Indentation Plastometry of Very Hard Metals

Campbell¹,

Gaiser-Porter

Gu³

et al. 2022

Adv Eng Mater

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This investigation concerns the application of profilometry‐based indentation plastometry (PIP) to metals with very high hardness, i.e., those with yield stresses of 1.5–3 GPa. The PIP procedure comprises (a) applying a force to an indenter ball, penetrating the sample to a preselected depth, (b) measuring the profile of the indent, and (c) iteratively running a finite element method (FEM) model to obtain the true stress–true strain curve giving optimal agreement between measured and modeled profiles. The procedure is no different when the sample is very hard, although the ball must remain elastic during the process. It is shown that this can be achieved using silicon nitride balls. These can fracture under some conditions, but it is shown that a “proof‐testing” operation can be used to ensure that any particular ball will remain elastic under the complete range of service conditions. It is also shown, via systematic comparisons with the outcomes of uniaxial (tensile and compressive) tests, that reliable stress–strain curves can be obtained for very hard metals. Furthermore, PIP testing has advantages over uniaxial testing for obtaining information about their behavior at relatively high strains (≈15%), as well as being much easier and simpler to implement.

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Section: Indentation Plastometrymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Indentation Plastometry of Very Hard Metals

Campbell¹,

Gaiser-Porter

Gu³

et al. 2022

Adv Eng Mater

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“…Importantly, the observed grain size distribution is much lower than 500 μm, i.e., the threshold for the PIP test. Below the threshold, variability in local microstructure is not expected to affect the accuracy of indentation predictions, as the plastic zone is estimated to contain at least a few dozen grains (Clyne et al, 2021).…”

Section: Materials and Experimental Detailsmentioning

confidence: 99%

“…The relationship is inverse, so the simulation must be performed iteratively to optimize the parameters of the plasticity model to reproduce the observed profile. This process has been thoroughly documented elsewhere (Campbell et al, 2021;Clyne et al, 2021). The following overview is included to support discussion of uncertainty quantification.…”

Section: Plasticity Modelingmentioning

confidence: 99%

Uncertainty Quantification of a High-Throughput Profilometry-Based Indentation Plasticity Test of Al 7075 T6 Alloy

et al. 2022

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The quantification of spatially variable mechanical response in structural materials remains a challenge. Additive manufacturing methods result in increased spatial property variations—the effect of which on component performance is of key interest. To assist iterative design of additively manufactured prototypes, lower-cost benchtop test methods with high precision and accuracy will be necessary. Profilometry-based indentation plastometry (PIP) promises to improve upon the instrumented indentation test in terms of the measurement uncertainty. PIP uses an isotropic Voce hardening model and inverse numerical methods to identify plasticity parameters. The determination of the baseline uncertainty of PIP test is fundamental to its use in characterizing spatial material property variability in advanced manufacturing. To quantify the uncertainty of the PIP test, ninety-nine PIP tests are performed on prepared portions of a traditionally manufactured Al 7075 plate sample. The profilometry data and the Voce parameter predictions are examined to distinguish contributions of noise, individual measurement uncertainty, and additional set-wide variations. Individual measurement uncertainty is estimated using paired profilometry measurements that are taken from each indentation. Principal component analysis is used to analyze and model the measurement uncertainty. The fitting procedure used within the testing device software is employed to examine the effect of profile variations on plasticity predictions. The expected value of the error in the plasticity parameters is given as a function of the number of tests taken, to support rigorous use of the PIP method. The modeling of variability in the presence of measurement uncertainty is discussed.

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“…The spherical indentation profile has been proved to be more sensitive to the plastic parameters of materials than the load-displacement curve [ 13 ]. In the work by Clyne et al [ 23 ], the advantages of using the indentation imprint were summarized. It does not require the extra indentation loading–unloading data, thus eliminating the uncertainties involved in machine compliance.…”

Section: Introductionmentioning

confidence: 99%

An Inverse Method for Measuring Elastoplastic Properties of Metallic Materials Using Bayesian Model and Residual Imprint from Spherical Indentation

Wang

2021

Materials

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In this paper, an inverse method is proposed for measuring the elastoplastic properties of metallic materials using a spherical indentation experiment. In the new method, the elastoplastic parameters are correlated with sub-space coordinates of indentation imprints using proper orthogonal decomposition (POD), and inverse identification of material properties is solved using a statistical Bayesian framework. The advantage of the method is that model parameters in the numerical optimization process are treated as the stochastic variables, and potential uncertainties can be considered. The posterior results obtained from the measuring method can provide valuable probabilistic information of the estimated elastoplastic properties. The proposed method is verified by the application on 2099-T83 Al-Li alloys. Results indicate that posterior distribution of material parameters exhibits more than one peak region when indentation load is not large enough. In addition, using the weighting imprints under different loads can facilitate the uniqueness in identification of elastoplastic parameters. The influence of the weighting coefficient on posterior identification results is analyzed. The elastoplastic properties identified by indentation and tensile experiment show good agreement. Results indicate that the established measuring method is effective and reliable.

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Profilometry‐Based Inverse Finite Element Method Indentation Plastometry

Cited by 52 publications

References 74 publications

Indentation Plastometry of Very Hard Metals

Indentation Plastometry of Very Hard Metals

Uncertainty Quantification of a High-Throughput Profilometry-Based Indentation Plasticity Test of Al 7075 T6 Alloy

An Inverse Method for Measuring Elastoplastic Properties of Metallic Materials Using Bayesian Model and Residual Imprint from Spherical Indentation

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