Accessing pore microstructure–property relationships for additively manufactured materials

Raßloff, Alexander; Schulz, P.; Kühne, Robert; Ambati, Marreddy; Koch, Ilja; Zeuner, A.; Gude, Μaik; Zimmermann, Martina; Kästner, Markus

doi:10.1002/gamm.202100012

Cited by 11 publications

(4 citation statements)

References 52 publications

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“…The descriptorbased nature of the algorithm enables to create large data bases of synthetic 3D microstructure from few observations through interpolation in descriptor space. This exploration of feasible microstructures leads to valuable insight and computationally-obtained process-structure-property linkages like [21] work unit only. TensorFlow [1] is used for just-in-time compilation in order to generate efficient GPU code from a simple Python definition of the descriptors and the loss function.…”

Section: Discussionmentioning

confidence: 99%

Descriptor-based reconstruction of three-dimensional microstructures through gradient-based optimization

Seibert¹,

Raßloff²,

Ambati³

et al. 2021

Preprint

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Microstructure reconstruction is an important cornerstone to the inverse materials design concept. In this work, a general algorithm is developed to reconstruct a three-dimensional microstructure from given descriptors. Based on two-dimensional (2D) micrographs, this reconstruction algorithm allows valuable insight through spatial visualization of the microstructure and in silico studies of structure-property linkages. The formulation ensures computational efficiency by casting microstructure reconstruction as a gradient-based optimization problem. Herein, the descriptors can be chosen freely, such as spatial correlations or Gram matrices, as long as they are differentiable with respect to the microstructure. Because real microstructure samples are commonly available as 2D microscopy images only, the desired descriptors for the reconstruction process are prescribed on orthogonal 2D slices. This adds a source of noise, which is handled in a new, superior and interpretable manner. The efficiency and applicability of this formulation is demonstrated by various numerical experiments.

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Section: Discussionmentioning

confidence: 99%

Descriptor-based reconstruction of three-dimensional microstructures through gradient-based optimization

Seibert¹,

Raßloff²,

Ambati³

et al. 2021

Preprint

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“…The relationship between fatigue strength and defect size can be written as

\Delta {\sigma}_{\mathrm{w}}=\Delta {\sigma}_{\mathrm{w}0}\sqrt{\frac{a_0}{a+{a}_0}}

with

\Delta {\sigma}_{\mathrm{w}}

as the fatigue limit,

\Delta {\sigma}_{\mathrm{w}0}

as the fatigue limit of the material without defects and

a=\sqrt{area}=\sqrt{\pi \cdotp b\cdotp c}

the square root of the ellipse fitted to the largest projected area of the largest defect with the major half‐axis

b

and the second largest half‐axis

c

[30,38]. The El‐Haddad constant

{a}_0=\sqrt{are{a}_0}=\frac{1}{\pi }{\left(\frac{\Delta {K}_{\mathrm{th},\mathrm{LC}}}{F_{\mathrm{w}}\cdotp \Delta {\sigma}_{\mathrm{w}0}}\right)}^2,

is calculated with the crack propagation threshold

$$ \Delta {K}_{\mat...

…”

Section: Experimental and Data Analysis Methodsmentioning

confidence: 99%

“…with Δ𝜎 w as the fatigue limit, Δ𝜎 w0 as the fatigue limit of the material without defects and a = √ area = √ 𝜋 ⋅ b ⋅ c the square root of the ellipse fitted to the largest projected area of the largest defect with the major half-axis b and the second largest half-axis c [30,38]. The El-Haddad constant…”

Section: Influence Of Pore Size On Fatigue Strengthmentioning

confidence: 99%

“…Numerical and empirical material models are developed based on data from experimental analysis to simulate the fatigue behavior of AM materials. Raßloff et al [38] use light microscopy and CT data as input for microscale crystal plasticity simulations to obtain fatigue indicating parameters for Ti6Al4V manufactured by LPBF. The empirical

\sqrt{\mathrm{area}}

‐parameter model developed by Murakami [34] allows for a fast estimation of the criticality of defects in AM components.…”

Section: Introductionmentioning

confidence: 99%

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Influence of CT image processing on the predicted impact of pores on fatigue of additively manufactured Ti6Al4V and AlSi10Mg

et al. 2022

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Pores are inherent to additively manufactured components and critical especially in technical components. Since they reduce the component's fatigue life, a reliable identification and description of pores is vital to ensure the component's performance. X‐ray computed tomography (CT) is an established and non‐destructive testing method to investigate internal defects. The CT scan process can induce noise and artefacts in the resulting images which afterwards have to be reduced through image processing. To reconstruct the internal defects of a component, the images need to be segmented in defect region and bulk material by applying a threshold. The application of the threshold as well as the previous image processing alter the geometry and size of the identified defects. This contribution aims to quantify the influence of selected commercial image processing and segmentation methods on identified pores in several additively manufactured components made of AlSi10Mg and Ti6Al4V as well as in an artificial CT scan. To that aim, gray value histograms and characteristic parameters thereof are compared for different image processing tools. After the segmentation of the processed images, particle characteristics are compared. The influence of image processing and segmentation on the predicted fatigue life of the material is evaluated through the change of the largest pore in each set of data applying Murakami's empirical area$$ \sqrt{\mathrm{area}} $$‐parameter model.

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Preface on mechanics of additive manufacturing—Part I

et al. 2021

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PREFACEphysics-based powder and melt pool modeling as well as the microstructure modeling and the overall thermomechanically coupled simulation framework at the macroscale are covered.Material modeling and, in particular, the accurate modeling of phase changes during selective laser melting is also addressed in [3]. The main goal of the model presented therein is to predict the process-induced irreversible strains as accurately as possible on a sub-macro level. The results obtained by the related simulations are then to be used as input for simulations at the macroscale in terms of the inherent strain method.

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Accessing pore microstructure–property relationships for additively manufactured materials

Cited by 11 publications

References 52 publications

Descriptor-based reconstruction of three-dimensional microstructures through gradient-based optimization

Descriptor-based reconstruction of three-dimensional microstructures through gradient-based optimization

Influence of CT image processing on the predicted impact of pores on fatigue of additively manufactured Ti6Al4V and AlSi10Mg

Preface on mechanics of additive manufacturing—Part I

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