The third Sandia fracture challenge: predictions of ductile fracture in additively manufactured metal

Kramer, Sharlotte Lorraine Bolyard; Jones, Amanda; Mostafa, Ahmed; Ravaji, Babak; Tancogne-Dejean, Thomas; Roth, Christian C.; Bandpay, Maysam Gorji; Pack, Keunhwan; Foster, Janet; Behzadinasab, Masoud; Sobotka, James C.; McFarland, John; Stein, Jeremy C.; Spear, Ashley D.; Newell, Pania; Czabaj, Michael W.; Williams, Bruce W.; Simha, H.; Gesing, Mark; Gilkey, Lindsay Noelle; Jones, Christopher; Dingreville, Remi Philippe Michel; Sanborn, Scott Edward; Bignell, John L.; Cerrone, Albert; Keim, V.; Nonn, Aida; Cooreman, Steven; Thibaux, Philippe; Ames, Nicoli M.; Connor, Devin O.; Parno, Matthew; Davis, B.R.; Tucker, Joseph C.; Coudrillier, Baptiste; Karlson, Kyle N.; Ostien, Jakob T.; Foulk, James W.; Hammetter, Chris; Grange, Spencer; Emery, John M; Brown, Judith A.; Bishop, Joseph E.; Johnson, Kyle L.; Ford, Kurtis Ross; Brinckmann, Steffen; Neilsen, Michael K.; Jackiewicz, J.; Ravi‐Chandar, Krishnaswamy; Thomas, Ivanoff,; Bradley, Salzbrenner,; Boyce, Brad Lee

doi:10.1007/s10704-019-00361-1

Cited by 70 publications

(19 citation statements)

References 90 publications

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“…Since the dependence of the non-local deformation gradients, i.e., Eqs. (16), (25), and (28), on displacement is linear, the following constitutive model is constructed for consistency with linear elastostatics:…”

Section: Numerical Examplesmentioning

confidence: 99%

“…The unstable behavior appears as zero-energy mode oscillations in meshless peridynamic simulations and has been largely attributed to the cancellation of the non-uniform parts of deformation, which is allowed within the integration (averaging) technique [2,7,13,31,36]. The instabilities can lead to large errors in practical applications [16]. To address the issue, stabilization techniques have been proposed, such as (1) addition of penalty terms to deviations from homogeneous deformations [20,31], which involves artificial (non-physical) parameters, and (2) splitting of the integration domain into multiple sub-regions [13], which is unsettling as a continuum theory.…”

Section: Introductionmentioning

confidence: 99%

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A Unified, Stable and Accurate Meshfree Framework for Peridynamic Correspondence Modeling—Part I: Core Methods

Behzadinasab

Trask

Bazilevs

2020

J Peridyn Nonlocal Model

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The overarching goal of this work is to develop an accurate, robust, and stable methodology for finite deformation modeling using strong-form peridynamics (PD) and the correspondence modeling framework. We adopt recently developed methods that make use of higher-order corrections to improve the computation of integrals in the correspondence formulation. A unified approach is presented that incorporates the reproducing kernel (RK) and generalized moving least square (GMLS) approximations in PD to obtain non-local gradients of higher-order accuracy. We show, however, that the improved quadrature rule does not suffice to handle instability issues that have proven problematic for the correspondence model-based PD. In Part I of this paper, a bond-associative, higher-order core formulation is developed that naturally provides stability without introducing artificial stabilization parameters. Numerical examples are provided to study the convergence of RK-PD, GMLS-PD, and their bond-associated versions to a local counterpart, as the degree of non-locality (i.e., the horizon) approaches zero. Problems from linear elastostatics are utilized to verify the accuracy and stability of our approach. It is shown that the bond-associative approach improves the robustness of RK-PD and GMLS-PD formulations, which is essential for practical applications. The higher-order, bond-associated model can obtain second-order convergence for smooth problems and first-order convergence for problems involving field discontinuities, such as curvilinear free surfaces. In Part II of this paper we use our unified PD framework to (a) study wave propagation phenomena, which have proven problematic for the state-based correspondence PD framework; (b) propose a new methodology to enforce natural boundary conditions in correspondence PD formulations, which should be particularly appealing to coupled problems. Our results indicate that bond-associative methods accompanied by higher-order gradient corrections provide the key ingredients to obtain the necessary accuracy, stability, and robustness characteristics needed for engineering-scale simulations.

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Section: Numerical Examplesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Unified, Stable and Accurate Meshfree Framework for Peridynamic Correspondence Modeling—Part I: Core Methods

Behzadinasab

Trask

Bazilevs

2020

J Peridyn Nonlocal Model

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“…Remark 8. Recently, Behzadinasab and Foster (2019), within the context of Sandia Fracture Challenge 2017 (Kramer et al, 2019), used the m = 1 model to predict the deformations and failure of an additively manufacture metal under tensile loading.…”

Section: Source Of the Instabilitymentioning

confidence: 99%

On the stability of the generalized, finite deformation correspondence model of peridynamics

Behzadinasab

Foster

2020

International Journal of Solids and Structures

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A class of peridynamic material models known as constitutive correspondence models provide a bridge between classical continuum mechanics and peridynamics. These models are useful because they allow well-established local constitutive theories to be used within the nonlocal framework of peridynamics. A recent finite deformation correspondence theory (Foster and Xu, 2018) was developed and reported to improve stability properties of the original correspondence model . This paper presents a stability analysis that indicates the reported advantages of the new theory were overestimated. Homogeneous deformations are analyzed and shown to exibit unstable material behavior at the continuum level. Additionally, the effects of a particle discretization on the stability of the model are reported. Numerical examples demonstrate the large errors induced by the unstable behavior. Stabilization strategies and practical applications of the new finite deformation model are discussed.

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“…Hence, sequential calibration of the individual properties and sequential calibration of their statistical distribution is required. The third Sandia Fracture Challenge (SFC3) (Kramer et al 2019) is a case study of the structural engineering task: blind computational predictions for a complex component produced by AM.…”

Section: Introductionmentioning

confidence: 99%

“…SFC3 (Kramer et al 2019) uses the same three steps as the previous challenges: calibration experiments guide material model identification, blind numerical predictions of the global and local behavior, and experimental verification using a custom 3D-geometry. This challenge used a 316L stainless steel, which was produced by Direct Metal Laser Sintering (DMLS) (also referred to as Laser Powder Bed Fusion (LPBF) King et al 2015).…”

Section: Introductionmentioning

confidence: 99%

A framework for material calibration and deformation predictions applied to additive manufacturing of metals

Brinckmann

2019

Int J Fract

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Additive manufacturing of metals offers the possibility of net-shape production of topologies that are infeasible by conventional subtractive methods, e.g. milling. However, additive manufacturing of metals posses a high defect density, which necessitates accounting for the larger statistical material variation than in conventional metals. To prevent timeconsuming experimental component testing, computational methods are required that account for the topology and metal as well as that precisely predict component failure even for metals with statistically varying properties. Predictions require an automatic and modular evaluation of the possibly large set of material properties and their scatter by employing calibration experiments. In addition, a module for failure and deformation prediction as well as a module for the aggregation of experimental data are required. In this contribution, such a modular framework is presented and the encapsulated and non-structured storage of statistically varying material properties is highlighted. In addition, the framework includes multiple FEM solvers and a multitude of optimizers, which are compared and the objective function is addressed. The approach is employed for the third Sandia Fracture Challenge for which two configurations (homogeneous and heterogeneous material properties) are studied and discussed. The blind-predictions of the verification geom

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The third Sandia fracture challenge: predictions of ductile fracture in additively manufactured metal

Cited by 70 publications

References 90 publications

A Unified, Stable and Accurate Meshfree Framework for Peridynamic Correspondence Modeling—Part I: Core Methods

A Unified, Stable and Accurate Meshfree Framework for Peridynamic Correspondence Modeling—Part I: Core Methods

On the stability of the generalized, finite deformation correspondence model of peridynamics

A framework for material calibration and deformation predictions applied to additive manufacturing of metals

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