Programmed Plastic Deformation in Mathematically-Designed Architected Cellular Materials

Al‐Ketan, Oraib

doi:10.3390/met11101622

Cited by 13 publications

(6 citation statements)

References 62 publications

(70 reference statements)

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“…This feature, however, poses a drawback in the case of brittle constituents: when one unit cell fails, the other unit cells will successively fail under critical compression loading, causing a sudden and catastrophic failure in the structure . This detrimental failure mode prevents early detection of failure, prompting the development of asymmetric cellular materials, which are materials consisting of heterogeneous microstructures. − …”

Section: Asymmetric Cellular Structuresmentioning

confidence: 99%

From Brittle to Ductile: Symmetry Breaking in Strut-Based Architected Materials

Lee

Zhang

et al. 2023

ACS Materials Lett.

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Strut-based cellular structures have gained remarkable attention in recent years due to their improved strength-to-weight ratio, energy absorption abilities, and heat transfer properties. A key feature of cellular structures employed in modern infrastructure and devices is a symmetric configuration with repeating unit cells. This periodic design makes fabrication more feasible for next-generation aerospace and biomedical materials. However, such a design with brittle constituents often undergoes a sudden and catastrophic failure as all unit cells along a fracture surface tend to fail simultaneously at a critical loading condition. In this paper, we propose an elegant solution to achieve progressive failure by adjusting the diameter of each strut to create asymmetric or irregular cellular structures. Finite element simulations are conducted and validated by comparing with experiments on additively manufactured samples. Designs are then categorized into three failure modes and the relationship between the failure modes and the stress–strain curves are analyzed. Lastly, simulation-based Bayesian optimization is applied to design the structures with a more distributed stress field before failure and therefore improve their strength and energy absorption capabilities. Results show that the proposed designs fail at the boundaries and the cracks grow locally without penetrating through the entire structure, leading to more progressive failure. This research proposes novel cellular structures via symmetry breaking to achieve structures with promising manufacturability and damage-tolerant failure, greatly broadening their applications.

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Section: Asymmetric Cellular Structuresmentioning

confidence: 99%

From Brittle to Ductile: Symmetry Breaking in Strut-Based Architected Materials

Lee

Zhang

et al. 2023

ACS Materials Lett.

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“…To conclude, although the dataset is very restricted and confined, functional gradation strategy seems very promising in terms of enhancing the compressive stiffness and strength of TPMS structures. Unifrom D [114] Uniform G [114] Longitudinal hybrid [114] Radial hybrid [120] Unifrom G [117] Stochastic G [117] Stochastic sheet-based [118] RDG1T [98] RDG1T [98] RDG2 [98] RDG3 [98] CSG1 [98] CSG2 [98] CSG2T [98] CSG3 [98] Uniform Sheet G [100] Graded G [100] Graded Rhombic [101] Unifrom P [101] Graded Arrows [101] Unifrom P [101] ρ Unifrom G [117] Stochastic G [117] RDG2 [98] RDG3 [98] CSG1 [98] CSG2 [98] CSG2T [98] CSG3 [98] Uniform Sheet G [100] Graded G [100] Graded Rhombic [101] Unifrom P [101] Graded Arrows [101] Unifrom P […”

Section: Hybridization Of Tpms Structuresmentioning

confidence: 99%

“…Almesmari et al [128] reported that for mesoscale structures, the geometrical deviation between the as-built and as-designed lattices increased as their aspect ratio (i.e., ratio of cell wall thickness to unit cell size) approached the minimum resolution of an FDM printer. Jiang and Ning [129] utilized the printing-debinding-sintering Unifrom D [114] Uniform G [114] Longitudinal hybrid [114] Radial hybrid [120] Unifrom G [117] Stochastic G [117] Stochastic sheet-based [118] RDG1T [98] RDG2 [98] RDG3 [98] CSG1 [98] CSG2 [98] CSG2T [98] CSG3 [98] Uniform Sheet G [100] Graded G [100] Graded Rhombic [101] Unifrom P [101] Graded Arrows (PDS) process to fabricate BCC, FCC, and BCC-FCC plate lattices made of 17-4 stainless steel in a multistep procedure consisting of FDM printing of metal-polymer composites, debinding the printed pats (i.e., green parts) to remove polymeric wax and then sintering the components in a furnace to improve the layers binding strength. Utilization of the PDS process seems very promising to enhance the printing accuracy of the conventional FDM technology.…”

Section: Plate Lattice Materialsmentioning

confidence: 99%

“…Additionally, Oladapo et al [183] designed and tested polymer composite-based gyroid and BCCO scaffolds as dental implants (Figure 15d). The results revealed that these structures possess similar elastic and shear moduli as compared Stochastic G [117] RDG2 [98] RDG3 [98] CSG1 [98] CSG2 [98] CSG2T [98] CSG3 [98] Graded G [100] Graded Rhombic [101] Graded Arrows [101] G (size gradation) [99] D (size gradation) [99] Hybrid [99] Gyroid [99] Lattice A [169] Lattice B…”

Section: Applicationsmentioning

confidence: 99%

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Recent Advancements in Design Optimization of Lattice‐Structured Materials

et al. 2023

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Metamaterials, also known as lattice‐structured materials, imitate the multifunctionality of natural architects as tailoring their physical properties is associated with manipulating their microstructure. As the recent evolution of additive manufacturing enables the creation of intricate geometries with minimal material wastage, improving the design to manufacturing cycle of lattice structured materials has become one of the trending research areas. Triply periodic minimal surface (TPMS) and plate lattice materials are renowned for their exceptional mechanical behavior in lightweight applications. Apparently, several types of design optimization strategies are explored to maximize their performance for better biocompatibility and mechanical loading resistance. Some of these strategies include functional gradation and multimorphology hybridization that are comprehensively described in this review. Their benefits and drawbacks are highlighted with a focus on TPMS and plate lattice materials. The review anticipates the utilization of automated design exploration methods (i.e., topology optimization and data‐driven methods) to further enhance the design optimization procedure of lattice structured materials.

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“…In Figure 3, the feature being graded is the width of the rectangular unit cell, which increases from left to right. In addition to modulating cell size, it is also possible to spatially prescribe variations in wall thickness, even with discrete step changes in value, as shown in one example from the published literature in Figure 4a [19]. With advances in simulation capabilities, particularly with topology optimization, it is possible to prescribe these gradients in response to a field derived from simulation [20,21].…”

Section: Types Of Aperiodic Cellular Materialsmentioning

confidence: 99%

A Classification of Aperiodic Architected Cellular Materials

Ramirez-Chavez

Anderson

Sharma

et al. 2022

Designs

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Architected cellular materials encompass a wide range of design and performance possibilities. While there has been significant interest in periodic cellular materials, recent emphasis has included consideration of aperiodicity, most commonly in studies of stochastic and graded cellular materials. This study proposes a classification scheme for aperiodic cellular materials, by first dividing the design domain into three main types: gradation, perturbation, and hybridization. For each of these types, two design decisions are identified: (i) the feature that is to be modified and (ii) the method of its modification. Considerations such as combining different types of aperiodic design methods, and modulating the degree of aperiodicity are also discussed, along with a review of the literature that places each aperiodic design within the classification developed here, as well as summarizing the performance benefits attributed to aperiodic cellular materials over their periodic counterparts.

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Programmed Plastic Deformation in Mathematically-Designed Architected Cellular Materials

Cited by 13 publications

References 62 publications

From Brittle to Ductile: Symmetry Breaking in Strut-Based Architected Materials

From Brittle to Ductile: Symmetry Breaking in Strut-Based Architected Materials

Recent Advancements in Design Optimization of Lattice‐Structured Materials

A Classification of Aperiodic Architected Cellular Materials

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