Investigations on Mechanical Properties of Lattice Structures with Different Values of Relative Density Made from 316L by Selective Laser Melting (SLM)

Płatek, Paweł; Sienkiewicz, Judyta; Janiszewski, Jacek; Jiang, Fengchun

doi:10.20944/preprints202005.0112.v1

Cited by 5 publications

(4 citation statements)

References 88 publications

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“…The statistical analysis confirms that cell size and strut thickness influence the plateau stress of lattice structures. This outcome is consistent with previous studies that explored the influence of cell size and strut diameter on the mechanical response of lattices [7,[28][29][30][31]. The strength and modulus of the lattices increased with the decrease in the unit cell size and/or increase in strut diameter, due to the associated denser structures [29].…”

Section: Discussionsupporting

confidence: 92%

“…The influence of diverse geometric parameters (unit cell type, cell size, cell orientation, strut thickness, strut cross-section, etc.) on the mechanical properties of lattice structures has been investigated by analytical, numerical, and experimental techniques [7,[26][27][28][29][30][31]. For instance, scaling law models have been used to model the relationship between strut diameter, cell size, and mechanical properties [22,28], and have been validated experimentally [7,[29][30][31].…”

Section: Introductionmentioning

confidence: 99%

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Influence of Geometric and Manufacturing Parameters on the Compressive Behavior of 3D Printed Polymer Lattice Structures

et al. 2021

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Fused deposition modeling represents a flexible and relatively inexpensive alternative for the production of custom-made polymer lattices. However, its limited accuracy and resolution lead to geometric irregularities and poor mechanical properties when compared with the digital design. Although the link between geometric features and mechanical properties of lattices has been studied extensively, the role of manufacturing parameters has received little attention. Additionally, as the size of cells/struts nears the accuracy limit of the manufacturing process, the interaction between geometry and manufacturing parameters could be decisive. Hence, the influence of three geometric and two manufacturing parameters on the mechanical behavior was evaluated using a fractional factorial design of experiments. The compressive behavior of two miniature lattice structures, the truncated octahedron and cubic diamond, was evaluated, and multilinear regression models for the elastic modulus and plateau stress were developed. Cell size, unit cell type, and strut diameter had the largest impact on the mechanical properties, while the influence of feedstock material and layer thickness was very limited. Models based on factorial design, although limited in scope, could be an effective tool for the design of customized lattice structures.

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Section: Discussionsupporting

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Influence of Geometric and Manufacturing Parameters on the Compressive Behavior of 3D Printed Polymer Lattice Structures

et al. 2021

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“…With the deepening of the research, the configuration mode, 10,11 distribution characteristics, 12 equivalent elastic properties 13,14 of the cellular materials and related research methods are gradually studied. 15,16 In order to further explore the performance advantages of cellular materials, people's focus has been extended from uniform lattice structures to nonuniform lattice structures such as graded lattice and variable-density lattice, 17 and the performance of cellular materials has expanded from structural lightweight to multi-functional characteristics, such as vibration resistance, shock resistance, heat and heat transfer, sound absorption and noise reduction, and zero/ negative thermal expansion, ect. 18,19 Seharing et al 20 analyzed the design, mechanical behaviors, manufacturability, and application of the graded lattice structure manufactured via metallic additive manufacturing technology.…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A discretization method for predicting the equivalent elastic parameters of the graded lattice structure

Zhao

Zhang

et al. 2020

Advances in Mechanical Engineering

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In recent years, cellular materials have been widely studied and applied in aerospace and other fields due to the advantages of lightweight and multi-function. However, it is difficult to predict the equivalent elastic properties of the graded lattice structure and other non-uniform cellular materials because of the complex configuration and non-uniformity. A new discretization method for predicting the equivalent elastic parameters of the graded lattice structure is proposed based on the strain energy equivalent method and the discretization method in this paper. The graded lattice structure is discretized into lattice cells, the equivalent elastic properties are predicted by calculating the global equivalent elastic parameters with the parameters of lattice cells, and the calculation formulas are derived. After that, taking edge cube, face-centered cubic and body-centered cubic lattice as examples, the effectiveness and accuracy of the method are verified by theoretical calculation, numerical analysis, and experiment. The results show that the calculation errors of equivalent elastic parameters are between 4.5%–9.7%, and the errors can be significantly improved by reducing the graded factor. It proves that the proposed discretization method can predict the equivalent elastic parameters of the graded lattice structure effectively, and is suitable for different lattice structures.

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Effect of microstructural evolution during melt pool formation on nano-mechanical properties in LPBF based SS316L parts

Jeyaprakash,

Saravana Kumar,

Yang

et al. 2024

Journal of Alloys and Compounds

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Investigations on Mechanical Properties of Lattice Structures with Different Values of Relative Density Made from 316L by Selective Laser Melting (SLM)

Cited by 5 publications

References 88 publications

Influence of Geometric and Manufacturing Parameters on the Compressive Behavior of 3D Printed Polymer Lattice Structures

Influence of Geometric and Manufacturing Parameters on the Compressive Behavior of 3D Printed Polymer Lattice Structures

A discretization method for predicting the equivalent elastic parameters of the graded lattice structure

Effect of microstructural evolution during melt pool formation on nano-mechanical properties in LPBF based SS316L parts

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