Excellent Mechanical Properties and Energy Absorption of Hexagonal‐Body‐Centered Lattice Structure Fabricated by Selective Laser Melting

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In this work, three types of multi‐hierarchical lattice structures (MHLSs) with different configurations were designed based on the body‐centered cubic (BCC) unit cell. The designed lattice structures were fabricated using Ti‐6Al‐4V powder as feedstock material through selective laser melting (SLM) technology. The microstructure and surface morphology of the SLM‐formed samples were observed by optical microscopy and scanning electron microscopy, respectively. Theoretical calculation and quasi‐static compression experiment were carried out to investigate their mechanical properties. The result showed that the size error of slave‐cell with small strut diameters was greater than that of master‐cell with larger strut diameters. All MHLSs exhibited superior mechanical properties compared to the BCC lattice structure. Moreover, the specific elastic modulus and specific yield strength of MHLSs with the best mechanical properties were 70.1 % and 51.0 % higher than that of BCC lattice structure, respectively. Meanwhile, theoretical calculation results of the elastic modulus and yield strength were consistent with the results of quasi‐static compression testing. The fracture morphology analysis indicated that the struts of the MHLSs samples exhibit a mixed brittle‐plastic fracture mode, while the nodes exhibit a plastic fracture mode.This article is protected by copyright. All rights reserved.

Section: Introductionmentioning

confidence: 99%

Mechanical Properties of Selective Laser Melting‐Processed Multihierarchical Lattice Structure Based on Body‐Centered‐Cubic Unit Cell

Nie,

Ren,

Gao

et al. 2024

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Mechanical Properties and Deformation Behaviors of Layered‐Hybrid Lattice Structure Fabricated by Selective Laser Melting

Ren,

Liu,

Cai

et al. 2023

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Three types of layered‐hybrid lattice structures (LHLSs) with different layer thickness composed of body‐centered cubic (BCC) and face‐centered cubic (FCC) unit cells were designed and manufactured by selective laser melting using Ti‐6Al‐4V powder. The microstructure and surface morphologies of the three types of the SLM‐formed LHLSs were examined by optical microscope and scanning electron microscope, respectively. Quasi‐static compression experiments were carried out to investigate the mechanical properties. The results showed that the layer thickness had a significant effect on the mechanical properties and deformation behaviors. The elastic modulus, yield strength and ultimate compressive strength of LHLS increased with the increasing of BCC and FCC layer thickness, respectively. Based on the observations of deformation process, a 45° shear band and axial fracture were observed in LHLS‐8; and step‐like deformation bands were observed in both LHLS‐4 and LHLS‐2 samples. Besides, the influence of different loading directions on mechanical properties was also investigated, it was found that the ultimate compressive strength loaded in the transverse direction was independent of the layer thickness in LHLSs.This article is protected by copyright. All rights reserved.

Mechanical Properties and Deformation Behaviors of Node‐Reinforced Ti–6Al–4V Lattice Structures Manufactured by Laser Powder Bed Fusion

Zhao,

Ren,

Cai

et al. 2024

Node reinforcement represents an effective strategy for enhancing the mechanical properties of lattice structures. Herein, four types of body‐centered‐cubic with Z‐strut (BCCZ) lattice structures with different node arrangements are fabricated using laser powder bed fusion (LPBF) technology. The surface morphology of four node‐reinforced BCCZ lattice structures fabricated by LPBF is examined using scanning electron microscopy. Quasistatic compression tests are conducted on these four types of node‐reinforced lattice structures. The experimental results show that the mechanical properties of all samples with node‐reinforced BCCZ lattice structures are superior to those of the traditional BCCZ lattice structure. Furthermore, the mechanical properties of the lattice structure improve in proportion to the density of the reinforced node sphere arrangement. Concurrently, an analysis of the deformation behavior of the BCCZ lattice structure with node reinforcement reveals that the TFB‐3 exhibits shear band formation at a strain level of 6.2%, which is the highest strain among all the tested structures. The results indicate that the diagonal reinforcement strategy can significantly minimize the formation of shear bands and enhance the mechanical properties of BCCZ lattice structure.