Compressive Mechanics and Hyperelasticity of Ni-Ti Lattice Structures Fabricated by Selective Laser Melting

Zhang, Cong; Jin, Jiulu; He, Meng; Liu, Yang

doi:10.3390/cryst12030408

Cited by 6 publications

(2 citation statements)

References 45 publications

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“…This is a common method to calculate the stress on porous structures. [20,[28][29][30] The cyclic compression test was done incrementally from 2% to 10% compressive strain along the build direction (xz) depending on the condition of the samples. After the highest cyclic compression cycles, the sample was compressed until rupture.…”

Section: Characterization Of the Specimensmentioning

confidence: 99%

A Systematic Approach to Optimize Parameters in Manufacturing Complex Lattice Structures of NiTi Using Electron Beam Powder Bed Fusion Process

Lin,

Dadbakhsh,

Larsson

et al. 2024

Adv Eng Mater

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In this study, the quality and accuracy to manufacture delicate parts from NiTi powder using electron beam powder bed fusion (EB‐PBF) technology is investigated. Therefore, benchmarks with thin cylinders and thin walls were designed and fabricated using two distinct scan strategies of EB‐PBF manufacturing (i.e., continuous melting and spot melting) with different process parameter sets. After these optimizations, four different lattice structures (i.e., octahedron, cell gyroid, sheet gyroid and channel) were manufactured and characterized. It is shown both continuous melting and spot melting modes are able to manufacture lattices with relative densities over 97%. And, as‐built lattice structures exhibit an excellent pseudoelasticity up to 8% depending on the design of the structure, e.g., the channel structure shows more deformation recoverability than the cell gyroid. This is attributed to the integrity of geometry as well as compressive mode of the mechanical loading. Of course, the compressive strength and ultimate compressive strength also increases with increasing the volume fraction. Moreover, the spot melting could be used as an engineering tool to customize a delicate beam‐shaped structure with a superior pseudoelasticity.This article is protected by copyright. All rights reserved.

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Section: Characterization Of the Specimensmentioning

confidence: 99%

A Systematic Approach to Optimize Parameters in Manufacturing Complex Lattice Structures of NiTi Using Electron Beam Powder Bed Fusion Process

Lin,

Dadbakhsh,

Larsson

et al. 2024

Adv Eng Mater

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show abstract

“…Currently, Nickel-Titanium (NiTi) shape memory alloy has garnered attention as a raw material for designing intelligent components due to its unique properties, including superelasticity (SE) and shape memory effect (SME) [24]. Nevertheless, existing NiTi porous structures, such as triply periodic minimal surface structures [25] and cellular lattice structures [26,27], are prone to severe stress concentration accompanied by irreversible plastic deformation under loading, or catastrophic failure if their strength is exceeded. These limitations hinder the full utilization of the NiTi alloy's potential.…”

Section: Introductionmentioning

confidence: 99%

Design and additive manufacturing of bionic hybrid structure inspired by cuttlebone to achieve superior mechanical properties and shape memory function

Yuan,

Gu,

Liu

et al. 2024

Int. J. Extrem. Manuf.

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Lightweight porous materials with high load-bearing, damage tolerance and energy absorption as well as intelligence of shape recovery after material deformation are beneficial and critical for many applications, e.g., aerospace, automobiles, electronics, etc. Cuttlebone produced in the cuttlefish has evolved vertical walls with the optimal corrugation gradient, enabling stress homogenization, significant load bearing, and damage tolerance to protect the organism from high external pressures in the deep sea. This work illustrated that the complex hybrid wave shape in cuttlebone walls, becoming more tortuous from bottom to top, creates a lightweight, load-bearing structure with progressive failure. By mimicking the cuttlebone, a novel bionic hybrid structure (BHS) was proposed, and as a comparison, a regular corrugated structure (RCS) and a straight wall structure (SWS) were designed. Three types of designed structures have been successfully manufactured by laser powder bed fusion with NiTi powder. The LPBF-processed BHS exhibited a total porosity of 0.042% and a good dimensional accuracy with a peak deviation of 17.4 μm. Microstructural analysis indicated that the LPBF-processed BHS had a strong (001) crystallographic orientation and an average size of 9.85 μm. Mechanical analysis revealed the LPBF-processed BHS could withstand over 25 000 times its weight without significant deformation and had the highest specific energy absorption value (5.32 J/g) due to the absence of stress concentration and progressive wall failure during compression. Cyclic compression testing showed that LPBF-processed BHS possessed superior viscoelastic and elasticity energy dissipation capacity. Importantly, the uniform reversible phase transition from martensite to austenite in the walls enables the structure to largely recover its pre-deformation shape when heated (over 99% recovery rate). These design strategies can serve as valuable references for the development of intelligent components that possess high mechanical efficiency and shape memory capabilities.

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SLM Additive Manufacturing of NiTi Porous Implants: A Review of Constitutive Models, Finite Element Simulations, Manufacturing, Heat Treatment, Mechanical, and Biomedical Studies

et al. 2023

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Compressive Mechanics and Hyperelasticity of Ni-Ti Lattice Structures Fabricated by Selective Laser Melting

Cited by 6 publications

References 45 publications

A Systematic Approach to Optimize Parameters in Manufacturing Complex Lattice Structures of NiTi Using Electron Beam Powder Bed Fusion Process

A Systematic Approach to Optimize Parameters in Manufacturing Complex Lattice Structures of NiTi Using Electron Beam Powder Bed Fusion Process

Design and additive manufacturing of bionic hybrid structure inspired by cuttlebone to achieve superior mechanical properties and shape memory function

SLM Additive Manufacturing of NiTi Porous Implants: A Review of Constitutive Models, Finite Element Simulations, Manufacturing, Heat Treatment, Mechanical, and Biomedical Studies

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