Modeling SEBM process of tantalum lattices

Yue, Mingkai; Li, Meie; An, Ning; Yang, Kun; Wang, Jian; Zhou, Jinxiong

doi:10.1108/rpj-05-2022-0152

Cited by 6 publications

(3 citation statements)

References 55 publications

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“…Additive manufacturing (AM) enables the manufacture of very complex shapes and alloys [1,2]. More specifically, the laser-based powder bed fusion process [3][4][5], due to its implementation of small grain size powder (15-45 µm) allowing small and thin structures to be manufactured, enables the fabrication of lattice structures. Such structures are likely to promote bone growth in implantology.…”

Section: Introductionmentioning

confidence: 99%

In Vivo Bone Progression in and around Lattice Implants Additively Manufactured with a New Titanium Alloy

Obaton

Fain²,

Meinel

et al. 2023

Applied Sciences

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The osseointegration in/around additively manufactured (AM) lattice structures of a new titanium alloy, Ti–19Nb–14Zr, was evaluated. Different lattices with increasingly high sidewalls gradually closing them were manufactured and implanted in sheep. After removal, the bone–interface implant (BII) and bone–implant contact (BIC) were studied from 3D X-ray computed tomography images. Measured BII of less than 10 µm and BIC of 95% are evidence of excellent osseointegration. Since AM naturally leads to a high-roughness surface finish, the wettability of the implant is increased. The new alloy possesses an increased affinity to the bone. The lattice provides crevices in which the biological tissue can jump in and cling. The combination of these factors is pushing ossification beyond its natural limits. Therefore, the quality and speed of the ossification and osseointegration in/around these Ti–19Nb–14Zr laterally closed lattice implants open the possibility of bone spline key of prostheses. This enables the stabilization of the implant into the bone while keeping the possibility of punctual hooks allowing the implant to be removed more easily if required. Thus, this new titanium alloy and such laterally closed lattice structures are appropriate candidates to be implemented in a new generation of implants.

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Section: Introductionmentioning

confidence: 99%

In Vivo Bone Progression in and around Lattice Implants Additively Manufactured with a New Titanium Alloy

Obaton

Fain²,

Meinel

et al. 2023

Applied Sciences

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“…Hence, the maximum displacement can be obtained by Hook's law (Equation (4)) and Euler-Bernoulli (Equation ( 5)) cantilever beam theory. 4) and (5) show the maximum displacement according to Hook´s law and Euler-Bernoulli's theory for stretching and bending, respectively. Fz is the applied external force along the z-direction, Fu and Fv are the strut's axial (u) and transversal (v) components of Fz, respectively; L is the length of the strut; h is the unit cell size; and δz, δx, δu, and δv are the resulting displacements in the z, x, u, and v directions.…”

Section: Discussionmentioning

confidence: 99%

“…For metals processing, laser powder bed fusion (LPBF) is one of the most common methods thanks to the short production time, reduced economic impact, and low-volume production [ 3 , 4 ]. The combination of several process parameters (such as laser energy, laser scanning, and chamber environment) will influence the temperature and residual stress distribution, and hence, on the final part’s properties [ 5 ]. Even though this process accomplishes high-dense and near-net-shaping structures by iteratively laser melting metallic powder in a layer-by-layer process [ 6 ], the obtained surface quality is poor and rough compared with conventional machining [ 7 ].…”

Section: Introductionmentioning

confidence: 99%

Mechanical Properties of AISI 316L Lattice Structures via Laser Powder Bed Fusion as a Function of Unit Cell Features

et al. 2023

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The growth of additive manufacturing processes has enabled the production of complex and smart structures. These fabrication techniques have led research efforts to focus on the application of cellular materials, which are known for their thermal and mechanical benefits. Herein, we studied the mechanical behavior of stainless-steel (AISI 316L) lattice structures both experimentally and computationally. The lattice architectures were body-centered cubic, hexagonal vertex centroid, and tetrahedron in two cell sizes and at two different rotation angles. A preliminary computational study assessed the deformation behavior of porous cylindrical samples under compression. After the simulation results, selected samples were manufactured via laser powder bed fusion. The results showed the effects of the pore architecture, unit cell size, and orientation on the reduction in the mechanical properties. The relative densities between 23% and 69% showed a decrease in the bulk material stiffness up to 93%. Furthermore, the different rotation angles resulted in a similar porosity level but different stiffnesses. The simulation analysis and experimental results indicate that the variation in the strut position with respect to the force affected the deformation mechanism. The tetrahedron unit cell showed the smallest variation in the elastic modulus and off-axis displacements due to the cell orientation. This study collected computational and experimental data for tuning the mechanical properties of lattice structures by changing the geometry, size, and orientation of the unit cell.

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A Review of Residual Stress and Deformation Modeling for Metal Additive Manufacturing Processes

Rashid,

Gopaluni

2023

Chinese Journal of Mechanical Engineering: Additive Manufacturi

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Modeling SEBM process of tantalum lattices

Cited by 6 publications

References 55 publications

In Vivo Bone Progression in and around Lattice Implants Additively Manufactured with a New Titanium Alloy

In Vivo Bone Progression in and around Lattice Implants Additively Manufactured with a New Titanium Alloy

Mechanical Properties of AISI 316L Lattice Structures via Laser Powder Bed Fusion as a Function of Unit Cell Features

A Review of Residual Stress and Deformation Modeling for Metal Additive Manufacturing Processes

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