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Abstract

Additive manufacturing (AM) continues to grow in engineering fields due to its capability to manufacture complex geometries. AM processes such as laser powder bed fusion (LPBF), in particular, have gained increasing relevance within the aerospace industry due to their effectiveness in developing complex geometries. One of the most critical objectives in the aerospace industry is to create high strength-to-weight ratio components. Thus, lattice structures are an ideal candidate to achieve this goal due to their low weight and high specific strength characteristics. However, metal AM is expensive and time-consuming, and there has been limited work in predicting the build results of complex lattice structures. If a complex part has not been optimized or designed for AM, there is the potential for build failure, or it may not be worth printing. Finite element analysis (FEA) of the AM process has proven to be an efficient resource for avoiding build failure and saving manufacturers’ time and money. This study examines the printability of a novel type of tetrahedral lattice based on the bubble-mesh method. In this work, FEA AM simulations are performed to examine how adjusting the parameters of the lattice generation method can lead to latticed cube designs that are optimal for LPBF printability. The results showed the lattice generation method could design lattices with ideal overhang angles (>45°) that are less likely to fail during an AM build due to lower deformations. The AM-optimized lattices were then printed and scanned to examine AM process deformations and validate the AM simulations. It was found that the latticed cube with a larger overhang angle had lower roughness and deformations, which agreed with the deformations findings from the AM simulations.

Keywords

AM process FEA simulation coordinate measuring machine scanning Design for Additive Manufacturing laser powder bed fusion lattice structures

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References

Wong

, Hernandez

. A review of additive manufacturing. ISRN Mech Eng, 2012; 2012:1–10.

Bandyopadhyay

, Zhang

, Bose

. Recent developments in metal additive manufacturing. Curr Opin Chem Eng, 2020; 28:96–104.

Blakey-Milner

, Gradl

, Snedden

, et al. Metal additive manufacturing in aerospace: A review. Materials & Design, 2021; 209:110008.

Song

, Feih

, Zhai

, et al. Advances in additive manufacturing process simulation: Residual stresses and distortion predictions in complex metallic components. Materials & Design, 2020; 193:108779.

Bandyopadhyay

, Traxel

. Invited review article: Metal-additive manufacturing—Modeling strategies for application-optimized design. Addit Manuf, 2018; 22:758–774.

Echeta

, Feng

, Dutton

, et al. Review of defects in lattice structures manufactured by powder bed fusion. Int J Adv Manuf Technol, 2019; 106(5–6):2649–2668.

Merulla

, Gatto

, Bassoli

, et al. Weight reduction by topology optimization of an engine subframe mount, designed for additive manufacturing production. Materials Today: Proceedings, 2019; 19:1014–1018.

Kantareddy

SNR

. Saving weight with metallic lattice structures: Design challenges with a real-world example. In: Paper presented at 27th Annual International Solid Freeform Fabrication Symposium—An Additive Manufacturing Conference. 2016, pp. 2139–2154.

Yamakawa

, Shimada

. Anisotropic tetrahedral meshing via bubble packing and advancing front. Numerical Meth Engineering, 2003; 57(13):1923–1942.

10.

Agwu

, Wang

, Singh

, et al. Assessing tetrahedral lattice parameters for engineering applications through finite element analysis. 3D Print Addit Manuf, 2021; 8(4):238–252.

11.

Zeng

, Pal

, Stucker

. A review of thermal analysis methods in Laser sintering and selective laser melting. In: National Science Foundation Solid Freedom Fabrication Symposium. 2012.

12.

Murphy

. What is SLM?”. 2019. Available from: https://all3dp.com/2/selective-laser-melting-slm-3d-printing-simply-explained/

13.

Boillat

, Kolossov

, Glardon

, et al. Finite element and neural network models for process optimization in selective laser sintering. Proc Inst Mech Eng B J Eng Manuf, 2004; 218(6):607–614.

14.

Schoinochoritis

, Chantzis

, Salonitis

. Simulation of metallic powder bed additive manufacturing processes with the finite element method: A critical review. Proc Inst Mech Eng B J Eng Manuf, 2016; 231(1):96–117.

15.

Cattenone

, Morganti

, Auricchio

. Basis of the Lattice Boltzmann method for additive manufacturing. Arch Computat Methods Eng, 2019; 27(4):1109–1133.

16.

Bayat

, Dong

, Thorborg

, et al. A review of multi-scale and multi-physics simulations of metal additive manufacturing processes with focus on modeling strategies. Additive Manufacturing, 2021; 47:102278.

17.

Wang

, Papadopoulos

. Coupled thermomechanical analysis of fused deposition using the finite element method. Finite Elements in Analysis and Design. Archives of Computational Methods in Engineering, 2021; 197:103607.

18.

Alzyod

, Ficzere

. Using finite element analysis in the 3D printing of metals. Arch Comput Methods Eng, 2021; 49(2):65–70.

19.

Carraturo

, Jomo

, Kollmannsberger

, et al. Modeling and experimental validation of an immersed thermo-mechanical part-scale analysis for laser powder bed fusion processes. Additive Manufacturing, 2020; 36:101498.

20.

Gouge

, Denlinger

, Irwin

, et al. Experimental validation of thermo-mechanical part-scale modeling for laser powder bed fusion processes. Additive Manufacturing, 2019; 29:100771.

21.

Ninpetch

, Kowitwarangkul

, Chalermkarnnon

, et al. Numerical modeling of distortion of Ti-6Al-4V components manufactured using laser powder bed fusion. Metals, 2022; 12(9):1484.

22.

Mazur

, Leary

, Sun

, et al. Deformation and failure behaviour of ti-6al-4v lattice structures manufactured by Selective Laser Melting (SLM). Int J Adv Manuf Technol, 2015.

23.

Leary

, Mazur

, Williams

, et al. Inconel 625 lattice structures manufactured by Selective Laser Melting (SLM): Mechanical properties, deformation and failure modes. Materials & Design, 2018; 157:179–199.

24.

Hussein

, Hao

, Yan

, et al. Advanced lattice support structures for metal additive manufacturing. J Mater Process Technol, 2013; 213(7):1019–1026.

25.

Ameen

, Mohammed

, Al-Ahmari

. Evaluation of support structure removability for additively manufactured ti6al4v overhangs via electron beam melting. J Mater Process Technol, 2019; 9(11).

26.

Chouhan

, Bala Murali

. Designs, advancements, and applications of three-dimensional printed gyroid structures: A Review. Proc Inst Mech Eng E J Process Mech Eng, 2023; 238(2):965–987.

27.

Shaikhnag

, Tyrer-Jones

, Hanaphy

, et al. HRL Laboratories Places High Strength Aluminum in the Hands of 3D Printers; 2019. Available from: https://3dprintingindustry.com/news/hrl-laboratories-places-high-strength-aluminum-in-the-hands-of-3d-printers-162886/

28.

King

, Anderson

, Ferencz

, et al. Laser powder-bed fusion additive manufacturing of metals; physics, computational, and materials challenges. Additive Manufacturing Handbook, 2017; 461–502.

29.

ANSYS Inc. Additive Calibration Simulation. 2019.

30.

Ganeriwala

, Strantza

, King

, et al. Evaluation of a thermomechanical model for prediction of residual stress during laser powder bed fusion of Ti-6Al-4V. Additive Manufacturing, 2019; 27:489–502.

31.

Mayer

, Brändle

, Schönenberger

, et al. Simulation and validation of residual deformations in additive manufacturing of metal parts. Heliyon, 2020; 6(5):e03987.

32.

Pant

, Sjöström

, Simonsson

, et al. A simplified layer-by-layer model for prediction of residual stress distribution in additively manufactured parts. Metals, 2021; 11(6):861.

Evaluating Tetrahedral Latticed Cubes Optimized for Additive Manufacturing Through Finite Element Analysis and Geometric Scanning Validation

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