Sage Journals: Discover world-class research

Abstract

The objective of this study is to investigate the mechanical performance of Ti6Al4V cellular structures, including different unit cell forms such as honeycomb, re-entrant, hybrid (honeycomb + re-entrant), and chiral structures manufactured with selective laser melting. The study examines the influence of rib thickness and unit cell orientation on compressive strength, elasticity modulus, Poisson's ratio, energy absorption, and specific energy absorption. Increasing the rib thickness of the unit cells improved not only the compressive strength and elasticity modulus of the samples but also their energy absorption capacities. The mechanical properties of the cellular structures varied with changes in unit cell orientation, and no direct relationship was found. The highest values for compressive strength, energy absorption, and specific energy absorption were observed in re-entrant structures, while hybrid structures had the highest elasticity modulus values. It was also found that chiral structures had the lowest compressive strength, modulus of elasticity and energy absorption capacity of all the parameters investigated. In addition, re-entrant structures with negative Poisson's ratio tend to perform positive Poisson’s ratio when they are subjected to deformation under compression. The elasticity modulus of the biocompatible Ti6Al4V cellular structures is similar to that of femoral bone values. These structures meet the requirements for use in the core of implants. The results obtained from this experimental study may guide researchers in the field of biomechanics.

Keywords

Selective laser melting cellular structures Ti6Al4V energy absorption compressive strength

Get full access to this article

View all access options for this article.

References

Alabort

Barba

Reed

. Design of metallic bone by additive manufacturing. Scr Mater 2019; 164: 110–114.

Kolken

HMA

Janbaz

Leeflang

SMA

, et al. Rationally designed meta-implants: a combination of auxetic and conventional meta-biomaterials. Mater Horiz 2018; 5: 28–35.

Ergene

. Simulation of the production of inconel 718 and Ti6Al4 V biomedical parts with different relative densities by selective laser melting (SLM) method. J Fac Eng Archit 2022; 37: 469–484.

Jamshidi

Aristizabal

Kong

, et al. Selective Laser melting of ti-6Al-4V: the impact of post-processing on the tensile, fatigue and biological properties for medical implant applications. Materials (Basel) 2020; 13: 2813.

Popovich

Sufiiarov

Polozov

, et al. Producing hip implants of titanium alloys by additive manufacturing. Int J Bioprinting 2016; 2: 78–84.

Abate

Nazir

Jeng

. Design, optimization, and selective laser melting of vin tiles cellular structure-based hip implant. J Adv Manuf Technol 2021; 112: 2037–2050.

Ghosh

Abanteriba

Wong

, et al. Selective laser melted titanium alloys for hip implant applications: surface modification with new method of polymer grafting. J Mech Behav Biomed Mater 2018; 87: 312–324.

Lee

Jeong

Yoo

, et al. Effect of auxetic structures on crash behavior of cylindrical tube. Compos Struct 2019; 208: 836–846.

Lotfi

Masoumi

. Experimental and numerical analysis of a novel 3D re-entrant auxetic structure. Proc Inst Mech Eng D: J Automob Eng 2022; 237: 3478–3493.

10.

Wilson airless basketball. https://www.wilson.com/en-us/explore/basketball/airless-prototype, Last Access Date: 19.02.2024.

11.

Ferro

Varetti

Pasquale

, et al. Lattice structured impact absorber with embedded anti-icing system for aircraft wings fabricated with additive SLM process. Mater Today Commun 2018; 15: 185–189.

12.

Qiu

Yuan

, et al. Research on shape memory alloy honeycomb structures fabricated by selective laser melting additive manufacturing. Opt Laser Technol 2022; 152: 108160.

13.

Bolat

Ergene

Ispartalı

. A comparative analysis of the effect of post production treatments and layer thickness on tensile and impact properties of additively manufactured polymers. Int Polym Process 2023; 38: 244–256.

14.

Ergene

Ispartalı

Karakılınç

. Impact behavior of PET-G parts produced by fused deposition modelling depending on layer height and test temperature. J Fac Eng Archit 2023; 38: 1345–1359.

15.

Zhang

Qin

, et al. Influence of processing parameters on AlSi10Mg lattice structure during selective laser melting: manufacturing defects, thermal behavior and compression properties. Opt Laser Technol 2023; 161: 109182.

16.

Jarfors

AEW

Shashidhar

ACGH

Yepur

, et al. Build strategy and impact strength of SLM produced maraging steel (1.2709). Metals (Basel) 2021; 11: 51.

17.

Maconachie

Leary

Zhang

, et al. Effect of build orientation on the quasi-static and dynamic response of SLM AlSi10Mg. Mater Sci amp; Eng 2020; 788: 139445.

18.

Ivekovic

Sistiaga

MLM

Vanmeensel

, et al. Effect of processing parameters on microstructure and properties of tungsten heavy alloys fabricated by SLM. Int J Refract Met Hard Mater 2019; 82: 23–30.

19.

Lesyk

Martinez

Mordyuk

, et al. Post-processing of the inconel 718 alloy parts fabricated by selective laser melting: effects of mechanical surface treatments on surface topography, porosity, hardness and residual stress. Surf Coat Technol 2020; 381: 125136.

20.

Plessis

Yadroitsava

Yadroitsev

. Ti6Al4 V lightweight lattice structures manufactured by laser powder bed fusion for load-bearing applications. Opt Laser Technol 2018; 108: 521–528.

21.

Zhao

Liu

, et al. Improved mechanical properties and energy absorption of BCC lattice structures with triply periodic minimal surfaces fabricated by SLM. Mater 2018; 11: 2411.

22.

Shi

Liao

, et al. Comparison of compression performance and energy absorption of lattice structures fabricated by selective Laser melting. Adv Eng Mater 2020; 22: 2000453.

23.

Jin

Wang

, et al. Failure and energy absorption characteristics of four lattice structures under dynamic loading. Mater Des 2019; 169: 107655.

24.

, et al. Laser additive manufacturing of bio-inspired lattice structure: forming quality, microstructure and energy absorption behavior. Mater Sci amp; Eng 2020; 773: 138857.

25.

Dong

Zhao

, et al. Experimental and numerical studies on the compressive mechanical properties of the metallic auxetic reentrant honeycomb. Mater Des 2019; 182: 108036.

26.

Xiao

Dong

, et al. Compression behavior of the graded metallic auxetic reentrant honeycomb: experiment and finite element analysis. Mater Sci amp; Eng 2019; 758: 163–171.

27.

Wei

Tian

Huang

, et al. Topological study about failure behavior and energy absorption of honeycomb structures under various strain rates. Def Technol 2023; 24: 214–227.

28.

Deng

. Energy absorption and in-plane mechanical behavior of honeycomb structures with reinforced strut. Compos Struct 2023; 322: 117339.

29.

Zhang

Dong

, et al. Mechanical properties of negative poisson's ratio metamaterial units and honeycomb structures with cosine-like re-entrant structure. Mater Lett 2023; 331: 133451.

30.

Wei

Zhao

, et al. In-plane compression behaviors of the auxetic star honeycomb: experimental and numerical simulation. Aerosp Sci Technol 2021; 115: 106797.

31.

Günaydın

Rea

Kazancı

. Energy absorption enhancement of additively manufactured hexagonal and re-entrant (auxetic) lattice structures by using multi-material reinforcements. Addit Manuf 2022; 59: 103076.

32.

Cheng

Wang

Peng

, et al. Effects of cellular crossing paths on mechanical properties of 3D printed continuous fiber reinforced biocomposite honeycomb structures. Compos - A: Appl Sci Manuf 2024; 178: 107972.

33.

EOS Titanium Ti64 Grade 5 Material Data Sheet. https://www.eos.info/03_system-related-assets/material-related-contents/metal-materials-and-examples/metal-material-datasheet/titan/ti64/material_datasheet_eos_titanium_ti64_grade5_en_web.pdf, Last Access Date: 10.02.2024.

34.

Gibson

Ashby

. Cellular Solids: Structure and Properties Cambridge University Press, ISBN 10: 0521499119 / ISBN 13: 9780521499118. 1999.

35.

Zhang

Ding

, et al. Numerical investigation on dynamic crushing behavior of auxetic honeycombs with various cell-wall angles. Adv Mech Eng 2015; 7: 1–12.

36.

Burr

Turner

Naick

, et al.

Does microdamage accumulation affect the mechanical properties of bone?

J Biomech 1998; 31: 337–345.

37.

Havaldar

Pilli

Putti

. Insights into the effects of tensile and compressive loadings on human femur bone. Adv Biomed Res 2014 Mar 25; 3: 01.. PMID: 24800190; PMCID: PMC4007336.

38.

Huang

Lei

, et al. Microstructural features and compressive properties of SLM Ti6Al4 V lattice structures. Surf Coat Technol 2020; 403: 126419.

39.

Chen

Hao

, et al. Mechanical behaviors of 3D re-entrant honeycomb polyamide structure under compression. Mater Today Commun 2020; 24: 101062.

40.

Ingrole

Hao

Liang

. Design and modeling of auxetic and hybrid honeycomb structures for in-plane property enhancement. Mater Des 2017; 117: 72–83.

41.

Wang

Bian

Yang

, et al. Mechanical properties and energy absorption of FCC lattice structures with different orientation angles. Acta Mech 2020; 231: 3129–3144.

42.

Mir

Ali

Sami

, et al. Review of mechanics and applications of auxetic structures. Adv Mater Sci Eng 2014; 2014: 753496.

43.

. Dynamic crushing strength of hexagonal honeycombs. Int J Impact Eng 2010; 37: 467–474.

44.

Liu

Yang

, et al. In-plane elastic properties of a 2D chiral cellular structure with V-shaped wings. Eng Struct 2020; 210: 110384.

45.

Tan

, et al. In-plane crashworthiness of re-entrant hierarchical honeycombs with negative Poisson’s ratio. Compos Struct 2019; 229: 111415.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

4.12 MB

0.02 MB

Experimental investigation on the mechanical properties of Ti6Al4V cellular structures produced with selective laser melting: Effects of rib thickness,unit cell type and orientation

Abstract

Keywords

Get full access to this article

References

Supplementary Material