Research Article
BibTex RIS Cite
Year 2023, Volume: 7 Issue: 4, 372 - 383, 31.12.2023
https://doi.org/10.30939/ijastech..1360762

Abstract

References

  • [1] Ozdemir Z, Hernandez-Nava E, Tyas A, Warren JA, Fay SD, Goodall R, et al. Energy absorption in lattice structures in dynamics: Experiments. Int J Impact Eng 2016;89:49–61.
  • [2] Yang S, Qi C. Blast-resistant improvement of sandwich armor structure with aluminum foam composite. Adv Mater Sci Eng [3] Imbalzano G, Tran P, Ngo TD, Lee PVS. Three-dimensional modelling of auxetic sandwich panels for localised impact resistance. J Sandw Struct Mater 2017;19:291–316.
  • [4] Deshpande VS, Fleck NA. Isotropic constitutive models for metallic foams. J Mech Phys Solids 2000;48:1253–83.
  • [5] Zhao H, Abdennadher S. On the strength enhancement under impact loading of square tubes made from rate insensitive metals. Int J Solids Struct 2004;41:6677–97.
  • [6] Chen Z, Xie YM, Wu X, Wang Z, Li Q, Zhou S. On hybrid cellular materials based on triply periodic minimal surfaces with extreme mechanical properties. Mater Des 2019;183.
  • [7] Maskery I, Aboulkhair NT, Aremu AO, Tuck CJ, Ashcroft IA. Compressive failure modes and energy absorption in additively manufactured double gyroid lattices. Addit Manuf 2017;16:24–9.
  • [8] Maskery I, Aboulkhair NT, Aremu AO, Tuck CJ, Ashcroft IA, Wildman RD, et al. A mechanical property evaluation of graded density Al-Si10-Mg lattice structures manufactured by selective laser melting. Mater Sci Eng A 2016;670:264–74.
  • [9] Abueidda DW, Elhebeary M, Shiang CS (Andrew), Pang S, Abu Al-Rub RK, Jasiuk IM. Mechanical properties of 3D printed polymeric Gyroid cellular structures: Experimental and finite element study. Mater Des 2019;165.
  • [10] Ashby MF. The properties of foams and lattices. Philos Trans R Soc A Math Phys Eng Sci 2006;364:15–30.
  • [11] Maskery I, Sturm L, Aremu AO, Panesar A, Williams CB, Tuck CJ, et al. Insights into the mechanical properties of several triply periodic minimal surface lattice structures made by polymer additive manufacturing. Polymer (Guildf) 2018;152:62–71.
  • [12] Lei H, Li C, Meng J, Zhou H, Liu Y, Zhang X, et al. Evaluation of compressive properties of SLM-fabricated multi-layer lattice structures by experimental test and μ-CT-based finite element analysis. Mater Des 2019;169.
  • [13] Kocabaş GB, Çetin E, Yalçınkaya S, Şahin Y. Experimental Comparison of the Energy Absorption Performance of Traditional Lattice and Novel Lattice Filled Tubes. Int J Automot Sci Technol 2023.
  • [14] Vrana R, Koutny D, Palousek D. Impact resistance of different types of lattice structures manufactured by SLM. MM Sci J 2016;2016:1579–85. https://doi.org/10.17973/MMSJ.2016_12_2016186.
  • [15] Niendorf T, Brenne F, Schaper M. Lattice structures manufactured by SLM: On the effect of geometrical dimensions on microstructure evolution during processing. Metall Mater Trans B Process Metall Mater Process Sci 2014;45:1181–5.
  • [16] Amani Y, Dancette S, Delroisse P, Simar A, Maire E. Compression behavior of lattice structures produced by selective laser melting: X-ray tomography based experimental and finite element approaches. Acta Mater 2018;159:395–407.
  • [17] Zhang L, Feih S, Daynes S, Chang S, Wang MY, Wei J, et al. Energy absorption characteristics of metallic triply periodic minimal surface sheet structures under compressive loading. Addit Manuf 2018;23:505–15.
  • [18] Alomar Z, Concli F. A Review of the Selective Laser Melting Lattice Structures and Their Numerical Models. Adv Eng Mater 2020;22.
  • [19] Yang L, Harrysson O, West H, Cormier D. Mechanical properties of 3D re-entrant honeycomb auxetic structures realized via additive manufacturing. Int J Solids Struct 2015;69–70:475–90.
  • [20] Maconachie T, Leary M, Lozanovski B, Zhang X, Qian M, Faruque O, et al. SLM lattice structures: Properties, performance, applications and challenges. Mater Des 2019;183.
  • [21] Sun Q, Sun J, Guo K, Wang L. Compressive mechanical properties and energy absorption characteristics of SLM fabricated Ti6Al4V triply periodic minimal surface cellular structures. Mech Mater 2022;166.
  • [22] Zhao M, Zhang DZ, Liu F, Li Z, Ma Z, Ren Z. Mechanical and energy absorption characteristics of additively manufactured functionally graded sheet lattice structures with minimal surfaces. Int J Mech Sci 2020;167.
  • [23] Leary M, Mazur M, Williams H, Yang E, Alghamdi A, Lozanovski B, et al. Inconel 625 lattice structures manufactured by selective laser melting (SLM): Mechanical properties, deformation and failure modes. Mater Des 2018;157:179–99.
  • [24] Ramos H, Santiago R, Soe S, Theobald P, Alves M. Response of gyroid lattice structures to impact loads. Int J Impact Eng 2022;164.
  • [25] Al-Ketan O, Rowshan R, Abu Al-Rub RK. Topology-mechanical property relationship of 3D printed strut, skeletal, and sheet based periodic metallic cellular materials. Addit Manuf 2018;19:167–83.
  • [26] Xu W, Yu A, Lu X, Tamaddon M, Wang M, Zhang J, et al. Design and performance evaluation of additively manufactured composite lattice structures of commercially pure Ti (CP–Ti). Bioact Mater 2021;6:1215–22.
  • [27] Yan C, Hao L, Hussein A, Raymont D. Evaluations of cellular lattice structures manufactured using selective laser melting. Int J Mach Tools Manuf 2012;62:32–8.
  • [28] Dokumacı E, Aybarç U, Önel K. Effect of Ultrasonic Treatment Parameters on Microstructural and Mechanical Properties of A356 Aluminum Alloy. Int J Automot Sci Technol 2020;4:234–43.
  • [29] Aliheidari N, Christ J, Tripuraneni R, Nadimpalli S, Ameli A. Interlayer adhesion and fracture resistance of polymers printed through melt extrusion additive manufacturing process. Mater Des 2018;156:351–61.
  • [30] Lu C, Zhang Y, Aziz M, Wen P, Zhang C, Shen Q, et al. Mechanical behaviors of multidimensional gradient gyroid structures under static and dynamic loading: A numerical and experimental study. Addit Manuf 2022;59.
  • [31] Ha NS, Pham TM, Vo NH, Hao H. Dynamic crushing characteristics of bio-inspired minimal surface primitive structures. Compos Struct 2023;304.
  • [32] Novak N, Al-Ketan O, Krstulović-Opara L, Rowshan R, Abu Al-Rub RK, Vesenjak M, et al. Quasi-static and dynamic compressive behaviour of sheet TPMS cellular structures. Compos Struct 2021;266.
  • [33] Committee E. Test methods for tension testing of metallic materials. ASTM Int 2011:1–27.
  • [34] Li Z hua, Nie Y fei, Liu B, Kuai Z zhou, Zhao M, Liu F. Mechanical properties of AlSi10Mg lattice structures fabricated by selective laser melting. Mater Des 2020;192.
  • [35] Breitenecker F, Kugi A, Troch I. MATHMOD 2015 - Abstract Volume: Content and Preface, 2018.
  • [36] Lu C, Zhang C, Wen P, Chen F. Mechanical behavior of Al–Si10–Mg gyroid surface with variable topological parameters fabricated via laser powder bed fusion. J Mater Res Technol 2021;15:5650–61.
  • [37] Lobdell M, Croop B, Lobo H. Comparison of Crash Models for Ductile Plastics. Mater. Sci., 2015.
  • [38] Wu Y, Sun L, Yang P, Fang J, Li W. Energy absorption of additively manufactured functionally bi-graded thickness honeycombs subjected to axial loads. Thin-Walled Struct 2021;164.
  • [39] Zhu H, Wang P, Wei D, Si J, Wu Y. Energy absorption of diamond lattice cylindrical shells under axial compression loading. Thin-Walled Struct 2022;181.
  • [40] Yin H, Liu Z, Dai J, Wen G, Zhang C. Crushing behavior and optimization of sheet-based 3D periodic cellular structures. Compos Part B Eng 2020;182.
  • [41] Gümrük R, Mines RAW. Compressive behaviour of stainless steel micro-lattice structures. Int J Mech Sci 2013;68:125–39.
  • [42] Liu J, Song Y, Chen C, Wang X, Li H, Zhou C, et al. Effect of scanning speed on the microstructure and mechanical behavior of 316L stainless steel fabricated by selective laser melting. Mater Des 2020;186.
  • [43] Bahrami Babamiri B, Askari H, Hazeli K. Deformation mechanisms and post-yielding behavior of additively manufactured lattice structures. Mater Des 2020.
  • [44] Smith M, Guan Z, Cantwell WJ. Finite element modelling of the compressive response of lattice structures manufactured using the selective laser melting technique. Int J Mech Sci 2013;67:28–41.

Investigation of Energy Absorbing and Damage Behavior of Gyroid and Diamond Cell Based Lattice Structures Manufactured through Powder Bed Fusion Technology

Year 2023, Volume: 7 Issue: 4, 372 - 383, 31.12.2023
https://doi.org/10.30939/ijastech..1360762

Abstract

Cellular porous structures are used as an alternative to blocking structures in in-dustrial fields where multi-functionality and mechanical efficiency are necessary. Many industries, such as automotive, aerospace and defense, utilize the benefits of these structures due to their high specific strength, outstanding noise and vibration damping abilities, thermal shielding, and superior specific energy absorption capacities.
This study aims to reveal energy absorbing behavior and deformation mechanisms under compression load of Gyroid and Diamond cell based triply periodic minimal surface (TPMS) structures manufactured by powder bed fusion (PBF) technology. The TPMS lattice structures fabricated using AlSi10Mg material were designed in different relative densities according to cell wall thickness and cell number. Crushing behaviors of these structures were numerically investigated with a commercial Ls-Dyna finite elements (FE) software. The numerical results were obtained in a good agreement with the experimental data. The FE analysis facilitated understanding of the deformation damage mechanisms and stress distribution on the cell surfaces of the TPMS lattice structures designed with different relative densities. The findings of the study demonstrated that peak stress values computed during crushing of the TPMS lattice structures go up significantly with increasing relative density. Crush force efficiency (CFE) and energy absorption capacity of the TPMS lattice structures remarkably varied depending on deformation damage mechanisms occurred during crushing process. The highest CFE values for the Diamond and Gyroid cell-based lattice structures was obtained as 54% and 51%, respectively. Moreover, it was found that specific energy absorption capacity of the Diamond cell based TPMS lattice structures is 50% more than that of the Gyroid cell based TPMS lattice structures with close relative densities.

Ethical Statement

The authors certify that they have no affiliations with or involvement in any organization or entity with any financial interest (such as honoraria; educational grants; participation in speakers’ bureaus; membership, employment, consultancies, stock ownership, or other equity interest; and expert testimony or patent-licensing arrangements), or non-financial interest (such as personal or professional relationships, affiliations, knowledge or beliefs) in the subject matter or materials discussed in this manuscript.

Supporting Institution

KARADENIZ TECHNICAL UNIVERSITY

Thanks

This study was supported by Karadeniz Technical University. As researchers, we thank the Karadeniz Technical University.

References

  • [1] Ozdemir Z, Hernandez-Nava E, Tyas A, Warren JA, Fay SD, Goodall R, et al. Energy absorption in lattice structures in dynamics: Experiments. Int J Impact Eng 2016;89:49–61.
  • [2] Yang S, Qi C. Blast-resistant improvement of sandwich armor structure with aluminum foam composite. Adv Mater Sci Eng [3] Imbalzano G, Tran P, Ngo TD, Lee PVS. Three-dimensional modelling of auxetic sandwich panels for localised impact resistance. J Sandw Struct Mater 2017;19:291–316.
  • [4] Deshpande VS, Fleck NA. Isotropic constitutive models for metallic foams. J Mech Phys Solids 2000;48:1253–83.
  • [5] Zhao H, Abdennadher S. On the strength enhancement under impact loading of square tubes made from rate insensitive metals. Int J Solids Struct 2004;41:6677–97.
  • [6] Chen Z, Xie YM, Wu X, Wang Z, Li Q, Zhou S. On hybrid cellular materials based on triply periodic minimal surfaces with extreme mechanical properties. Mater Des 2019;183.
  • [7] Maskery I, Aboulkhair NT, Aremu AO, Tuck CJ, Ashcroft IA. Compressive failure modes and energy absorption in additively manufactured double gyroid lattices. Addit Manuf 2017;16:24–9.
  • [8] Maskery I, Aboulkhair NT, Aremu AO, Tuck CJ, Ashcroft IA, Wildman RD, et al. A mechanical property evaluation of graded density Al-Si10-Mg lattice structures manufactured by selective laser melting. Mater Sci Eng A 2016;670:264–74.
  • [9] Abueidda DW, Elhebeary M, Shiang CS (Andrew), Pang S, Abu Al-Rub RK, Jasiuk IM. Mechanical properties of 3D printed polymeric Gyroid cellular structures: Experimental and finite element study. Mater Des 2019;165.
  • [10] Ashby MF. The properties of foams and lattices. Philos Trans R Soc A Math Phys Eng Sci 2006;364:15–30.
  • [11] Maskery I, Sturm L, Aremu AO, Panesar A, Williams CB, Tuck CJ, et al. Insights into the mechanical properties of several triply periodic minimal surface lattice structures made by polymer additive manufacturing. Polymer (Guildf) 2018;152:62–71.
  • [12] Lei H, Li C, Meng J, Zhou H, Liu Y, Zhang X, et al. Evaluation of compressive properties of SLM-fabricated multi-layer lattice structures by experimental test and μ-CT-based finite element analysis. Mater Des 2019;169.
  • [13] Kocabaş GB, Çetin E, Yalçınkaya S, Şahin Y. Experimental Comparison of the Energy Absorption Performance of Traditional Lattice and Novel Lattice Filled Tubes. Int J Automot Sci Technol 2023.
  • [14] Vrana R, Koutny D, Palousek D. Impact resistance of different types of lattice structures manufactured by SLM. MM Sci J 2016;2016:1579–85. https://doi.org/10.17973/MMSJ.2016_12_2016186.
  • [15] Niendorf T, Brenne F, Schaper M. Lattice structures manufactured by SLM: On the effect of geometrical dimensions on microstructure evolution during processing. Metall Mater Trans B Process Metall Mater Process Sci 2014;45:1181–5.
  • [16] Amani Y, Dancette S, Delroisse P, Simar A, Maire E. Compression behavior of lattice structures produced by selective laser melting: X-ray tomography based experimental and finite element approaches. Acta Mater 2018;159:395–407.
  • [17] Zhang L, Feih S, Daynes S, Chang S, Wang MY, Wei J, et al. Energy absorption characteristics of metallic triply periodic minimal surface sheet structures under compressive loading. Addit Manuf 2018;23:505–15.
  • [18] Alomar Z, Concli F. A Review of the Selective Laser Melting Lattice Structures and Their Numerical Models. Adv Eng Mater 2020;22.
  • [19] Yang L, Harrysson O, West H, Cormier D. Mechanical properties of 3D re-entrant honeycomb auxetic structures realized via additive manufacturing. Int J Solids Struct 2015;69–70:475–90.
  • [20] Maconachie T, Leary M, Lozanovski B, Zhang X, Qian M, Faruque O, et al. SLM lattice structures: Properties, performance, applications and challenges. Mater Des 2019;183.
  • [21] Sun Q, Sun J, Guo K, Wang L. Compressive mechanical properties and energy absorption characteristics of SLM fabricated Ti6Al4V triply periodic minimal surface cellular structures. Mech Mater 2022;166.
  • [22] Zhao M, Zhang DZ, Liu F, Li Z, Ma Z, Ren Z. Mechanical and energy absorption characteristics of additively manufactured functionally graded sheet lattice structures with minimal surfaces. Int J Mech Sci 2020;167.
  • [23] Leary M, Mazur M, Williams H, Yang E, Alghamdi A, Lozanovski B, et al. Inconel 625 lattice structures manufactured by selective laser melting (SLM): Mechanical properties, deformation and failure modes. Mater Des 2018;157:179–99.
  • [24] Ramos H, Santiago R, Soe S, Theobald P, Alves M. Response of gyroid lattice structures to impact loads. Int J Impact Eng 2022;164.
  • [25] Al-Ketan O, Rowshan R, Abu Al-Rub RK. Topology-mechanical property relationship of 3D printed strut, skeletal, and sheet based periodic metallic cellular materials. Addit Manuf 2018;19:167–83.
  • [26] Xu W, Yu A, Lu X, Tamaddon M, Wang M, Zhang J, et al. Design and performance evaluation of additively manufactured composite lattice structures of commercially pure Ti (CP–Ti). Bioact Mater 2021;6:1215–22.
  • [27] Yan C, Hao L, Hussein A, Raymont D. Evaluations of cellular lattice structures manufactured using selective laser melting. Int J Mach Tools Manuf 2012;62:32–8.
  • [28] Dokumacı E, Aybarç U, Önel K. Effect of Ultrasonic Treatment Parameters on Microstructural and Mechanical Properties of A356 Aluminum Alloy. Int J Automot Sci Technol 2020;4:234–43.
  • [29] Aliheidari N, Christ J, Tripuraneni R, Nadimpalli S, Ameli A. Interlayer adhesion and fracture resistance of polymers printed through melt extrusion additive manufacturing process. Mater Des 2018;156:351–61.
  • [30] Lu C, Zhang Y, Aziz M, Wen P, Zhang C, Shen Q, et al. Mechanical behaviors of multidimensional gradient gyroid structures under static and dynamic loading: A numerical and experimental study. Addit Manuf 2022;59.
  • [31] Ha NS, Pham TM, Vo NH, Hao H. Dynamic crushing characteristics of bio-inspired minimal surface primitive structures. Compos Struct 2023;304.
  • [32] Novak N, Al-Ketan O, Krstulović-Opara L, Rowshan R, Abu Al-Rub RK, Vesenjak M, et al. Quasi-static and dynamic compressive behaviour of sheet TPMS cellular structures. Compos Struct 2021;266.
  • [33] Committee E. Test methods for tension testing of metallic materials. ASTM Int 2011:1–27.
  • [34] Li Z hua, Nie Y fei, Liu B, Kuai Z zhou, Zhao M, Liu F. Mechanical properties of AlSi10Mg lattice structures fabricated by selective laser melting. Mater Des 2020;192.
  • [35] Breitenecker F, Kugi A, Troch I. MATHMOD 2015 - Abstract Volume: Content and Preface, 2018.
  • [36] Lu C, Zhang C, Wen P, Chen F. Mechanical behavior of Al–Si10–Mg gyroid surface with variable topological parameters fabricated via laser powder bed fusion. J Mater Res Technol 2021;15:5650–61.
  • [37] Lobdell M, Croop B, Lobo H. Comparison of Crash Models for Ductile Plastics. Mater. Sci., 2015.
  • [38] Wu Y, Sun L, Yang P, Fang J, Li W. Energy absorption of additively manufactured functionally bi-graded thickness honeycombs subjected to axial loads. Thin-Walled Struct 2021;164.
  • [39] Zhu H, Wang P, Wei D, Si J, Wu Y. Energy absorption of diamond lattice cylindrical shells under axial compression loading. Thin-Walled Struct 2022;181.
  • [40] Yin H, Liu Z, Dai J, Wen G, Zhang C. Crushing behavior and optimization of sheet-based 3D periodic cellular structures. Compos Part B Eng 2020;182.
  • [41] Gümrük R, Mines RAW. Compressive behaviour of stainless steel micro-lattice structures. Int J Mech Sci 2013;68:125–39.
  • [42] Liu J, Song Y, Chen C, Wang X, Li H, Zhou C, et al. Effect of scanning speed on the microstructure and mechanical behavior of 316L stainless steel fabricated by selective laser melting. Mater Des 2020;186.
  • [43] Bahrami Babamiri B, Askari H, Hazeli K. Deformation mechanisms and post-yielding behavior of additively manufactured lattice structures. Mater Des 2020.
  • [44] Smith M, Guan Z, Cantwell WJ. Finite element modelling of the compressive response of lattice structures manufactured using the selective laser melting technique. Int J Mech Sci 2013;67:28–41.
There are 43 citations in total.

Details

Primary Language English
Subjects Material Production Technologies, Automotive Engineering Materials
Journal Section Articles
Authors

İsmail Özen 0000-0001-9640-7208

Mustafa Aslan 0000-0003-2299-8417

Publication Date December 31, 2023
Submission Date September 15, 2023
Acceptance Date December 6, 2023
Published in Issue Year 2023 Volume: 7 Issue: 4

Cite

APA Özen, İ., & Aslan, M. (2023). Investigation of Energy Absorbing and Damage Behavior of Gyroid and Diamond Cell Based Lattice Structures Manufactured through Powder Bed Fusion Technology. International Journal of Automotive Science And Technology, 7(4), 372-383. https://doi.org/10.30939/ijastech..1360762
AMA Özen İ, Aslan M. Investigation of Energy Absorbing and Damage Behavior of Gyroid and Diamond Cell Based Lattice Structures Manufactured through Powder Bed Fusion Technology. IJASTECH. December 2023;7(4):372-383. doi:10.30939/ijastech.1360762
Chicago Özen, İsmail, and Mustafa Aslan. “Investigation of Energy Absorbing and Damage Behavior of Gyroid and Diamond Cell Based Lattice Structures Manufactured through Powder Bed Fusion Technology”. International Journal of Automotive Science And Technology 7, no. 4 (December 2023): 372-83. https://doi.org/10.30939/ijastech. 1360762.
EndNote Özen İ, Aslan M (December 1, 2023) Investigation of Energy Absorbing and Damage Behavior of Gyroid and Diamond Cell Based Lattice Structures Manufactured through Powder Bed Fusion Technology. International Journal of Automotive Science And Technology 7 4 372–383.
IEEE İ. Özen and M. Aslan, “Investigation of Energy Absorbing and Damage Behavior of Gyroid and Diamond Cell Based Lattice Structures Manufactured through Powder Bed Fusion Technology”, IJASTECH, vol. 7, no. 4, pp. 372–383, 2023, doi: 10.30939/ijastech..1360762.
ISNAD Özen, İsmail - Aslan, Mustafa. “Investigation of Energy Absorbing and Damage Behavior of Gyroid and Diamond Cell Based Lattice Structures Manufactured through Powder Bed Fusion Technology”. International Journal of Automotive Science And Technology 7/4 (December 2023), 372-383. https://doi.org/10.30939/ijastech. 1360762.
JAMA Özen İ, Aslan M. Investigation of Energy Absorbing and Damage Behavior of Gyroid and Diamond Cell Based Lattice Structures Manufactured through Powder Bed Fusion Technology. IJASTECH. 2023;7:372–383.
MLA Özen, İsmail and Mustafa Aslan. “Investigation of Energy Absorbing and Damage Behavior of Gyroid and Diamond Cell Based Lattice Structures Manufactured through Powder Bed Fusion Technology”. International Journal of Automotive Science And Technology, vol. 7, no. 4, 2023, pp. 372-83, doi:10.30939/ijastech. 1360762.
Vancouver Özen İ, Aslan M. Investigation of Energy Absorbing and Damage Behavior of Gyroid and Diamond Cell Based Lattice Structures Manufactured through Powder Bed Fusion Technology. IJASTECH. 2023;7(4):372-83.


International Journal of Automotive Science and Technology (IJASTECH) is published by Society of Automotive Engineers Turkey

by.png