Frontiers of Mechanical Engineering >

2020 , Vol. 15 >Issue 2: 319 - 327

DOI: https://doi.org/10.1007/s11465-019-0549-7

RESEARCH ARTICLE

Compressive behavior and energy absorption of polymeric lattice structures made by additive manufacturing

  • Sheng WANG 1 ,
  • Jun WANG , 1,2 ,
  • Yingjie XU , 1,3 ,
  • Weihong ZHANG 1 ,
  • Jihong ZHU 1
Expand
  • 1. State IJR Center of Aerospace Design and Additive Manufacturing, Northwestern Polytechnical University, Xi’an 710072, China
  • 2. Intelligent Materials and Structures, Unmanned System Research Institute, Northwestern Polytechnical University, Xi’an 710072, China
  • 3. Shaanxi Engineering Laboratory of Aerospace Structure Design and Application, Northwestern Polytechnical University, Xi’an 710072, China

Received date: 22 Apr 2019

Accepted date: 05 Jun 2019

Published date: 15 Jun 2020

Copyright

2020 Higher Education Press
Fold

Abstract

Lattice structures have numerous outstanding characteristics, such as light weight, high strength, excellent shock resistance, and highly efficient heat dissipation. In this work, by combining experimental and numerical methods, we investigate the compressive behavior and energy absorption of lattices made through the stereolithography apparatus process. Four types of lattice structures are considered: (i) Uniform body-centered-cubic (U-BCC); (ii) graded body-centered-cubic (G-BCC); (iii) uniform body-centered-cubic with z-axis reinforcement (U-BCCz); and (iv) graded body-centered-cubic with z-axis reinforcement (G-BCCz). We conduct compressive tests on these four lattices and numerically simulate the compression process through the finite element method. Analysis results show that BCCz has higher modulus and strength than BCC. In addition, uniform lattices show better energy absorption capabilities at small compression distances, while graded lattices absorb more energy at large compression distances. The good correlation between the simulation results and the experimental phenomena demonstrates the validity and accuracy of the present investigation method.

Key words: lattice structure; polymer; compressive behavior; additive manufacturing; simulation

Cite this article

Sheng WANG , Jun WANG , Yingjie XU , Weihong ZHANG , Jihong ZHU . Compressive behavior and energy absorption of polymeric lattice structures made by additive manufacturing[J]. Frontiers of Mechanical Engineering, 2020 , 15(2) : 319 -327 . DOI: 10.1007/s11465-019-0549-7

Acknowledgements

This work was supported by the National Key Research and Development Program of China (Grant No. 2017YFB1102800) and the National Natural Science Foundation of China (Grant Nos. 11872310 and 5171101743).

References

Publishing order | Descend order by publishing year | Descend order by cited within
1
Gibson L J, Ashby M F. Cellular Solids: Structure and Properties. 2nd ed. Cambridge: Cambridge University Press, 1999

2
Evans A G, Hutchinson J W, Fleck N A, . The topological design of multifunctional cellular metals. Progress in Materials Science, 2001, 46(3‒4): 309–327

DOI

3
Xue Z, Hutchinson J W. A comparative study of impulse-resistant metal sandwich plates. International Journal of Impact Engineering, 2004, 30(10): 1283–1305

DOI

4
Kim T, Hodson H P, Lu T J. Fluid-flow and endwall heat-transfer characteristics of an ultralight lattice-frame material. International Journal of Heat and Mass Transfer, 2004, 47(6‒7): 1129–1140 doi:10.1016/j.ijheatmasstransfer.2003.10.012

5
Wang J, Lu T J, Woodhouse J, . Sound transmission through lightweight double-leaf partitions: Theoretical modelling. Journal of Sound and Vibration, 2005, 286(4‒5): 817–847

DOI

6
Liu T, Deng Z C, Lu T J. Bi-functional optimization of actively cooled, pressurized hollow sandwich cylinders with prismatic cores. Journal of the Mechanics and Physics of Solids, 2007, 55(12): 2565–2602

DOI

7
Wang Y, Xu H, Pasini D. Multiscale isogeometric topology optimization for lattice materials. Computational Methods in Applied Mathematics and Engineering, 2017, 316: 568–585

DOI

8
Wang Y, Arabnejad S, Tanzer M, . Hip implant design with three-dimensional porous architecture of optimized graded density. Journal of Mechanical Design, 2018, 140(11): 111406 doi:10.1115/1.4041208

9
Wu Z, Xia L, Wang S, . Topology optimization of hierarchical lattice structures with substructuring. Computational Methods in Applied Mathematics and Engineering, 2019, 345: 602–617

DOI

10
Da D, Yvonnet J, Xia L, . Topology optimization of periodic lattice structures taking into account strain gradient. Computers & Structures, 2018, 210: 28–40 doi:10.1016/j.compstruc.2018.09.003

11
Wang Z P, Poh L H, Dirrenberger J, . Isogeometric shape optimization of smoothed petal auxetic structures via computational periodic homogenization. Computational Methods in Applied Mathematics and Engineering, 2017, 323: 250–271

DOI

12
Wang Z P, Poh L H, Zhu Y, . Systematic design of tetra-petals auxetic structures with stiffness constraint. Materials & Design, 2019, 170: 107669 doi:10.1016/j.matdes.2019.107669

13
Helou M, Kara S. Design, analysis and manufacturing of lattice structures: An overview. International Journal of Computer Integrated Manufacturing, 2018, 31(3): 243–261

DOI

14
Hou Y, Tie Y, Li C, . Low-velocity impact behaviors of repaired CFRP laminates: Effect of impact location and external patch configurations. Composites. Part B, Engineering, 2019, 163: 669–680

DOI

15
Deshpande V S, Fleck N A, Ashby M F. Effective properties of the octet-truss lattice material. Journal of the Mechanics and Physics of Solids, 2001, 49(8): 1747–1769

DOI

16
Rathbun H J, Wei Z, He M Y, . Measurement and simulation of the performance of a lightweight metallic sandwich structure with a tetrahedral truss core. Journal of Applied Mechanics, 2004, 71(3): 368–374

DOI

17
Zok F W, Waltner S A, Wei Z, . A protocol for characterizing the structural performance of metallic sandwich panels: Application to pyramidal truss cores. International Journal of Solids and Structures, 2004, 41(22‒23): 6249–6271

DOI

18
Wang J, Evans A G, Dharmasena K, . On the performance of truss panels with Kagome cores. International Journal of Solids and Structures, 2003, 40(25): 6981–6988

DOI

19
Moongkhamklang P, Elzey D M, Wadley H N. Titanium matrix composite lattice structures. Composites. Part A: Applied Science and Manufacturing, 2008, 39(2): 176–187 doi:10.1016/j.compositesa.2007.11.007

20
Luxner M H, Stampfl J, Pettermann H E. Finite element modeling concepts and linear analyses of 3D regular open cell structures. Journal of Materials Science, 2005, 40(22): 5859–5866

DOI

21
Roberts A P, Garboczi E J. Elastic properties of model random three-dimensional open-cell solids. Journal of the Mechanics and Physics of Solids, 2002, 50(1): 33–55

DOI

22
Brennan-Craddock J, Brackett D, Wildman R, . The design of impact absorbing structures for additive manufacture. Journal of Physics: Conference Series, 2012, 382(1): 012042

DOI

23
Gümrük R, Mines R A. Compressive behavior of stainless steel micro-lattice structures. International Journal of Mechanical Sciences, 2013, 68: 125–139

DOI

24
Mines R A, Tsopanos S, Shen Y, . Drop weight impact behavior of sandwich panels with metallic micro lattice cores. International Journal of Impact Engineering, 2013, 60: 120–132

DOI

25
Smith M, Guan Z, Cantwell W J. Finite element modelling of the compressive response of lattice structures manufactured using the selective laser melting technique. International Journal of Mechanical Sciences, 2013, 67: 28–41

DOI

26
Shen Y, Cantwell W, Mines R, . Low-velocity impact performance of lattice structure core based sandwich panels. Journal of Composite Materials, 2014, 48(25): 3153–3167

DOI

27
Gümrük R, Mines R A, Karadeniz S. Static mechanical behaviours of stainless steel micro-lattice structures under different loading conditions. Materials Science and Engineering A, 2013, 586: 392–406

DOI

28
Vrána R, Koutny D, Paloušek D, . Impact resistance of lattice structure made by selective laser melting technology. Modern Machinery (MM) Science Journal, 2015, 852–855

DOI

29
McMillan M L, Jurg M, Leary M, . Programmatic generation of computationally efficient lattice structures for additive manufacture. Rapid Prototyping Journal, 2017, 23(3): 486–494

DOI

30
Meng L, Zhang W, Quan D, . From topology optimization design to additive manufacturing: Today’s success and tomorrow’s roadmap. Archives of Computational Methods in Engineering, 2019 (in press)

DOI

31
International Organization for Standardization. DIN EN ISO 604:2002, Plastics—Determination of Compressive Properties. 2002

Options
Outlines

/