Sage Journals: Discover world-class research

Abstract

Kirigami-inspired honeycomb structures demonstrate outstanding self-expanding capabilities and exceptional mechanical properties. To further enhance the shape recovery properties and load-carrying capacity of kirigami-inspired honeycomb, the hierarchical structure is introduced by importing porous structures into cell walls of 4D-printed kirigami-inspired honeycomb (Structure II), and then an innovative honeycomb structure (Structure I) is designed for achieving the hierarchical effect. Additionally, three hierarchical structures with different shape configurations (Structure III–V) are also designed for comparing with traditional Structure II. The finite element analysis and experiments are conducted to compare the compression deformation behavior and energy absorption capacity of Structure I–V. It is found that Structure I exhibits significantly improved properties compared with the traditional Structure II. The stiffness of Structure I is increased by 50.43%, and the energy absorption performance is also increased by 65.00%. The recovery time has been shortened by 27.27% and it has a better shape recovery rate. Structure III–V can also enhance the performances compared with traditional Structure II. Structure IV exhibits the best energy absorption capacity, with an increase of 76.25%. Thus, the developed hierarchical kirigami-inspired honeycombs have broad application prospects for the multifunctional applications of honeycomb structures in the future.

Keywords

Kirigami-inspired honeycomb hierarchical structure 4D printing compression deformation energy absorption

Get full access to this article

View all access options for this article.

References

Zhang

You

Large deformation and energy absorption of additively manufactured auxetic materials and structures: a review. Compos B Eng 2020; 201: 108340.

Jiang

Yang

Advanced honeycomb designs for improving mechanical properties: a review. Compos B Eng 2021; 227: 109393.

Xue

Liu

, et al. Advances in multiple assembly acoustic structural design strategies for honeycomb composites: a review. Mater Today Commun 2024; 38: 108013.

Shirvani

SMN

Gholami

Afrasiab

, et al. Optimal design of a composite sandwich panel with a hexagonal honeycomb core for aerospace applications. Iran J Sci Technol Trans Mech Eng 2023; 47(2): 557–568.

Fan

, et al. Compression performance and failure mechanism of honeycomb structures fabricated with reinforced wood. Structures 2023; 48: 1868–1882.

Cascino

Meli

Rindi

A strategy for lightweight designing of a railway vehicle car body including composite material and dynamic structural optimization. Railw Eng Sci 2023; 31(4): 340–350.

Crupi

Epasto

Guglielmino

Comparison of aluminium sandwiches for lightweight ship structures: honeycomb vs. foam. Mar Struct 2013; 30: 74–96.

Wang

Shi

Yang

, et al. Strength, stiffness, and panel peeling strength of carbon fiber-reinforced composite sandwich structures with aluminum honeycomb cores for vehicle body. Compos Struct 2018; 184: 1189–1196.

Boudjemai

Amri

Mankour

, et al. Modal analysis and testing of hexagonal honeycomb plates used for satellite structural design. Mater Des 2012; 35: 266–275.

10.

Baek

Lee

Kim

, et al. A study on the microwave absorbing honeycomb core embedded with conductive periodic patterned surfaces for the effective dielectric constant. Compos Struct 2022; 289: 115471.

11.

Xiao

Feng

Fan

, et al. 3D printing of titanium-coated gradient composite lattices for lightweight mandibular prosthesis. Compos B Eng 2020; 193: 108057.

12.

, et al. Recent advances in space-deployable structures in China. Engineering 2022; 17: 207–219.

13.

Wang

, et al. Customized deformation behavior of morphing wing through reversibly assembled multi-stable metamaterials. Smart Mater Struct 2024; 33(4): 045015.

14.

Alshebly

Nafea

Ali

, et al. Review on recent advances in 4D printing of shape memory polymers. Eur Polym J 2021; 159: 110708.

15.

Zhou

Ren

Song

, et al. Advances in 3D/4D printing of mechanical metamaterials: from manufacturing to applications. Compos B Eng 2023; 254: 110585.

16.

Xin

Lin

, et al. Compressive properties and energy absorption of 4D printed auxetic mechanical metamaterials. Compos Struct 2024; 340: 118135.

17.

Sun

Shi

, et al. 4D printing of temperature-responsive composites with programmable thermochromic deformation bifunctional. Sens Actuators A Phys 2024; 368: 115138.

18.

Lin

Xin

Tian

, et al. Thermal-, magnetic-, and light-responsive 4D printed SMP composites with multiple shape memory effects and their promising applications. Compos B Eng 2024; 274: 111257.

19.

Wang

, et al. Soft magnetic composites for highly deformable actuators by four-dimensional electrohydrodynamic printing. Compos B Eng 2022; 231: 109596.

20.

Schäfer

Lutzi

Khan

, et al. Magneto-active composites with locally tailored stiffness produced by laser powder bed fusion. Addit Manuf 2024; 79: 103905.

21.

Morales Ferrer

Sánchez Cruz

Caplan

, et al. Multiscale heterogeneous polymer composites for high stiffness 4D printed electrically controllable multifunctional structures. Adv Mater 2024; 36(8): 2307858.

22.

Tang

Xiang

Tian

, et al. Machine learning-based morphological and mechanical prediction of kirigami-inspired active composites. Int J Mech Sci 2024; 266: 108956.

23.

Zhang

Paik

Kirigami design and modeling for strong, lightweight metamaterials. Adv Funct Mater 2022; 32(21): 2107401.

24.

Tao

Khosravi

Deshpande

, et al. Engineering by cuts: how kirigami principle enables unique mechanical properties and functionalities. Adv Sci 2023; 10(1): 2204733.

25.

Zeng

Chen

Koz

, et al. Kirigami-inspired organic and inorganic film-based flexible thermoelectric devices with built-in heat sink. Nano Energy 2024; 121: 109213.

26.

Huang

, et al. Cushioning performance design of meta-sandwich structures inspired by Kirigami. Virtual Phys Prototyp 2023; 18(1): e2285894.

27.

Neville

Scarpa

Pirrera

Shape morphing Kirigami mechanical metamaterials. Sci Rep 2016; 6: 31067.

28.

Zhai

Jiang

Mechanical metamaterials based on origami and kirigami. Appl Phys Rev 2021; 8(4): 041319.

29.

Zhang

Yan

Nan

, et al. A mechanically driven form of Kirigami as a route to 3D mesostructures in micro/nanomembranes. Proc Natl Acad Sci 2015; 112(38): 11757–11764.

30.

Wang

Zhang

, et al. Kirigami-inspired thick-panel deployable structures. Int J Solids Struct 2022; 251: 111752.

31.

Neville

Chen

Guo

, et al. A Kirigami shape memory polymer honeycomb concept for deployment. Smart Mater Struct 2017; 26(5): 05lt03.

32.

Kernin

Ventura

Soul

, et al. Kirigami inspired shape programmable and reconfigurable multifunctional nanocomposites for 3D structures. Mater Des 2022; 224: 111335.

33.

Qiu

Feng

Hong

, et al. Lightweight multi-layer graded pyramid folded structure based on tucked kirigami for green manufacturing. Compos Sci Technol 2024; 246: 110383.

34.

Dai

Chai

, et al. Energy absorption of sandwich structures with a kirigami-inspired pyramid foldcore under quasi-static compression and shear. Mater Des 2021; 206: 109808.

35.

Yue

Zhao

, et al. Shape recovery properties and load-carrying capacity of a 4D printed thick-walled kirigami-inspired honeycomb structure. Biodes Manuf 2023; 6: 189–203.

36.

Ruan

Zhang

Dou

, et al. Experiments and design of a kirigami-based multi-stage energy absorption structure subjected to axial impact. Thin Wall Struct 2024; 200: 111920.

37.

Zheng

Chen

Yang

, et al. Kirigami reconfigurable gradient metasurface. Adv Funct Mater 2021; 32(5): 2107699.

38.

Jin

Yang

Engineering kirigami frameworks toward real-world applications. Adv Mater 2024; 36(9): e2308560.

39.

Zheng

Chen

Feng

A review of kirigami/origami metasurfaces for controlling electromagnetic waves. Annalen der Physik 2024; 536(12): 2400213.

40.

Korupolu

Budarapu

Vusa

, et al. Impact analysis of hierarchical honeycomb core sandwich structures. Compos Struct 2022; 280: 114827.

41.

Wang

Zhang

, et al. In-plane crushing behaviour of hierarchical honeycombs: finite element simulation and analytical modelling. Acta Mech Sin 2023; 39(11): 423067.

42.

Song

Zhang

, et al. Bio-inspired hierarchical honeycomb metastructures with superior mechanical properties. Compos Struct 2023; 304: 116452.

43.

Zhao

Wang

, et al. Mechanical performance of bio-inspired hierarchical honeycomb metamaterials. Int J Solids Struct 2022; 254–255: 111866.

44.

Peng

Han

Liu

, et al. Effect of manufacturing process parameters on the compression and energy absorption properties of 4D-printed deformable honeycomb structure. Smart Mater Struct 2024; 33(7): 075035.

45.

Saito

Pellegrino

Nojima

Manufacture of arbitrary cross-section composite honeycomb cores based on origami techniques. J Mech Des 2014; 136(5): 051011.

46.

Peng

Liu

Wang

, et al. Controllable deformation design for 4D-printed active composite structure: optimization, simulation, and experimental verification. Compos Sci Technol 2023; 243: 110265.

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

Effect of hierarchical structure on the shape recovery properties and load-carrying capacity of 4D-printed kirigami-inspired honeycomb

Abstract

Keywords

Get full access to this article

References

Supplementary Material