Investigation of out-of-plane compression mechanical property for novel hierarchical reentrant honeycomb structures

• Autorzy: Wu Dongquan , Xu Zhenyi , Yuan Zhuo , Li Yupeng , Zhang Zhiqiang

Identyfikatory

DOI

10.15632/jtam-pl/194340

• Języki publikacji: EN

Abstrakty

EN

In this study, three novel types of hierarchical reentrant honeycomb structures were designed, which comprised subunits with a semi-reentrant, reentrant, and hexagonal honeycomb. These subunits exhibited zero/negative/positive Poisson’s ratios, respectively. Geometric relationships of those structures were established. The out of plane compression behavior and deformation characteristics were investigated through finite element simulations and experiments. It was showed that the hierarchical structure composed of reentrant subunits had the best mechanical properties among three structures. The hierarchical structure composed of the classic hexagonal honeycomb subunit exhibited plastic deformation characteristic spreading from the middle and upper layers to the whole region during compression.

Słowa kluczowe

EN

hierarchical reentrant structure; honeycomb structures; out-of-plane; 3D printing; compression performance

• Wydawca: Polskie Towarzystwo Mechaniki Teoretycznej i Stosowanej
• Czasopismo: Journal of Theoretical and Applied Mechanics
• Rocznik: 2025
• Tom: Vol. 63 nr 1
• Strony: 3--12
• Opis fizyczny: Bibliogr. 28 poz., rys., tab.

Twórcy

autor

Wu Dongquan

• Sino-European Institute of Aviation Engineering, Civil Aviation University of China, Tianjin, China

autor

Xu Zhenyi

• Sino-European Institute of Aviation Engineering, Civil Aviation University of China, Tianjin, China

autor

Yuan Zhuo

• Sino-European Institute of Aviation Engineering, Civil Aviation University of China, Tianjin, China

autor

Li Yupeng

• Sino-European Institute of Aviation Engineering, Civil Aviation University of China, Tianjin, China

autor

Zhang Zhiqiang

• Institute of Aviation Engineering, Civil Aviation University of China, Tianjin, China

Bibliografia

• 1. Ahmed N., Xue P., 2019, Governing the in-plane axial crushing of honeycomb with regular hexagonal symmetric division cells using cross-hinge inserts, International Journal of Mechanical Sciences, 161-162, 105062.
• 2. Arbaoui J., Schmitt Y., Pierrot J.-L., Royer F.-X., 2014, Numerical simulation and experimental bending behaviour of multi-layer sandwich structures, Journal of Theoretical and Applied Mechanics, 52, 2, 431-442 .
• 3. Bouazza M., Becheri T., Boucheta A., Benseddiq N., 2019, Bending behavior of laminated composite plates using the refined four-variable theory and the finite element method, Earthquakes and Structures, 17, 3, 257-270.
• 4. Davalos J.F., Qiao P., Xu X.F., Robinson J., Barth K.E., 2001, Modeling and characterization of fiber-reinforced plastic honeycomb sandwich panels for highway bridge applications, Composite Structures, 52, 3-4, 441-452.
• 5. Farrokhabadi A., Ashrafian M.M., Behravesh A.H., Hedayati S.K. 2022, Assessment of fiber-reinforcement and foam-filling in the directional energy absorption performance of a 3D printed accordion cellular structure, Composite Structures, 297, 115945.
• 6. Gadkaree K.P., 1998, Carbon honeycomb structures for adsorption applications, Carbon, 36, 7-8, 981-989.
• 7. Gao W., Zhang W., Yu H., Xing W., Yang X., et al., 2022, 3D CNT/MXene microspheres for combined photothermal/photodynamic/chemo for cancer treatment, Frontiers in Bioengineering and Biotechnology, 10, 996177.
• 8. Garg A., Belarbi M.O., Chalak H.D., Li L., Sharma A., et al., 2023, Buckling and free vibration analysis of bio-inspired laminated sandwich plates with helicoidal/Bouligand face sheets containing softcore, Ocean Engineering, 270, 113684.
• 9. Gong X., Ren C., Sun J., et al., 2022, 3D zero Poisson’s ratio honeycomb structure for morphing wing applications, Biomimetics, 7, 4, 198.
• 10. Gunaydın K., Rea C., Kazancı Z. , 2022, Energy absorption enhancement of additively manufactured hexagonal and re-entrant (auxetic) lattice structures by using multi-material reinforcements, Additive Manufacturing, 59, 103076.
• 11. Ha N.S., Pham T.M., Hao H., Lu G., 2021, Energy absorption characteristics of bio-inspired hierarchical multi-cell square tubes under axial crushing, International Journal of Mechanical Sciences, 201, 106464.
• 12. Ha N.S., Pham T.M., Tran T.T., Hao H., Lu G., 2022, Mechanical properties and energy absorption of bio-inspired hierarchical circular honeycomb, Composites Part B: Engineering, 236, 109818.
• 13. Hamzehei R., Zolfagharian A., Dariushi S., Bodaghi M., 2022, 3D-printed bio-inspired zero Poisson’s ratio graded metamaterials with high energy absorption performance, Smart Materials and Structures, 31, 3, 035001.
• 14. Heo H., Ju J., Kim D.M., 2013, Compliant cellular structures: Application to a passive morphing airfoil, Composite Structures, 106, 560-569.
• 15. Ingrole A., Hao A., Liang R., 2017, Design and modeling of auxetic and hybrid honeycomb structures for in-plane property enhancement, Materials and Design, 117, 72-83.
• 16. Lei Z., Sun X., Zhu S., Dong K., Liu X., et al., 2022, Nature inspired MXene-decorated 3D honeycomb-fabric architectures toward efficient water desalination and salt harvesting, Nano-Micro Letters, 14, 1, 10.
• 17. Li Z., Liu D., Qian Y., Wang Y., Wang T., Wang L., 2019, Enhanced strength and weakened dynamic sensitivity of honeycombs by parallel design, International Journal of Mechanical Sciences, 151, 672-683.
• 18. Liang H., Wang Q., Pu Y., Zhao Y., Ma F., 2021, In-plane compressive behavior of a novel self-similar hierarchical honeycomb with design-oriented crashworthiness, International Journal of Mechanical Sciences, 209, 106723.
• 19. Liu J., Chen W., Hao H., Wang Z., 2021, In-plane crushing behaviors of hexagonal honeycombs with different Poisson’s ratio induced by topological diversity, Thin-Walled Structures, 159, 107223.
• 20. Liu L., Wang H., Guan Z., 2015, Experimental and numerical study on the mechanical response of Nomex honeycomb core under transverse loading, Composite Structures, 121, 304-314.
• 21. Masuda H., Fukuda K., 1995, Ordered metal nanohole arrays made by a two-step replication of honeycomb structures of anodic alumina, Science, 268, 5216, 1466-1468.
• 22. Shukla S., Behera B.K., 2022, Auxetic fibrous structures and their composites: A review, Composite Structures, 290, 115530.
• 23. Solak A., Așҫioğlu Temiztas, B., Bolat B., 2023, Numerical investigation of the mechanical behavior of the vertical stabilizer leading edge with wavy honeycomb sandwich structure under bird strike, Journal of Sandwich Structures and Materials, 25, 3, 387-400
• 24. Teng X.C., Ren X., Zhang Y., Jiang W., Pan Y., 2022, A simple 3D re-entrant auxetic metamaterial with enhanced energy absorption, International Journal of Mechanical Sciences, 229, 107524.
• 25. Wang Z., Zhou Y., Wang X., Wei K., 2021, Compression behavior of strut-reinforced hierarchical lattice – Experiment and simulation, International Journal of Mechanical Sciences, 210, 106749.
• 26. Wu D., Li D., Zhang Z., Chen J., 2023, Numerical study on compression properties of semi-reentrant filled tubular structures, Journal of Theoretical and Applied Mechanics, 61, 2, 233-244.
• 27. Yang M., Han B., Su P., Zhang Q., Zhang Q.C., et al., 2021, Crashworthiness of hierarchical truncated conical shells with corrugated cores, International Journal of Mechanical Sciences, 193, 106171.
• 28. Zhang X., Zhang H., 2013, Theoretical and numerical investigation on the crush resistance of rhombic and kagome honeycombs, Composite Structures, 96, 143-152.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa nr POPUL/SP/0154/2024/02 w ramach programu "Społeczna odpowiedzialność nauki II" - moduł: Popularyzacja nauki i promocja sportu (2025).