Novel energy-absorbing auxetic sandwich panel with detached corrugated aluminium layers

Al-Rifaie, Hasan

doi:10.21008/j.0860-6897.2023.2.15

Artykuł - szczegóły

Tytuł artykułu

Novel energy-absorbing auxetic sandwich panel with detached corrugated aluminium layers

Autorzy

Al-Rifaie Hasan

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.21008/j.0860-6897.2023.2.15

Warianty tytułu

Języki publikacji

Abstrakty

Sandwich panels have the potential to serve as plastically deforming sacrificial structures that can absorb blast or impact energies. Auxetic sandwich panels with welded or bolted corrugated layers have, as far as the author is aware, had their blast behaviour thoroughly addressed in the literature. Therefore, the objective of this numerical analysis was to create a novel, low-cost, simple-to-build graded sandwich panel with detached corrugated layers that may be employed as a multi-purpose sacrificial protective structure against a wide range of blast threats. The suggested sandwich panel has overall dimensions of 330x330x150mm and is made of six detached aluminium (AL6063-T4) layers enclosed in a steel (Weldox 460E) frame. With different stepwise plate thicknesses of 0.4, 0.8, and 1.2mm for each pair of layers, the six layers all have the same re-entrant auxetic geometry. Utilising the Abaqus/Explicit solver, the numerical analysis was carried out. A wide variety of blast intensities (4, 7, 11, 13, and 16 MPa peak reflected over-pressures) were tested on the suggested auxetic sandwich panel, and the results showed uniform progressive collapse, a superior decrease in reaction forces, and greater energy dissipation compared to comparable non-auxetic topologies. The innovative sandwich panel design has potential uses for both military and civic structures that need to be protected.

Słowa kluczowe

energy absorbers auxetic sandwich panels damping systems blast impact shock Abaqus

absorber energii auksetyk płyty warstwowe systemy tłumienia wybuch uderzenie wstrząs Abaqus

Wydawca

Poznan University of Technology. Institute of Applied Mechanics

Czasopismo

Vibrations in Physical Systems

Rocznik

2023

Tom

Vol. 34, nr 2

Strony

art. no. 2023215

Opis fizyczny

Bibliogr. 63 poz., il. kolor., rys., wykr.

Twórcy

autor

Al-Rifaie Hasan

hasan.al-rifaie@put.poznan.pl

Poznan University of Technology, Poznan, Poland

https://orcid.org/0000-0002-2984-1247

Bibliografia

1. H. Draganić, G. Gazić, D. Varevac; Experimental investigation of design and retrofit methods for blast load mitigation-A state-of-the-art review; Engineering Structures, 2019, 190, 189-209
2. P. Sielicki, T. Łodygowski, H. Al-Rifaie, W. Sumelka; Designing of Blast Resistant Lightweight Elevation System-Numerical Study; Procedia Engineering, 2017, 172, 991-998
3. S. A. Mazek; Performance of sandwich structure strengthened by pyramid cover under blast effect; Structural Engineering and Mechanics, 2014, 50, 471-486
4. S. Lotfi, S. M. Zahrai; Blast behavior of steel infill panels with various thickness and stiffener arrangement; Structural Engineering and Mechanics, 2018, 65, 587-600
5. H. Al-Rifaie, W. Sumelka; Numerical analysis of reaction forces in blast resistant gates; Structural Engineering and Mechanics, 2017, 63, 347-359
6. R. Alberdi, J. Przywara, K. Khandelwal; Performance evaluation of sandwich panel systems for blast mitigation; Engineering Structures, 2013, 56, 2119-2130
7. H. Al-Rifaie; Application of Passive Damping Systems in Blast Resistant Gates; I ed. Poznan, Poland: Wydawnictwo Politechniki Poznańskiej, 2019
8. H. Al-Rifaie, W. Sumelka; The developement of a new shock absorbing Uniaxial Graded Auxetic Damper (UGAD); Materials, 2019, 12, 2573
9. N. Novak, M. Vesenjak, Z. Ren; Auxetic cellular materials-a review; Strojniški vestnik-Journal of Mechanical Engineering, 2016, 62, 485-493
10. N. Novak, L. Starčevič, M. Vesenjak, Z. Ren; Blast response study of the sandwich composite panels with 3D chiral auxetic core; Composite Structures, 2019, 210, 167-178
11. P. Baranowski, J. Malachowski, L. Mazurkiewicz; Numerical and experimental testing of vehicle tyre under impulse loading conditions; International Journal of Mechanical Sciences, 2016, 106, 346-356
12. Z. Nowak, M. Nowak, R. Pecherski, M. Potoczek, R. Sliwa; Numerical simulations of mechanical properties of alumina foams based on computed tomography; Coupled Field Problems and Multiphase Materials, 2017, 107
13. E. Andrews, W. Sanders, L. J. Gibson; Compressive and tensile behaviour of aluminum foams; Materials Science and Engineering: A, 1999, 270, 113-124
14. R. B. Pecherski, M. Nowak, Z. Nowak; Virtual metallic foams. Application for dynamic crushing analysis; International Journal for Multiscale Computational Engineering, 2017, 15(5), 431-442
15. D. Papadopoulos, I. C. Konstantinidis, N. Papanastasiou, S. Skolianos, H. Lefakis, D. Tsipas; Mechanical properties of Al metal foams; Materials letters, 2004, 58, 2574-2578
16. L. Peroni, M. Avalle, M. Peroni; The mechanical behaviour of aluminium foam structures in different loading conditions; International Journal of Impact Engineering, 2008, 35, 644-658
17. L. J. Gibson, M. F. Ashby; Cellular solids: structure and properties: Cambridge University Press, 1999
18. K. P. Dharmasena, H. N. Wadley, Z. Xue, J. W. Hutchinson; Mechanical response of metallic honeycomb sandwich panel structures to high-intensity dynamic loading; International Journal of Impact Engineering, 2008, 35, 1063-1074
19. X. Li, P. Zhang, Z. Wang, G. Wu, L. Zhao; Dynamic behavior of aluminum honeycomb sandwich panels under air blast: Experiment and numerical analysis; Composite Structures, 2014, 108, 1001-1008
20. H. Rathbun, D. Radford, Z. Xue, M. He, J. Yang, V. Deshpande, et al.; Performance of metallic honeycomb-core sandwich beams under shock loading; International journal of solids and structures, 2006, 43, 1746-1763
21. L. Hu, T. Yu; Dynamic crushing strength of hexagonal honeycombs; International Journal of Impact Engineering, 2010, 37, 467-474
22. D. Okumura, N. Ohno, H. Noguchi; Post-buckling analysis of elastic honeycombs subject to in-plane biaxial compression; International Journal of Solids and Structures, 2002, 39, 3487-3503
23. Z. Zou, S. Reid, P. Tan, S. Li, J. Harrigan; Dynamic crushing of honeycombs and features of shock fronts; International Journal of Impact Engineering, 2009, 36, 165-176
24. D. Ruan, G. Lu, B. Wang, T. X. Yu; In-plane dynamic crushing of honeycombs - a finite element study; International Journal of Impact Engineering, 2003, 28, 161-182
25. H. AL-RIFAIE, W. Sumelka; Auxetic Damping Systems for Blast Vulnerable Structures; in Handbook of Damage Mechanics, G. Z. Voyiadjis, Ed., II ed: Springer, 2020, 25
26. S. Xu, J. H. Beynon, D. Ruan, G. Lu; Experimental study of the out-of-plane dynamic compression of hexagonal honeycombs; Composite Structures, 2012, 94, 2326-2336
27. A. A. Nia, M. Sadeghi; The effects of foam filling on compressive response of hexagonal cell aluminum honeycombs under axial loading-experimental study; Materials & Design, 2010, 31, 1216-1230
28. P. Zhang, J. Liu, Y. Cheng, H. Hou, C. Wang, Y. Li; Dynamic response of metallic trapezoidal corrugated-core sandwich panels subjected to air blast loading-An experimental study; Materials & Design (1980-2015), 2015, 65, 221-230
29. C. J. Wiernicki, F. Liem, G. D. Woods, A. J. Furio; Structural analysis methods for lightweight metallic corrugated core sandwich panels subjected to blast loads; Naval Engineers Journal, 1991, 103, 192-202
30. R. Studziński, T. Gajewski, M. Malendowski, W. Sumelka, H. Al-Rifaie, P. Peksa, et al.; Blast test and failure mechanisms of soft-core sandwich panels for storage halls applications; Materials, 2021, 12, 70
31. H. Al-Rifaie, P. Wożniak, T. Łodygowski; Improving the blast resistance of steel columns using trapezoidal sandwich panels; in Science for Defence: Safety for Critical Infrastructure, 1 ed Warsaw: Wydawnictwo Instytutu Technicznego Wojsk Lotniczych, 2022, 33-54
32. H. Al-Rifaie, R. Studziński, T. Gajewski, M. Malendowski, P. Peksa, W. Sumelka, et al.; Full scale field testing of trapezoidal core sandwich panels subjected to adjacent and contact detonations; in Modern Trends in Research on Steel, Aluminium and Composite Structures, ed: Routledge, 2021, 393-399
33. R. Studziński, Z. Pozorski; Experimental and numerical analysis of sandwich panels with hybrid core; Journal of Sandwich Structures & Materials, 2018, 20, 271-286
34. Y. Rong, J. Liu, W. Luo, W. He; Effects of geometric configurations of corrugated cores on the local impact and planar compression of sandwich panels; Composites Part B: Engineering, 2018, 152, 324-335
35. H. Al-Rifaie, R. Studziński, T. Gajewski, M. Malendowski, W. Sumelka, P. W. Sielicki; A new blast absorbing sandwich panel with unconnected corrugated layers - numerical study; Energies, 2021, 14(1), 214
36. X. Hou, Z. Deng, K. Zhang; Dynamic Crushing Strength Analysis of Auxetic Honeycombs; Acta Mechanica Solida Sinica, 2016, 29, 490-501
37. G. Imbalzano, S. Linforth, T. D. Ngo, P. V. S. Lee, P. Tran; Blast resistance of auxetic and honeycomb sandwich panels: Comparisons and parametric designs; Composite Structures, 2018, 183, 242-261
38. H. Al-Rifaie, N. Novak, M. Vesenjak, Z. Ren, W. Sumelka; Fabrication and Mechanical Testing of the Uniaxial Graded Auxetic Damper; Materials, 2022, 15, 387
39. N. Novak, H. Al-Rifaie, A. Airoldi, L. Krstulović-Opara, T. Łodygowski, Z. Ren, et al.; Quasi-static and impact behaviour of foam-filled graded auxetic panel; International Journal of Impact Engineering, 2023, 104606
40. H. Al-Rifaie, W. Sumelka; Improving the Blast Resistance of Large Steel Gates-Numerical Study; Materials, 2020, 13, 2121
41. A. Yeganeh-Haeri, D. J. Weidner, J. B. Parise; Elasticity of or-cristobalitez A silicon dioxide with a negative Poisson’s ratio; Science, 1992, 257, 31
42. X. Y. Zhang, X. Ren, Y. Zhang, Y. M. Xie; A novel auxetic metamaterial with enhanced mechanical properties and tunable auxeticity; Thin-Walled Structures, 2022, 174, 109162
43. M. Zhang, H. Hu, H. Kamrul, S. Zhao, Y. Chang, M. Ho, et al.; Three-dimensional composites with nearly isotropic negative Poisson's ratio by random inclusions: Experiments and finite element simulation; Composites Science and Technology, 2022, 218, 109195
44. H. Al-Rifaie, W. Sumelka; Tłumik jednoosiowy dla układów bezpieczeństwa bram, drzwi lub okien (in Polish); Uniaxial damper as a safety system for gates, doors or windows. Patent, 2021,
45. J. Michalski, T. Strek; Blast resistance of sandwich plate with auxetic anti-tetrachiral core; Vibrations in Physical Systems, 2020, 31, 2020317
46. A. Mrozek, T. Strek; Numerical analysis of dynamic properties of an auxetic structure with rotating squares with holes; Materials, 2022, 15, 8712
47. J. Michalski, T. Strek; Response of a sandwich plate with auxetic anti-tetrachiral core to puncture; In: Advances in Manufacturing III. MANUFACTURING 2022. Lecture Notes in Mechanical Engineering; B. Gapiński, O. Ciszak, V. Ivanov (eds), Springer, Cham, 2022, 1-14.
48. T. Strek, J. Michalski, H. Jopek; Computational analysis of the mechanical impedance of the sandwich beam with auxetic metal foam core; Physica Status Solidi (b), 2019, 256, 1800423
49. A. Alderson; A triumph of lateral thought; Chemistry & Industry, 1999, 17, 384-391
50. W. Yang, Z.-M. Li, W. Shi, B.-H. Xie, M.-B. Yang; Review on auxetic materials; Journal of Materials Science, 2004, 39, 3269-3279
51. G. N. Greaves; Poisson's ratio over two centuries: challenging hypotheses; Notes Rec. R. Soc., 2013, 67, 37-58
52. Y. Liu, H. Hu; A review on auxetic structures and polymeric materials; Scientific Research and Essays, 2010, 5, 1052-1063
53. Y. Prawoto; Seeing auxetic materials from the mechanics point of view: a structural review on the negative Poisson’s ratio; Computational Materials Science, 2012, 58, 140-153
54. H. Al-Rifaie, R. Studziński, W. Sumelka; A New Shock Absorbing Sandwich Panel with Unconnected Trapezoidal Corrugated Layers;presented at the Seventh International Symposium On Explosion, Shock Wave And High-strain-rate Phenomena, Maribor, Slovenia, 2023
55. S. E. Rigby, S. D. Fay, A. Tyas, J. A. Warren, S. D. Clarke; Angle of incidence effects on far-field positive and negative phase blast parameters; International Journal of Protective Structures, 2015, 6, 23-42
56. M. Chipley, W. Lyon, R. Smilowitz, P. Williams, C. Arnold, W. Blewett, et al.; Primer to Design Safe School Projects in Case of Terrorist Attacks and School Shootings. Buildings and Infrastructure Protection Series. FEMA-428/BIPS-07/January 2012. Edition 2; US Department of Homeland Security, 2012
57. G. R. Johnson, W. H. Cook; A constitutive model and data for metals subjected to large strains, high strain rates and high temperatures; in Proceedings of the 7th International Symposium on Ballistics, 1983, 541-547
58. G. R. Johnson, W. H. Cook; Fracture characteristics of three metals subjected to various strains, strain rates, temperatures and pressures; Engineering fracture mechanics, 1985, 21, 31-48
59. M. Grazka, J. Janiszewski; Identification of Johnson-Cook Equation Constants using Finite Element Method; Engineering Transactions, 2012, 60, 215-223
60. A. Shrot, M. Bäker; Determination of Johnson-Cook parameters from machining simulations; Computational Materials Science, 2012, 52, 298-304
61. T. Børvik, O. Hopperstad, T. Berstad, M. Langseth; A computational model of viscoplasticity and ductile damage for impact and penetration; European Journal of Mechanics-A/Solids, 2001, 20, 685-712
62. ASM Specification Aerospace Metals. Aluminum 6063-T4; Available: http://asm.matweb.com
63. S. Hou, C. Shu, S. Zhao, T. Liu, X. Han, Q. Li; Experimental and numerical studies on multi-layered corrugated sandwich panels under crushing loading; Composite Structures, 2015, 126, 371-385

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-1abf503b-c898-4c31-a7b5-23cc9f81f4ae