Mechanical response of galvanised steel sandwich structure with different numbers of web core and different spacing distance of web plate under bending load

Authors

  • N.K. Romli Faculty of Mechanical and Automotive Engineering Technology, Universiti Malaysia Pahang, 26600 Pekan, Pahang Malaysia. Phone: +6094246324
  • M.R.M. Rejab Faculty of Mechanical and Automotive Engineering Technology, Universiti Malaysia Pahang, 26600 Pekan, Pahang Malaysia. Phone: +6094246324
  • X.X. Jiang School of Mechanical Engineering, Ningxia University, 750021 Yinchuan, China
  • S.M. Soffie Faculty of Mechanical and Automotive Engineering Technology, Universiti Malaysia Pahang, 26600 Pekan, Pahang Malaysia. Phone: +6094246324
  • M. Ishak Faculty of Mechanical and Automotive Engineering Technology, Universiti Malaysia Pahang, 26600 Pekan, Pahang Malaysia. Phone: +6094246324

DOI:

https://doi.org/10.15282/jmes.16.4.2022.10.0734

Keywords:

Sandwich structure, Three-point bending, Number of core, Spacing distance, Laser welding

Abstract

Sandwich structures are widely used in a variety of industrial applications due to their ability to provide high bending stiffness while remaining lightweight. The deformation of this structure and its relation to the stiffness of the galvanized steel is investigated. A series of three-point bending response and subsequent failure modes in web-core laser-welded sandwich structure based on galvanised steel is also investigated. The web-core sandwich structure was manufactured using fibre laser welding technique to joint face and web plates perpendicularly to produce a range of lightweight sandwich structure. The role of the number of cores and spacing distance were purposed to determine the overall deformation of global deflection behaviour of the sandwich structure. The results were compared, and it is showed that the acted load produced bending on faceplate and caused debonding at weld joint (between faceplate and web plate). The continued bending was also caused debonding between PVC foam and adjacent plate. Subsequently, load-displacement trace was used as evidence of the comparison, where seven cores with 20 mm spacing distance exhibited higher force, approximately 1.091 kN. The three-point bending test results indicated that the higher number of cores possessed better performance in bending strength. The effect of the spacing distance of web plates in sandwich structure was also examined. In five cores specimen, it is showed that as the spacing distance decreased, the bending strength increased, where bending stiffness value of 18 mm (0.313 kN/mm) is higher than 19 mm (0.288 kN/mm) and 20 mm (0.281 kN/mm). The effectiveness of the sandwich structure depended on the optimal design as to achieve lightweight and its bending strength.

References

J. Bühring, M. Nuño, and K.U. Schröder, "Additive manufactured sandwich structures: Mechanical characterization and usage potential in small aircraft," Aerospace Science and Technology, vol. 111, p. 106548, 2021.

J. Vinson, "The behavior of sandwich structures of isotropic and composite materials," Routledge, New York, 1999.

A. Cernescu and J. Romanoff, "Bending deflection of sandwich beams considering local effect of concentrated force," Composite Structures, vol. 134, pp. 169-175, 2015.

J. Romanoff and P. Varsta, "Bending response of web-core sandwich plates," Composite Structures, vol. 81, no. 2, pp. 292-302, 2007.

J. Romanoff and P. Varsta, "Bending response of web-core sandwich beams," Composite Structures, vol. 73, no. 4, pp. 478-487, 2006,

E. Wang, N. Gardner, and A. Shukla, "The blast resistance of sandwich composites with stepwise graded cores," International Journal of Solids and Structures, vol. 46, no. 18-19, pp. 3492-3502, 2009.

A. Jamil, Z.W. Guan, W.J. Cantwell, X.F. Zhang, G.S. Langdon, and Q.Y. Wang, "Blast response of aluminium/thermoplastic polyurethane sandwich panels – experimental work and numerical analysis," International Journal of Impact Engineering, vol. 127, pp. 31-40, 2019.

V. Crupi, G. Epasto, and E. Guglielmino, "Comparison of aluminium sandwiches for lightweight ship structures: Honeycomb vs. foam," Marine Structures, vol. 30, pp. 74-96, 2013.

W. Huang, W. Zhang, D. Li, N. Ye, W. Xie, and P. Ren, "Dynamic failure of honeycomb-core sandwich structures subjected to underwater impulsive loads," European Journal of Mechanics - A/Solids, vol. 60, pp. 39-51, 2016.

N. Ye, W. Zhang, D. Li, W. Huang, W. Xie, X. Huang and X. Jiang, "Dynamic response and failure of sandwich plates with PVC foam core subjected to impulsive loading," International Journal of Impact Engineering, vol. 109, pp. 121-130, 2017.

K. Arslan and R. Gunes, "Experimental damage evaluation of honeycomb sandwich structures with Al/B4C FGM face plates under high velocity impact loads," Composite Structures, vol. 202, pp. 304-312, 2018.

W. Lestari and P. Qiao, "Damage detection of fiber-reinforced polymer honeycomb sandwich beams," Composite Structures, vol. 67, no. 3, pp. 365-373, 2005.

S. Shi, Z. Sun, X. Hu, and H. Chen, "Flexural strength and energy absorption of carbon-fiber–aluminum-honeycomb composite sandwich reinforced by aluminum grid," Thin-Walled Structures, vol. 84, pp. 416-422, 2014.

M. He and W. Hu, "A study on composite honeycomb sandwich panel structure," Materials & Design, vol. 29, no. 3, pp. 709-713, 2008.

M. R. M. Rejab and W. J. Cantwell, "The mechanical behaviour of corrugated-core sandwich panels," Composites Part B: Engineering, vol. 47, pp. 267-277, 2013.

F. Roland and T. Reinert, "Laser welded sandwich panels for the shipbuilding industry," Lightweight Construction–latest Developments, pp. 1-12, 2000.

J. Lou, L. Wu, L. Ma, J. Xiong, and B. Wang, "Effects of local damage on vibration characteristics of composite pyramidal truss core sandwich structure," Composites Part B: Engineering, vol. 62, pp. 73-87, 2014.

A. S. Sayyad and Y. M. Ghugal, "Bending, buckling and free vibration of laminated composite and sandwich beams: A critical review of literature," Composite Structures, vol. 171, pp. 486-504, 2017.

B. Wicklein et al., "Thermally insulating and fire-retardant lightweight anisotropic foams based on nanocellulose and graphene oxide," Nature Nanotechnology, vol. 10, no. 3, pp. 277-283, 2015.

J. Xie, R. Zhang, G. Xie, and O. Manca, "Thermal and thermomechanical performance of actively cooled pyramidal sandwich panels," International Journal of Thermal Sciences, vol. 139, pp. 118-128, 2019.

Z. Xue and J. W. Hutchinson, "Crush dynamics of square honeycomb sandwich cores," International Journal for Numerical Methods in Engineering, vol. 65, no. 13, pp. 2221-2245, 2006.

T. Ali, Y. Peng, Z. Jinhao, L. Kun, and Y. Renchuan, "Crashworthiness optimization method for sandwich plate structure under impact loading", Ocean Engineering, vol. 250, p. 110870, 2022.

P. Kujala and A. Klanac, "Steel sandwich panels in marine applications," Shipbuilding: Theory and practice of shipbuilding and marine engineering, vol. 56, no. 4, pp. 305-314, 2005.

Q. Zhong and D. Wang, "Ultimate strength behavior of laser-welded web-core sandwich plates under in-plane compression," Ocean Engineering, vol. 238, p. 109685, 2021.

J. van der Zwaal, "Feasibility study of an all-sandwich superstructure for hopper dredgers," Master Thesis, TU Delft, 2005.

J. Kortenoeven, B. Boon, and A. de Bruijn, "Application of sandwich panels in design and building of dredging ships," Journal of Ship Production, vol. 24, no. 3, pp. 125-134, 2008.

A. T. Karttunen, J. N. Reddy, and J. Romanoff, "Two-scale micropolar plate model for web-core sandwich panels," International Journal of Solids and Structures, vol. 170, pp. 82-94, 2019.

S. Yan and J. Jelovica, "Buckling and free vibration of laser-welded web-core sandwich panels: Extreme sensitivity to variation of weld rotational stiffness," Engineering Structures, vol. 244, p. 112737, 2021.

P. Paczos, P. Wasilewicz, and E. Magnucka-Blandzi, "Experimental and numerical investigations of five-layered trapezoidal beams", Composite Structures, vol. 145, pp. 129-141, 2016.

J. Romanoff, P. Varsta, and H. Remes, "Laser-welded web-core sandwich plates under patch loading," Marine Structures, vol. 20, no. 1, pp. 25-48, 2007.

X.X. Jiang, J.M. Li, R. Cao, L. Zhu, J.H. Chen, Y.X. Wu, and Z.G. Li, "Microstructures and properties of sandwich plane laser-welded joint of hull steel," Materials Science and Engineering: A, vol. 595, pp. 43-53, 2014.

H. Kolsters and P. Wennhage, "Optimisation of laser-welded sandwich panels with multiple design constraints," Marine Structures, vol. 22, no. 2, pp. 154-171, 2009,

J. Romanoff, H. Remes, G. Socha, M. Jutila, and P. Varsta, "The stiffness of laser stake welded T-joints in web-core sandwich structures," Thin-Walled Structures, vol. 45, no. 4, pp. 453-462, 2007.

Y. Sun, M. Saafi, W. Zhou, C. Zhang, and H. Li, "Analysis and experiment on bending performance of laser-welded web-core sandwich plates," Materials Today: Proceedings, vol. 2, pp. 279-288, 2015.

K. Liu, L. Ke, Y. Sha, G. Wu, P. Wang, and Z. Wang, "Dynamic response of laser-welded corrugated sandwich panels subjected to plane blast wave," International Journal of Impact Engineering, vol. 164, p. 104203, 2022.

Z. Guo, R. Bai, Z. Lei, H. Jiang, J. Zou, and C. Yan, "Experimental and numerical investigation on ultimate strength of laser-welded stiffened plates considering welding deformation and residual stresses," Ocean Engineering, vol. 234, p. 109239, 2021.

S. Chowdhury, Y. Nirsanametla, M. Muralidhar, S. Bag, C. P. Paul, and K. S. Bindra, "Identification of modes of welding using parametric studies during ytterbium fiber laser welding," Journal of Manufacturing Processes, vol. 57, pp. 748-761, 2020.

J. Romanoff, "Periodic and homogenized bending response of faceplates of filled web-core sandwich beams," Composite Structures, vol. 113, pp. 83-88, 2014.

J. Romanoff, J. Jelovica, J. N. Reddy, and H. Remes, "Post-buckling of web-core sandwich plates based on classical continuum mechanics: success and needs for non-classical formulations," Meccanica, vol. 56, no. 6, pp. 1287-1302, 2021.

H. Kolsters and D. Zenkert, "Buckling of laser-welded sandwich panels. Part 1: Elastic buckling parallel to the webs," Proceedings of the Institution of Mechanical Engineers, Part M: Journal of Engineering for the Maritime Environment, vol. 220, no. 2, pp. 67-79, 2006.

J. Jelovica and J. Romanoff, "Load-carrying behaviour of web-core sandwich plates in compression," Thin-walled structures, vol. 73, pp. 264-272, 2013.

X. X. Jiang, L. Zhu, J. S. Qiao, Y. X. Wu, Z. G. Li, and J. H. Chen, "The strength of laser welded web-core steel sandwich plates," in Applied Mechanics and Materials, vol. 551, pp. 42-46, 2014.

G. Schuh, G. Bergweiler, K. Lichtenthäler, F. Fiedler, and S. d. l. Puente Rebollo, "Topology optimisation and metal based additive manufacturing of welding jig elements," Procedia CIRP, vol. 93, pp. 62-67, 2020.

B. Zhang, X. Wang, and H. Wang, "Virtual machine placement strategy using cluster-based genetic algorithm," Neurocomputing, vol. 428, pp. 310-316, 2021.

J. Ordieres, E. Rodríguez, A. Bayón, J. Caixas, A. Barbensi, and P. Guglielmi, "Improvement of manufacturing jigs design for reduction of welding distortion in Vacuum Vessel PS1 through finite element analysis," Fusion Engineering and Design, vol. 146, pp. 2168-2171, 2019.

A. Kampker, G. Bergweiler, A. Hollah, K. Lichtenthäler, and S. Leimbrink, "Design and testing of the different interfaces in a 3D printed welding jig," Procedia CIRP, vol. 81, pp. 45-50, 2019.

N. Ma, H. Huang, and H. Murakawa, "Effect of jig constraint position and pitch on welding deformation," Journal of Materials Processing Technology, vol. 221, pp. 154-162, 2015.

J. Ordieres, E. Rodríguez, A. Bayón, J. Caixas, A. Barbensi, and C. Martín, "Determination of the influence of clamping on welding distortion applied to PS2 mock-up using finite element simulations," Fusion Engineering and Design, vol. 166, p. 112327, 2021.

A. Azimi, F. Ashrafizadeh, M. R. Toroghinejad, and F. Shahriari, "Metallurgical analysis of pimples and their influence on the properties of hot dip galvanized steel sheet," Engineering Failure Analysis, vol. 26, pp. 81-88, 2012.

A. Azimi, F. Ashrafizadeh, M. R. Toroghinejad, and F. Shahriari, "Metallurgical assessment of critical defects in continuous hot dip galvanized steel sheets," Surface and Coatings Technology, vol. 206, no. 21, pp. 4376-4383, 2012.

P. Ren et al., "High-velocity impact response of metallic sandwich structures with PVC foam core", International Journal of Impact Engineering, vol. 144, p. 103657, 2020.

Y. Deng, N. Zhou, X. Li, X. Wang, G. Wei, and H. Jia, "Dynamic response and failure mechanism of S-shaped CFRP foldcore sandwich structure under low-velocity impact," Thin-Walled Structures, vol. 173, p. 109007, 2022.

F. Z. Utyashev and G. I. Raab, "Influence of large and severe plastic deformation mechanisms on structure formation in metals," Materials Letters, vol. 302, p. 130241, 2021.

H. Li, Y. Hu, X. Fu, X. Zheng, H. Liu, and J. Tao, "Effect of adhesive quantity on failure behavior and mechanical properties of fiber metal laminates based on the aluminum–lithium alloy", Composite Structures, vol. 152, pp. 687-692, 2016.

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Published

2022-12-27 — Updated on 2022-12-28

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How to Cite

[1]
N. K. Romli, M. R. Mat Rejab, X.X. Jiang, S.M. Soffie, and M. Ishak, “Mechanical response of galvanised steel sandwich structure with different numbers of web core and different spacing distance of web plate under bending load”, J. Mech. Eng. Sci., vol. 16, no. 4, pp. 9289–9306, Dec. 2022.

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