Experimental study of the influence of glass microspheres on flexural response of honeycomb structures reinforced with syntactic foams

Collaguazo, D.; Sarmiento, R.; Díaz, C.; Sotomayor, O.

Growing Science » Engineering Solid Mechanics » Experimental study of the influence of glass microspheres on flexural response of honeycomb structures reinforced with syntactic foams

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Engineering Solid Mechanics

ISSN 2291-8752 (Online) - ISSN 2291-8744 (Print) Quarterly Publication Volume 8 Issue 2 pp. 77-82 , 2020

Experimental study of the influence of glass microspheres on flexural response of honeycomb structures reinforced with syntactic foams Pages 77-82 Download PDF

Authors: David C. Collaguazo, Romulo W. Sarmiento, Carlos W. Díaz, Oscar E. Sotomayor

DOI: 10.5267/j.esm.2019.11.001

Keywords: Honeycomb nomex, Microspheres, Epoxy resin, Flexural stiffness

Abstract: This paper studies the bending behavior of honeycomb structures by varying their weight through the introduction of glass microspheres. For this purpose, four different types of syntactic foam specimens were manufactured, varying the percentage by volume of glass microspheres between 20%, 30% and 40%. Afterwards, three-point bending tests were performed on each of these groups of specimens based on ASTM D7264/D7264M-15, thus obtaining data that allowed determining mechanical behavior and comparing it with material without glass microspheres. The optimum positive influence of microspheres over specific flexural strength was found at 30% of addition of glass bubbles. Additionally, results of the structures under impact gravity test confirm that 30% is a good proportion for these structures.

How to cite this paper

 Collaguazo, D., Sarmiento, R., Díaz, C & Sotomayor, O. (2020). Experimental study of the influence of glass microspheres on flexural response of honeycomb structures reinforced with syntactic foams.Engineering Solid Mechanics, 8(2), 77-82.

Refrences

Ajdari, A., Nayeb-Hashemi, H., & Vaziri, A. (2011). Dynamic crushing and energy absorption of regular, irregular and functionally graded cellular structures. International Journal of Solids and Structures, 48(3-4), 506-516.
Aliha, M. R. M., Linul, E., Bahmani, A., & Marsavina, L. (2018). Experimental and theoretical fracture toughness investigation of PUR foams under mixed mode I+ III loading. Polymer Testing, 67, 75-83.
Aliha, M. R. M., Mousavi, S. S., Bahmani, A., Linul, E., & Marsavina, L. (2019). Crack initiation angles and propagation paths in polyurethane foams under mixed modes I/II and I/III loading. Theoretical and Applied Fracture Mechanics, 101, 152-161.
Ashby, M. F., & Gibson, L. J. (1997). Cellular solids: structure and properties. Press Syndicate of the University of Cambridge, Cambridge, UK, 175-231.
Craven, A. (2011). Flexural Response of Syntactic Foam Core Sandwich Structures: Effects of Graded Face Sheets and Interpenetrating Phase Composite Foam Core (Doctoral dissertation).
Jhaver, R., & Tippur, H. (2010). Characterization and modeling of compression behavior of syntactic foam-filled honeycombs. Journal of Reinforced Plastics and Composites, 29(21), 3185-3196.
Lu, C., Zhao, M., Jie, L., Wang, J., Gao, Y., Cui, X., & Chen, P. (2015). Stress distribution on composite honeycomb sandwich structure suffered from bending load. Procedia Engineering, 99, 405-412.
Lu, G., & Yu, T. X. (2003). Energy absorption of structures and materials. Elsevier.
Marsavina, L., Constantinescu, D. M., Linul, E., Apostol, D. A., Voiconi, T., & Sadowski, T. (2014). Refinements on fracture toughness of PUR foams. Engineering Fracture Mechanics, 129, 54-66.
Motoring, E. (2018). Ficha tecnca de fibra de carbono 3k. Retrieved from https://www.ebay.com/itm/132405870431
Negru, R., Serban, D. A., Pop, C., & Marsavina, L. (2018). Notch effect assessment in a PUR material using a ring shaped specimen. Theoretical and Applied Fracture Mechanics, 97, 500-506.
Nemati, S., Sharafi, P., & Samali, B. (2019). Effects of cold joints on the structural behaviour of polyurethane rigid foam panels. Engineering Solid Mechanics, 7(1), 1-12.
Samali, B., Nemati, S., Sharafi, P., Abtahi, M., & Aliabadizadeh, Y. (2018). An experimental study on the lateral pressure in foam-filled wall panels with pneumatic formwork. Case Studies in Construction Materials, 9, e00203.
Sharafi, P., Nemati, S., Samali, B., Bahmani, A., & Khakpour, S. (2018). Behavior of integrated connections between adjacent foam-filled modular sandwich panels. Engineering Solid Mechanics, 6(4), 361-370.
Sharafi, P., Nemati, S., Samali, B., Bahmani, A., Khakpour, S., & Aliabadizadeh, Y. (2018). Flexural and shear performance of an innovative foam-filled sandwich panel with 3-D high density polyethylene skins. Engineering Solid Mechanics, 6(2), 113-128.