{"title":"Numerical Study for Compressive Strength of Basalt Composite Sandwich Infill Panel","authors":"Viriyavudh Sim, Jung Kyu Choi, Yong Ju Kwak, Oh Hyeon Jeon, Woo Young Jung","volume":131,"journal":"International Journal of Civil and Environmental Engineering","pagesStart":1558,"pagesEnd":1562,"ISSN":"1307-6892","URL":"https:\/\/publications.waset.org\/pdf\/10008179","abstract":"
In this study, we investigated the buckling performance of basalt fiber reinforced polymer (BFRP) sandwich infill panels. Fiber Reinforced Polymer (FRP) is a major evolution for energy dissipation when used as infill material of frame structure, a basic Polymer Matrix Composite (PMC) infill wall system consists of two FRP laminates surrounding an infill of foam core. Furthermore, this type of component is for retrofitting and strengthening frame structure to withstand the seismic disaster. In-plane compression was considered in the numerical analysis with ABAQUS platform to determine the buckling failure load of BFRP infill panel system. The present result shows that the sandwich BFRP infill panel system has higher resistance to buckling failure than those of glass fiber reinforced polymer (GFRP) infill panel system, i.e. 16% increase in buckling resistance capacity.<\/p>\r\n","references":"[1]\tA. Saneinejad, and B. Hobbs, \u201cInelastic design of infilled frames,\u201d Journal of Structural Engineering, 1995, vol. 121, no. 4, pp. 634-650.\r\n[2]\tK. Jung-Min, and K. Myung-Ho, \u201cThe study about indoor temperature effect on productivity by brainwave type of occupants,\u201d International Journal of Technology and Engineering Studies, 2016, vol. 2, no. 4, pp. 117-124.\r\n[3]\tW. Y. Jung, and A. J. Aref, \u201cAnalytical and numerical studies of polymer matrix composite sandwich infill panels,\u201d Composite structures, 2005, vol. 68, no. 3, pp. 359-370.\r\n[4]\tA. J. Aref, and W. Y. Jung, \u201cEnergy-dissipating polymer matrix composite-infill wall system for seismic retrofitting,\u201d Journal of Structural Engineering, 2003, vol. 129, no. 4, pp. 440-448.\r\n[5]\tV. Sim, and W. Y. Jung, \u201cComparison of PMC infills compressive strength performance under laminate orientation and temperature effect,\u201d Journal of Engineering and Applied Sciences, 2017, vol. 12, no. 3, pp. 748-752.\r\n[6]\tR. V. Subramanian, and H. F. Austin, \u201cSilane coupling agents in basalt-reinforced polyester composites,\u201d International Journal of Adhesion and Adhesives, 1980, vol. 1, no. 1, pp. 50-54.\r\n[7]\tP. I. Bashtannik, V. G. Ovcharenko, and Y. A. Boot, \u201cEffect of combined extrusion parameters on mechanical properties of basalt fiber-reinforced plastics based on polypropylene,\u201d Mechanics of composite materials, 1997, vol. 33, no. 6, pp. 600-603.\r\n[8]\tT. Czig\u00e1ny, \u201cSpecial manufacturing and characteristics of basalt fiber reinforced hybrid polypropylene composites: mechanical properties and acoustic emission study,\u201d Composites science and technology, 2006, vol. 66, no. 16, pp. 3210-3220.\r\n[9]\tM. Botev, H. Betchev, D. Bikiaris, and C. Panayiotou, \u201cMechanical properties and viscoelastic behavior of basalt fiber-reinforced polypropylene,\u201d Journal of Applied Polymer Science, 1999, vol. 74, no. 3, pp. 523-531.\r\n[10]\tSyst\u00e8mes, Dassault, ABAQUS User\u2019s & Theory Manuals\u2014Release 6.13-1, Providence, RI, USA, 2013.\r\n[11]\tR. M. Jones, \u201cMechanics of Composite Materials,\u201d McGraw-Hill, New York, 2nd ed., 1975.\r\n[12]\tK. K. Chawla, \u201cComposite Materials-Science and Engineering,\u201d Springer-Verlag, New York, 3rd ed., 2012.\r\n[13]\tM. Sudheer, K. R. Pradyoth, and S. Somayaji, \u201cAnalytical and Numerical Validation of Epoxy\/Glass Structural Composites for Elastic Models,\u201d American Journal of Materials Science, 2015, vol. 5, no. 3C, pp. 162-168.","publisher":"World Academy of Science, Engineering and Technology","index":"Open Science Index 131, 2017"}