Effects of Barite Sand Addition on Glass Fiber Reinforced Concrete Mechanical Behavior

Year 2017, , 100 - 105, 27.12.2017

Sadık Alper Yıldızel

https://doi.org/10.24107/ijeas.366441

Cited By: 2

Abstract

Glass fiber reinforced concrete (GFRC) is a cementitious composite
reinforced by the addition of alkali-resistant glass fibers. GFRC is widely
used for various types of precast products in civil engineering industries.
GRFC mixes generally include silica sand to produce precast concrete elements;
however, silica sand was replaced with barite sand at the ratios of 5%, 10 %
and 15 % of wt. in order to reveal its applicability and potential for
different engineering purposes. The flexural strength and the
freeze-thaw(F&T) resistance of the composites were studied. The
experimental results showed that the replacement of silica sand with barite
sand up to 15 % of wt. enhances the mechanical properties of the composites in
respect to flexural strength and F&T resistance properties.

Keywords

Glass fiber, silica sand, barite sand, silica sand replacement

References

• [1] Yoo, D.-Y., Lee, J.-H., Yoon, Y.-S., Effect of fiber content on mechanical and fracture properties of ultra high performance fiber reinforced cementitious composites, Composite Structures, 106, 742–53, 2013.
• [2] Yoo, D.Y., Yoon, Y.S., Banthia, N., Predicting the post-cracking behavior of normal- and high-strength steel-fiber-reinforced concrete beams, Construction and Building Materials, 93, 477–85, 2015.
• [3] Wittmann, F.H., Rokugo, K., Brühwiler, E., Mihashi, H., Simonin, P., Fracture energy and strain softening of concrete as determined by means of compact tension specimens, Materials and Structures, 21, 21–32, 1988.
• [4] Newman, J., Choo, B.S., Advanced Concrete Technology, Butterworth-Heinemann, 1st edition, 2003.
• [5] Kizilkanat, A.B., Kabay, N., Akyüncü, V., Chowdhury, S., Akça, A.H., Mechanical properties and fracture behavior of basalt and glass fiber reinforced concrete: An experimental study, Construction and Building Materials, 100, 218–24, 2015.
• [6] Tassew, S.T., Lubell, A.S., Mechanical properties of glass fiber reinforced ceramic concrete, Construction and Building Materials, 51, 215–24, 2014.
• [7] Chandramouli, K., Rao S.S., Pannirselvam, N., Sekhar, S.T., Sravana, P., Strength Properties of Glass Fibre Concrete, Journal of Engineering and Applied Sciences, 5, 1–6, 2010.
• [8] Bashter, I.I., Calculation of radiation attenuation coefficients for shielding concretes, Annals of Nuclear Energy, 24, 1389–401, 1997.
• [9] Akkurt, I., Basyigit, C., Kilincarslan, S., Mavi, B., Akkurt, A., Radiation shielding of concretes containing different aggregates, Cement and Concrete Composites, 28, 153–7, 2006.
• [10] Sakr, K., El-Hakim, E., Effect of high temperature or fire on heavy weight concrete properties, Cement and Concrete Research, 35, 590–6, 2005.
• [11] Kilincarslan, S., Akkurt, I., Basyigit, C., The effect of barite rate on some physical and mechanical properties of concrete, Materials Science and Engineering A, 424, 83–6, 2006.
• [12] Saidani, K., Ajam, L., Ben Ouezdou, M., Barite powder as sand substitution in concrete: Effect on some mechanical properties, Construction and Building Materials, 95, 287–95, 2015.