Experimental Study On Conventional Concrete Over Polymer Impregnated Concrete Using Silica Fumes

Authors

  • Gutthi Aswini UG Scholar , Saveetha School of Engineering, Saveetha Institute of Medical and Technical Sciences, Chennai , India Author
  • Mrs.Kalpana Assistant Professor, Saveetha School of Engineering, Saveetha Institute of Medical and Technical Sciences, Chennai , India Author

DOI:

https://doi.org/10.61841/ry79c283

Keywords:

Super plasticizer, polymer, split tensile strength, compression strength, flexural strength, cement and aggregates

Abstract

In this experimental study, we are utilizing silica exhaust with styrene and polyester monomers to increase the quality of the solid. With the reference to study cases, we can say that there are numerous materials accessible for expanding the quality of the solid. In part, polymer is utilized for improving the quality, yet it isn't usually utilized. There are numerous studies that have improved the quality of cement by utilizing polymers. Polymer impregnated concrete is one of the generally utilized polymer composites. It is only a regular precast concrete, relieved and dried in a broiler or by dielectric warming, from which the air in open cells is expelled by the vacuum process. At that point, a low-thickness monomer or prepolymer halfway or completely is impregnated or diffused into the pore arrangement of the solidified concrete composites or concrete and afterward polymerized utilizing radiation, the use of warmth, or substance initation. Ferrocement is delivered by applying concrete mortar made out of fine totals and concrete into support utilizing plasterer procedures. Accordingly, the property of ferrocement recognizes it from fortified cement. While of comparable sturdiness, it is more versatile than fortified cement. 

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References

1. Zain, M.F.M., Safiuddin, Md. And Mahmud, H. (2000). “Development of high-performance concrete using

silica fume at relatively high waterbinder ratios”, Cement and Concrete Research, Vol. 30, pp. 1501-1505.

2. Pradhan D., Dutta. D. (2013). Influence of Silica Fume on Normal Concrete. Int. Journal of Engineering

Research and Applications, Vol. 3, pp. 79-82.

3. Amudhavalli N. K., Mathew Jeena. (2012) Effect of silica fume on strength and durability parameters of

concrete. International Journal of Engineering Sciences & Emerging Technologies. Volume 3, Issue 1, pp.

28-35.

4. Karein S. Mahmoud Motahari , Ramezanianpour A.A. , Taghi Ebadi and Isapour Soroush (2017) A new

approach for application of silica fume in concrete: wet granulation. Construction and Building Materials

page573–581.

5. Zhang Zengqi , Zhang Bo and Yan Peiyu (2016). Comparative study of effect of raw and densified silica fume

in the paste, mortar and concrete. Construction and Building Materials 105, pages 82–93.

6. Khan M.I, Abbas Y.M. (2017) Curing optimization for strength and durability of silica fume and fuel ash

concretes under hot weather conditions. Construction and Building Materials 157 (page) 1092–1105.

7. Okoye Francis N, Prakash Satya , Singh Nakshatra B. (2017) Durability of fly ash-based geopolymer

concrete in the presence of silica fume.Journal of Cleaner Production 149. (Page) 1062-1067.

8. Ali K., Ghalehnovi M., Brito J. de, Shamsabadi E. A. (2017) Durability performance of structural concrete containing silica fume and marble industry waste powder. Journal of Cleaner Production 170 (pages 42 and 60).

9. Siddique R, Jameel A, Singh M., Hunek D. B., Mokhtar A. A., Belarbi. R., Rajor. A. (2017). Effect of bacteria on strength, permeation characteristics, and micro-structure of silica fume concrete. Construction and Building Materials 142 (Page) 92–100.

10. Wang, L., Zhou, S.H., Y. Shi, Tang, S.W., Chen, E. (2017). Effect of silica fume and PVA fiber on the abrasion resistance and volume stability of concrete. Composites Part B 130. (pages 28 and 37).

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Published

31.05.2020

Issue

Vol. 24 No. 3 (2020): 24 (3) 2020

Section

Articles

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How to Cite

Aswini, G., & Kalpana. (2020). Experimental Study On Conventional Concrete Over Polymer Impregnated Concrete Using Silica Fumes. International Journal of Psychosocial Rehabilitation, 24(3), 4103-4113. https://doi.org/10.61841/ry79c283