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Year 2018, , 209 - 213, 30.09.2018
https://doi.org/10.17350/HJSE19030000096

Abstract

References

  • 1. Ghezal, A., Khayat, K.H., Optimizing Self-Consolidating Concrete with Limestone Filler by Using Statistical Factorial Design Methods, ACI Materials Journal, (99), 264–272, 2002.
  • 2. Khayat, K.H., Paultre, P., Tremblay, S., Structural Performance and In-Place Properties of SCC Used for Casting Highly Reinforced Columns, ACI Materials Journal (98), 371–378, 2001.
  • 3. Felekoğlu, B., Türkel, S., Baradan, B., Effect of Water/ Cement Ratio on the Fresh and Hardened Properties of SelfCompacting Concrete, Build Environment Journal, (42), 1795–1802, 2007.
  • 4. Carro-lópez, D., González-Fonteboa, B., Brito, J., MartínezAbella, F., González-Taboada, I., Silva, P., Study of the Rheology of Self-Compacting Concrete with Fine Recycled Concrete Aggregates, Construction and Building Materials, (96), 491-501 2015.
  • 5. Kapoor, K., Singh, S.P., Singh, B. Durability of SelfCompacting Concrete Made with Recycled Concrete Aggregates and Mineral Admixtures. Construction and Building Materials, (128), 67-76, 2016.
  • 6. Khayat, K.H., Optimization and Performance of AirEntrained SCC, ACI Materials Journal, (97), 526–535, 2000.
  • 7. Schutter, G. D., Guidelines for Testing Fresh Self-Compacting Concrete, European Research Project, Growth Contract No. GRD2-2000-30024, 2005.
  • 8. Sabău, M., One , T., Petean, A. I., Hardened Properties of Self-Compacting Concrete, First International Conference for PhD students in Civil Engineering CE-PhD, 4-7 November 2012, Cluj-Napoca, Romania.
  • 9. Barluenga, G., Palomar, I., Puentes, J., Hardened Properties and Microstructure of SCC with Mineral Additions, Construction and Building Materials, (94), 728-736, 2015.
  • 10. Ulubeyli, G.C., Artir, R., Properties of Hardened Concrete Produced by Waste Marble Powder, Procedia, Social and Behavioral Sciences, (195), 2181-2190, 2015.
  • 11. Atmaca, N., Abbas, M.L., Atmaca, A., Effects of nano-silica on the gas permeability, durability and mechanical properties of high-strength lightweight concrete, Construction and Building Materials, (147), 17-26, 2017.
  • 12. Atmaca, N., Atmaca, A., Aljumaili M., Ozcetin A.I., Strength and shrinkage properties of self-compacting concretes incorporating waste PVC dust, The International Journal of Energy & Engineering Sciences (3), 47-57, 2018.
  • 13. Siddique, R., Klaus, J., Influence of Metakaolin on The Properties of Mortar and Concrete: A Review, Applied Clay Science, (43), 392–400, 2009.
  • 14. Mermerdaş, K., Caracterization and Utilization of Calcined Turkish Kaolins for Improving Strength and Durability Aspects of Concrete. Published Ph. D. Thesis, Gaziantep University, Institute of Science and Technology, Gaziantep, 2013.
  • 15. Mallik, A., Barık, A.K., Pal, B., Comparative Studies on Physico-Mechanical Properties of Composite Materials of Low Density Polyethylene and Raw/Calcined Kaolin. Journal of Asian Ceramic Societies, (3), 212-216, 2015.
  • 16. Yuan, Y., Chen, H., Lin, J., Yan, J.Y., Surface Modification of Calcined Kaolin with Toluene Diisocyanate Based on High Energy Ball Milling, Applied Surface Science, (284), 214- 221, 2013.

The Investigation of Strength and Water Absorption of Self-Compacting Concrete by Inclusion of Metakaolin and Calcined Kaolin

Year 2018, , 209 - 213, 30.09.2018
https://doi.org/10.17350/HJSE19030000096

Abstract

In this study, commercially available high reactivity Czech metakaolin and calcined impure local kaolin were used for production Self Compacting Concrete SCC samples and some hardened properties of these concretes have been investigated. Four types of SCC mixtures were prepared with 0%, 5% and 10% replacement level of Metakaoline and calcined kaolin with including control mixture without any mineral admixtures. Only Portland Cement PC was used for production of the control mixture and this mixture was produced with the purpose of comparison. The highest compressive strength value was obtained as 83.5 MPa with 10% replacement level of Metakaolin. The lowest water penetration depth was also calculated as 3.5 mm with 10% replacement level of Metakaolin. The compressive strength and water penetration tests showed that the best strength and durability performance values obtained from mixtures with 10% replacement level of Metakaolin.

References

  • 1. Ghezal, A., Khayat, K.H., Optimizing Self-Consolidating Concrete with Limestone Filler by Using Statistical Factorial Design Methods, ACI Materials Journal, (99), 264–272, 2002.
  • 2. Khayat, K.H., Paultre, P., Tremblay, S., Structural Performance and In-Place Properties of SCC Used for Casting Highly Reinforced Columns, ACI Materials Journal (98), 371–378, 2001.
  • 3. Felekoğlu, B., Türkel, S., Baradan, B., Effect of Water/ Cement Ratio on the Fresh and Hardened Properties of SelfCompacting Concrete, Build Environment Journal, (42), 1795–1802, 2007.
  • 4. Carro-lópez, D., González-Fonteboa, B., Brito, J., MartínezAbella, F., González-Taboada, I., Silva, P., Study of the Rheology of Self-Compacting Concrete with Fine Recycled Concrete Aggregates, Construction and Building Materials, (96), 491-501 2015.
  • 5. Kapoor, K., Singh, S.P., Singh, B. Durability of SelfCompacting Concrete Made with Recycled Concrete Aggregates and Mineral Admixtures. Construction and Building Materials, (128), 67-76, 2016.
  • 6. Khayat, K.H., Optimization and Performance of AirEntrained SCC, ACI Materials Journal, (97), 526–535, 2000.
  • 7. Schutter, G. D., Guidelines for Testing Fresh Self-Compacting Concrete, European Research Project, Growth Contract No. GRD2-2000-30024, 2005.
  • 8. Sabău, M., One , T., Petean, A. I., Hardened Properties of Self-Compacting Concrete, First International Conference for PhD students in Civil Engineering CE-PhD, 4-7 November 2012, Cluj-Napoca, Romania.
  • 9. Barluenga, G., Palomar, I., Puentes, J., Hardened Properties and Microstructure of SCC with Mineral Additions, Construction and Building Materials, (94), 728-736, 2015.
  • 10. Ulubeyli, G.C., Artir, R., Properties of Hardened Concrete Produced by Waste Marble Powder, Procedia, Social and Behavioral Sciences, (195), 2181-2190, 2015.
  • 11. Atmaca, N., Abbas, M.L., Atmaca, A., Effects of nano-silica on the gas permeability, durability and mechanical properties of high-strength lightweight concrete, Construction and Building Materials, (147), 17-26, 2017.
  • 12. Atmaca, N., Atmaca, A., Aljumaili M., Ozcetin A.I., Strength and shrinkage properties of self-compacting concretes incorporating waste PVC dust, The International Journal of Energy & Engineering Sciences (3), 47-57, 2018.
  • 13. Siddique, R., Klaus, J., Influence of Metakaolin on The Properties of Mortar and Concrete: A Review, Applied Clay Science, (43), 392–400, 2009.
  • 14. Mermerdaş, K., Caracterization and Utilization of Calcined Turkish Kaolins for Improving Strength and Durability Aspects of Concrete. Published Ph. D. Thesis, Gaziantep University, Institute of Science and Technology, Gaziantep, 2013.
  • 15. Mallik, A., Barık, A.K., Pal, B., Comparative Studies on Physico-Mechanical Properties of Composite Materials of Low Density Polyethylene and Raw/Calcined Kaolin. Journal of Asian Ceramic Societies, (3), 212-216, 2015.
  • 16. Yuan, Y., Chen, H., Lin, J., Yan, J.Y., Surface Modification of Calcined Kaolin with Toluene Diisocyanate Based on High Energy Ball Milling, Applied Surface Science, (284), 214- 221, 2013.
There are 16 citations in total.

Details

Primary Language English
Journal Section Research Article
Authors

Nihat Atmaca This is me

Adem Atmaca This is me

Gözde Şafak Sezer This is me

Publication Date September 30, 2018
Published in Issue Year 2018

Cite

Vancouver Atmaca N, Atmaca A, Sezer GŞ. The Investigation of Strength and Water Absorption of Self-Compacting Concrete by Inclusion of Metakaolin and Calcined Kaolin. Hittite J Sci Eng. 2018;5(3):209-13.

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