Using Waste Marbles in Self Compacting Lightweight Concrete
In this study, the effects of waste marbles as aggregate material on workability and hardened concrete characteristics of self compacting lightweight concrete are investigated. For this purpose, self compacting light weight concrete are produced by waste marble aggregates are replaced with fine aggregate at 5%, 7.5%, and 10% ratios. Fresh concrete properties, slump flow, T50 time, V funnel, compressive strength and ultrasonic pulse velocity of self compacting lightweight concrete are determined. It is concluded from the test results that using waste marbles as aggregate material by replacement with fine aggregate slightly affects fresh and hardened concrete characteristics of self compacting lightweight concretes.
[1] H.Y. Wang and C.C., Lin, “A study of fresh and engineering properties of self-compacting high slag concrete (SCHSC),” vol. 42, pp. 132-136, 2013.
[2] B. Craeye, G. De Schutter, B. Desmet, J. Vantomme, G. Heirman, and L. Vandewalle, “Effect of mineral filler type on autogenous shrinkage of self-compacting concrete,” Cement Concrete Research, vol. 40, pp. 908–913, 2010.
[3] R.D. Swamy, M.K.M.V. Ratnam and U.R. Raju, “Effect of mineral admixture on properties of self compacting concrete,” International Journal for Innovative Research in Science & Technology, vol.1, no. 11, pp. 503-511, April 2015.
[4] Okamura H., and Ouchi M., (2003). Self-Compacting Concrete. Journal of Advanced Concrete Technology Vol.1, No 1, pp5-15.
[5] M. Ouchi, S. Nakamura, T. Osterberg, S.E. Hallberg and M. Lwin, “Applications of self compacting concrete in Japon, Europe and the United States,” ISHPC, 2003.
[6] S.N. Tande and P.B. Mohite, “Applications of self compacting concrete,” 32nd Conference on Our World ın Concrete Structures, 28 - 29 August 2007, Singapore.
[7] Functional classification of lightweight concretes. (1978). RILEM.
[8] M. Kaffetzakis, and C.G. Papanicolaou, “Bond behavior of reinforcement in lightweight aggregate self-compacting concrete,” Construction and Buildings, vol. 113, pp. 641-652, 2016.
[9] C. Ozyildirim, “Durability of structural lightweight concrete,” Concrete Bridge Conference, St Louis, MO, 2008.
[10] T. Uygunoglu, I.B. Topçu, “Thermal expansion of self-consolidating normal and lightweight concrete at elevated temperature, “Construction and Building Materials, vol. 23, pp. 3063-3069, 2009.
[11] A. Kumar and R. Prakash, “Mechanical properties of structural light weight concrete by blending cinder & LEECA,” International Advanced Research Journal in Science, Engineering and Technology, vol. 2, no. 10, October, 2015.
[12] Wilson, N.S. 2003. Effect of mositure and porosity on the thermal properties of a conventional refractorty concrete. Journal of the European Seramic Society, 23, 745-755.
[13] M. Uysal and K. Yılmaz, “Effect of mineral admixtures on properties of self-compacting concrete,” Cement Concrete Composites, vol. 33, no. 7, pp. 771-776, August 2011.
[14] FMA. Filho, BE. Barragán, JR. Casas and ALHC. El Debs “Hardened properties of self compacting concrete – a statistical approach,” Construction Building Materials, vol. 24, pp. 1608–1615, 2013.
[15] O. Gencel, C. Ozel, F. Köksal, G.M. Barrerae and W. Brostowf “Properties of concrete paving blocks made with waste marble,” Journal of Cleaner Production, Vol 21, No 1, 62-70.
[16] T. Uygunoğlu, İ.B. Topçu and A.G. Çelik, “Use of waste marble and recycled aggregates in self-compacting concrete for environmental sustainability,” Journal of Cleaner Production, Vol 84, No 1, 691-700.
[17] S. Juradin and G. Boloevic, 2012. Experimental Testing of the Effects of Fine Particles on the Properties of the SCC, Advances in Material Science and Engineering.
[18] Aukour F.J. and Al-Qinna, M.I. 2008. Marble Production and Environmental Constrains: Case Study from Zarqa Governorate, Jordan Journal of Earth and Environmental Sciences, Vol 1, No 1, 11-21.
[19] Alyamaç, K.E., and Ince, R., (2009). A preliminary concrete mix design for SCC with marble powders. Construction and Building Materials, 23, 1201-1210.
[20] TS EN 197-1 (2005). “Cement. Part 1: compositions and conformity criteria for common cements”. Turkish Standards Institutions, Ankara.
[21] TS 706 EN 12620 (2009). “Aggregates for concrete”. Turkish Standards Institutions, Ankara.
[22] TS EN 12350-8 (2011). Testing fresh concrete - Part 8: Self-compacting concrete - Slump-flow test.
[23] TS EN 12350-9 (2011). Testing fresh concrete - Part 8: Self-compacting concrete - V funnel test
[24] EFNARC. (2005). The European guidelines for self compacting concrete: Specification, production and use. Cambridge, UK: The Self-Compacting Concrete European Project Group.ESCSI. (2004).
[25] ASTM C597, “Standard Test Method for Pulse Velocity through Concrete”. Standard ASTM C597-83, American Society for Testing Materials, Philadelphia, 2002.
[26] TS EN 12390–3, “Testing Hardened Concrete – Part 3: Compressive Strength of Test Specimens”, Turkish Standard, Turkey (in Turkish), 2003.
[1] H.Y. Wang and C.C., Lin, “A study of fresh and engineering properties of self-compacting high slag concrete (SCHSC),” vol. 42, pp. 132-136, 2013.
[2] B. Craeye, G. De Schutter, B. Desmet, J. Vantomme, G. Heirman, and L. Vandewalle, “Effect of mineral filler type on autogenous shrinkage of self-compacting concrete,” Cement Concrete Research, vol. 40, pp. 908–913, 2010.
[3] R.D. Swamy, M.K.M.V. Ratnam and U.R. Raju, “Effect of mineral admixture on properties of self compacting concrete,” International Journal for Innovative Research in Science & Technology, vol.1, no. 11, pp. 503-511, April 2015.
[4] Okamura H., and Ouchi M., (2003). Self-Compacting Concrete. Journal of Advanced Concrete Technology Vol.1, No 1, pp5-15.
[5] M. Ouchi, S. Nakamura, T. Osterberg, S.E. Hallberg and M. Lwin, “Applications of self compacting concrete in Japon, Europe and the United States,” ISHPC, 2003.
[6] S.N. Tande and P.B. Mohite, “Applications of self compacting concrete,” 32nd Conference on Our World ın Concrete Structures, 28 - 29 August 2007, Singapore.
[7] Functional classification of lightweight concretes. (1978). RILEM.
[8] M. Kaffetzakis, and C.G. Papanicolaou, “Bond behavior of reinforcement in lightweight aggregate self-compacting concrete,” Construction and Buildings, vol. 113, pp. 641-652, 2016.
[9] C. Ozyildirim, “Durability of structural lightweight concrete,” Concrete Bridge Conference, St Louis, MO, 2008.
[10] T. Uygunoglu, I.B. Topçu, “Thermal expansion of self-consolidating normal and lightweight concrete at elevated temperature, “Construction and Building Materials, vol. 23, pp. 3063-3069, 2009.
[11] A. Kumar and R. Prakash, “Mechanical properties of structural light weight concrete by blending cinder & LEECA,” International Advanced Research Journal in Science, Engineering and Technology, vol. 2, no. 10, October, 2015.
[12] Wilson, N.S. 2003. Effect of mositure and porosity on the thermal properties of a conventional refractorty concrete. Journal of the European Seramic Society, 23, 745-755.
[13] M. Uysal and K. Yılmaz, “Effect of mineral admixtures on properties of self-compacting concrete,” Cement Concrete Composites, vol. 33, no. 7, pp. 771-776, August 2011.
[14] FMA. Filho, BE. Barragán, JR. Casas and ALHC. El Debs “Hardened properties of self compacting concrete – a statistical approach,” Construction Building Materials, vol. 24, pp. 1608–1615, 2013.
[15] O. Gencel, C. Ozel, F. Köksal, G.M. Barrerae and W. Brostowf “Properties of concrete paving blocks made with waste marble,” Journal of Cleaner Production, Vol 21, No 1, 62-70.
[16] T. Uygunoğlu, İ.B. Topçu and A.G. Çelik, “Use of waste marble and recycled aggregates in self-compacting concrete for environmental sustainability,” Journal of Cleaner Production, Vol 84, No 1, 691-700.
[17] S. Juradin and G. Boloevic, 2012. Experimental Testing of the Effects of Fine Particles on the Properties of the SCC, Advances in Material Science and Engineering.
[18] Aukour F.J. and Al-Qinna, M.I. 2008. Marble Production and Environmental Constrains: Case Study from Zarqa Governorate, Jordan Journal of Earth and Environmental Sciences, Vol 1, No 1, 11-21.
[19] Alyamaç, K.E., and Ince, R., (2009). A preliminary concrete mix design for SCC with marble powders. Construction and Building Materials, 23, 1201-1210.
[20] TS EN 197-1 (2005). “Cement. Part 1: compositions and conformity criteria for common cements”. Turkish Standards Institutions, Ankara.
[21] TS 706 EN 12620 (2009). “Aggregates for concrete”. Turkish Standards Institutions, Ankara.
[22] TS EN 12350-8 (2011). Testing fresh concrete - Part 8: Self-compacting concrete - Slump-flow test.
[23] TS EN 12350-9 (2011). Testing fresh concrete - Part 8: Self-compacting concrete - V funnel test
[24] EFNARC. (2005). The European guidelines for self compacting concrete: Specification, production and use. Cambridge, UK: The Self-Compacting Concrete European Project Group.ESCSI. (2004).
[25] ASTM C597, “Standard Test Method for Pulse Velocity through Concrete”. Standard ASTM C597-83, American Society for Testing Materials, Philadelphia, 2002.
[26] TS EN 12390–3, “Testing Hardened Concrete – Part 3: Compressive Strength of Test Specimens”, Turkish Standard, Turkey (in Turkish), 2003.
@article{"International Journal of Architectural, Civil and Construction Sciences:74555", author = "Z. Funda Türkmenoğlu and Mehmet Türkmenoglu and Demet Yavuz and ", title = "Using Waste Marbles in Self Compacting Lightweight Concrete", abstract = "In this study, the effects of waste marbles as aggregate material on workability and hardened concrete characteristics of self compacting lightweight concrete are investigated. For this purpose, self compacting light weight concrete are produced by waste marble aggregates are replaced with fine aggregate at 5%, 7.5%, and 10% ratios. Fresh concrete properties, slump flow, T50 time, V funnel, compressive strength and ultrasonic pulse velocity of self compacting lightweight concrete are determined. It is concluded from the test results that using waste marbles as aggregate material by replacement with fine aggregate slightly affects fresh and hardened concrete characteristics of self compacting lightweight concretes.
", keywords = "Hardened concrete characteristics, self compacting lightweight concrete, waste marble, workability. ", volume = "10", number = "12", pages = "1636-4", }
