How to cite this paper
Hashemi, S. (2014). Experimental study on mechanical properties of different lightweight aggregate concretes.Engineering Solid Mechanics, 2(3), 201-208.
Refrences
Aliha, M. R. M., Heidari-Rarani, M., Shokrieh, M. M., & Ayatollahi, M. R. (2012). Experimental determination of tensile strength and K (IC) of polymer concretes using semi-circular bend(SCB) specimens. Structural Engineering and Mechanics, 43(6), 823-833.
Aliha, M. R. M., Behbahani, H., Fazaeli, H., & Rezaifar, M. H. (2014). Study of characteristic specification on mixed mode fracture toughness of asphalt mixtures. Construction and Building Materials, 54, 623-635.
Aliha, M. R. M., & Ayatollahi, M. R. (2009). Brittle fracture evaluation of a fine grain cement mortar in combined tensile?shear deformation. Fatigue & Fracture of Engineering Materials & Structures, 32(12), 987-994.
Ameri, M., Mansourian, A., Pirmohammad, S., Aliha, M. R. M., & Ayatollahi, M. R. (2012).Mixed mode fracture resistance of asphalt concrete mixtures. Engineering Fracture Mechanics, 93, 153-167.
Andiç-Cak?r, ?., & H?zal, S. (2012). Influence of elevated temperatures on the mechanical properties and microstructure of self consolidating lightweight aggregate concrete. Construction and Building Materials, 34, 575-583.
Beigi, M. H., Berenjian, J., LotfiOmran, O., SadeghiNik, A., & Nikbin, I. M. (2013).An experimental survey on combined effects of fibers and nanosilica on the mechanical, rheological, and durability properties of self-compacting concrete. Materials & Design, 50, 1019-1029.
Bogas, J. A., & Gomes, A. (2013).Compressive behavior and failure modes of structural lightweight aggregate concrete–Characterization and strength prediction. Materials & Design, 46, 832-841.
Cheng, C. M., Su, D. G., He, J., & Jiao, C. J. (2012).Compressive Strength of Organic Lightweight Aggregate Concrete. Advanced Materials Research, 374, 1531-1536.
Chi, J. M., Huang, R., Yang, C. C., & Chang, J. J. (2003).Effect of aggregate properties on the strength and stiffness of lightweight concrete. Cement and Concrete Composites, 25(2), 197-205.
Gao, Y., Cheng, L., Gao, Z., & Guo, S. (2013). Effects of different mineral admixtures on carbonation resistance of lightweight aggregate concrete. Construction and Building Materials, 43, 506-510.
Go, C. G., Tang, J. R., Chi, J. H., Chen, C. T., & Huang, Y. L. (2012). Fire-resistance property of reinforced lightweight aggregate concrete wall. Construction and Building Materials, 30, 725-733.
Hassanpour, M., Shafigh, P., & Mahmud, H. B. (2012).Lightweight aggregate concrete fiber reinforcement–a review. Construction and Building Materials, 37, 452-461.
Heidari-Rarani, M., Aliha, M. R. M., Shokrieh, M. M., & Ayatollahi, M. R. (2014). Mechanical durability of an optimized polymer concrete under various thermal cyclic loadings- An experimental study. Construction and Building Materials, Doi: 10.1016/j.conbuildmat.2014.04.031
Hussain, H. K., Liu, G. W., & Yong, Y. W. (2014). Experimental study to investigate mechanical properties of new material polyurethane–cement composite (PUC).Construction and Building Materials, 50, 200-208.
Ibrahim, A., Mahmoud, E., Yamin, M., & Patibandla, V. C. (2014).Experimental study on Portland cement pervious concrete mechanical and hydrological properties. Construction and Building Materials, 50, 524-529.
Kayali, O., Haque, M. N., & Zhu, B. (1999).Drying shrinkage of fibre-reinforced lightweight aggregate concrete containing fly ash. Cement and concrete research, 29(11), 1835-1840.
Kim, H. K., Jeon, J. H., & Lee, H. K. (2012).Workability, and mechanical, acoustic and thermal properties of lightweight aggregate concrete with a high volume of entrained air. Construction and Building Materials, 29, 193-200.
Libre, N. A., Shekarchi, M., Mahoutian, M., & Soroushian, P. (2011). Mechanical properties of hybrid fiber reinforced lightweight aggregate concrete made with natural pumice. Construction and Building Materials, 25(5), 2458-2464.
Lo, T. Y., Tang, W. C., & Cui, H. Z. (2007). The effects of aggregate properties on lightweight concrete. Building and Environment, 42(8), 3025-3029.
Mahmud, H., Shafigh, P., & Jumaat, M. Z. (2014).Structural lightweight aggregate concrete containing high volume waste materials. Key Engineering Materials, 594, 498-502.
Mills-Beale, J., & You, Z. (2010).The mechanical properties of asphalt mixtures with recycled concrete aggregates. Construction and Building Materials, 24(3), 230-235.
Mouli, M., & Khelafi, H. (2008).Performance characteristics of lightweight aggregate concrete containing natural pozzolan. Building and environment, 43(1), 31-36.
Nabavi, F., Nejadi, S., & Samali, B. (2013). Experimental investigation on mix design and mechanical properties of polymer (Latex) modified concrete. Advanced Materials Research, 687, 112-117.
Pan, L. Y., Yuan, H., & Zhao, S. B. (2011). Experimental study on mechanical properties of hybrid fiber reinforced full lightweight aggregate concrete. Advanced Materials Research, 197, 911-914.
Paul, S. C., & van Zijl, G. P. (2013). Mechanical and durability properties of recycled concrete aggregate for normal strength structural concrete. International Journal of Sustainable Construction Engineering and Technology, 4(1), 89-103.
Rossignolo, J. A., & Agnesini, M. V. (2002). Mechanical properties of polymer-modified lightweight aggregate concrete. Cement and Concrete Research, 32(3), 329-334.
Rossignolo, J. A., & Agnesini, M. V. (2004). Durability of polymer-modified lightweight aggregate concrete. Cement and Concrete Composites, 26(4), 375-380.
Sari, D., & Pasamehmetoglu, A. G. (2005).The effects of gradation and admixture on the pumice lightweight aggregate concrete. Cement and concrete research, 35(5), 936-942.
Shafigh, P., Jumaat, M. Z., & Mahmud, H. (2010). Mix design and mechanical properties of oil palm shell lightweight aggregate concrete: A review. International Journal of the Physical Sciences, 5(14), 2127-2134.
SoleymaniAshtiani, M., Scott, A. N., & Dhakal, R. P. (2013).Mechanical and fresh properties of high-strength self-compacting concrete containing class C fly ash. Construction and Building Materials, 47, 1217-1224.
Tay, J. H., Yip, W. K., & Show, K. Y. (1991). Clay-blended sludge as lightweight aggregate concrete material. Journal of Environmental Engineering, 117(6), 834-844.
Thomas, M., & Bremner, T. (2012). Performance of lightweight aggregate concrete containing slag after 25years in a harsh marine environment. Cement and Concrete Research, 42(2), 358-364.
Uyguno?lu, T., & Topçu, ?. B. (2009).Thermal expansion of self-consolidating normal and lightweight aggregate concrete at elevated temperature. Construction and Building Materials, 23(9), 3063-3069.
Uyguno?lu, T., Brostow, W., Gencel, O., & Topçu, ?. B. (2013).Bond strength of polymer lightweight aggregate concrete. Polymer Composites, 34(12), 2125-2132.
Wang, H. Y., Sheen, Y. N., & Hung, M. F. (2010). Performance characteristics of dredged silt and high-performance lightweight aggregate concrete. Computers and Concrete, 7(1).
Wang, Y. W., & Tang, B. X. (2012).Experimental study of the foam agent in lightweight aggregate concrete. Applied Mechanics and Materials, 226, 1776-1779.
Wasserman, R., & Bentur, A. (1997).Effect of lightweight fly ash aggregate microstructure on the strength of concretes. Cement and Concrete Research, 27(4), 525-537.
Zhuang, Y. Z., Chen, C. Y., & Ji, T. (2013).Effect of shale ceramsite type on the tensile creep of lightweight aggregate concrete. Construction and Building Materials, 46, 13-18.
Aliha, M. R. M., Behbahani, H., Fazaeli, H., & Rezaifar, M. H. (2014). Study of characteristic specification on mixed mode fracture toughness of asphalt mixtures. Construction and Building Materials, 54, 623-635.
Aliha, M. R. M., & Ayatollahi, M. R. (2009). Brittle fracture evaluation of a fine grain cement mortar in combined tensile?shear deformation. Fatigue & Fracture of Engineering Materials & Structures, 32(12), 987-994.
Ameri, M., Mansourian, A., Pirmohammad, S., Aliha, M. R. M., & Ayatollahi, M. R. (2012).Mixed mode fracture resistance of asphalt concrete mixtures. Engineering Fracture Mechanics, 93, 153-167.
Andiç-Cak?r, ?., & H?zal, S. (2012). Influence of elevated temperatures on the mechanical properties and microstructure of self consolidating lightweight aggregate concrete. Construction and Building Materials, 34, 575-583.
Beigi, M. H., Berenjian, J., LotfiOmran, O., SadeghiNik, A., & Nikbin, I. M. (2013).An experimental survey on combined effects of fibers and nanosilica on the mechanical, rheological, and durability properties of self-compacting concrete. Materials & Design, 50, 1019-1029.
Bogas, J. A., & Gomes, A. (2013).Compressive behavior and failure modes of structural lightweight aggregate concrete–Characterization and strength prediction. Materials & Design, 46, 832-841.
Cheng, C. M., Su, D. G., He, J., & Jiao, C. J. (2012).Compressive Strength of Organic Lightweight Aggregate Concrete. Advanced Materials Research, 374, 1531-1536.
Chi, J. M., Huang, R., Yang, C. C., & Chang, J. J. (2003).Effect of aggregate properties on the strength and stiffness of lightweight concrete. Cement and Concrete Composites, 25(2), 197-205.
Gao, Y., Cheng, L., Gao, Z., & Guo, S. (2013). Effects of different mineral admixtures on carbonation resistance of lightweight aggregate concrete. Construction and Building Materials, 43, 506-510.
Go, C. G., Tang, J. R., Chi, J. H., Chen, C. T., & Huang, Y. L. (2012). Fire-resistance property of reinforced lightweight aggregate concrete wall. Construction and Building Materials, 30, 725-733.
Hassanpour, M., Shafigh, P., & Mahmud, H. B. (2012).Lightweight aggregate concrete fiber reinforcement–a review. Construction and Building Materials, 37, 452-461.
Heidari-Rarani, M., Aliha, M. R. M., Shokrieh, M. M., & Ayatollahi, M. R. (2014). Mechanical durability of an optimized polymer concrete under various thermal cyclic loadings- An experimental study. Construction and Building Materials, Doi: 10.1016/j.conbuildmat.2014.04.031
Hussain, H. K., Liu, G. W., & Yong, Y. W. (2014). Experimental study to investigate mechanical properties of new material polyurethane–cement composite (PUC).Construction and Building Materials, 50, 200-208.
Ibrahim, A., Mahmoud, E., Yamin, M., & Patibandla, V. C. (2014).Experimental study on Portland cement pervious concrete mechanical and hydrological properties. Construction and Building Materials, 50, 524-529.
Kayali, O., Haque, M. N., & Zhu, B. (1999).Drying shrinkage of fibre-reinforced lightweight aggregate concrete containing fly ash. Cement and concrete research, 29(11), 1835-1840.
Kim, H. K., Jeon, J. H., & Lee, H. K. (2012).Workability, and mechanical, acoustic and thermal properties of lightweight aggregate concrete with a high volume of entrained air. Construction and Building Materials, 29, 193-200.
Libre, N. A., Shekarchi, M., Mahoutian, M., & Soroushian, P. (2011). Mechanical properties of hybrid fiber reinforced lightweight aggregate concrete made with natural pumice. Construction and Building Materials, 25(5), 2458-2464.
Lo, T. Y., Tang, W. C., & Cui, H. Z. (2007). The effects of aggregate properties on lightweight concrete. Building and Environment, 42(8), 3025-3029.
Mahmud, H., Shafigh, P., & Jumaat, M. Z. (2014).Structural lightweight aggregate concrete containing high volume waste materials. Key Engineering Materials, 594, 498-502.
Mills-Beale, J., & You, Z. (2010).The mechanical properties of asphalt mixtures with recycled concrete aggregates. Construction and Building Materials, 24(3), 230-235.
Mouli, M., & Khelafi, H. (2008).Performance characteristics of lightweight aggregate concrete containing natural pozzolan. Building and environment, 43(1), 31-36.
Nabavi, F., Nejadi, S., & Samali, B. (2013). Experimental investigation on mix design and mechanical properties of polymer (Latex) modified concrete. Advanced Materials Research, 687, 112-117.
Pan, L. Y., Yuan, H., & Zhao, S. B. (2011). Experimental study on mechanical properties of hybrid fiber reinforced full lightweight aggregate concrete. Advanced Materials Research, 197, 911-914.
Paul, S. C., & van Zijl, G. P. (2013). Mechanical and durability properties of recycled concrete aggregate for normal strength structural concrete. International Journal of Sustainable Construction Engineering and Technology, 4(1), 89-103.
Rossignolo, J. A., & Agnesini, M. V. (2002). Mechanical properties of polymer-modified lightweight aggregate concrete. Cement and Concrete Research, 32(3), 329-334.
Rossignolo, J. A., & Agnesini, M. V. (2004). Durability of polymer-modified lightweight aggregate concrete. Cement and Concrete Composites, 26(4), 375-380.
Sari, D., & Pasamehmetoglu, A. G. (2005).The effects of gradation and admixture on the pumice lightweight aggregate concrete. Cement and concrete research, 35(5), 936-942.
Shafigh, P., Jumaat, M. Z., & Mahmud, H. (2010). Mix design and mechanical properties of oil palm shell lightweight aggregate concrete: A review. International Journal of the Physical Sciences, 5(14), 2127-2134.
SoleymaniAshtiani, M., Scott, A. N., & Dhakal, R. P. (2013).Mechanical and fresh properties of high-strength self-compacting concrete containing class C fly ash. Construction and Building Materials, 47, 1217-1224.
Tay, J. H., Yip, W. K., & Show, K. Y. (1991). Clay-blended sludge as lightweight aggregate concrete material. Journal of Environmental Engineering, 117(6), 834-844.
Thomas, M., & Bremner, T. (2012). Performance of lightweight aggregate concrete containing slag after 25years in a harsh marine environment. Cement and Concrete Research, 42(2), 358-364.
Uyguno?lu, T., & Topçu, ?. B. (2009).Thermal expansion of self-consolidating normal and lightweight aggregate concrete at elevated temperature. Construction and Building Materials, 23(9), 3063-3069.
Uyguno?lu, T., Brostow, W., Gencel, O., & Topçu, ?. B. (2013).Bond strength of polymer lightweight aggregate concrete. Polymer Composites, 34(12), 2125-2132.
Wang, H. Y., Sheen, Y. N., & Hung, M. F. (2010). Performance characteristics of dredged silt and high-performance lightweight aggregate concrete. Computers and Concrete, 7(1).
Wang, Y. W., & Tang, B. X. (2012).Experimental study of the foam agent in lightweight aggregate concrete. Applied Mechanics and Materials, 226, 1776-1779.
Wasserman, R., & Bentur, A. (1997).Effect of lightweight fly ash aggregate microstructure on the strength of concretes. Cement and Concrete Research, 27(4), 525-537.
Zhuang, Y. Z., Chen, C. Y., & Ji, T. (2013).Effect of shale ceramsite type on the tensile creep of lightweight aggregate concrete. Construction and Building Materials, 46, 13-18.