Authors: Amir Mahmoudi

Abstract:

In this research the effects of adding silica and alumina nanoparticles on flow ability and compressive strength of cementitious composites based on Portland cement were investigated. In the first stage, the rheological behavior of different samples containing nanosilica, nanoalumina and polypropylene, polyvinyl alcohol and polyethylene fibers were evaluated. With increasing of nanoparticles in fresh samples, the slump flow diameter reduced. Fibers reduced the flow ability of the samples and viscosity increased. With increasing of the micro silica particles to cement ratio from 2/1 to 2/2, the slump flow diameter increased. By adding silica and alumina nanoparticles up to 3% and 2% respectively, the compressive strength increased and after decreased. Samples containing silica nanoparticles and fibers had the highest compressive strength.

Keywords: Portland cement, Composite, Nanoparticles, Compressive Strength.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1099358

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1909

References:

[1] Nazari, S. Riahi, Al2O3 nanoparticles in concrete and different curing media, Energy and Buildings, 43, 2011, 1480-1488.
[2] B. W. Jo, C. H. Kim, G. H. Tae, and J. B. Park, Characteristics of cement mortar with nano-SiO2 particles, Construction and Building Materials, 21, 2007, 1351-1355.
[3] W. Y. Kuo, J. S. Huang, C. H. Lin, Effects of organo-modified montmorillonite on strengths and permeability ofcement mortars, Cement and Concrete Research, 36, 2006, 886 – 895.
[4] J. Chen, S. C. Kou, C. S. Poon, Hydration and properties of nano-TiO2 blended cement composites, Cement & Concrete Composites, 34, 2012, 642–649.
[5] L. Raki, J. Beaudoin, R. Alizadeh, J. Makar, T. Sato, Cement and Concrete Nanoscience and Nanotechnology, Materials, 3, 2010, 918- 942.
[6] D. Abdullah, T.R. Pitt Ford, S. Papaioannou, J. Nicholson, F. McDonald, An evaluation of accelerated Portland cement as a restorative material, Biomaterials, 23, 2002, 4001-4010.
[7] M.G. Gandolfi, F. Perut, G. Ciapetti, R. Mongiorgi, C. Prati, New Portland Cement–based Materials for Endodontics Mixed with Articaine Solution: A Study of Cellular Response, Journal of Endodontics, 34, 2008, 39-44.
[8] A.L. Gomes Cornélio, L.P. Salles, M. Campos da Paz, J.A. Cirelli, J.M. Guerreiro-Tanomaru, M. Tanomaru Filho, Cytotoxicity of Portland Cement with Different Radiopacifying Agents: A Cell Death Study, Journal of Endodontics, 37, 2011, 203-210.
[9] D.A. Ribeiro, M.A.H. Duarte, M.A. Matsumoto, M.E.A. Marques, D.M.F. Salvadori, Biocompatibility In Vitro Tests of Mineral Trioxide Aggregate and Regular and White Portland Cements, Journal of Endodontics, 31 (2005) 605-607.
[10] S. Shahi, S. Rahimi, H.R. Yavari, H. Mokhtari, L. Roshangar, M.M. Abasi, S. Sattari, M. Abdolrahimi, Effect of Mineral Trioxide Aggregates and Portland Cements on Inflammatory Cells, Journal of Endodontics, 36, 2010, 899-903.
[11] N. Wongkornchaowalit, V. Lertchirakarn, Setting Time and Flowability of Accelerated Portland Cement Mixed with Polycarboxylate Superplasticizer, Journal of Endodontics, 37, 2011, 387-389.
[12] M. D. Lepech, V. C. Li, Water permeability of engineered cementitious composites, Cement & Concrete Composites, 31, 2009, 744-753.
[13] M. Şahmaran, V. C. Li, De-icing salt scaling resistance of mechanically loaded engineeredcementitious composites, Cement and Concrete Research, 37, 2007, 1035-1046.
[14] A. Spagnoli, A micromechanical lattice model to describe the fracture behaviour ofengineered cementitious composites, Computational Materials Science, 46, 2009, 7-14.
[15] C. Panganayi, H. Ogata, K. Hattori, Effect of plate thickness on crack propagation characteristics of engineered cementitious composites, Asian Journal of Applied Sciences, 4, 2011, 542-547.