Damene ZİNEB, Goual Mohammed SAYAH, Saiti ISSAM

Valorisation of Dune Sand and Wase Brick Filler in Elaboration of Cellular Concrete: Mechanical and Thermal Properties

The aim of this work is both to enhance the dune sand in the production of lightweight concrete with local resources, but also enhances the performance of the sandcrete by incorporating fines mineral as fines from waste of brick. Different parameters were studied, in which the quantity of substitution of fines in the dune sand, the proportions substitutions of lime in the cement, the dosage of expansive agent. The result shows that it is possible to producing lightweight concrete suited to the hot and arid environment with an acceptable heat insulation and sufficient compressive strength. The greatest introduced porosity and lowest density are reached from composition without lime and with 0.5 % Al.

Anahtar Kelimeler:

Brick wastes, Cellular concrete, Dune Sand, Lime

Valorisation of Dune Sand and Wase Brick Filler in Elaboration of Cellular Concrete: Mechanical and Thermal Properties

Keywords:

Brick wastes, Cellular concrete, Dune Sand, Lime,

PDF

___

I. K. Cisse, M. Laquerbe. Mechanical characterization of filler sandcretes with rice husk ash additions : Study applied of Senegal. Cement and Concrete Research 30; 2000 ; 13-18.
A. S. Al-Harthy, M. Abdelhalim, R. Taha, K. S. Aljabri. The properties of concrete made with fine dune sand. Construction and Building Material 21; 2007 ; 1803-1808.
H. Wajahat, Mirza, Solman, I. Al- Noury. Utilisation of Saoudi sands for aerated concrete production. The International Journal of Cement and Composites and Lightweight Concrete. Volume 8, number 2; May 1986.
N. Narayanan, K. Ramamurthy. Structure and properties of aerated concrete: a review. Cement & Concrete Composites 22 ; 2000 ; 321-329.
R. Cabrillac, B. Fiorio, A. Liss Beaucour, H. Dumontet, S. Ortola. Experimental study of the mechanical anisotropy of aerated concretes and of the adjustment parameters of the introduced porosity. Construction and Building Materials 20 ; 2006 ; 286-295.
Shrivastava OP. Lightweight concrete – a review. Indian Concrete Journal 51; 1977; 10-23.
FC. McCormick. Rational proportioning of performed foam cellular concrete. ACI Material Journal 64 ; 1967 ; 104-109.
C. Guegan, P. Legras, J.F. Mazzoleni, C. Colin, T. Breiner, N. Foussier. Mémento du béton cellulaire. Grouppe Eyrolle; 2005.
P. Lawrance, M. Cyr, E. Ringot. Mineral admixtures in mortars effect of type, amount and fineness of fine constituents on compressive strength. Cement and Concrete Research 35; 2005 ; 1092-1105.
M. Cyr, P. Lawrance, E. Ringot. Efficiency of mineral admixtures in mortars: quantification of the physical and chemical effects of fine admixtures in relation with compressive strength. Cement and Concrete Research 36; 2006 ; 264-277.
U. Chinje Melo, N. Billong. Activité pouzzolanique des déchets de briques et tuiles cuites. African Journal of Science and Technology, Science and Engineering Serie ; Volume 5 ; numéro 1 ; pp 92- 100.
KL. Watson, NB Eden, JR Farrant. Autoclaved aerated mateials from slate powder and portland cement. Precast concrete ; 1977 ; 81-85.
TG. Richard. Low temperature behavior of cellular concrete. J Am Conc Inst ; 47 ; 1977 ; 173-178.
RC. Valore. Insulation concrete. J Am Conc Inst ; 28 ; 1956 ; 509-532.
JL. Kass, Allen D. Campbell. Functional classification of lightweight concrete. Matériaux et Construction ; Volume 5 ; N° 27 ; pp 171-172.