This work’s aim is to participate in local materials (raw or fiber improved), which can be used in sustainable and accessible buildings to every Senegalese. To do this, studied materials are respectively collected from a laterite clay pit in Ndouloumadjie Dembe (Matam, Northern Senegal) and another from a termite mound in Tattaguine (Fatick, Central Senegal). These samples are first subjected to Geotechnical identification tests. Mud bricks are then made with raw or sifted millet involucre improved to 1%, 2%, and 3% at 5 mm sieve samples. These briquettes are subjected to compression tests and thermal evaluations. Lagrange and Newton methods of numeric modelling are used to test the whole mixture points between 1% and 3% millet involucre for a better correlation between mechanical and thermal parameters. The results show that in Matam, as well as in Tattaguine, these muds, raw or improved, are of good thermomechanical quality when they are used in bricks making. And the thermomechanical coupling quality reaches a maximum situated at 2.125% for Ndouloumadjie and 2.05% for Tattaguine. These briquettes’ building quality depends on the mud content used in iron, aluminum, silica and clay. Thus, same natural materials can be used in the establishment of habitats according to their geotechnical, chemical, mechanical and thermal characteristics.
References
[1]
Fall, M., Sarr, D., Cissé, E.M. and Konaté, D. (2021) Physico-Mechanical Characterization of Clay and Laterite Bricks Stabilized or Not with Cement. OpenJournalofCivilEngineering, 11, 60-69. https://doi.org/10.4236/ojce.2021.111004
[2]
Kouakou, C.H. and Morel, J.C. (2009) Strength and Elasto-Plastic Properties of Non-Industrial Building Materials Manufactured with Clay as a Natural Binder. Applied ClayScience, 44, 27-34. https://doi.org/10.1016/j.clay.2008.12.019
[3]
Bruno, A.W., Gallipoli, D., Perlot-Bascoules, C., Mendes, J. and Salmon, N. (2015) Briques de terre crue: Procédure de compactage haute pression et influence sur les propriétés mécaniques. Rencontres Universitaires de Génie Civil.
[4]
BACHIR (2014) Etude du comportement physico-Mécanique du bloc de terre comprimée avec fibre. Thèse de Doctorat de Génie Civil, Université Mohamed Khider, 183 p.
[5]
Fall, M., Mbengue, A., Gueye, N.S. and Sall, O.A. (2021) Physico-Mechanical Characterization of Composite Bricks from Laterite, Typha and/or Rice Hull. AmericanJournalofCivilEngineeringandArchitecture, 9, 9-12.
[6]
FAYCAL (2013) Conception, production et qualification des briques de terre cuite et en terre crue. Thèse de Doctorat de Génie Civil, Ecole Centrale de Lille, 123 p.
[7]
Eurocode 6 (1996) Calcul des ouvrages en maçonnerie. AFNOR-CEN. Envi.
[8]
Kabore, M. (2015) Enjeux de la simulation pour l’étude des performances énergétiques des bâtiments en Afrique sub-saharienne. Thèse de Doctorat de Génie Civil et Sciences de l’Habitat, Université de Grenoble, 195 p.
[9]
Minke, G. (2006) Building with Earth Design and Technology of the Sustainable Architecture. Birkhäuser—Publisher for Architecture, 207 p.
[10]
Roger, J., Noel, B.J., Barusseau, J.P., Serrano, O., Nehlig, P. and Duvail, C. (2009) Notice explicative de la carte géologique du Sénégal à 1/500000, feuilles nord-ouest, nord-est et sud-ouest. Ministère des Mines, de l’Industrie et des PME, Direction des Mines et de la Géologie, 61 p.
[11]
Brezinski, C. and Redivo-Zaglia, M. (2013) Interpolation, approximation et extrapolation rationnelles. Techniques de l’Ingénieur, AF1390 V1. https://doi.org/10.51257/a-v1-af1390
[12]
Brezinski, C. and Redivo-Zaglia, M. (2020) Extrapolation and Rational Approximation. Springer Nature. https://doi.org/10.1007/978-3-030-58418-4
