An Experimental Study to Evaluate the Properties of a Clayey Silt Treated with Lime for the Manufacture of Mud Bricks

Louis Ahouet *

Institut Supérieur d’ Architecture, Urbanisme, Bâtiment et Travaux Publics, Université Denis SASSOU N’GUESSO – Brazzaville, Congo, Département de Génie Civil, Ecole Nationale Supérieure Polytechnique, Université Marien Ngouabi, – Brazzaville, Congo and Bureau de Contrôle du Bâtiment et Travaux Publics (BCBTP) – Brazzaville, BP-752, Congo.

Sylvain Ndinga Okina

Institut Supérieur d’ Architecture, Urbanisme, Bâtiment et Travaux Publics, Université Denis SASSOU N’GUESSO – Brazzaville, Congo and Département de Génie Civil, Ecole Nationale Supérieure Polytechnique, Université Marien Ngouabi, – Brazzaville, Congo.

Alain Symphorien Ndongo

Institut Supérieur d’ Architecture, Urbanisme, Bâtiment et Travaux Publics, Université Denis SASSOU N’GUESSO – Brazzaville, Congo.

*Author to whom correspondence should be addressed.


Abstract

This work involved evaluating the properties of Cubitermes sp termite mound soil treated with 3 - 9% lime for the manufacture of adobe mud bricks and compressed earth bricks CEBs. X-Ray Diffraction and other geotechnical methods for soil characterisation were used to analyse the selected material samples. The results show that the soil is a class A-2 clayey silt with a low organic content, composed of 19.18% clay, 47.20% silt and a sand content of 23.62%. The addition of lime reduces the clay and silt content, while the sand content increases and improves the granulometry, which incorporates spindles (adobes and CEBs) with lime contents ranging from 5% to 9%. The clay content of both the raw soil and the mixes is below the 30% maximum, while the sand content of the mixes is above the 30% minimum permitted by most standards. The specific surface area SSA and cation exchange capacity CEC decrease with the addition of lime, and the mechanical properties of the material improve. Raw soil and mixes have good moulding properties and a compressive strength of CS (3.89 - 5.95 MPa) suitable for the manufacture of adobe bricks and CEBs. The microstructure shows that the soil in the Cubitermes sp termite mound is composed of kaolinite, illite, smectite, quartz, calcite and iron oxide (haematite). Kaolinite is important for making solid bricks and illite helps the soil to sinter at a relatively low temperature.

Keywords: Earth bricks, Cubitermes sp termite mound soil, adobes, clay, granulometry


How to Cite

Ahouet , Louis, Sylvain Ndinga Okina, and Alain Symphorien Ndongo. 2024. “An Experimental Study to Evaluate the Properties of a Clayey Silt Treated With Lime for the Manufacture of Mud Bricks”. Journal of Materials Science Research and Reviews 7 (1):30-40. https://journaljmsrr.com/index.php/JMSRR/article/view/308.


References

Houben H, Guillard H. Treatise on earthen construction craterre. In: The Encyclopaedia of Earth Construction.Paris : Parenthèses. 1989;1:300.

Guillaud H. Characterization of earthen materials. In: Avrami E, Guillaud H, Hardy M, editors. Terra literature review - an overview of research in earthen architecture conservation. Los Angeles: The Getty conservation Institute. 2008;21-31.

Louis Ahouet, Mondésire Odilon Ngoulou, Sylvain Ndinga Okina. Evaluation of the geotechnical properties of cubitermes sp and macrotermes sp termite mound soils for the manufacture of earth bricks. Saudi Journal of Civil Engineering. 2023;7(7):146-157.

Shantanu Paul, Mohammad Shariful Islam, Mohammad Iqbal Hossain. Suitability of Vetiver straw fibers in improving the engineering characteristics of compressed earth blocks. Construction and Building Materials. 2023;409. Available:https://doi.org/10.1016/j.conbuildmat.2023.134224.

Hadjri K, Osmani M, Baiche B, Chifunda C. Attitude towards earth building for zambian housing provision, proceeding of the institutions of civil engineers: Engineering sustainability. 2007;160 (ES3):141-149.

Rogers CD, Glendinning S. Lime requirement for stabilization, Transportation research Record: Journal of the Transportation Research Board. 20001;721.

Van Damme H, Houben H. Earth concrete. Stabilization revisited, Cem. Concr. Res; 2017. Available:http://dx.doi.org/10.1016/j.cemconres.2017.02.035

Manasseh J, Olufemi AT. Effect of lime on some geotechnical properties of igumale shale. Electronic Journal of Geotechnical Engineering. 2008;13:1-12.

Coks G, Keeley R, Leek C, Foley P, Bond T, Crey A, Paige-Green P, Emery S, Clayton R, Iness Mc D. The use of naturally occurring materials for pavements in western Australia. Australian Geomechanics, 2015;30;1.

Osula DOA. A comparative evaluation of cement and lime modification of laterite. Engineering geology. 1996;42(1):71-81.

Attoh Okie NO. Lime treatment of laterite soils and gravels revisited construction and building materials. 1995;9(5):283-287.

Thi Thanh Hang Nguyen, Thèse de doctorat. Stabilisation des sols traités à la chaux et leur comportement au gel. 2015;19-20,317p.

Shantanu Paul, Mohammad Shariful Islam, Mohammad Iqbal Hossain. Suitability of Vetiver straw fibers in improving the engineering characteristics of compressed earth blocks. 2023;409:134224. Available:https://doi.org/10.1016/j.conbuildmat.2023.134224

NF P94-056 French standard. Soil: investigation and testing – Granulometric analysis. Dry sieving method after washing; 1996.

NF P94-057 French standard. The granulometric analysis by sieving of soil for grains smaller than 80m; 2018.

NF P 94-051 French standard. Soils: Reconnaissance and testing. Determination of atterberg limits; limit of liquidity at compelled – Limit of plasticity at Rouleau; 1993.

NF P94-068 French standard. NF P94-068. Soils: Investigation and testing – Measuring of the methylene blue adsorption capacity of a rocky soil. Determination of the methylene blue of a soil by means of the strain test; 1998.

NF P94-093 French standard. Soils: Reconnaissance and testing. Determination of the compaction references of a material; 1999.

Delgado MCJ, Guerrero JC. The selection of soils for instabilised earth building: A normative review. Construction and Building Materials. 2007;21:237-251.

NTE E80, Peru. Little recommendations and these are for granularity (Adobe); 2000.

Smith EW, Austin GS. Adobe, pressed-earth and rammed earth industries in New Mexico, Bulletin 159. Socorro, NM: New Mexico Bureau of Mines and Mineral Resources; 1996.

Houben H, Guillaud H. Earth construction: a comprehensive Guide. London: Intermediate Technology Publications; 1994.

ARSO. Regional Africa. Granularity and plasticity nomograms. Classification by nature. Enumerate and classify the soil test, not procedure explained (Compressed earth blocks); 1996.

AFNOR XP P13-901 (2001). Granularity and plasticity nomograms. Classification by nature for the soil evaluation (Compressed earth blocks).

Delgado MCJ, Guerrero IC. The selection of soils for unstabilized earth building: A normative review. Construction and Building Materials, 2007l;21:237–251.

Jana Madejova and Peter Komadel. Baseline studies of the clay minerals society source Clays: infrared methods. Clays and Minerals. 2001;49(5):410-432,2(X)I.

Available:https://doi:10.1346/CCMN.2001.0490508.

Nayak PS, Singh BK. Instrumental characterization of clay by XRF, XRD and FTIR. Bull Mater Sci. 2007;30:235–238. Available:https://doi.org/10.1007/s12034-007-0042-5

Louis Ahouet, Sylvain Ndinga Okina, Joseph Arsène Bockou Ekockaut. Efect of lime addition on the particle size fractions and microstructure of a clayey silt. Arabian Journal of Geosciences. 2023;16:548. Available:https://doi.org/10.1007/s12517-023-11625-5

Brandl, alteration of soil parameters by stabilization with lime. Proceedings of the 10th international conference on soil mechanics and foundations stockholm, Suede. 1981;587-594.