Effect of Coconut Fiber and Expired Cement on the Physical-Mechanical and Thermal Properties of Adobe Blocks

Russell Jeanpierre Laureano  Hurtado; Sandra Milena Melo  Vasquez; Doris Martinez  Asto; Manuel Ismael Laurencio  Luna

doi:10.22146/jcef.22352

Russell Jeanpierre Laureano Hurtado Faculty of Civil Engineering, Continental University, 12001, Huancayo, PERU
Sandra Milena Melo Vasquez Faculty of Civil Engineering, Continental University, 12001, Huancayo, PERU
Doris Martinez Asto Faculty of Civil Engineering, Continental University, 12001, Huancayo, PERU
Manuel Ismael Laurencio Luna Faculty of Civil Engineering, Continental University, 12001, Huancayo, PERU

DOI: https://doi.org/10.22146/jcef.22352

Keywords: Adobe, Coconut fiber, Expired cement, Thermal conductivity, Water absorption, Mechanical strength

Abstract

Adobe remains an essential construction material for rural housing in the Andean highlands, yet its performance is limited by high water absorption, insufficient durability, and moderate mechanical strength. This study systematically evaluated the effect of combined coconut fiber and expired cement additions on the mechanical, hygrothermal, and economic properties of adobe blocks and walls. Soil was characterized, and blocks were reinforced with coconut fiber (0.6%, 0.9%, 1.2%, 1.5% by weight) and expired cement (3%, 6%, 9%), both by weight of dry soil. A total of 135 samples underwent tests for compressive, tensile, and flexural strength, water absorption, thermal conductivity, and wall compressive performance. Statistical analysis using ANOVA confirmed highly significant improvements (p < 0.0001) across all evaluated properties. The optimal mixture, comprising 0.9% coconut fiber and 9% expired cement, achieved a compressive strength of 37.86 kg.cm^-2, nearly double that of the control sample (adobe without additives), which reached 17.69 kg.cm^-2, while wall compressive strength reached 33.9 kg.cm^-2. Tensile and flexural strengths increased to 11.43 kg.cm^-2 and 19.78 kg.cm-2, respectively; water absorption decreased to 7.82%, and thermal conductivity was reduced to 0.52 W.m^-1.K^-1. Economically, the improved adobe presented a unit cost of S/ 154.14 per m² (Peruvian soles), 27% higher than the control sample, although offset by notable gains in durability and overall performance. In summary, the combined use of coconut fiber and expired cement in adobe yields statistically validated improvements in structural, hygrothermal, and economic behavior, offering a practical and sustainable alternative for resilient rural housing in high altitude regions.

References

Abbas, W. A. and Ibrahim, H. A. (2023), ‘Fresh properties of self-consolidating expired cement-fly ash cold bonded lightweight aggregate concrete with different mineral admixtures’, Engineering and Technology Jour-nal 41(5). URL: https://www.iasj.net/iasj/article/283206

Abdulla, K. F., Cunningham, L. S. and Gillie, M. (2021), ‘Out-of-plane strengthening of adobe masonry using hemp fibre ropes: An experimental investigation’, Engineering Structures 245, 112931. URL: https://doi.org/10.1016/j.engstruct.2021.112931

Al-Osta, M. A., Isa, M. N., Baluch, M. H. and Rahman, M. K. (2017), ‘Flexural behavior of reinforced concrete beams strengthened with ultra-high performance fiber reinforced concrete’, Construction and Building Materials 134, 279–296. URL: https://doi.org/10.1016/j.conbuildmat.2016.12.094

Araya-Letelier, G. et al. (2021), ‘Experimental evaluation of adobe mixtures reinforced with jute fibers’, Construction and Building Materials 276, 122127. URL: https://doi.org/10.1016/j.conbuildmat.2020.122127

ASTM International (2021), ‘C518 standard test method for steady-state thermal transmission properties by means of the heat flow meter apparatus’. URL: https://store.astm.org/c0518-21.html

Balador, Z. (2024), Agricultural by-products as construction materials, in ‘Sustainability and Toxicity of Building Materials’, Elsevier, pp. 263–287. URL: https://doi.org/10.1016/B978-0-323-98336-5.00013-3

Balasubramanian, N. and Sarangapani, C. (2024), ‘A review on the factors influencing the performance of sustainable ternary cement composites’, Environment, Development and Sustainability 26(10), 24569–24596. URL: https://doi.org/10.1007/s10668-023-03685-0

Baquedano Juliá, P., Stellacci, S. and Poletti, E. (2024), ‘Evaluation of retrofitting techniques for historical adobe constructions using a multi-criteria decision analysis: The case study of chile’, International Journal of Architectural Heritage 18(1), 40–63. URL: https://doi.org/10.1080/15583058.2022.2103476

Bertelsen, I. M. G., Belmonte, L. J., Fischer, G. and Ottosen, L. M. (2021), ‘Influence of synthetic waste fibres on drying shrinkage cracking and mechanical properties of adobe materials’, Construction and Building Materials 286, 122738. URL: https://doi.org/10.1016/j.conbuildmat.2021.122738

Boukaré et al. (2024), ‘Improvement of mechanical qualities of clay material through coconut fiber stabilization’, Materials Sciences and Applications 15(7), 201–212. URL: https://doi.org/10.4236/msa.2024.157014

Caballero-Caballero, M., Chinas-Castillo, F., Montes Bernabé, J. L., Alavéz-Ramirez, R. and Silva Rivera, M. E. (2018), ‘Effect on compressive and flexural strength of agave fiber reinforced adobes’, Journal of Natural Fibers 15(4), 575–585. URL: https://doi.org/10.1080/15440478.2017.1349709

Cecilia, N. et al. (2025), ‘Analysis of the mechanical properties of adobe with chillihua fibre and recycled ldpe for sustainable construction in the andes’, Civil Engineering and Architecture 13(1), 193–209. URL: https://doi.org/10.13189/cea.2025.130111

Chofore, A. T., Mitikie, B. B. and Haile, A. T. (2022), ‘Experimental investigation on bond, microstructure and durability of expired hardened cement blended with ground granulated blast furnace slag as partial replacement of cement in high-strength concrete’, International Journal of Concrete Structures and Materials 16(1), 1–15. URL: https://doi.org/10.1186/s40069-022-00560-6

Circular Ecology (2025), ‘En15804 modules explained’. URL: https://circularecology.com/en15804-modulesexplained.html

da Silva, N. A. et al. (2024), ‘Influence of coconut fiber incorporation on the mechanical behavior of adobe blocks’, Agronomy Research 22(Special Issue 3), 0–0. URL: https://doi.org/10.15159/ar.24.064

Danso, H. (2017), ‘Properties of coconut, oil palm and bagasse fibres: As potential building materials’, Procedia Engineering 200, 1–9. URL: https://doi.org/10.1016/j.proeng.2017.07.002

Dao, K., Ouedraogo, M., Millogo, Y., Aubert, J. E. and Gomina, M. (2018), ‘Thermal, hydric and mechanical behaviours of adobes stabilized with cement’, Construction and Building Materials 158, 84–96. URL: https://doi.org/10.1016/j.conbuildmat.2017.10.001

Fidjah, A. et al. (2024), ‘The effect of glass and palm fibers on the mechanical and thermal properties of compressed earth blocks (ceb) stabilized with cement’, Journal of Natural Fibers 21(1). URL: https://doi.org/10.1080/15440478.2024.2397809

Gallipoli, D. et al. (2022), Durability of earth materials: Weathering agents, testing procedures and stabilisation methods, in ‘RILEM State-of-the-Art Reports’, Vol. 35, Springer, pp. 211–241. URL: https://doi.org/10.1007/978-3-030-83297-16

Goutsaya, J., Ntamack, G. E., Kenmeugne, B. and d’Ouazzane, S. C. (2021), ‘Mechanical characteristics of compressed earth blocks, compressed stabilized earth blocks and stabilized adobe bricks with cement in the town of ngaoundere cameroon’, Journal of Building Materials and Structures 8(2), 139–159. URL: https://doi.org/10.34118/jbms.v8i2.1441

Ibrahim, H. A. and Abbas, W. A. (2024), ‘Production of cold-bonding pelletized artificial expired cement–fly ash lightweight aggregates with various curing regime’, Tikrit Journal of Engineering Sciences 31(2), 184–197. URL: https://doi.org/10.25130/tjes.31.2.18

Inegbedion, F. and Osasona, I. E. (2024), ‘Coconut fibre (coir) composites: A review’, Journal of Materials Engineering, Structures and Computation 3(2), 2024–2039. URL: https://doi.org/10.5281/zenodo.11406198

Instituto Nacional de Calidad (INACAL) (2025), ‘Normas técnicas peruanas’. URL: https://www.inacal.gob.pe/cid/categoria/normastecnicas-peruanas

Instituto Nacional de Estadística e Informática (2017), ‘En el país existen más de diez millones de viviendas particulares censadas - censo nacional 2017’. URL: https://censo2017.inei.gob.pe/en-el-pais-existenmas-de-diezmillones-de-viviendas-particularescensadas/

International Organization for Standardization (ISO) (2006), ‘Iso 14040:2006 - gestión ambiental — evaluación del ciclo de vida — principios y marco’. URL: https://www.iso.org/standard/37456.html

Jakrapan, W. and Pailyn, T. (2019), ‘Effect of para rubber latex and coir on compressive strength, water absorption and volumetric change of adobe brick’, ResearchGate. URL: https://www.researchgate.net/publication/332250824-Effect of-Para-rubber-latexand-coir-on-compressivestrength-water-absorption-and-volumetric-change-ofadobe-brick

Javier, A. R. A., Lopez, N. E. and Juanzon, J. B. P. (2017), ‘Compressive strength and chloride penetration tests of modified type ip cement concrete with rice ash’, Procedia Engineering 171, 543–548. URL: https://doi.org/10.1016/j.proeng.2017.01.369

Jesudass, A., Gayathri, V., Geethan, R., Gobirajan, M. and Venkatesh, M. (2021), ‘Earthen blocks with natural fibres – a review’, Materials Today: Proceedings 45, 6979–6986. URL: https://doi.org/10.1016/j.matpr.2021.01.434

Kidari, R. and Tilioua, A. (2024), ‘Investigation of the thermomechanical characteristics of compressed earth bricks reinforced with cement and corn straw waste fibers’, Cleaner Waste Systems 9, 100160. URL: https://doi.org/10.1016/j.clwas.2024.100160

Laibi, A. B., Poullain, P., Leklou, N., Gomina, M. and Sohounhloué, D. K. C. (2018), ‘Influence of the kenaf

fiber length on the mechanical and thermal properties of compressed earth blocks (ceb)’, KSCE Journal of Civil Engineering 22(2), 785–793. URL: https://doi.org/10.1007/s12205-017-1968-9

Laid, M., Baouia, K., Chaib, H., Kchired, A. and Kateb, S. (2023), ‘Contribution to study of the influence of lime addition on the thermo-mechanical properties of hajira clay-based adobe’, Journal of Survey in Fisheries Sciences 10(3), 552–558. URL: https://doi.org/10.53555/sfs.v10i3.1891

Lopez, X., Torbisco, D., Rodriguez, J. and Eyzaguirre, C. (2019), Benefits of cabuya fiber in the mechanical properties of compacted adobe, in ‘Proceedings of the 7th International Engineering, Sciences and Technology Conference (IESTEC 2019)’, pp. 455–460. URL: https://doi.org/10.1109/IESTEC46403.2019.00088

Meddah, A., Chikouche, M. A., Yahia, M., Deghfel, M. and Beddar, M. (2022), ‘The efficiency of recycling expired cement waste in cement manufacturing: A sustainable construction material’, Circular Economy and Sustainability 2(3), 1213–1224. URL: https://doi.org/10.1007/s43615-022-00161-1

Ministerio de Transportes y Comunicaciones (2014), ‘RD N° 18_2014_MTC_14 Original_Aprueba manual de ensayo de materiales’. Ministerio de Vivienda, Construcción y Saneamiento (2017), ‘Diseño y construcción con tierra reforzada’. Separata especial difundida por ICG – Instituto de la Construcción y Gerencia. URL: http://www.construccion.org

Morsy, M. I. et al. (2022), ‘Recycling rice straw ash to produce low thermal conductivity and moistureresistant geopolymer adobe bricks’, Saudi Journal of Biological Sciences 29(5), 3759–3771. URL: https://doi.org/10.1016/j.sjbs.2022.02.046

Ouedraogo, M. et al. (2019), ‘Physical, thermal and mechanical properties of adobes stabilized with fonio (Digitaria exilis) straw’, Journal of Building Engineering 23, 250–258. URL: https://doi.org/10.1016/j.jobe.2019.02.005

O’Kelly, B. C., Vardanega, P. J. and Haigh, S. K. (2018), ‘Use of fall cones to determine Atterberg limits: A review’, Géotechnique 68(10), 843–856. URL: https://doi.org/10.1680/jgeot.17.R.039

Preve, B. (n.d.), ‘Portland Cement (CEM I) produced in Europe’.

Rajapakse, A. M., Mudunkotuwa, D. Y., Sanjula, S. N., Nishantha, K. and Bandara, T. R. (2022), ‘Cement and clay bricks reinforced with coconut fiber and fiber dust’, Advances in Technology 2022(3), 233–248. URL: https://doi.org/10.31357/ait.v2i3.5534

Ramakrishnan, S., Loganayagan, S., Kowshika, G., Ramprakash, C. and Aruneshwaran, M. (2021), ‘Adobe blocks reinforced with natural fibres: A review’, Materials Today: Proceedings 45, 6493–6499. URL: https://doi.org/10.1016/j.matpr.2020.11.377

Rocco, A., Vicente, R., Rodrigues, H. and Ferreira, V. (2024), ‘Adobe blocks reinforced with vegetal fibres: Mechanical and thermal characterisation’, Buildings 14(8), 2582. URL: https://doi.org/10.3390/buildings14082582

RPP (2025), ‘Las alergias producidas por el moho y la humedad’. URL: https://rpp.pe/lima/actualidad/lasalergiasproducidas-por-el-moho-y-la-humedad-noticia-388538

Sanou, I., Bamogo, H., Sory, N., Gansoré, A. and Millogo, Y. (2024), ‘Effect of the coconut fibers and cement on the physico-mechanical and thermal properties of adobe blocks’, Heliyon 10(19), e38752. URL: https://doi.org/10.1016/j.heliyon.2024.e38752

Sanou, I. et al. (2024), ‘Kenaf fibres from Burkina Faso valorization in the improvement of durability, thermal properties and fracture behavior of adobes amended with cement’, Industrial Crops and Products 219, 119077. URL: https://doi.org/10.1016/j.indcrop.2024.119077

Santos, L. M. A., Neto, J. A. D. S. and De Azerêdo, A. F. N. (2020), ‘Soil characterization for adobe mixtures containing Portland cement as stabilizer’, Matéria (Rio de Janeiro) 25(1), e–12565. URL: https://doi.org/10.1590/s1517-707620200001.0890

SENAMHI (2025), ‘Senamhi advierte sobre importantes precipitaciones en la sierra peruana’, RPP Noticias. URL: https://rpp.pe/peru/actualidad/senamhi-adviertesobre-importantes-precipitaciones-en-la-sierraperuana-noticia-1600201

SENAMHI (n.d.), ‘Estaciones’. Consultado el 29 de enero de 2025. URL: https://www.senamhi.gob.pe/?p=estaciones

Serebe, Y. A. A. et al. (2024), ‘Optimization of kenaf fiber content for the improvement of the thermophysical and mechanical properties of adobes’, Construction and Building Materials 431, 136469. URL: https://doi.org/10.1016/j.conbuildmat.2024.136469

Suarez-Riera, D. et al. (2024), ‘An overview of methods to enhance the environmental performance of cementbased materials’, Infrastructures 9(6), 94. URL: https://doi.org/10.3390/infrastructures9060094

Thanushan, K. and Sathiparan, N. (2022), ‘Mechanical performance and durability of banana fibre and coconut coir reinforced cement stabilized soil blocks’, Materialia 21, 101309. URL: https://doi.org/10.1016/j.mtla.2021.101309

Thanushan, K., Yogananth, Y., Sangeeth, P., Coonghe, J. G. and Sathiparan, N. (2021), ‘Strength and durability characteristics of coconut fibre reinforced earth cement blocks’, Journal of Natural Fibers 18(6), 773–788. URL: https://doi.org/10.1080/15440478.2019.1652220

Vaca, L. F. G., Gómez, J. M., Crespo, M. F. B. and Trujillo, A. J. R. (2021), ‘Energy analysis of adobe performance as a housing construction material in Ecuador’, International Journal of Mathematics in Operational Research 18(2), 154–168. URL: https://doi.org/10.1504/IJMOR.2021.112930

Velasco-Aquino, A. A., Espuna-Mujica, J. A., Perez-Sanchez, J. F., Zuñiga-Leal, C., Palacio-Perez, A. and Suarez Dominguez, E. J. (2020), ‘Compressed earth block reinforced with coconut fibers and stabilized with aloe vera and lime’, Journal of Engineering, Design and Technology 19(3), 795–807. URL: https://doi.org/10.1108/JEDT-02-2020-0055

Zhang, J., Li, Z., Chen, W., Wang, X., Sun, M. and Guo, Q. (2017), ‘The properties of potassium silicate/fly ash slurry used in the conservation of adobe structures’, Studies in Conservation 62(2), 114–121. URL: https://doi.org/10.1080/00393630.2016.1149912

Effect of Coconut Fiber and Expired Cement on the Physical-Mechanical and Thermal Properties of Adobe Blocks

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