Granite coated tiles offer excellent mechanical properties for cladding applications. But, as with any application in the housing field, the question of their durability arises. The durability study and the alkaline degradation process of the cementitious medium were undertaken in this work to evaluate the effect of granite and marble coating on the substrate. The mixture of the constituents with different characteristics results in a material whose properties will vary depending on the density of each constituent. For this purpose, the bilayer materials were subjected to different chemical attacks such as concentrated solutions of strong and weak acids and strong bases and the resistance to chemical attack of the samples immersed in each of these solutions is evaluated according to ASTM C 267-96. The results obtained show that before 7 days of immersion, the bilayer materials and the mortar increase their capacity to resist the attack solutions. As for 35 days of immersion, the mass losses are 9.49%, 40.63%, 3.48% for the mortar; 3.81%, 18.51%, 1.07% for the granite bilayer materials and 10.44%, 22.62% 2.94% for the marble bilayer materials in HCl solutions. This study also highlights the alkaline degradation affecting the interface of bilayer materials and it is found that hydrated cement releases basic substances, which react with acidic solutions to give salts easily soluble in water.
Published in | Advances in Materials (Volume 11, Issue 4) |
DOI | 10.11648/j.am.20221104.11 |
Page(s) | 77-84 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
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Copyright © The Author(s), 2022. Published by Science Publishing Group |
Granite Coated Tiles, Durability, Attack Solutions, Alkaline Degradation
[1] | Alexandra Berton, Understanding interactions between cementitious materials and microorganisms: a key to sustainable and safe concrete structures in various contexts, 2014. |
[2] | Al-Amoundi O. S. B., Maslehuddin M., Saadi M. M., Effet of magnesium sulfate and sodium sulfate on the durability performance of plain and blended cements. ACI Materials Journal. 1995; Vol. 92, No. 1, pp. 15-24. |
[3] | Sand W, Bock E, Concrete corrosion in Hamburg sewer system. Environ Technol Lett 5 (12): 517-528, 1984. |
[4] | Albrecht A, Bertron A, Libert, Microbial catalysis of redox reactions in concrete cells of nuclear waste repositories: a review and introduction. In Bart F, Cau-di-Coumes C, Frizon F, Lorente S (eds) Cement-based materials for nuclear waste storage. Springer New York, pp 147-159, 2013. |
[5] | Dubosc A, Escadeillas G, Blanc PJ, Characterization of biological stains on external concrete walls and influence of concrete as underlying material. Cem Concr Res 31. (11): 1613-1617, 2001. |
[6] | Libert M et al., Impact of microbial activity on radioactive waste disposal: long term prediction of biocorrosion processes. Bioelectrochemistry 97: 162-168, 2014. |
[7] | Alexandre Govin, Aspects physico-chimiques de l’interaction bois-ciment. Modification de l’hydratation du ciment par le bois, 2004. |
[8] | Jeremie Pourchez, Aspects physico-chimiques de l’interaction des éthers de cellulose avec la matrice cimentaire, 2006. |
[9] | Jonanthan Page, Amélioration du comportement à long terme de composites cimentaires renforcés par des fibres de lin, 2018. |
[10] | Geraldo Fajardo San Miguel, Paper of Canadian Journal of Civil Engineering, 2012. |
[11] | Jeremie Pourchez, Physico-chemical interactions between cement and cellulose ethers, 2006. |
[12] | Boukhelkhal Aboubakeur et al., Influence de la poudre de marbre sur les propriétés des bétons autoplaçants à l’état frais, 2012. |
[13] | Mohsen Tennich et al., Durabilité des bétons autoplaçants à base de déchets de marbre et de carrelage exposés à l’attaque de sulfate, 2017. |
[14] | Ilias Mouallif, Effet du viellissement sur les propriétés hygrothermiques et mécaniques des composites polyster/fibre de verre, 2013. |
[15] | Kenia S., Debieb F., Characterization of the durability of recycled concrete based on coarse and fine brick aggregates and crushed concrete, Materials and structures, vol. 44, 2011, pp. 815-824. |
[16] | Levy S. M., Helene P., Durability of recycled aggregates concrete: a safe way to sustainable development, Cement and concrete research, vol. 34, no. 18, 2004, p. 1975-1980. |
[17] | Shirakawa MA et al., Climate as the most impotant factor determining anti-fungal biocide performance in paint films. Sci Total Environ 408 (23): 5878-5885, 2010. |
[18] | Shirakawa MA et al., Inhibition of Cladosporium growth on gypsum panels treated with nanosilver particles. Int Biodeterior Biodegrad 85: 57-61, 2013. |
[19] | Gutarowska B et al., Application of silver nanoparticles for disinfection of materials to protect historial objects. Cur Nanosci 10 (2): 277-286, 2014. |
[20] | Verdier T et al., Antibacterial activity of TiO2 photocatalyst alone or in coatings on E. coli: influence of methodological aspects, 2014. |
[21] | de Niederhausern S et al., Self-cleaning and antibacteric ceramic tile surface. Int J Appl Ceram Technol 10 (6): 949-956, 2013. |
[22] | Valentin R et al., Pure short-chain glycerol fatty acid esters and glycerylic cyclocarbonic fatty acid esters as surface active and antimicrobial coagels protecting surfaces by promoting superhydrophilicity. J Colloid Interface Sci 365 (1): 280-288, 2012. |
[23] | Kaid N., Cyr M., Julien S.; Khelafi H. Durability of concrete containing a natural pozzolan as difined by performance based approach. Construction and building materials, vol. 23, 2009, pp 3457-3467. |
[24] | Shaker F. A., El-Dieb A. S., Reda M. M. Durability of styrene butadiene latex modified concrete. Cement and concrete research, vol. 27, 1997, pp. 711-720. |
[25] | Almussam A. A., Khan F. M., Dulaijan S. U. Al-Moudi O. S. B. Effectiveness of surface coatings in improving concrete durability. Cement and concrete composites, vol. 25, 2003, pp. 473-480. |
[26] | Badreddine Bessa A. Study of the contribution of mineral additions to the physical, mechanical and durability properties of mortar. PhD thesis of the University of Cergy Pontoise, 2004. |
[27] | Abderrahman Soufi. Study of the durability of reinforced concrete systems. PhD thesis from the University of La Rochelle, 2013. |
[28] | Zivica V., Bajza A. Acidic attack of cement based materials, a review part2. Factor of rate of acidic attack and protective measures. Construction and building Materials, vol. 16, 2002, pp. 215-222. |
[29] | Bertron A. Durability of cementitious materials subjected to organic acids: Case of livestock effluents, PhD thesis of the University INSA Toulouse, 2004. |
[30] | Toukourou C, Fagla Z. B., Prodjinonto V, Bello S. Study and Characterization of a Mineral Belayed Material: Case Tiles Coated Granites. International Journal of Applied Science and Technology, 2015; 5 (6). |
[31] | Ernesto V. C., Eduardo V. M., Jesus H. R., Jorge V. L. and Julio A. M. Kinetics of the water absorption in slag cement mortars. Cond-mat/ 0210138, Vol. 2, 23 July 2003. |
[32] | ASTM C 267-96. Standard Test Methods for chemical Resistance of Mortars, Grouts, and Monolithic Surfacing and Polymer concretes, Annual Book of ASTM Standard, American Society for Testing and Structures, June 1996. |
[33] | Said-Mansour M., Ghrici M., and Kenai S. Effect of compatibility of natural pozzolan and limestone on mortar and concrete properties. International Congress on Rehabilitation of Constructions and Sustainable Development. May 2005; T. 2, pp. 123-131, Algiers, 3-4. |
[34] | Ghrici M., Kenai S., Said Mansour and Meziane E. Performance of cement based on natural pozzolan of Beni-Saf. Congrès international Réhabilitation des Constructions et Développement Durable. May 2005; T. 2, pp. 108-115, Algiers, 3-4. |
[35] | Sayamipuk S. Strength and durability of mortars containing metakaolin from Thailand. PhD Thesis, School of Civil Engineering, Asian Institute of Technologr, 2001. |
APA Style
Bachir Kolade Adelakoun Ambelohoun, Koffi Judicael Agbelele, Yelome Judicael Fernando Kpomahou, Aristide Comlan Houngan. (2022). Study of the Durability of a Mineral Bilayer Material: Case of Granito Coated Tiles. Advances in Materials, 11(4), 77-84. https://doi.org/10.11648/j.am.20221104.11
ACS Style
Bachir Kolade Adelakoun Ambelohoun; Koffi Judicael Agbelele; Yelome Judicael Fernando Kpomahou; Aristide Comlan Houngan. Study of the Durability of a Mineral Bilayer Material: Case of Granito Coated Tiles. Adv. Mater. 2022, 11(4), 77-84. doi: 10.11648/j.am.20221104.11
@article{10.11648/j.am.20221104.11, author = {Bachir Kolade Adelakoun Ambelohoun and Koffi Judicael Agbelele and Yelome Judicael Fernando Kpomahou and Aristide Comlan Houngan}, title = {Study of the Durability of a Mineral Bilayer Material: Case of Granito Coated Tiles}, journal = {Advances in Materials}, volume = {11}, number = {4}, pages = {77-84}, doi = {10.11648/j.am.20221104.11}, url = {https://doi.org/10.11648/j.am.20221104.11}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.am.20221104.11}, abstract = {Granite coated tiles offer excellent mechanical properties for cladding applications. But, as with any application in the housing field, the question of their durability arises. The durability study and the alkaline degradation process of the cementitious medium were undertaken in this work to evaluate the effect of granite and marble coating on the substrate. The mixture of the constituents with different characteristics results in a material whose properties will vary depending on the density of each constituent. For this purpose, the bilayer materials were subjected to different chemical attacks such as concentrated solutions of strong and weak acids and strong bases and the resistance to chemical attack of the samples immersed in each of these solutions is evaluated according to ASTM C 267-96. The results obtained show that before 7 days of immersion, the bilayer materials and the mortar increase their capacity to resist the attack solutions. As for 35 days of immersion, the mass losses are 9.49%, 40.63%, 3.48% for the mortar; 3.81%, 18.51%, 1.07% for the granite bilayer materials and 10.44%, 22.62% 2.94% for the marble bilayer materials in HCl solutions. This study also highlights the alkaline degradation affecting the interface of bilayer materials and it is found that hydrated cement releases basic substances, which react with acidic solutions to give salts easily soluble in water.}, year = {2022} }
TY - JOUR T1 - Study of the Durability of a Mineral Bilayer Material: Case of Granito Coated Tiles AU - Bachir Kolade Adelakoun Ambelohoun AU - Koffi Judicael Agbelele AU - Yelome Judicael Fernando Kpomahou AU - Aristide Comlan Houngan Y1 - 2022/10/11 PY - 2022 N1 - https://doi.org/10.11648/j.am.20221104.11 DO - 10.11648/j.am.20221104.11 T2 - Advances in Materials JF - Advances in Materials JO - Advances in Materials SP - 77 EP - 84 PB - Science Publishing Group SN - 2327-252X UR - https://doi.org/10.11648/j.am.20221104.11 AB - Granite coated tiles offer excellent mechanical properties for cladding applications. But, as with any application in the housing field, the question of their durability arises. The durability study and the alkaline degradation process of the cementitious medium were undertaken in this work to evaluate the effect of granite and marble coating on the substrate. The mixture of the constituents with different characteristics results in a material whose properties will vary depending on the density of each constituent. For this purpose, the bilayer materials were subjected to different chemical attacks such as concentrated solutions of strong and weak acids and strong bases and the resistance to chemical attack of the samples immersed in each of these solutions is evaluated according to ASTM C 267-96. The results obtained show that before 7 days of immersion, the bilayer materials and the mortar increase their capacity to resist the attack solutions. As for 35 days of immersion, the mass losses are 9.49%, 40.63%, 3.48% for the mortar; 3.81%, 18.51%, 1.07% for the granite bilayer materials and 10.44%, 22.62% 2.94% for the marble bilayer materials in HCl solutions. This study also highlights the alkaline degradation affecting the interface of bilayer materials and it is found that hydrated cement releases basic substances, which react with acidic solutions to give salts easily soluble in water. VL - 11 IS - 4 ER -