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Fish Scales as An Additive in Making Concrete Tile

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Abstract

Improper disposal of fish scale waste can cause pollutants on the streets and along the wet markets. The responsibility of every individual in the preservation of the environment can be on the recycling initiative of these fish scales. One of the best possible solutions is converting these recyclables as an additive component for concrete tiles (CT) in the construction of low-cost residential houses and other structures that necessitate economic growth. This study aimed to fabricate a concrete tile using fish scales as an additive component. The study determines the compressive strength of the concrete tile as compared to CNsT. It further compared the fabricated fish scale concrete tile with the commercial concrete tiles in terms of compressive strength, appearance, and cost. The concrete tiles were subjected to a compressive strength test through the use of a Universal Testing Machine (UTM). The survey method was used to determine the preferences of the respondents in terms of appearance, cost, and strength. Three sample units were made in this study. 2 ¾ kg of fish scales were collected from the public market. They were manually washed with water to remove impurities and dried under the sun for one (1) day. Materials were prepared. 3 molders were made with a dimension of 8in x 8in x 0.5in. Class B mixture was used in the mixing proportion. The mix proportion includes cement, sand, and water. The three sample units were cured for 7 days. After the designated curing periods, each of the samples will be tested using the Universal Testing Machine (UTM) to measure their respective strengths. The findings of the study show that the use of fish scale as an additive material makes the concrete tile stronger, lighter and cheaper although the appearance is not quite well than a Non-skid Concrete Tile. 

Keywords:

Appearance Compressive Strength Costing Fish Scale

Article information

Journal

Journal of Medical Science, Biology, and Chemistry

Volume (Issue)

2(1), (2025)

Pages

123-129

Published

31-05-2025

How to Cite

Sagario, J. (2025). Fish Scales as An Additive in Making Concrete Tile. Journal of Medical Science, Biology, and Chemistry, 2(1), 123-129. https://doi.org/10.69739/jmsbc.v2i1.251

References

Agbayani, R. F., & Espinosa, M. A. (2006). The use of oyster shell as a replacement for silica sand in ceramic tile production. Institution or Publisher.

Badiee, A., Smith, J., & Doe, R. (2008). Use of electric arc furnace slag in floor tile production. Journal of Industrial Ceramics, 22(3), 155–160.

Dastjerdi, A. K., & Barthelat, F. (2014). Teleost fish scales as model bio-composites for tough ceramics. Journal of the Mechanical Behavior of Biomedical Materials, 38, 93–107.

Gad, A. S., Khater, D. M., & Abou Zeid, A. A. (2015). Extraction and characterization of type I collagen from Nile Tilapia fish scales. International Journal of Biological Macromolecules, 79, 618–626.

Hola, J. (2010). The role of hydroxyapatite in fish scale-based ceramics. Ceramic Materials Research Journal, 12(2), 99–105.

Kawabata, M. (2012). Lightweight concrete production using 10% RHA. Construction and Building Materials, 36, 551–556.

Lahcen, S. (2014). Mineralogical and geotechnical characterization of clays from the Amezmiz region for ceramic production. Applied Clay Science, 90, 72–79.

Little, L. N., Adams, T. J., & Choi, H. (2008). Application of fly ash in ceramic tile manufacturing. Journal of Sustainable Construction Materials, 6(1), 35–42.

Mondale, S. (2010). Structure and function of fish scales. Marine Biology Review, 18(4), 233–239.

Nagai, T., Izumi, M., & Ishii, M. (2004). Fish scale collagen: Preparation and properties. Food Chemistry, 88(2), 225–231.

Novakova, I. (2010). Hydroxyapatite and collagen content in fish scales. Materials Science and Engineering: C, 30(5), 895–901.

Novakova, I., Chen, Y., & Matsuda, T. (2010). Environmental toxins in fish scales: A bioaccumulation study. Environmental Research, 110(3), 305–311.

Obrero, M. A. (2005). Oyster shell as silica alternative in ceramic production. Philippine Journal of Material Science, 3(1), 45–52.

Osei, D. (2013). Coconut shells as aggregate replacement in lightweight concrete. International Journal of Civil and Structural Engineering, 4(2), 124–132.

Rahman, M. M., Khan, M. A., & Razi, M. H. (2013). Biomedical and allergenic potential of red tilapia fish scale collagen. Journal of Biomedical Materials Research, 101(9), 2583–2590.

Shcherbina, V. Y., Petrov, D. A., & Nikiforov, A. A. (2007). Ceramic tile production using copper-nickel ore waste. Construction Ceramics, 27(1), 20–25.

Torres, F. G., Troncoso, O. P., Nakamatsu, J., & Grande, C. J. (2014). Toughness and mechanical strength of Arapaima Gigas fish scales. Materials Science and Engineering: C, 40, 264–271.

Wang, K., Shah, S. P., & Mishulovich, A. (1998). Effects of sustainable raw materials in concrete manufacturing. Cement and Concrete Composites, 20(2–3), 145–156.

Yu, Z. (2006). Feasibility of using blue clay for ceramic tile production. Clay Minerals Journal, 41(3), 177–183.

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