Effect of waste oyster shell powder as additive on properties and sulfate attack resistance of mortar

Yu-Wen Liu; Shih-Wei Cho; Pou-Gang  Chiou

doi:10.7764/RDLC.23.2.164

Authors

Yu-Wen Liu Department of Civil and Water Resources Engineering, National Chiayi University, Chiayi (Taiwan)
Shih-Wei Cho Department of Civil Engineering and Engineering Management, National Quemoy University, Kinmen (Taiwan)
Pou-Gang Chiou Department of Civil and Water Resources Engineering, National Chiayi University, Chiayi (Taiwan)

DOI:

https://doi.org/10.7764/RDLC.23.2.164

Keywords:

Sulfate attack resistance, waste oyster shell powder, anti-sulfide bacteria effect, mortar.

Abstract

In this study, the waste oyster shell powder was added in mix design to investigate the properties, sulfate attack resistance and sulfide bacterial of concrete. Add 0%, 1%, 3%, 6% and 9% oyster shell powder to the concrete to replace part of the sand. The study conducted flow tests, compressive strength tests, sulfate corrosion resistance and antibacterial tests. From the results, it was found that adding oyster shell powder improved the resistance to sulfate corrosion and antibacterial properties and became more effective as the substitution ratio increased. In addition, the sulfate attack resistance and antibacterial have a linear relationship of mortar with oyster shell powders.

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References

Aiken, T. A., Kwasny, J., Sha, W., and Tong, K. T. (2020). Mechanical and Durability Properties of Alkali-Activated Fly Ash Concrete with Increasing Slag content. Construction and Building Materials. 251, 124330.

Akyuncu, V., Uysal, M., Tanyildizi, H., and Sumer, M. (2018). Modeling the Weight and Length Changes of the Concrete Exposed to Sulfate Using Artifi-cial Neural Network. Revista de la Construcción. Journal of Construction, 17(3), 337–353.

American Concrete Association (2014). Precast Concrete Pipe Durability, Concrete Pipe Information CPInfo. https://www.concretepipe.org/wpcontent/uploads/CP InfoDurability072116.pdf.

Botta, R., Asche, F., Borsum, J. S., and Camp, E., (2020). A Review of Global Oyster Aquaculture Production and Consumption. Marine Policy. 117, 103952.

Chang, H. B., and Choi, Y. C. (2020). Accelerated Performance Evaluation of Repair Mortars for Concrete Sewer Pipes Subjected to Sulfuric Acid Attack. Journal of Materials Research and Technology. 9, 13635-13645.

Chen, D., Zhang, P., Pan, T., and Liao, Y. (2019). Evaluation of the Eco-Friendly Crushed Waste Oyster Shell Mortars Containing Supplementary Ce-mentitious materials. Journal of Cleaner Production. 237, 117811.

Daniels C., Merrifield D., Boothroyd D., Davies S., and Factor, J. (2010). Effect of Dietary Bacillus Spp. and Mannan Oligosaccharides (MOS) on Europe-an Lobster (Homarus gammarus L.) Larvae Growth Performance, Gut Morphology and Gut Microbiota. Aquaculture. 304, 49-57.

Daczko, J. A., Johnson, D. A., and Arney, S. L. (1997). Decreasing Concrete Sewer Pipe Degradation Using Admixtures. Materials Performance. 36, 51-56.

Fernando Silva, Y., Delvasto, S., Valencia, W., and Araya-Letelier, G. (2024). Performance of Self-Compacting Concrete with Residue of Masonry and Recycled Aggregate under Sulfate Attack. Journal of Materials in Civil Engineering, 36(1), 04023491.

Grengg, C., Mittermayr, F., Koraimann, G., Konrad, F., Szabó, M., Demeny, A. and Dietzel, M. (2017)., The Decisive Role of Acidophilic Bacteria in Con-crete Sewer Networks: A New Model for Fast Progressing Microbial Concrete Corrosion. Cement and Concrete Research. 101, 93-101.

Grengg, C., Mittermayr, F., Ukrainczyk, N., Koraimann, G., Kienesberger, S., and Dietzel, M. (2018), Advances in Concrete Materials for Sewer Systems Affected by Microbial Induced Concrete Corrosion: A Review. Water Research. 134, 341-352.

Lavanya, M. R., Johnpaul, V., Balasundaram, N., and Venkatesan, G. (2024). Potential use of silane-modified oyster shell powder in hydrophobic con-crete. Materials Research Express, 11(5), 055508.

Lavigne, M. P., Bertron, A., Auer, L., Hernandez-Raquet, G., Foussard, J., Escadeillas, G., Cockx, A., and Paul, E. (2015). An Innovative Approach to Reproduce the Biodeterioration of Industrial Cementitious Products in a Sewer Environment. Part I: Test Design. Cement and Concrete Research. 73, 246-256.

Lian, W., Li, H., Yang, J., Joseph, S., Bian, R., Liu, X., Zheng, J., Drosos, M., Zhang, X., Li, L., Shan, S., and Pan, G. (2021). Influence of Pyrolysis Tempera-ture on the Cadmium and Lead Removal Behavior of Biochar Derived from Oyster Shell Waste. Bioresource Technology Reports. 15, 100709.

Monteny, J., De Belie, N., Vincke, E., Verstraete, W., and Taerwe, L. (2001). Chemical and Microbiological Tests to Simulate Sulfuric Acid Corrosion of Polymer-Modified Concrete, Cement and Concrete Research. 31, 1359-1365.

Mori, K., and Takahashi, K. (1998). Bactericidal Effects on Escherichia Coli of the Water Treated with New Ceramics Manufactured by a Combination of Burned Oyster Shells and Natural Zeolite. Mizushorigijutu (Water Purification and Liquid Waters Treatment). 39, 1-7.

Nnadi, E. O., and Lizarazo-Marriaga, J. (2013). Acid Corrosion of Plain and Reinforced Concrete Sewage Systems. Journal of Materials in Civil Engineer-ing. 25, 1353-1356.

Naqi, A., Siddique, S., Kim, H. K., and Jang, J. G. (2020). Examining the Potential of Calcined Oystershell Waste as Additive in High Volume Slag Cement. Construction and Building Materials. 230, 116973.

Roghanian, N.,and Banthia N. (2019). Development of a Sustainable Coating and Repair Material to Prevent Bio-Corrosion in Concrete Sewer and Waste-Water Pipes. Cement and Concrete Composites, 100, 99-107.

Sawai, J., and Shiga, H. (2006). Kinetic Analysis of the Antifungal Activity of Heated Scallop-Shell Powder Against Trichophyton and its Possible Applica-tion to the Treatment of Dermatophytosis. Biocontrol Science. 11, 125–128.

Shah, K.W., and Huseien G.F. (2020). Bond Strength Performance of Ceramic, Fly Ash and GBFS Ternary Wastes Combined Alkali-Activated Mortars Exposed to Aggressive Environments, Construction and Building Materials. 251, 119088.

Shargawi, J. M., Theaker, E. D., Drucker, D. B., MacFarlane, T., and Duxbury, A. J. (1999). Sensitivity of Candida Albicans to Negative Air Ion Streams. Journal of Applied Microbiology. 87, 889–897.

Tanyildizi, H. (2024). Durability of Concrete Exposed to Combined Freeze-thaw, Sulfate, and Acid Attacks after Two Years. Revista de la Construcción. Journal of Construction, 22(1), 102–121. https://doi.org/10.7764/RDLC.22.1.102

Torii, K., and Kawamura, M. (1994). Effects of Fly Ash and Silica Fume on the Resistance of Mortar to Sulfuric Acid and Sulfate Attack, Cement and Concrete Research. 24, 361-370.

Wang, T., Wu, K., Kan, L., and Wu, M. (2020). Current Understanding on Microbiologically Induced Corrosion of Concrete in Sewer Structures: a Review of the Evaluation Methods and Mitigation Measures. Construction and Building Materials. 247, 118539.

Wu, S. C., Hsu, H. C., Wu, Y. N., and Ho, W. F. (2011). Hydroxyapatite Synthesized from Oyster Shell Powders by Ball milling and Heat Treatment. Materials Characterization. 62, 1180-1187.

Wu, S. C., Hsu, H. C., Hsu, S. K., Tseng, C. P., and Ho, W. F. (2017). Preparation and Characterization of Hydroxyapatite Synthesized from Oyster Shell Powders. Advanced Powder Technology. 28, 1154-1158.

Wu, L., Hu, C., and Liu, W. V. (2018). The Sustainability of Concrete in Sewer Tunnel—A Narrative Review of Acid Corrosion in the City of Edmonton, Canada. Sustainability, 10, 517.

Wu, M., Wang, T., and Kan, L. (2020). Microbiologically Induced Corrosion of Concrete in Sewer Structures: A Review of the Mechanisms and Phenome-na. Construction and Building Materials. 239, 117813.

Effect of waste oyster shell powder as additive on properties and sulfate attack resistance of mortar

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