Effect of substituting white cement with ceramic waste powders (CWP) on the performance of a mortar based on crushed sand

• Autorzy: Mezidi Amar , Merabti Salem , Benyamina Smain , Sadouki Mustapha

Identyfikatory

DOI

10.2478/adms-2023-0026

• Języki publikacji: EN

Abstrakty

EN

The enormous quantities of ceramic waste lead us to its use in the construction field to solve both an environmental and an economic problem. The present study aims to recycle ceramic waste powders (CWP) to produce mortars. To this end, five crushed sand (CS) based mortar mixes with prismatic dimensions of 4x4x16 cm³ were prepared by partially replacing 0, 5, 10, 15, and 20% white cement with CWP. Tests were carried out to assess bulk density, compressive strength, and ultrasonic pulse velocity (UPV). The results obtained showed that increasing the proportion of ceramic waste powder (CWP) in mortar mixes led to a decrease in bulk density, compressive strength, and UPV in the different mortars. In addition, linear correlations were observed between the different variables studied.

Słowa kluczowe

EN

white cement; ceramic; waste powder; crushed sand; mortar; compressive strength; ultrasonic pulse velocity

PL

biały cement; ceramika; pył odpadowy; piasek; zaprawa; wytrzymałość na ściskanie; pomiar prędkości impulsu ultradźwiękowego

• Wydawca: Politechnika Gdańska
• Czasopismo: Advances in Materials Science
• Rocznik: 2023
• Tom: Vol. 23, nr 4(78)
• Strony: 123--133
• Opis fizyczny: Bibliogr. 29 poz., rys., tab., wykr.

Twórcy

autor

Mezidi Amar

• Acoustic and Civil Engineering Laboratory LAGC, Faculty of Sciences and Technology, University of Khemis Miliana, Algeria

autor

Merabti Salem

• Acoustic and Civil Engineering Laboratory LAGC, Faculty of Sciences and Technology, University of Khemis Miliana, Algeria

autor

Benyamina Smain

• Acoustic and Civil Engineering Laboratory LAGC, Faculty of Sciences and Technology, University of Khemis Miliana, Algeria

autor

Sadouki Mustapha

• Acoustic and Civil Engineering Laboratory LAGC, Faculty of Sciences and Technology, University of Khemis Miliana, Algeria

Bibliografia

• 1. Yarramsetty B.B., Goud E S.K., Geddada Y: Study of concrete behavior by partial replacement of cement with Ceramic Waste Powder in the presence of Sisal fiber. Materials Today: Proceedings 2023.
• 2. Li L., Liu W., You Q., Chen M., Zeng Q., Zhou C., Zhang M: Relationships between microstructure and transport properties in mortar containing recycled ceramic powder. Journal of Cleaner Production 263(2020) 121384.
• 3. El-Dieb, A.S., Taha, M.R., Abu-Eishah, S.I. The use of ceramic waste powder (CWP) in making eco-friendly concretes. Ceramic Materials: Synthesis, Characterization, Applications and Recycling (2019) IntechOpen.
• 4. Wang S., Nguyen V.T., Xiu Z., Han W: Test research on the effect of waste ceramic polishing powder on the compressive strength and chloride penetration resistance of seawater concrete. Construction and Building Materials 386(2023) 131590.
• 5. Yang J., Jiang P., Nassar R.U.D., Suhail S.A., Sufian M., Deifalla A.F: Experimental investigation and AI prediction modelling of ceramic waste powder concrete-An approach towards sustainable construction. Journal of Materials Research and Technology 23(2023) 3676e3696.
• 6. Medina C., Sánchez de Rojas M.I., Frías M: Properties of recycled ceramic aggregate concretes: Water Resistance. Cement and Concrete Composites 40(2013) 21-29.
• 7. Medina C., Sánchez de Rojas M.I., Thomas C., Polanco J.A., Frías M : Durability of recycled concrete made with recycled ceramic sanitary ware aggregate. Inter-indicator relationships. Construction and Building Materials 105(2016) 48-486.
• 8. Mohit M and Sharifi Y: Thermal and microstructure properties of cement mortar containing ceramic waste powder as alternative cementitious materials. Construction and Building Materials 223(2019) 643-656.
• 9. Nowak A.P., Trzciński K., Lisowska-Oleksiak A: Electrochemical Characterization of Gelatine Derived Ceramics. Advances in Materials Science 14(2014) 75-81.
• 10. Wu J., Li Z., Wen G., Gao Z., Li Y., Zhao Y: Friction mechanism analysis of copper-based composites reinforced with ball-milled and modified composite ceramic powders. Wear (2023) 204959.
• 11. Ying H., Ding G., ZhaoJ., Wang J., Liu Z., Zhou M., Ye J: Properties of PSN-PZT piezoelectric ceramic powder prepared by fast solid-phase reaction method. Materials Today Communications 35(2023) 106086.
• 12. Miller S.A., Horvath A., Monteiro P.J.M: Readily implementable techniques can cut annual CO2 emissions from the production of concrete by over 20%. Environmental Research Letters 11(2016) 074029.
• 13. Gautam L., Bansal S., Sharma K. V., Kalla P: Bone-china ceramic powder and granite industrial by-product waste in self-compacting concrete: A durability assessment with statistical validation. Structures 54(2023) 837-856.
• 14. Mohit M., Haftbaradaran H., Riahi H.T: Investigating the ternary cement containing Portland cement, ceramic waste powder, and limestone. Construction and Building Materials 369(2023) 130596.
• 15. Gautam L., Jain J.K., Jain A., Kalla P: Valorization of bone-china ceramic powder waste along with granite waste in self-compacting concrete. Construction and Building Materials 315(2022) 125730.
• 16. Chokkalingam P., El-Hassan H., El-Dieb A., El-Mir A: Multi-response optimization of ceramic waste geopolymer concrete using BWM and TOPSIS-based taguchi methods. Journal of Materials Research and Technology 21(2022) 4824-4845.
• 17. Uysal M., Aygörmez Y., Canpolat O., Cosgun T., Kuranlı Ö.F: Investigation of using waste marble powder, brick powder, ceramic powder, glass powder, and rice husk ash as eco-friendly aggregate in sustainable red mud-metakaolin based geopolymer composites. Construction and Building Materials 361(2022) 129718.
• 18. De Almeida D.H., Freitas Grillo R.H., Maestrelli S.C., Del Rover C: Properties of concrete manufactured with use of ceramic sanitary ware waste as aggregate. Revista Matéria 24(2019).
• 19. Sharifi Y., Ranjbar A., Mohit M: Acid resistance of cement mortars incorporating ceramic waste powder as cement replacement. ACI Materials Journal 117(2020).
• 20. Steiner L.R., Bernardin A.M., Pelisser F: Effectiveness of ceramic tile polishing residues as supplementary cementitious materials for cement mortars. Sustainable Materials and Technologies 4(2015) 30-35.
• 21. Ay, N., Unal. M: The use of waste ceramic tile in cement production. Cement and Concrete Research 30(2000) 497-499.
• 22. Ebrahimi M., Eslami A, Hajirasouliha I., Ramezanpour M., Pilakoutas K: Effect of ceramic waste powder as a binder replacement on the properties of cement- and lime-based mortars. Construction and Building Materials 379(2023) 131146.
• 23. Alsaif A: Utilization of ceramic waste as partially cement substitute – A review. Construction and Building Materials 300(2021) 124009.
• 24. Nayana, A.M., Rakesh, P: Strength and durability study on cement mortar with ceramic waste and micro-silica. Materials Today: Proceedings 5(2018) 24780–24791.
• 25. Al Arab A., Hamad B., Chehab G., Assaad J.J: Use of ceramic-waste powder as value-added pozzolanic material with improved thermal properties. Journal of Materials in Civil Engineering 32 (2020).
• 26. EN 197-1 Cement Part 1: Composition, specifications and conformity criteria for common cements. European Committee for Standardization. 2000.
• 27. EN 196-1: Methods of testing cement - Part 1: Determination of strength. 2016.
• 28. ASTM-C597. Standard test method for pulse velocity through concrete, Annual Book of ASTM Standards. 2016.
• 29. Pitarch A.M., Reig L., Tomás A E: López F.J: Effect of Tiles, Bricks and Ceramic Sanitary-Ware Recycled Aggregates on Structural Concrete Properties. Waste and Biomass Valorization 10(2019).

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).