Research Article
BibTex RIS Cite

A Comparative Study on the use of Waste Brick and Glass in Cement Mortars and their Effects on Strength Properties

Year 2023, Volume: 8 Issue: 4, 269 - 277, 19.12.2023
https://doi.org/10.47481/jscmt.1343456

Abstract

Sustainable development of the construction industry should use recycled materials to the great- est extent to reduce natural hazards due to the increased accumulation of waste and the deple- tion of natural resources. However, engineering applications using waste materials are always expected to perform satisfactorily. In this aspect, detailed and systematically carried out experi- mental studies are critical in selecting the type and the quantities of waste materials that will be recycled through their use within engineering applications. This study provides systematically produced experimental data on compressive and flexural strength performance to quantitatively compare the effects of using different percentages of waste glass and brick aggregates in cement mortars with a specified workability characteristic. Results show that mortar samples with waste glass aggregates perform better under compressive loading since only around 14% strength de- crease compared to the control mix was yielded with the inclusion of waste glass. In contrast, in both cases, a 30% strength decrease was recorded with the inclusion of waste bricks for 100% replacement of natural sand in the mortars. In the case of flexural strength performance, 50% replacements of natural aggregates with waste bricks and glass yielded around 27% and 38% strength decrease, indicating that using waste brick in cement mortars could result in a better flexural strength performance in comparison, provided that its content is controlled. Replace- ment of natural sand in cement mortars with waste brick and glass yielded less significant flex- ural strength, decreasing the difference between the two types of wastes when the replacement ratio was as high as 100%. Hence, based on the presented experimental evidence, it is concluded that the decision on the type and the quantity of the waste materials to be used should be made considering the area of the use of the mortar and its expected service type.

References

  • De Brito, J., & Saikia, N. (2012). Recycled aggregate in concrete: use of industrial, construction, and demolition waste. Springer Science & Business Media.
  • Shi, C., & Zheng, K. (2007). A review on the use of waste glasses in cement and concrete production. Resources, conservation, and recycling, 52(2), 234-247.
  • Du, H. & Tan, K. H. (2013). Use of waste glass as sand in mortar: Part I – Fresh, mechanical and durability properties. Cement and Concrete Composites, 35(1), 109-117.
  • Aygün, B. F. (2021). An overview of the impact of using glass powder on mechanical, durability properties in self-compacting concrete. Journal of Sustainable Construction Materials and Technologies, 6(3), 116-123.
  • Dilbas, H. (2022). An investigation on the effect of aggregate distribution on physical and mechanical properties of recycled aggregate concrete (RAC). Journal of Sustainable Construction Materials and Technologies, 7(2), 108-118.
  • Dimaculangan, E. (2023). Current construction and demolition waste management strategies for Philippine construction sector – A systematic literature review. Journal of Sustainable Construction Materials and Technologies, 8(1), 47-56.
  • Maurenbrecher, A. P. (2004). Mortars for repair of traditional masonry. Practice Periodical On Structural Design And Construction, 9(2), 62-65.
  • Bektas, F., Wang, K., & Ceylan, H. (2009). Effects of crushed clay brick aggregate on mortar durability. Construction and Building Materials, 23(5), 1909-1914.
  • Zhu, L., & Zhu, Z. (2020). Reuse of clay brick waste in mortar and concrete. Advances in Materials Science and Engineering, 2020(1), 1-11.
  • Du, H. & Tan, K. H. (2013). Use of waste glass as sand in mortar: Part I – Fresh, mechanical and durability properties. Cement and Concrete Composites, 35(1), 109-117.
  • Lu, J. X., & Poon, C. S. (2018). Use of waste glass in alkali activated cement mortar. Construction and Building Materials, 160(1), 399-407.
  • Afnan, R., Hadiyatmoko, D., Meyarto, C., Muhammad, P., Satyarno, I., & Solehudin, A. P. (2014). Practical method for mix design of cement-based grout. Procedia Engineering, 95(2014), 356-365.
  • Alazzeh, A. M. A. (2018). The Effect of Aggregate Gradation on The Performance of Fresh and Hardened Cement Grout. [Graduate Study Thesis, Faculty of Civil and Environmental Engineering, Near East University, Nicosia.]
  • ASTM C143 / C143M. (2020). Standart Test Method for Slump of Hydraulic Cement Concrete (Standards Volume: 04.02).
  • ASTM C 939. (2002). Standard Test Method for Flow of Grout for Preplaced-Aggregate Concrete (Flow Cone Method) (Document No. ASTM-C939-02).
  • TS EN 197-1:2012. (2012). Cement - Section 1: Compound, properties and conformity criteria of general cements.
  • EN 933-1. (2012). Tests for geometrical properties of aggregates Part 1: Determination of particle size distribution. (Sieving method, European Norms).
  • BS 882. (1992). Specification for aggregates from natural sources for concrete. (European Norms).
  • EN 196-1. (2005). Methods of testing cement.
  • Akpinar, P., & Khashman, A. (2017). Intelligent classification system for concrete compressive strength. Procedia Computer Science, 120(1), 712-718.
  • Akpinar, P., & Khashman, A. (2017). Non-Destructive Prediction of Concrete Compressive Strength Using Neural Networks. Procedia Computer Science, 108(1), 2358-2362.
  • Akpinar P., Al-Gburi S. N. A., & Helwan A. (2022). Machine learning in concrete's strength prediction. Computers and Concrete, 29(6), 433-444.
  • EN 196-1. (2005). Methods of testing cement - Part 1: Determination of strength. (European Norms).
  • Bhat A. A., Irfan, Z., & Shafi Z. S. (2017). Utilization of surkhi as a partial replacement of sand in concrete. International Journal for Research in Applied Science & Engineering Technology, 8(12), 2321-9653.
  • Aboutaleb, D., Belaid, A., Chahour, K., & Safi, B. (2017). Use of refractory bricks as sand replacement in self-compacting mortar. Cogent Engineering, 4(1), 1360235.
  • Shakir, A. A. (2017). The use of crushed brick waste for the internal curing in cement mortar. Muthanna Journal of Engineering and Technology, 5(1), 16-21.
  • Demir, I., Simsek, O., & Yaprak, H. A. S. B. I. (2011). Performance of cement mortars replaced by ground waste brick in different aggressive conditions. Ceramics-Silikáty, 55(3), 268-275.
  • Bhandari, P. S., Dhale S. A., Ghutke V. S., & Pathan V. G. (2014). Influence of fine glass aggregate on cement mortar. International Journal of Engineering and Computer Science 3(1), 3607-3610.
  • Anoop, P., & Darshita, T. (2014). Study of strength and workability of different grades of concrete by partial re-placement of fine aggregate by crushed brick and recycled glass powder. International Journal of Science and Research, 3(6), 1-5.
  • Astm, C. (2007). 270. Standard specification for mortar for unit masonry. United States American Society for Testing and Materials, 2-13.
  • Abbas, Z. K., Abbood, A. A., & Awad, H. K. (2017). Some properties of mortar and concrete using brick, glass and tile waste as partial replacement of cement. International Journal of Science and Research, 6(5), 1210-1215.
  • Oyawa, W., Shitote, S., & Tuaum, A. (2018). Experimental Study of Self-Compacting Mortar Incorporating Recycled Glass Aggregate. Buildings, 8(2), 15.
  • Neville, A. M. (1995). Properties of Concrete. Longman.
  • National Ready Mix Concrete Association. (2000). Concrete in Practice; CIP 16 Flexural Strength of Concrete. (888-84NRMC).
  • Lee, D. T. C., & Lee, T. S. (2017). The effect of aggregate condition during mixing on the mechanical properties of oil palm shell (OPS) concrete. In MATEC Web of Conferences 87(01019).
Year 2023, Volume: 8 Issue: 4, 269 - 277, 19.12.2023
https://doi.org/10.47481/jscmt.1343456

Abstract

References

  • De Brito, J., & Saikia, N. (2012). Recycled aggregate in concrete: use of industrial, construction, and demolition waste. Springer Science & Business Media.
  • Shi, C., & Zheng, K. (2007). A review on the use of waste glasses in cement and concrete production. Resources, conservation, and recycling, 52(2), 234-247.
  • Du, H. & Tan, K. H. (2013). Use of waste glass as sand in mortar: Part I – Fresh, mechanical and durability properties. Cement and Concrete Composites, 35(1), 109-117.
  • Aygün, B. F. (2021). An overview of the impact of using glass powder on mechanical, durability properties in self-compacting concrete. Journal of Sustainable Construction Materials and Technologies, 6(3), 116-123.
  • Dilbas, H. (2022). An investigation on the effect of aggregate distribution on physical and mechanical properties of recycled aggregate concrete (RAC). Journal of Sustainable Construction Materials and Technologies, 7(2), 108-118.
  • Dimaculangan, E. (2023). Current construction and demolition waste management strategies for Philippine construction sector – A systematic literature review. Journal of Sustainable Construction Materials and Technologies, 8(1), 47-56.
  • Maurenbrecher, A. P. (2004). Mortars for repair of traditional masonry. Practice Periodical On Structural Design And Construction, 9(2), 62-65.
  • Bektas, F., Wang, K., & Ceylan, H. (2009). Effects of crushed clay brick aggregate on mortar durability. Construction and Building Materials, 23(5), 1909-1914.
  • Zhu, L., & Zhu, Z. (2020). Reuse of clay brick waste in mortar and concrete. Advances in Materials Science and Engineering, 2020(1), 1-11.
  • Du, H. & Tan, K. H. (2013). Use of waste glass as sand in mortar: Part I – Fresh, mechanical and durability properties. Cement and Concrete Composites, 35(1), 109-117.
  • Lu, J. X., & Poon, C. S. (2018). Use of waste glass in alkali activated cement mortar. Construction and Building Materials, 160(1), 399-407.
  • Afnan, R., Hadiyatmoko, D., Meyarto, C., Muhammad, P., Satyarno, I., & Solehudin, A. P. (2014). Practical method for mix design of cement-based grout. Procedia Engineering, 95(2014), 356-365.
  • Alazzeh, A. M. A. (2018). The Effect of Aggregate Gradation on The Performance of Fresh and Hardened Cement Grout. [Graduate Study Thesis, Faculty of Civil and Environmental Engineering, Near East University, Nicosia.]
  • ASTM C143 / C143M. (2020). Standart Test Method for Slump of Hydraulic Cement Concrete (Standards Volume: 04.02).
  • ASTM C 939. (2002). Standard Test Method for Flow of Grout for Preplaced-Aggregate Concrete (Flow Cone Method) (Document No. ASTM-C939-02).
  • TS EN 197-1:2012. (2012). Cement - Section 1: Compound, properties and conformity criteria of general cements.
  • EN 933-1. (2012). Tests for geometrical properties of aggregates Part 1: Determination of particle size distribution. (Sieving method, European Norms).
  • BS 882. (1992). Specification for aggregates from natural sources for concrete. (European Norms).
  • EN 196-1. (2005). Methods of testing cement.
  • Akpinar, P., & Khashman, A. (2017). Intelligent classification system for concrete compressive strength. Procedia Computer Science, 120(1), 712-718.
  • Akpinar, P., & Khashman, A. (2017). Non-Destructive Prediction of Concrete Compressive Strength Using Neural Networks. Procedia Computer Science, 108(1), 2358-2362.
  • Akpinar P., Al-Gburi S. N. A., & Helwan A. (2022). Machine learning in concrete's strength prediction. Computers and Concrete, 29(6), 433-444.
  • EN 196-1. (2005). Methods of testing cement - Part 1: Determination of strength. (European Norms).
  • Bhat A. A., Irfan, Z., & Shafi Z. S. (2017). Utilization of surkhi as a partial replacement of sand in concrete. International Journal for Research in Applied Science & Engineering Technology, 8(12), 2321-9653.
  • Aboutaleb, D., Belaid, A., Chahour, K., & Safi, B. (2017). Use of refractory bricks as sand replacement in self-compacting mortar. Cogent Engineering, 4(1), 1360235.
  • Shakir, A. A. (2017). The use of crushed brick waste for the internal curing in cement mortar. Muthanna Journal of Engineering and Technology, 5(1), 16-21.
  • Demir, I., Simsek, O., & Yaprak, H. A. S. B. I. (2011). Performance of cement mortars replaced by ground waste brick in different aggressive conditions. Ceramics-Silikáty, 55(3), 268-275.
  • Bhandari, P. S., Dhale S. A., Ghutke V. S., & Pathan V. G. (2014). Influence of fine glass aggregate on cement mortar. International Journal of Engineering and Computer Science 3(1), 3607-3610.
  • Anoop, P., & Darshita, T. (2014). Study of strength and workability of different grades of concrete by partial re-placement of fine aggregate by crushed brick and recycled glass powder. International Journal of Science and Research, 3(6), 1-5.
  • Astm, C. (2007). 270. Standard specification for mortar for unit masonry. United States American Society for Testing and Materials, 2-13.
  • Abbas, Z. K., Abbood, A. A., & Awad, H. K. (2017). Some properties of mortar and concrete using brick, glass and tile waste as partial replacement of cement. International Journal of Science and Research, 6(5), 1210-1215.
  • Oyawa, W., Shitote, S., & Tuaum, A. (2018). Experimental Study of Self-Compacting Mortar Incorporating Recycled Glass Aggregate. Buildings, 8(2), 15.
  • Neville, A. M. (1995). Properties of Concrete. Longman.
  • National Ready Mix Concrete Association. (2000). Concrete in Practice; CIP 16 Flexural Strength of Concrete. (888-84NRMC).
  • Lee, D. T. C., & Lee, T. S. (2017). The effect of aggregate condition during mixing on the mechanical properties of oil palm shell (OPS) concrete. In MATEC Web of Conferences 87(01019).
There are 35 citations in total.

Details

Primary Language English
Subjects Material Production Technologies
Journal Section Research Articles
Authors

Hasan Dilek This is me 0009-0009-6958-0107

Pınar Akpınar 0000-0002-6885-8105

Early Pub Date December 19, 2023
Publication Date December 19, 2023
Submission Date August 15, 2023
Acceptance Date October 7, 2023
Published in Issue Year 2023 Volume: 8 Issue: 4

Cite

APA Dilek, H., & Akpınar, P. (2023). A Comparative Study on the use of Waste Brick and Glass in Cement Mortars and their Effects on Strength Properties. Journal of Sustainable Construction Materials and Technologies, 8(4), 269-277. https://doi.org/10.47481/jscmt.1343456

88x31_3.png

Journal of Sustainable Construction Materials and Technologies is open access journal under the CC BY-NC license  (Creative Commons Attribution 4.0 International License)

Based on a work at https://dergipark.org.tr/en/pub/jscmt

E-mail: jscmt@yildiz.edu.tr