Sustainable soil stabilization: the use of waste materials to improve the engineering properties of soft soils

• Autorzy: Chmielewska Iwona , Gosk Wojciech

Identyfikatory

DOI

10.37105/iboa.148

• Języki publikacji: EN

Abstrakty

EN

One of the biggest challenges of recent civil engineering is the need to make it sustainable by implementing environmentally friendly and cost-effective solutions. The search for new materials and technologies is an important and current issue also in the strengthening of soft soils. In the soft soil stabilization process, conventional materials (cement and lime) are being replaced by waste materials, such as stone slurry waste, spent coffee grounds, rice husk ash, crushed waste concrete and glass, natural fibers, sawdust, waste tire rubber and plastic waste materials. Appropriate waste admixture content contributes to soil reinforcement by reducing compressibility and increasing maximum density and shear strength. The application of waste as an admixture is an economically and ecologically beneficial method of soil improvement. It eliminates the cost of materials and helps to reduce the problem of waste disposal, which is sometimes very expensive and problematic. The study aims to analyze the effect of waste materials on improving the physical and mechanical properties of soils based on the research results presented in the literature.

Słowa kluczowe

EN

sustainability; circular economy; waste materials; geotechnical engineering

PL

rozwój zrównoważony; gospodarka o obiegu zamkniętym; odpady; inżynieria geotechniczna

• Wydawca: Centrum Rzeczoznawstwa Budowlanego Sp. z o.o.
• Czasopismo: Inżynieria Bezpieczeństwa Obiektów Antropogenicznych
• Rocznik: 2022
• Tom: Nr 3
• Strony: 34--41
• Opis fizyczny: Bibliogr. 26 poz., tab.

Twórcy

autor

Chmielewska Iwona

• Bialystok University of Technology, Faculty of Civil Engineering and Environmental Sciences, Bialystok, Poland

• https://orcid.org/0000-0001-6356-1188

autor

Gosk Wojciech

• Bialystok University of Technology, Faculty of Civil Engineering and Environmental Sciences, Bialystok, Poland

• https://orcid.org/0000-0001-5376-4686

Bibliografia

• 1. Al-Joulani, N. (2014). Utilization of stone slurry powder in production of artificial stones. Research Journal in Engineering and Applied Sciences, 3(4), 245–249.
• 2. Amiri, S. T., Nazir, R., Dehghanbanadaki, A. (2018). Experimental study of geotechnical characteristics of crushed glass mixed with kaolinite soil. International Journal of GEOMATE, 14(45), 170–176.
• 3. Attom, M. F., El-Emam, M. (2011). Soil stabilization using stone-slurry-waste recovered from cutting stone process in rock quarries. Journal of Solid Waste Technology and Management, 37(2), 141–152.
• 4. Azam, M. S., Sharma, A. K., Agarwal, A., Verma, R., Singh, L., Jee, N. (2020). Altering the geotechnical properties of clayey soil by using scrap rubber. International Journal of Engineering Research & Technology, 9(7), 199–203.
• 5. Bawadi, N. F., Ahmad, N. S., Mansor, A. F., Anuar, S. A., Rahim, M. A. (2020). Effect of natural fibers on the soil compaction characteristics. Earth and Environmental Science, 476, 1–5.
• 6. Bedaiwy, M.-N. A., Maksoud, Y. S. A., Saad, A. F. (2019). Coffee grounds as a soil conditioner: Effects on physical and mechanical properties – II. Effects on mechanical properties. Polish Journal of Soil Science, 52(2), 277–293.
• 7. Brahmachary, T. K., Ahsan, M. K., Rokonuzzaman, M. (2019). Impact of rice husk ash (RHA) and nylon fber on the bearing capacity of organic soil. SN Applied Sciences, 1(3), 1–13.
• 8. Chittoori, B. S., Puppala, A. J., Reddy, R. K., Marshall, D. (2012). Sustainable reutilization of excavated trench material. ASCE GeoCongress, Oakland, California, 4280–4289.
• 9. Chu, J., Varaskin, S., Klotz, U., Menge, P. (2009). Construction Processes. Proceedings of the 17th International Conference on Soil Mechanics and Geotechnical Engineering, Alexandria, Egypt, 3006–3135.
• 10. Devi, K., Chhachhia, A., Kumar, A. (2020). Soil improvement using waste materials: A review. Journal of Building Material Science, 2(1), 11–17.
• 11. Edil, T. B., Bosscher, P. J. (1994). Engineering properties of tire chips and soil mixtures. Geotechnical Testing Journal, 17(4), 454–464.
• 12. Gomes Correia, A., Winter, M. G., Puppala, A. J. (2016). A review of sustainable approaches in transport infrastructure geotechnics. Transportation Geotechnics, 7, 21–28.
• 13. Harlten, J. (1996). Methods of Construction. In: Harlten J., Wolski W. (Eds.), Embankments on Organic Soils. Amsterdam: Elsevier Science B.V.
• 14. Hassan, H. J. A., Rasul, J., Samin, M. (2021). Effects of plastic waste materials on geotechnical properties of clayey soil. Transportation Infrastructure Geotechnology, 8, 390–413.
• 15. Huat, B. B. K., Prasad, A., Asadi, A., Kazemian, S. (2014). Geotechnics of Organic Soils and Peat. London: Taylor & Francis Group.
• 16. Ibrahim, O. A., Cabalar, A. F., Abdulnafaa, M. D. (2018). Improving some geotechnical properties of an organic soil using crushed waste concrete. The International Journal of Energy & Engineering Sciences, 3(3), 100–112.
• 17. Ilies, N., Farcas, V., Gherman, C., Chiorean, V., Popa, D. (2015). Soils efficient improvement solutions with waste materials and binders. Journal of Environmental Protection and Ecology, 16(4), 1397–1406.
• 18. Karkush, M. O., Yassin, S. (2019). Improvement of geotechnical properties of cohesive soil using crushed concrete. Civil Engineering Journal, 5(10), 2110–2119.
• 19. Kazmi, D., Williams, D. J., Serati, M. (2019). Waste glass in civil engineering applications – A review. International Journal of Applied Ceramic Technology, 17(3), 529–554.
• 20. McNutt, J., He, Q. (2018). Spent coffee grounds: A review on current utilization. Journal of Industrial and Engineering Chemistry, 1–11.
• 21. Nicholson, P. G. (2015). Soil improvement and ground modification methods. Waltham: Elsevier Inc.
• 22. Niyomukiza, J. B., Wardani, S. P. R., Setiadji, B. H. (2020). The influence of Keruing sawdust on the geotechnical properties of expansive soils. Earth and Environmental Science, 448, 1–10.
• 23. Perera, S. T. A. M., Saberian, M., Zhu, J., Roychand, R., Li, J. (2022). Effect of crushed glass on the mechanical and microstructural behaviour of highly expansive clay subgrade. Case Studies in Construction Materials, 17, 1–19.
• 24. Sanjay, M. R., Arpitha, G. R., Naik, L. L., Gopalakrishna, K., Yogesha, B. (2016). Applications of natural fibers and its composites: An overview. Natural Resources, 7(3), 108-114.
• 25. Sun, S., Liu, B., Wang, T. (2018). Improvement of expansive soil properties using sawdust. The Journal of Solid Waste Technology and Management, 44(1), 78-85.
• 26. Vincevica-Gaile, Z., Teppand, T., Kriipsalu, M., Krievans, M., Jani, Y., Klavins, M., Setyobudi, R. H., Grinfelde, I., Rudovica, V., Tamm, T., Shanskiy, M., Saaremae, E., Zekker, I., Burlakovs, J. (2021). Towards sustainable soil stabilization in peatlands: Secondary raw materials as an alternative. Sustainability, 13, 1–24

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).