PL EN


Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
Tytuł artykułu

Treatment of Collapsible Soils with Granulated Blast Furnace Slag and Calcined Eggshell Waste

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
In order to meet environmental and socio-economic challenges, the recycling of waste tobe used in the treatment of geotechnical problems is one of the main ways of preserving the environment with a lower economic value. The objective of this experimental work is to improve the characteristics and to study the mechanical behaviour of collapsible soil treated with a new hydraulic stabilizer composed of Crushed Granulated Blast Furnace Slag (CGBS) active by Eggshell Waste (CES). The specimens were mixed with stabilizer content, varying from 0 to 15% in mass, with an initial water content of 4, 6 and 8% respectively. in mass. Oedometer apparatus was used to study the addition of new hydraulic stabilizer effect on the Collapse Potential. Triaxial tests are also conducted to determine the shear strength parameters (cohesion and internal friction angle) of this treated soil. The results of this research study show that the mechanical properties of the treated collapsible soil were significantly improved. An appreciable reduction in the collapse potential is observed. The addition of 15% of this new stabilizer with initial water content of 4% under a compaction of 60 blows/ layer is capable of increasing internal friction angle and cohesion. It can be concluded from this study that the mixture of granulated slag and calcined eggshell can be used as an effective treatment of collapsibility phenomenon at low cost while protecting the environment from industrial waste.
Rocznik
Strony
138--162
Opis fizyczny
Bibliogr. 47 poz., fot., rys., tab., wykr.
Twórcy
  • University of 8 May 1945, Guelma, Algeria
  • University of 8 May 1945, Guelma, Algeria
  • University of 8 May 1945, Guelma, Algeria
Bibliografia
  • 1. Reznik, YM 1995. Settlements of bearing plates on collapsible loessial soils. Environmental and Engineering Geoscience 1, 153-162.
  • 2. Ayadat, T and Gherabli, A 1995. Traitement des sols affaissables par du ciment CPA. In: Annales de l’Institut technique du bâtiment et des travaux publics 530(SF-224), 33-44.
  • 3. Ayadat, T, Dahili, M and Ahmed, KMH 1998. Traitement d’un sol effondrable par un liant hydrocarboné (bitume). Revue française géotechnique 85, 57-64.
  • 4. Consoli, NC, Prietto, PDM and Ulbrich, LA 1998. Influence of fiber and cement addition on behavior of sandy soil. Journal geotechnical and geoenvironmental engineering 124, 1211-1214.
  • 5. Yetimoglu T and Salbas, O 2003. A study on shear strength of sands reinforced with randomly distributed discrete fibers. Geotextiles and Geomembranes 21, 103-110.
  • 6. Chauhan, MS, Mittal, S and Mohanty, B 2008. Performance evaluation of silty sand subgrade reinforced with fly ash and fibre. Geotextiles and geomembranes 26, 429-435.
  • 7. Ahmad, F, Bateni, F and Azmi, M 2010. Performance evaluation of silty sand reinforced with fibres. Geotextiles and geomembranes 28, 93-99.
  • 8. Abbeche, K, Bahloul, O, Ayadat, T and Bahloul, A 2010.Treatment of collapsible soils by salts using the double consolidation method. Geotechnical Special Publication, Shanghai , China, 69-78.
  • 9. Chegenizadeh, A and Nikraz, PH 2012. Study on Sand and paper reinforcement. International journal of emerging technology & advanced engineering 2, 199-202.
  • 10. Al Adili, A, Azzam, R, Spagnoli, G and Schrader, J 2012. Strength of soil reinforced with fiber materials (Papyrus). Soil Mechanics and Foundation Engineering 48, 241-247.
  • 11. Mohamed, AMO and Gamal, MM 2012. Treatment of collapsible soils using sulfur cement. International Journal of Geotechnical Engineering 6, 65-77.
  • 12. Ayadat, T and Hanna, AM 2012. Assessement of soil collapse prediction methods. International Journal of Engineering, Transactions B: Applications 25, 19-26.
  • 13. Abdeldjouad, L, Asadi, A, Nahazanan, H, Huat, BBK, Dheyab, W and Elkhebu, AG 2019. Effect of Clay Content on Soil Stabilization with Alkaline Activation. International Journal of Geosynthetics and Ground Engineering 5, 167-174.
  • 14. Zhang, M, Guo, H, El-Korchi, T, Zhang, G and Tao, M 2013. Experimental feasibility study of geopolymer as the next-generation soil stabilizer. Construction and Building Materials 47, 1468-1478.
  • 15. Hambirao, GS and Rakaraddi, DPG 2014. Soil Stabilization Using Waste Shredded Rubber Tyre Chips. IOSR Journal of Mechanical and Civil Engineering 11, 20-27.
  • 16. Fattah, MY, Al-Ani, MM and Al-Lamy, MTA 2014. Studying collapse potential of Gypseous soil treated by grouting. Soils and Foundations 54, 396-404.
  • 17. Botero, E, Ossa, A, Sherwell, G and Ovando-Shelley, E 2015. Stress-strain behavior of a silty soil reinforced with polyethylene terephthalate (PET). Geotextiles and Geomembranes 43, 363-369.
  • 18. Das, AP and Thyagaraj, T 2016. Effect of pore fluid on compressibility and collapse of clayey sand. Environmental Geotechnics 4, 432-443.
  • 19. Sarsam, S, Al Saidi, A and Al Taie, A 2016. Assessment of shear and compressibility properties of asphalt stabilized collapsible soil. Applied research journal 2, 481-487.
  • 20. Arabani, M and Lasaki, BA 2017. Behavior of a Simulated Collapsible Soil Modified with XPS-Cement Mixtures. Geotechnical and Geological Engineering 35, 137-155.
  • 21. Adjabi, S, Nouaouria, MS and Betehi, C 2018. Effect of reinforcement fibers on the collapse potential of clayey sands. 2nd International Congress on Materials & Structural Stability - MATEC Web of Conferences, Morocco,1-5.
  • 22. Kodicherla, SPK, Muktinuthalapati, J and Revanna, N 2018. Effect of randomly distributed fibre reinforcements on engineering properties of beach sand. Jordan Journal of Civil Engineering 12, 99-108.
  • 23. Lv, Q, Chang, C, Zhao, B and Ma, B 2018. Loess Soil Stabilization by Means of SiO2 Nanoparticles. Soil Mechanics and Foundation Engineering 54, 409-413.
  • 24. Xing, H and Liu, L 2018. Field tests on influencing factors of negative skin friction for pile foundations in collapsible loess regions. International journal civil engineering 16, 1413-1422.
  • 25. Bellil, S, Abbeche, K and Bahloul, O 2018. Treatment of a collapsible soil using a bentonite-cement mixture. Studia Geotechnica et Mechanica 40, 233-243.
  • 26. Ziani, H, Abbèche, K, Messaoudene, I and Andrade Pais, L J 2019. Treatment of Collapsible Soils by Additions of Granulated Slag and Natural Pozzolan. KSCE Journal of Civil Engineering 23, 1028-1042.
  • 27. Maher, M, Ho, Y and Pincus, H 1993. Behavior of Fiber-Reinforced Cemented Sand Under Static and Cyclic Loads. Geotechnical Testing Journal 16, 330.
  • 28. Lee, SJ and Oh, SH 2003. Fabrication of calcium phosphate bioceramics by using eggshell and phosphoric acid. Materials Letters 57, 4570-4574.
  • 29. Balázsi, C, Wéber, F, Kövér, Z, Horváth, E and Németh, C 2007. Preparation of calcium - phosphate bioceramics from natural resources. Journal of the European Ceramic Society 27, 1601-1606.
  • 30. Wei, Z, Xu, C and Li, B 2009. Application of waste eggshell as low-cost solid catalyst for biodiesel production. Bioresource Technology 100, 2883-2885.
  • 31. Bougara, A, Lynsdale, C and Ezziane, K 2009. Activation of Algerian slag in mortars. Construction and Building Materials 23, 542-547.
  • 32. Behim, M, Cyr, M and Clastres, P 2011. Physical and chemical effects of El Hadjar slag used as an additive in cement-based materials. European Journal of Environmental and Civil Engineering 15, 1413-1432.
  • 33. Lawton, EC, Fragaszy, R J and Hetherington, MD 1992. Review of wetting induced collapse in compacted soil. Journal of Geotechnical and Geoenvironmental Engineering 118, 1376-1394.
  • 34. Novaouria, MS, Harireche, O and Rouaiguia, A 2002. Comportement de l’affaissement de loess. In: Annales du bâtiment et des travaux publics 3, 37-41.
  • 35. Jennings, JE 1975. A guide to construction on or with materials exhibiting additional settlement due to collapse of grain structure. Proceedings of the 6th Regional Conference for Africa on Soil Mechanics and Foundation Engineering, Durban 99-105.
  • 36. ASTM D2850, 03a (2007), Standard Test Methods for Unconsolidated-Undrained Triaxial Compression Test on Cohesive Soils. ASTM International, West Conshohocken.
  • 37. Abbeche, K, Ayadat, T and Lahmadi A 2009. Traitement d’un sol á effondrement brusque par la chaux lime stabilisation of a collapsible soil. Séminaire International Innovation et Valorisation dans le Génie Civil, Hammamet, Tunisia, 161-168.
  • 38. Firoozfar A and Dousti, M 2019. Kerman collapsible clay amendment by lime, bentonite, and nano silica. Magazine of Civil Engineering 90, 119-129.
  • 39. Al Shaba, AA, Abdelaziz, TM and Ragheb, AM 2018. Treatment of collapsible soils by mixing with iron powder. Alexandria Engineering Journal 57, 3737-3745.
  • 40. Iranpour, B 2016. The influence of nanomaterials on collapsible soil treatment. Engineering Geology 205, 40-53.
  • 41. Bahloul, O, Abbeche, K, Bahloul, A and Halitim, A 2014. Effect of sodium chloride on the wetting induced collapse strain of soils. Malaysian Journal of Civil Engineering 26, 119-135.
  • 42. Kinuthia, JM, Wild, S and Jones, GI 1999. Effects of monovalent and divalent metal sulphates on consistency and compaction of lime-stabilised kaolinite. Applied Clay Science 14, 27-45.
  • 43. Nidzam RM and Kinuthia, JM 2010. Sustainable soil stabilisation with blastfurnace slag–a review. Proceedings of Institution of Civil Engineers: Construction Materials 163, 157-165.
  • 44. Sherwood, P 1993. Soil stabilization with cement and lime. London: Her Majesty Stationary Office.
  • 45. Tajdini, M, Bonab, MH and Golmohamadi, S 2018. An experimental investigation on effect of adding natural and synthetic fibres on mechanical and behavioural parameters of soil–cement materials. International journal civil engineering 16, 353-370.
  • 46. Huat, BBK, Aziz, AA, Ali, FH and Azmi, NA 2008. Effect of wetting on collapsibility and shear strength of tropical residual soils. Electronic Journal of Geotechnical Engineering 13, 1-44.
  • 47. Sathonsaowaphak, A, Chindaprasirt, P and Pimraksa, K 2009. Workability and strength of lignite bottom ash geopolymer mortar. Journal of Hazardous Materials 168, 44-50.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-4174556e-5afd-4e99-83e6-e18668c335ce
JavaScript jest wyłączony w Twojej przeglądarce internetowej. Włącz go, a następnie odśwież stronę, aby móc w pełni z niej korzystać.