Use of waste stone powder to improve performance of problematic soils - A Review.

Sherwany, Jaylan Haji; Kakrasul, Jamal Ismael

doi:10.37649/aengs.2023.142979.1062

	Use of waste stone powder to improve performance of problematic soils - A Review.
Anbar Journal of Engineering Sciences
Volume 14, Issue 2, November 2023, Pages 27-39 PDF (621.58 K)
Document Type: Review Paper
DOI: 10.37649/aengs.2023.142979.1062
Authors
Jaylan Haji Sherwany¹; Jamal Ismael Kakrasul^* ²
¹Department of Civil Engineering, Faculty of Engineering, Soran University, Soran 44008, Kurdistan Region, Iraq
²Department of civil engineering, Soran University, Soran, Kurdistan Region, Iraq
Abstract
Problematic soils, especially clayey soil, are problematic for engineering projects in their natural state because of clay's swell-shrinkage phenomenon. Numerous methods and stabilizer materials have been used to enhance clay's geotechnical properties and make them appropriate for construction. One of the significant methods of stabilization of problematic soil is using waste materials like waste glass, waste stone, waste plastic, etc. Due to the waste stone's consistency reducing water content and increasing the soil's strength, it has been employed in many civil engineering studies. Waste stone is available in various forms, including waste stone powder (WSP). WSP is produced by blasting tunnels or cutting huge stone blocks. Hence, the main aim of this study is to review the influence of WSP on improving the geotechnical properties of problematic soils treated with WSP, for this purpose, the treated problematic soils with various percentages of WSP are compared with natural soils. This study evaluates physical properties (i.e., Index properties, linear shrinkage/swelling, optimum moisture content, and maximum dry density) and mechanical properties (i.e., unconfined compressive strength and California bearing ratio). Also, the effect of WSP on decreasing the thickness of pavement layers was reviewed
Keywords
Waste stone powder; Problematic soil; Unconfined compressive strength; California bearing ratio; Soil improvement and stabilization

References
Briscolland and R. Chown, “Problem soils: a review from a British perspective,” in Proceeding of Problematic Soils Conference, 2001, 53–66. Rezaei, R. Ajalloeian, and M. Ghafoori, “Geotechnical properties of problematic soils emphasis on collapsible cases,” International Journal of Geosciences, 3 (1), 105–110, 2012. H. Vakili, M. R. Bin Selamat, M. Salimi, and S. G. Gararei, “Evaluation of pozzolanic Portland cement as geotechnical stabilizer of a dispersive clay,” International Journal of Geotechnical Engineering, 15 (4), 504–511, 2021, https://doi: 10.1080/19386362.2019.1583515. H. Vakili, M. R. bin Selamat, M. Salimi, and M. S. Farhadi, “Effect of water quality on the filtration of dispersive base soils,” Arabian Journal of Geosciences, 14 (14), 2021, https://doi: 10.1007/s12517-021-07824-7. B. Khoshbakht, A. H. Vakili, M. S. Farhadi, and M. Salimi, “Reducing the negative impact of freezing and thawing cycles on marl by means of the electrokinetical injection of calcium chloride,” Cold Regions Science and Technology, 157, 196–205, 2019, https://doi: 10.1016/j.coldregions.2018.10.010. Waheed, M. U. Arshid, R. A. Khalid, and S. S. S. Gardezi, “Soil improvement using waste marble dust for sustainable development,” Civil Engineering Journal (Iran), 7 (9), 1594–1607, 2021, https://doi: 10.28991/cej-2021-03091746. K. Sharma and A. Bhardwaj, “Effect of construction demolition and glass waste on stabilization of clayey soil,” in International Conference on Sustainable Waste Management through Design, Springer, 2018, 87–94. Rabab’ah, O. Al Hattamleh, H. Aldeeky, and B. A. Alfoul, “Effect of glass fiber on the properties of expansive soil and its utilization as subgrade reinforcement in pavement applications,” Case Studies in Construction Materials, 14, e00485, 2021. Daraei et al., “Stabilization of problematic soil by utilizing cementitious materials,” Innovative Infrastructure Solutions, 4 (1), 1–11, 2019. K. Sharma and J. Hymavathi, “Effect of fly ash, construction demolition waste and lime on geotechnical characteristics of a clayey soil: a comparative study,” Environmental Earth Sciences, 75 (5), 377, 2016. H. Bahmani, B. B. K. Huat, A. Asadi, and N. Farzadnia, “Stabilization of residual soil using SiO2 nanoparticles and cement,” Construction and Building Materials, 64, 350–359, 2014, https://doi: 10.1016/j.conbuildmat.2014.04.086. F. Winterkorn and S. Pamukcu, “Soil stabilization and grouting,” in Foundation engineering handbook, Springer, 91, 317–378. Behnood, “Soil and clay stabilization with calcium-and non-calcium-based additives: A state-of-the-art review of challenges, approaches and techniques,” Transportation Geotechnics, 17, 14–32, 2018. Olufowobi, A. Ogundoju, B. Michael, and O. Aderinlewo, “Clay soil stabilisation using powdered glass,” Journal of Engineering Science and Technology, 9 (5), 541–558, 2014. Patel, “Soil stabilization,” in Geotechnical Investigations and Improvement of Ground Conditions, Elsevier, 19, 19–27. https://doi: 10.1016/B978-0-12-817048-9.00003-2. Gangwar and S. Tiwari, “Stabilization of soil with waste plastic bottles,” Materials Today: Proceedings, 47 (xxxx), 3802–3806, 2021, https://doi: 10.1016/j.matpr.2021.03.010. R. Kumar, R. S. Gadekari, G. Vani, and K. M. Mini, “Stabilization of black cotton soil and loam soil using reclaimed asphalt pavement and waste crushed glass,” Materials Today: Proceedings, 24, 379–387, 2020, https://doi: 10.1016/j.matpr.2020.04.289. A. M. Ogila, “The impact of natural ornamental limestone dust on swelling characteristics of high expansive soils,” Environmental Earth Sciences, 75 (24), 2016, https://doi: 10.1007/s12665-016-6305-y. L. McGeehan, “Impact of waste materials and organic amendments on soil properties and vegetative performance,” Applied and Environmental Soil Science, 2012, 2012, https://doi: 10.1155/2012/907831. -S. Ho, A. M. M. Sheinn, C. C. Ng, and C. T. Tam, “The use of quarry dust for SCC applications,” Cement and Concrete Research, 32 (4), 505–511, 2002. Ramos, A. M. Matos, B. Schmidt, J. Rio, and J. Sousa-Coutinho, “Granitic quarry sludge waste in mortar: Effect on strength and durability,” Construction and Building Materials, 47, 1001–1009, 2013. Medina, I. F. S. del Bosque, M. Frías, M. I. S. de Rojas, and C. Medina, “Durability of new recycled granite quarry dust-bearing cements,” Construction and Building Materials, 187, 414–425, 2018. Edinçliler and A. Cagatay, “Weak subgrade improvement with rubber fibre inclusions,” Geosynthetics International, 20 (1), 39–46, 2013, https://doi: 10.1680/gein.12.00038. H. Ibrahim, Y. I. Mawlood, and Y. M. Alshkane, “Using waste glass powder for stabilizing high-plasticity clay in Erbil city-Iraq,” International Journal of Geotechnical Engineering, 15 (4), 496–503, 2019, https://doi: 10.1080/19386362.2019.1647644. Balkaya, “Beneficial use of dredged materials in geotechnical engineering,” in Recycling and reuse approaches for better sustainability, Springer, 19, 21–38. Al-Baidhani and A. Al-Taie, “Stabilization of expansive soils using stone waste materials: a review,” IJO-International Journal of Mechanical and Civil Engineering, 2 (07), 1–7, 2019. A. M. Ogila, “The impact of natural ornamental limestone dust on swelling characteristics of high expansive soils,” Environmental Earth Sciences, 75 (24), 1–17, 2016. Roohbakhshan and B. Kalantari, “Stabilization of clayey soil with lime and waste stone powder,” Amirkabir Journal of Civil Engineering, 4 (48), 429–438, 2016. Chetia and A. Sridharan, “A review on the influence of rock quarry dust on geotechnical properties of soil,” in Geo-Chicago 2016, 16, 179–190. Sivrikaya, K. R. Kıyıldı, and Z. Karaca, “Recycling waste from natural stone processing plants to stabilise clayey soil,” Environmental Earth Sciences, 71 (10), 4397–4407, 2013, https://doi: 10.1007/s12665-013-2833-x. Karaca, A. Pekin, and A. H. Deliormanlı, “Classification of dimension stone wastes,” Environmental Science and Pollution Research, 19 (6), 2354–2362, 2012. Nayak and P. G. Sarvade, “Effect of cement and quarry dust on shear strength and hydraulic characteristics of lithomargic clay,” Geotechnical and Geological Engineering, 30 (2), 419–430, 2012. -Y. Xiao and W. Xu, “Assessment of strength development in cemented coastal silt admixed granite powder,” Construction and Building Materials, 206, 470–482, 2019. L. Roberts, P. S. Kandhal, E. R. Brown, D.-Y. Lee, and T. W. Kennedy, “Hot mix asphalt materials, mixture design and construction,” 1991. Hidalgo, G. Carvajal, and F. Muñoz, “Laboratory evaluation of finely milled brick debris as a soil stabilizer,” Sustainability, 11 (4), 967, 2019. D. Khadka, P. W. Jayawickrama, S. Senadheera, and B. Segvic, “Stabilization of highly expansive soils containing sulfate using metakaolin and fly ash based geopolymer modified with lime and gypsum,” Transportation Geotechnics, 23, 100327, 2020. Liu et al., “Stabilization of expansive soil using cementing material from rice husk ash and calcium carbide residue,” Construction and Building Materials, 221, 1–11, 2019. I Al-Azzo, “Treatment of expansive clayey soil in AL-Wahda Districtat Mosul City with crushed limestone,” Iraqi National Journal of Earth Sciences, 9 (2), 1–10, 2009. H. Ibrahim, Y. M. Alshkane, Y. I. Mawlood, K. M. G. Noori, and A. M. Hasan, “Improving the geotechnical properties of high expansive clay using limestone powder,” Innovative Infrastructure Solutions, 5 (3), 2020, https://doi: 10.1007/s41062-020-00366-z. Nakayenga, A. A. Cikmit, T. Tsuchida, and T. Hata, “Influence of stone powder content and particle size on the strength of cement-treated clay,” Construction and Building Materials, 305 (September), 124710, 2021. M. H. Mustafa, O. S. B. Al-Amoudi, S. Ahmad, M. Maslehuddin, and M. H. Al-Malack, “Utilization of Portland cement with limestone powder and cement kiln dust for stabilization/solidification of oil-contaminated marl soil,” Environmental Science and Pollution Research, 28 (3), 3196–3216, 2021. Yang et al., “Environmental and economical friendly ultra-high performance-concrete incorporating appropriate quarry-stone powders,” Journal of Cleaner Production, 260, 121112, 2020, https://doi: 10.1016/j.jclepro.2020.121112. Ural, C. Karakurt, and A. T. Cömert, “Influence of marble wastes on soil improvement and concrete production,” Journal of Material Cycles and Waste Management, 16 (3), 500–508, 2013, https://doi: 10.1007/s10163-013-0200-3. Mishra, S. N. Sachdeva, and R. Manocha, “Subgrade Soil Stabilization Using Stone Dust and Coarse Aggregate: A Cost Effective Approach,” International Journal of Geosynthetics and Ground Engineering, 5 (3), 2019, https://doi: 10.1007/s40891-019-0171-0. A. Blayi, A. F. H. Sherwani, F. H. R. Mahmod, and H. H. Ibrahim, “Influence of Rock Powder on the Geotechnical Behaviour of Expansive Soil,” International Journal of Geosynthetics and Ground Engineering, 7 (1), 2021, https://doi: 10.1007/s40891-021-00260-3. Fırat, G. Yılmaz, A. T. Cömert, and M. Sümer, “Utilization of marble dust, fly ash and waste sand (Silt-Quartz) in road subbase filling materials,” KSCE Journal of Civil Engineering, 16 (7), 1143–1151, 2012. Bayesteh, M. Sharifi, and A. Haghshenas, “Effect of stone powder on the rheological and mechanical performance of cement-stabilized marine clay/sand,” Construction and Building Materials, 262, 120792, 2020, https://doi: 10.1016/j.conbuildmat.2020.120792. Yorulmaz, O. Sivrikaya, and F. Uysal, “Evaluation of the bearing capacity of poor subgrade soils stabilized with waste marble powder according to curing time and freeze-thaw cycles,” Arabian Journal of Geosciences, 14 (5), 2021, https://doi: 10.1007/s12517-021-06749-5. Al-Joulani, “Effect of stone powder and lime on strength, compaction and CBR properties of fine soils,” Jordan Journal of Civil Engineering, 6 (1), 1–16, 2012. I. Akinwumi and C. A. Booth, “Experimental insights of using waste marble fines to modify the geotechnical properties of a lateritic soil,” Journal of Environmental Engineering and Landscape Management, 23 (2), 121–128, 2015, Sivrikaya, K. R. Kıyıldı, and Z. Karaca, “Recycling waste from natural stone processing plants to stabilise clayey soil,” Environmental Earth Sciences, 71 (10), 4397–4407, 2014. M. Segadães, M. A. Carvalho, and W. Acchar, “Using marble and granite rejects to enhance the processing of clay products,” Applied Clay Science, 30 (1), 42–52, 2005, https://doi: 10.1016/j.clay.2005.03.004. L. Pastor, J. Chai, and I. Sánchez, “Strength and Microstructure of a Clayey Soil Stabilized with Natural Stone Industry Waste and Lime or Cement,” Applied Sciences (Switzerland), 13 (4), 2023, https://doi: 10.3390/app13042583. F. Cabalar and R. A. Omar, “Stabilizing a silt using waste limestone powder,” Bulletin of Engineering Geology and the Environment, 82 (8), 300, 2023. Ahmed, L. D. Swindale, and S. A. EL‐SWAIFY, “Effects of adsorbed cations on physical properties of tropical red earths and tropical black earths: I. Plastic limit, percentage stable aggregates, and hydraulic conductivity,” Journal of Soil Science, 20 (2), 255–268, 1969. C. Dang, B. Fatahi, and H. Khabbaz, “Behaviour of Expansive Soils Stabilized with Hydrated Lime and Bagasse Fibres,” Procedia Engineering, 143 (Ictg), 658–665, 2016. HD 26/06, “Pavement design and maintenance-foundation,volume 7, Design Manual for Roads and Bridges (DMRB),” London: The Stationary Office, 2006.
Statistics Article View: 860 PDF Download: 49