International Journal of Geological and Geotechnical Engineering

Open Access  Subscription or Fee Access

During the construction of the various structures, soil strength plays a vital role in structural performance. Hence, soil improvement techniques are needed to improve soil strength as well. This study aimed to improve shear strength of sandy soil using Granulated waste glass (GWG) and Micro steel fiber (MSF). In order to apply this idea, there have been taken two kinds of sandy soil such as fine sand (locally available in Kushtia) and coarse sand (locally available in Domar). As for basic properties of sand, fineness modulus, specific gravity, maximum dry density, etc. are determined from experimental results. After grounding the waste glasses into granulated form and cutting the 0.70 mm steel wire into a uniform size of 10 mm in length, the GWG and MSF have been mixed in the sand by various proportions namely 5%, 10% and 15% by weight. The observation on the soil improvement technique which is adopted in this paper is summarized that the cohesion of the Kushtia sand is increased up to 1376.7% for 10% MSF and angle of internal friction is increased up to 8.7% for 10% GWG. The cohesion of the Domar sand is increased up to 1877.5% for 10% MSF and angle of internal friction is increased up to 24.4% for 15% MSF. Therefore, it can be concluded that the shear strength becomes increase for both sand up to optimum content using the considered percentage of GWG and/or MSF.

Adunoye, G. O., Agbede, O. A. and Olorunfemi, M. O. (2018). Development of Shear Strength Model for Banded Gneiss Derived Soils. IOSR Journal of Applied Geology and Geophysics (IOSR-JAGG) 6(6):14-23, DOI: 10.9790/0990-0606011424

Akayuli, C., Ofosu, B., Nyako, S. O. and Opuni, K. O. (2013). The Influence of Observed Clay Content on Shear Strength and Compressibility of Residual Sandy Soils. International Journal of Engineering Research and Applications (IJERA) 3(4):2538-2542

Peethamparan, S. and Olek, J. (2008). Study of the Effectiveness of Cement Kiln Dusts in Stabilizing Na-montmorillonite Clay. Journal of Materials in Civil Engineering 20(2):137-146, DOI: 10.1061/(ASCE)0899-1561(2008)20:2(137)

Al-Azzo, S. I. (2009). Treatment of Expansive Clayey Soil in AL-Wahda District at Mosul City with Crushed Limestone. Iraqi National Journal of Earth Sciences 9(2):1-10

Abd-El-Aziz, M. A. and Abo-Hashema, M. A. (2013). Measured Effects on Engineering Properties of Clayey Subgrade using Lime–Homra Stabilizer. International Journal of Pavement Engineering 14(4):321-332, DOI: 10.1080/10298436.2012.655739

Sabat, A. K. (2013). Engineering Properties of an Expansive Soil Stabilized with Rice Husk Ash and Lime Sludge. International Journal of Engineering and Technology 5(6):4826-4833

Saxena, D. (2017). Effects of Marble Powder and Fine Sand on Properties of Expansive Soil. International Journal of Engineering Trends and Technology 52(1):12-16, DOI: 10.14445/22315381/IJETT-V52P203

Rathee, A., Shivdasani, G., Sharma, S. and Sharma, Y. (2018). Soil Stabilization using Powdered Glass. International Research Journal of Engineering and Technology (IRJET) 5(5):1054-1056

Olufowobi, J., Ogundoju, A., Michael, B. and Aderinlewo, O. (2014). Clay Soil Stabilization using Powdered Glass. Journal of Engineering Science and Technology 9(5):541-558

Hambirao, G. S. and Rakaraddi, P. G. (2014). Soil Stabilization using Waste Shredded Rubber Tyre Chips. IOSR Journal of Mechanical and Civil Engineering (IOSR-JMCE) 11(1):20-27

Kumari. B., Sonthwal, V. K. and Rattan, J. S. (2016). Soil Stabilization by using Waste Material: A Review. International Journal of Engineering Science Invention Research and Development 3(1):85-90

Arora, K. R. (2003). Soil Mechanic and Foundation Engineering. Standard Publishers Distributors, Delhi

Das, B. M. (2006). Principles of Geotechnical Engineering. Thomson Canada Limited, Canada

Aziz, M. A. (2016). A Textbook of Engineering Materials. University Campus Printing Press, Dhaka