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Bhatt, Pankaj, Sinha, Anil, Dayana P J, Mariya, Geetha Sreekantan, Parvathi, Hasan, Murtaza. (1403). Performance Evaluation of Zinc Tailing Waste Material for Embankment Construction: Experimental and Numerical Investigation. , 15(4), 1177-1191. doi: 10.22044/jme.2024.13368.2459
Pankaj Bhatt; Anil Kumar Sinha; Mariya Dayana P J; Parvathi Geetha Sreekantan; Murtaza Hasan. "Performance Evaluation of Zinc Tailing Waste Material for Embankment Construction: Experimental and Numerical Investigation". , 15, 4, 1403, 1177-1191. doi: 10.22044/jme.2024.13368.2459
Bhatt, Pankaj, Sinha, Anil, Dayana P J, Mariya, Geetha Sreekantan, Parvathi, Hasan, Murtaza. (1403). 'Performance Evaluation of Zinc Tailing Waste Material for Embankment Construction: Experimental and Numerical Investigation', , 15(4), pp. 1177-1191. doi: 10.22044/jme.2024.13368.2459
Bhatt, Pankaj, Sinha, Anil, Dayana P J, Mariya, Geetha Sreekantan, Parvathi, Hasan, Murtaza. Performance Evaluation of Zinc Tailing Waste Material for Embankment Construction: Experimental and Numerical Investigation. , 1403; 15(4): 1177-1191. doi: 10.22044/jme.2024.13368.2459

Performance Evaluation of Zinc Tailing Waste Material for Embankment Construction: Experimental and Numerical Investigation

Journal of Mining and Environment
مقاله 1، دوره 15، شماره 4، دی 2024، صفحه 1177-1191    اصل مقاله (9.63 M)
نوع مقاله: Original Research Paper
شناسه دیجیتال (DOI): 10.22044/jme.2024.13368.2459
نویسندگان
Pankaj Bhatt* 1؛ Anil Kumar Sinha2؛ Mariya Dayana P J2؛ Parvathi Geetha Sreekantan2؛ Murtaza Hasan1
1Department of Civil Engineering, Chandigarh University, Mohali, India
2CSIR-Central Road Research Institute, New Delhi, India
چکیده
The rapid development of road networks needs huge construction materials. Mining and industrial wastes can be used as sustainable road construction materials and will be alternatives to fulfill the huge demand in road construction. Zinc tailing is one such mining waste and has the potential for road construction. This material was collected from Zawar mines (Rajasthan), and characterization was carried out for embankment/subgrade applications. A physical model test was conducted in the laboratory to examine the stress-settlement behaviour. To improve the modulus value of tailing, it was reinforced with geogrid in two different laying patterns, viz. layer/loop and stress-settlement behavior was studied. Different parameters were studied: reinforcement depth, layer of reinforcement, number of loops, and depth of loop of reinforcement. The experimental result was validated with the numerical finite element method (SoilWorks). Tailing comprises fine-grained silt-size particles (61%) with no swelling behavior and non-plastic nature. It has values of MDD and OMC as 1.86 g/cm3 and 11%, respectively. It has a higher value of CBR (12%) and internal friction angle (34.6o) with cohesionless nature. The variation of settlement with stress is linear for reinforced and unreinforced tailing fill. As the depth of reinforcement increases, settlement increases in both layer and loop reinforcement. The settlement trajectory obtained from a numerical method closely resembles that of a laboratory physical model, particularly when the applied stress is up to 600 kPa. The modulus of elasticity of tailing was significantly improved with the introduction of geogrid reinforcement either in layer or loop.
کلیدواژه‌ها
Zinc tailing؛ waste material؛ geogrid؛ embankment؛ numerical analysis
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