A case laboratory study on effect of quarry dust based geopolymer on physical and mechanical properties of laterit soil

  • Affiliations:

    1 Civil Engineering Faculty, Hanoi University of Mining and Geology, Vietnam
    2 Civil Engineering Faculty, University of Transport Technology, Vietnam
    3 Bac Kan City Department of Transportation and Communication, Vietnam4 Department of Civil Engineering, Michael Okpara University of Agriculture, Umudike, P. M. B. 7267, Umuahia 440109, Abia State, Nigeria

  • *Corresponding:
    This email address is being protected from spambots. You need JavaScript enabled to view it.
  • Received: 15th-Oct-2020
  • Revised: 23rd-Nov-2020
  • Accepted: 31st-Dec-2020
  • Online: 31st-Dec-2020
Pages: 48 - 56
Views: 2222
Downloads: 607
Rating: 1.0, Total rating: 60
Yours rating

Abstract:

This paper presents a case study on the laboratory examination of quarry dust based geopolymer on some physical and mechanical properties of stabilized laterit soil. The laboratory test results indicate that both CBR and shrinkage limit of studied soil increased substantailly with increased rate of quarry dust based geopolymer (QD-based geopolymer). Specifically, the laterit soils were treated with QD-based geopolymer in the proportions of 10%, 20%, 20%, 30%, 40%, 50%, 60%, respectively, by weight of dry soil; the CBR values were increased from 7.4% to 35.71% at proportion of 40% QD-based geopolymer. The obtained CBR value of 35.71% meets the requirement to be used as filled meterials for pavement purpose according to the TCVN 8857:2012. In constrast with the increase in CBR and shrinkage values, the swelling potential of treated soils was found to be decreased with raising QD-geopolymer proportion, for example, the swelling potential decreased from 14.5÷6.9% as adding 10, and 60% of QD- based geopolymer, respectively .

How to Cite
Bui, D.Van, Dao, L.Phuc, Nguyen, M.Van, Nong, A.Quoc and O., K. 2020. A case laboratory study on effect of quarry dust based geopolymer on physical and mechanical properties of laterit soil (in Vietnamese). Journal of Mining and Earth Sciences. 61, 6 (Dec, 2020), 48-56. DOI:https://doi.org/10.46326/JMES.HTCS2020.07.
References

Abdel-Gawwad, H. A., (2016). A novel method to produce dry geopolymer cement powder. HBRC Journal, 12(1), 13-24.

Abdullah, H. H., (2020). Review of Fly-Ash-Based Geopolymers for Soil Stabilisation with Special Reference to Clay. Geosciences, 10(7), 249.

Casagrande, A. (1932). Research on the Atterberg limits of soils. Public Roads, 13(8), 121-136.

Davidovits, J., (2013). Geopolymer cement. A Review. Geopolymer Institute, Technical Papers, 21, 1-11.

Kennedy, C., (2018). Comparative Evaluation of Cementitious Agents Composite materials on Strength Improvement Behavior of Black Cotton Clay Soil. European Journal of Advances in Engineering and Technology, 5(6), 368-374.

Kumar, A., (2007). Influence of fly ash, lime, and polyester fibers on compaction and strength properties of expansive soil. Journal of Materials in Civil Engineering, 19(3), 242-248.

Provis, J. L., (2009). Geopolymers: Structures, processing, properties and industrial applications. Elsevier.

Soosan, T. G., (2001). Use of quarry dust in embankment and highway construction. Proceedings of Indian Geo-Technical Conference, 274-277.

Zhou, S., (2019). Study on physical-mechanical properties and microstructure of expansive soil stabilized with fly ash and lime. Advances in Civil Engineering, 2019. 

Other articles