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Some geotechnical properties of pure and waste gypsum for geoelectrical grounding applications

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Natural occurring gypsum is a soft mineral consists of hydrated calcium sulphate, mainly used in cement industry. On the other hand, red gypsum (RG) is a waste generated from a sulphate process of ilmenite ore to acquire titanium dioxide. Due to the gypsum content in both materials are similar, it is expected that both gypsum type can be used for similar engineering applications. In this study, RG was tested and compared to pure gypsum for geoelectrical grounding applications. The geotechnical properties and plasticity characteristics were carefully measured and tested. In addition, X-ray fluorescence (XRF) was employed to study the chemical constituents of the materials. Test results showed that, the geotechnical properties of RG is different to that of white gypsum. The plasticity index (PI) of RG was 239.6% greater due to the presence of Fe ions. Surprisingly, the electrical resistivity of both material were found to be similar. It was also noted that, although the plasticity of pure gypsum is high, the plasticity of pure gypsum was found to be short lived primarily due to instantaneous exothermic reaction between water and semihydrated gypsum. The change in the plasticity also affected the resistivity as gypsum hardened after short duration. Based on the geotechnical and plasticity characteristics determined, RG was found to be a better as grounding material as compared to gypsum.
Rocznik
Strony
97--106
Opis fizyczny
Bibliogr. 28 poz., tab., wykr.
Twórcy
  • Universiti Malaysia Pahang, Faculty of Civil Engineering and Earth Reources, Gambang, Kuantan (Pahang)
  • Universiti Malaysia Pahang, Faculty of Civil Engineering and Earth Reources, Gambang, Kuantan (Pahang)
  • Universiti Malaysia Pahang, Faculty of Civil Engineering and Earth Reources, Gambang, Kuantan (Pahang)
  • Universiti Malaysia Pahang, Faculty of Civil Engineering and Earth Reources, Gambang, Kuantan (Pahang)
Bibliografia
  • 1. Alphan, JG van and Romero, F. de los R 1971. Gypsiferous soils notes on their characteristics and management, International Institute for Land Reclamation and Improvement, p. 44.
  • 2. Cooper, AH and Calow, RC 1998. Avoiding gypsum geohazards: guidance for planning and construction, Water, p. 57.
  • 3. Herrero, J and Porta, J 2000. The terminology and the concepts of gypsumrich soils, Geoderma, 96(1–2), p. 47–61.
  • 4. Bhamidipati, R 2016. Use Of Laboratory Geophysical And Geotechnical Investigation Methods To Characterize Gypsum Rich Soils. MSc dissertation, University of Kentucky.
  • 5. Samson, G, Phelipot-Mardelé, A and Lanos, C 2017. Thermal and mechanical properties of gypsum–cement foam concrete: effects of surfactant, European Journal of Environmental and Civil Engineering. 21(12), p. 1502–1521.
  • 6. Tang, J et al 2018. An empirical rate law for gypsum powder dissolution, Chemical Geology, 498(September), pp. 96-105.
  • 7. Rahman, M and Ghataora, G 2011. Use of waste gypsum for trench backfill. International Journal of Geotechnical Engineering, 5(4), 405-413.
  • 8. Azdarpour, A et al 2018. CO2 sequestration through direct aqueous mineral carbonation of red gypsum’, Petroleum. Elsevier Taiwan LLC, 4(4), pp. 398-407.
  • 9. Fauziah, I, Zauyah, S and Jamal, T 1996. Characterization and land application of red gypsum: A waste product from the titanium dioxide industry, Science of the Total Environment, 188(2–3), pp. 243–251.
  • 10. Kamarudin, RA and Zakaria, MS 2007. The Utilization of Red Gypsum Waste for Glazes., Malaysian Journal of Analytical Sciences, 11(1), pp. 57-64.
  • 11. Hughes, PN et al 2011. Use of red gypsum in soil mixing engineering applications, Proceedings of the Institution of Civil Engineers - Geotechnical Engineering, 164(3), pp. 223–234.
  • 12. August, AE, Noble, BC and Tooze, JF 2013. Red gypsum in civil engineering applications.
  • 13. Gazquez, MJ et al 2013. Cement & Concrete Composites Evaluation of the use of TiO 2 industry red gypsum waste in cement production, Cement and Concrete Composites, 37, pp. 76–81.
  • 14. Hasni, NAM, Abd-Rahman, R, Ahmad, H, Jamail, NAM, Kamaruddin, MS and Ridzwan, SS 2017. Investigation of Potential Grounding Compound for Portable Applications. International Journal of Electrical and Computer Engineering, 7(6), 3140.
  • 15. Lim, SC et al 2015. Behaviour of backfill materials for electrical grounding systems under high voltage conditions, Journal of Engineering Science and Technology, 10(6), pp. 811–826.
  • 16. Moh Nazar, NS, Thanakodi, S and Muhammad, H 2018. New Waste Material to Enhance the Performance of Grounding System, TELKOMNIKA (Telecommunication Computing Electronics and Control), 15(4), p. 1530.
  • 17. Louie, O et al 2012. Characterization of the Gypsum Composite for Electrical Conductivity, American Journal of Chemistry, 2(5), pp. 245–247.
  • 18. Keilmas, M 2018. Importance of the Electrical Properties of Gypsum, Leaf Group. Available at: https://sciencing.com/info-12026554-importanceelectrical-properties-gypsum.html.
  • 19. Guinea, A, Playà, E, Rivero, L, Himi, M and Bosch, R 2010. Geoelectrical classification of gypsum rocks. Surveys in geophysics, 31(6), 557-580.
  • 20. Tadza, MYM 2011. Soil-water characteristic curves and shrinkage behaviour of highly plastic clays: an experimental investigation. PhD Thesis, Cardiff University.
  • 21. Tadza, MYM, Azmi, NSM, Mustapha, R, Desa, ND and Samuding, K 2017. Malaysian alternative to international reference bentonite buffer in underground nuclear waste repository. AIP Conference Proceedings 1799(1) p. 030002. AIP Publishing.
  • 22. Tripathy, S, Tadza, MYM and Thomas, HR 2014. Soil-water characteristic curves of clays. Canadian geotechnical journal, 51(8), 869-883.
  • 23. Mitchell, JK and Soga, K 2005. Fundamentals of soil behavior (Vol. 3). Hoboken, NJ: John Wiley & Sons.
  • 24. Tadza, MM, Mohamad, D, Tripathy, S, Rahman, RA and Ismail, MAM 2019. Bentonite and marconite for electrical grounding applications from geotechnical engineering perspective. In AIP Conference Proceedings 2129(1), 020078. AIP Publishing.
  • 25. Zhang, H 2011. Building materials in civil engineering. Elsevier.
  • 26. Schilling, CH 2001. Colloid Casting in Encyclopedia of Materials: Science and Technology.
  • 27. Cizman, A et al 2017. The effect of Fe on the structure and electrical conductivity of sodium borosilicate glasses, Physical Chemistry Chemical Physics, 19(34), pp. 23318–23324.
  • 28. Rahimi, S and Siddiqua, S 2017. Relationships between degree of saturation, total suction, and electrical and thermal resistivity of highly compacted bentonite. Journal of Hazardous, Toxic, and Radioactive Waste, 22(2), 04017025.
Uwagi
PL
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-2dc68073-4601-49d3-93b4-b1f0e11724f3
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