Research Article
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Year 2023, Volume: 11 Issue: 1, 53 - 63, 01.07.2023
https://doi.org/10.51354/mjen.1211527

Abstract

References

  • Ding D., Song X., Wei C., LaChance J. A review on the sustainability of thermal treatment for contaminated soils. Environmental Pollution, 253, (2019), 449-463.
  • Vidonish J. E., Alvarez P. J., Zygourakis K. Pyrolytic Remediation of Oil-Contaminated Soils: Reaction Mechanisms, Soil Changes, and Implications for Treated Soil Fertility. Industrial & Engineering Chemistry Research, 57(10), (2018) 3489–3500.
  • Bykova M.V., Pashkevich M.A.. “Engineering and ecological survey of oil-contaminated soils in industrial areas and efficient way to reduce the negative impact” in Scientific and Practical Studies of Raw Material Issues. 1st Ed, ImprintCRC Press. 2019.
  • Kemelov K., Maymekov U., Sambaeva D., Maymekov Z. Reducing concentrations of Benzo (a) pyrene in gas phase soot particles by using and burning water fuel emulsions. Polish Journal of Environmental Studies, 29(4), (2020), 2669-2677.
  • Ossai I. C., Ahmed A., Hassan A., Hamid, F. S. Remediation of soil and water contaminated with petroleum hydrocarbon: A review. Environmental Technology & Innovation, Volume, 17, (2020), 100526
  • Zivdar Z., Heidarzadeh N., Asadollahfardi G. Remediation of diesel-contaminated soil by low-temperature thermal desorption. Int. J. Environ. Sci. Technol., 16, (2019), 6113–6124.
  • Lee T., Nam I.-H., Kim J.-H., Zhang M., Jeong T. Y., Baek K., Kwon E.E. The enhanced thermolysis of heavy oil contaminated soil using CO2 for soil remediation and energy recovery. Journal of CO2 Utilization, 28, (2018), 367–373.
  • Sang Y., Yu W., He L., Wang Z., Ma F., Jiao W., Gu Q. Sustainable remediation of lube oil-contaminated soil by low temperature indirect thermal desorption: Removal behaviors of contaminants, physicochemical properties change and microbial community recolonization in soils. Environmental Pollution, 287, (2021), 117599.
  • Lee S. H., Kim S. O., Lee S. W., Kim M. S., Park H. Application of Soil Washing and Thermal Desorption for Sustainable Remediation and Reuse of Remediated Soil. Sustainability, 13(22), (2021), 12523.
  • He L., Sang Y., Yu W., Lu T., Wang F., Ma F., Jiao W. Sustainable remediation of dibenzofuran-contaminated soil by low-temperature thermal desorption: Robust decontamination and carbon neutralization. Chemosphere, 302, (2022), 134810.
  • Li Y., Wei M., Yu B., Liu L., Xue Q. Thermal desorption optimization for the remediation of hydrocarbon- contaminated soils by a self-built sustainability evaluation tool. Journal of Hazardous Materials, (2022), 129156.
  • Bykova M.V., Alekseenko A.V., Pashkevich M.A., Drebenstedt C. Thermal desorption treatment of petroleum hydrocarbon-contaminated soils of tundra, taiga, and forest steppe landscapes. Environmental Geochemistry and Health, 43(6), (2021), 2331–2346.
  • Baymanov G. "Scientists of the Kyzylorda State University named after Korkyt-Ata have developed a method for cleaning oil-contaminated areas in an arid hot climate" 08/05/2017 Kyzylorda, Kazakhstan. https://www.kt.kz/rus/science/kizilordinskie_uchenie_usovershenstvovali_metod_ochistki_neftezagrjaznen nih_territorij_1153644002.html https://www.kt.kz [Accessed: 20 Sept. 2022].
  • Dzhusipbekov U.Zh., Nurgalieva G.O., Kuttumbetov M.A., Zhumasil E., Duisenbay D., Suleimenova O.Ya. Pilot- industrial testing of the process of processing oil-contaminated soil, Chemical Journal of Kazakhstan, 3, (2015), 234-240. (in Russian)
  • Dzhusipbekov U.Zh., Nurgaliyeva G.O., Kuttumbetov M.A., Zhumasil E. “Neutralization of oil-contaminated soil using humate-based energy-accumulating substance” Materals Vserossiyskoy scientific and practical. conference- Nizhnekamsk, 1, 88-89, 2015. (in Russian)
  • Dzhusipbekov U.Zh., Nurgalieva G.O., Bayakhmetova Z.K., Aizvert L.G. Determination of the hazard class of contaminated and neutralized soil - Chemical Journal of Kazakhstan - Almaty, 1 (65), (2019), 37-49 (in Russian)
  • Dzhusipbekov et al. Physical and chemical bases for the restoration of oil-contaminated and disturbed soils-Almaty, 1, (2022), 162-169 (in Russian)
  • Trusov B. G., Badrak S. A., Turov V. P., Baryshevskaya I. M. Automated system of thermodynamic data and calculations of equilibrium states. Mathematical methods of chemical thermodynamics, Novosibirsk: Nauka, (1982), 213-219. (in Russian)
  • Badrul I. Petroleum sludge, its treatment and disposal: a review. Int. J. Chem. Sci.13(4), (2015), 1584-1602.
  • Krzhizh L., Reznik D. Technology of cleaning the geological environment from oil pollution. Ecology of production, 10, (2007), 54. (in Russian)
  • Ivanov A.A., Yudina N.V., Maltseva E.V., Matis E.Ya. Study of biostimulating and detoxifying properties of humic acids of various origins in oil-contaminated soil. Chemistry of vegetable raw materials, 1, (2007), 99- 103. (in Russian)
  • Kolbasov G.A. “Assessment of the possibility of using industrial humates in the biological reclamation of oil-contaminated peat soils”. Dissertation, 03.02.13. – M.: Moscow State University. M.V. Lomonosov, 2011 (in Russian)

Prediction of the formation of low-molecular components, particles, and condensed phases during thermal destruction of oil-contaminated soil

Year 2023, Volume: 11 Issue: 1, 53 - 63, 01.07.2023
https://doi.org/10.51354/mjen.1211527

Abstract

In this study, thermodynamic modelling of the process of thermal destruction of oil-contaminated soil of Ozenmunaigas JSC, which includes compounds such as carbon, silicon, aluminum, iron, calcium, magnesium, sodium, potassium, chromium, phosphorus, manganese, copper, titanium, molybdenum, nickel, vanadium, and water, was carried out. The physicochemical and thermodynamic parameters of the complex system were calculated at P=0.1 MPa, T=598-3000 K. The concentration distribution of components, particles, and condensed phases in the gas phase has been established. In the process of thermal destruction of oil-contaminated soil, the formation of condensed phases was as follows: SiO2(c), Al2O3(c), AlO3H3(c), Cu(c), Cu2O(c), FeO(c), Fe2O3(c), Fe3O4(c), Fe2SiO4(c), NiO(c), MnO(c), Mn3O4(c), MnO2H2(c), Cr2O3(c), MoO2(c), V2O3(c), V2O4(c), TiO2(c), MgSiO3(c), Mg2SiO4(c), MgTi2O5(c), Ca3P2O8(c), Mg2SiO4(c), MgTi2O5(c), Ca3P2O8(c), CaCO3(c), CaSiO3(c), CaTiO3(c), Na2Si2O5(c), K2Si4O9(c). At the same time, the amount of condensed calcium silicate CaSiO3(c) was significant and amounted to 3.2 mol/kg, which is due to the initial standard content of oxides of the type (g/kg): SiO2-473,7, CaO-181,5 in oil-contaminated soil. The formation of various types of condensed phases (from 10-30 to 10-4 mol/kg) during thermal degradation can help reduce the synergism and toxicity of metal particles in oil-contaminated soils. In the process of thermal destruction of oil-contaminated soil, its carbon-containing components (mg/kg: С12-6,27; С13-10,98; С14-15,69; С15-18,82; С16-23,52; С17-31,37; С18-27,80; С19-17,25; С20-29,80) were mainly converted into oxide, carbon dioxide, and water, and thereby neutralized the organic mass of the soil.

References

  • Ding D., Song X., Wei C., LaChance J. A review on the sustainability of thermal treatment for contaminated soils. Environmental Pollution, 253, (2019), 449-463.
  • Vidonish J. E., Alvarez P. J., Zygourakis K. Pyrolytic Remediation of Oil-Contaminated Soils: Reaction Mechanisms, Soil Changes, and Implications for Treated Soil Fertility. Industrial & Engineering Chemistry Research, 57(10), (2018) 3489–3500.
  • Bykova M.V., Pashkevich M.A.. “Engineering and ecological survey of oil-contaminated soils in industrial areas and efficient way to reduce the negative impact” in Scientific and Practical Studies of Raw Material Issues. 1st Ed, ImprintCRC Press. 2019.
  • Kemelov K., Maymekov U., Sambaeva D., Maymekov Z. Reducing concentrations of Benzo (a) pyrene in gas phase soot particles by using and burning water fuel emulsions. Polish Journal of Environmental Studies, 29(4), (2020), 2669-2677.
  • Ossai I. C., Ahmed A., Hassan A., Hamid, F. S. Remediation of soil and water contaminated with petroleum hydrocarbon: A review. Environmental Technology & Innovation, Volume, 17, (2020), 100526
  • Zivdar Z., Heidarzadeh N., Asadollahfardi G. Remediation of diesel-contaminated soil by low-temperature thermal desorption. Int. J. Environ. Sci. Technol., 16, (2019), 6113–6124.
  • Lee T., Nam I.-H., Kim J.-H., Zhang M., Jeong T. Y., Baek K., Kwon E.E. The enhanced thermolysis of heavy oil contaminated soil using CO2 for soil remediation and energy recovery. Journal of CO2 Utilization, 28, (2018), 367–373.
  • Sang Y., Yu W., He L., Wang Z., Ma F., Jiao W., Gu Q. Sustainable remediation of lube oil-contaminated soil by low temperature indirect thermal desorption: Removal behaviors of contaminants, physicochemical properties change and microbial community recolonization in soils. Environmental Pollution, 287, (2021), 117599.
  • Lee S. H., Kim S. O., Lee S. W., Kim M. S., Park H. Application of Soil Washing and Thermal Desorption for Sustainable Remediation and Reuse of Remediated Soil. Sustainability, 13(22), (2021), 12523.
  • He L., Sang Y., Yu W., Lu T., Wang F., Ma F., Jiao W. Sustainable remediation of dibenzofuran-contaminated soil by low-temperature thermal desorption: Robust decontamination and carbon neutralization. Chemosphere, 302, (2022), 134810.
  • Li Y., Wei M., Yu B., Liu L., Xue Q. Thermal desorption optimization for the remediation of hydrocarbon- contaminated soils by a self-built sustainability evaluation tool. Journal of Hazardous Materials, (2022), 129156.
  • Bykova M.V., Alekseenko A.V., Pashkevich M.A., Drebenstedt C. Thermal desorption treatment of petroleum hydrocarbon-contaminated soils of tundra, taiga, and forest steppe landscapes. Environmental Geochemistry and Health, 43(6), (2021), 2331–2346.
  • Baymanov G. "Scientists of the Kyzylorda State University named after Korkyt-Ata have developed a method for cleaning oil-contaminated areas in an arid hot climate" 08/05/2017 Kyzylorda, Kazakhstan. https://www.kt.kz/rus/science/kizilordinskie_uchenie_usovershenstvovali_metod_ochistki_neftezagrjaznen nih_territorij_1153644002.html https://www.kt.kz [Accessed: 20 Sept. 2022].
  • Dzhusipbekov U.Zh., Nurgalieva G.O., Kuttumbetov M.A., Zhumasil E., Duisenbay D., Suleimenova O.Ya. Pilot- industrial testing of the process of processing oil-contaminated soil, Chemical Journal of Kazakhstan, 3, (2015), 234-240. (in Russian)
  • Dzhusipbekov U.Zh., Nurgaliyeva G.O., Kuttumbetov M.A., Zhumasil E. “Neutralization of oil-contaminated soil using humate-based energy-accumulating substance” Materals Vserossiyskoy scientific and practical. conference- Nizhnekamsk, 1, 88-89, 2015. (in Russian)
  • Dzhusipbekov U.Zh., Nurgalieva G.O., Bayakhmetova Z.K., Aizvert L.G. Determination of the hazard class of contaminated and neutralized soil - Chemical Journal of Kazakhstan - Almaty, 1 (65), (2019), 37-49 (in Russian)
  • Dzhusipbekov et al. Physical and chemical bases for the restoration of oil-contaminated and disturbed soils-Almaty, 1, (2022), 162-169 (in Russian)
  • Trusov B. G., Badrak S. A., Turov V. P., Baryshevskaya I. M. Automated system of thermodynamic data and calculations of equilibrium states. Mathematical methods of chemical thermodynamics, Novosibirsk: Nauka, (1982), 213-219. (in Russian)
  • Badrul I. Petroleum sludge, its treatment and disposal: a review. Int. J. Chem. Sci.13(4), (2015), 1584-1602.
  • Krzhizh L., Reznik D. Technology of cleaning the geological environment from oil pollution. Ecology of production, 10, (2007), 54. (in Russian)
  • Ivanov A.A., Yudina N.V., Maltseva E.V., Matis E.Ya. Study of biostimulating and detoxifying properties of humic acids of various origins in oil-contaminated soil. Chemistry of vegetable raw materials, 1, (2007), 99- 103. (in Russian)
  • Kolbasov G.A. “Assessment of the possibility of using industrial humates in the biological reclamation of oil-contaminated peat soils”. Dissertation, 03.02.13. – M.: Moscow State University. M.V. Lomonosov, 2011 (in Russian)
There are 22 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Research Article
Authors

Umirzak Dzhusipbekov This is me 0000-0002-2354-9878

Dametken Fischer 0000-0001-8326-1545

Gulzipa Nurgalieva This is me 0000-0003-2659-3361

Kubat Kemelov 0000-0001-7375-6325

Damira Sambaeva 0000-0002-9834-341X

Zarlık Maymekov 0000-0002-9117-262X

Early Pub Date June 23, 2023
Publication Date July 1, 2023
Published in Issue Year 2023 Volume: 11 Issue: 1

Cite

APA Dzhusipbekov, U., Fischer, D., Nurgalieva, G., Kemelov, K., et al. (2023). Prediction of the formation of low-molecular components, particles, and condensed phases during thermal destruction of oil-contaminated soil. MANAS Journal of Engineering, 11(1), 53-63. https://doi.org/10.51354/mjen.1211527
AMA Dzhusipbekov U, Fischer D, Nurgalieva G, Kemelov K, Sambaeva D, Maymekov Z. Prediction of the formation of low-molecular components, particles, and condensed phases during thermal destruction of oil-contaminated soil. MJEN. July 2023;11(1):53-63. doi:10.51354/mjen.1211527
Chicago Dzhusipbekov, Umirzak, Dametken Fischer, Gulzipa Nurgalieva, Kubat Kemelov, Damira Sambaeva, and Zarlık Maymekov. “Prediction of the Formation of Low-Molecular Components, Particles, and Condensed Phases During Thermal Destruction of Oil-Contaminated Soil”. MANAS Journal of Engineering 11, no. 1 (July 2023): 53-63. https://doi.org/10.51354/mjen.1211527.
EndNote Dzhusipbekov U, Fischer D, Nurgalieva G, Kemelov K, Sambaeva D, Maymekov Z (July 1, 2023) Prediction of the formation of low-molecular components, particles, and condensed phases during thermal destruction of oil-contaminated soil. MANAS Journal of Engineering 11 1 53–63.
IEEE U. Dzhusipbekov, D. Fischer, G. Nurgalieva, K. Kemelov, D. Sambaeva, and Z. Maymekov, “Prediction of the formation of low-molecular components, particles, and condensed phases during thermal destruction of oil-contaminated soil”, MJEN, vol. 11, no. 1, pp. 53–63, 2023, doi: 10.51354/mjen.1211527.
ISNAD Dzhusipbekov, Umirzak et al. “Prediction of the Formation of Low-Molecular Components, Particles, and Condensed Phases During Thermal Destruction of Oil-Contaminated Soil”. MANAS Journal of Engineering 11/1 (July 2023), 53-63. https://doi.org/10.51354/mjen.1211527.
JAMA Dzhusipbekov U, Fischer D, Nurgalieva G, Kemelov K, Sambaeva D, Maymekov Z. Prediction of the formation of low-molecular components, particles, and condensed phases during thermal destruction of oil-contaminated soil. MJEN. 2023;11:53–63.
MLA Dzhusipbekov, Umirzak et al. “Prediction of the Formation of Low-Molecular Components, Particles, and Condensed Phases During Thermal Destruction of Oil-Contaminated Soil”. MANAS Journal of Engineering, vol. 11, no. 1, 2023, pp. 53-63, doi:10.51354/mjen.1211527.
Vancouver Dzhusipbekov U, Fischer D, Nurgalieva G, Kemelov K, Sambaeva D, Maymekov Z. Prediction of the formation of low-molecular components, particles, and condensed phases during thermal destruction of oil-contaminated soil. MJEN. 2023;11(1):53-6.

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