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RAW MATERIAL BASE
ArticleName World reserves of oil shales: review
DOI 10.17580/em.2024.02.06
ArticleAuthor Nazarenko М. Yu., Rudko V. А., Saltykova S. N.
ArticleAuthorData

Saint-Petersburg Mining University, Saint-Petersburg, Russia

Nazarenko М. Yu., Associate Professor, Candidate of Engineering Sciences, nazarenko_myu@pers.spmi.ru
Rudko V. А., Chief Operating Officer, Candidate of Engineering Sciences
Saltykova S. N., Associate Professor, Candidate of Engineering Sciences

Abstract

Currently, the search is underway for new promising carbonaceous materials that can partially or completely replace high-quality coking coals in a number of metallurgical and coke-chemical processes, for example, in reduction or agglomeration. In addition, effective and economical ways of using local low-grade hydrocarbon raw materials, including oil shales, are being developed, which is an urgent area of research in many countries. The world’s reserves of oil shales are huge, and the potential for their use has not yet been fully explored. This work is devoted to the analysis of the properties and composition of oil shales at the largest deposits in the world. The theoretical studies described in this work allow identifying possible potential ways of processing oil shales to obtain valuable products for the metallurgical and coke chemical industries, based on the knowledge of the chemical composition and properties of this raw material.

keywords Oil shale, low-grade carbon raw materials, oil shale coke, shale oil, deposit, integrated processing, rational use of natural resources
References

1. Jia B., Su J. Advancements and environmental implications in oil shale exploration and processing. Applied Sciences. 2023. Vol. 13, Iss. 13. ID 7657.
2. Litvinenko V. S., Tsvetkov P. S., Dvoynikov M. V., Buslaev G. V. Barriers to implementation of hydrogen initiatives in the context of global energy sustainable development. Journal of Mining Institute. 2020. Vol. 244. pp. 428–438.
3. Vasilyev V. V., Salamatova E. V., Petrovich N. I., Ostroukhov N. N., Strakhov V. M. Comparison of heavy fuel-oil fractions produced by Semicoking of Kukersite Shale in Kiviter and Petroter Systems. Coke and Chemistry. 2023. Vol. 65. pp. 439–448.
4. Gerasimov A. M., Ustinov I. D., Zyryanova O. V. Use of clay-containing waste as pozzolanic additives. Journal of Mining Institute. 2023. Vol. 260. pp. 313–320.
5. Sabanov S., Qureshi A.R., Dauitbay Z., Kurmangazy G. A method for the modified estimation of oil shale mineable reserves for shale oil projects: A case study. Energies. 2023. Vol. 16, Iss. 16. ID 5853.
6. Guseinova E. A., Aliyeva N. T., Khalafova I. A., Hamzayeva N. Kh. Thermal analysis of oil shale in the Baygushly and Iyimish fields. Kimya Problemleri. 2022. Vol. 20, No.4. pp. 341–346.
7. Litvinenko V., Naumov I., Bowbriсk I., Zaitseva Z. Global guidelines and requirements for professional competencies of natural resource extraction engineers: Implications for ESG principles and sustainable development goals. Journal of Cleaner Production. 2022. Vol. 338. ID 130530.
8. Potapov A. A. Experimental assessment of the possible contamination of groundwater by phenols during the flooding of the mines of the Leningrad oil shale deposit. Vestnik of Saint Petersburg University. Earth Sciences. 2018. Vol. 63, Iss. 2. pp. 194–208.
9. Razvigorova M., Budinova T., Tsyntsarski B., Petrova B., Petrov N. et al. Comparative characterization of organic matter of oil shale from the main deposits in Bulgaria. Oil Shale. 2019. Vol. 3, Iss. 2. pp. 305–317.
10. Sabanov S., Mukhamedyarova Z. Prospectivity analysis of oil shale in Kazakhstan. Oil Shale. 2020. Vol. 37, Iss. 4. pp. 269–280.
11. Lapidus A. L., Khudyakov D. S., Trukhina M. A., Kozlov A. M., Zhagfarov F. G. et al. Solid fossil fuels as a source of trace elements. Solid Fuel Chemistry. 2022. Vol. 56, No. 1. pp. 3–18.
12. Sharikov Y. V., Sharikov F. Y., Krylov K. A. Mathematical model of optimum control for petroleum coke production in a rotary tube kiln. Theoretical Foundations of Chemical Engineering. 2021. Vol. 55, No. 4. pp. 711–719.
13. Dubovikov O. A., Beloglazov I. I., Alekseev A. A. Specific features of the use of pulverized coal fuel in combined chemical processing. Obogashchenie Rud. 2022. No. 6. pp. 32–38.
14. Kovalskaya K. V., Gorlanov E. S. Al–Ti–B master alloys: structure formation in modified alloys. Tsvetnye Metally. 2022. No. 7. pp. 57–64.
15. Welsby D., Price J., Pye S., Ekins P. Unextractable fossil fuels in a 1.5 °C world. Nature. 2021. Vol. 597. pp. 230–234.
16. Kang Z., Zhao Y., Yang D., Tian L., Li X. A pilot investigation of pyrolysis from oil and gas extraction from oil shale by in-situ superheated steam injection. Journal of Petroleum Science and Engineering. 2020. Vol. 186. ID 106785.
17. Zubkova O. S., PYagay I. N., Pankratieva K. A., Toropchina M. A. Development of composition and study of sorbent properties based on saponite. Journal of Mining Institute. 2023. Vol. 259. pp. 21–29.
18. Kang Z., Zhao Y., Yang D. Review of oil shale in-situ conversion technology. Applied Energy. 2020. Vol. 269. ID 115121.
19. Pyagay I. N., Lebedev A. B. Effects of alumina on the stability of ferrite–calcium sinter with dicalcium silicate. CIS Iron Steel Review. 2023. No. 1. pp. 10–16.
20. Zhiyanov A. B., Nurtayev B. H., Alimov M. U., Islomov A. H. U. Problems and prospects for the use of oil shale in Uzbekistan. Proceedings of IV International Scientific and Practical Conference Open Innovation. 2018. pp. 39–42
21. Mukhamedzhanov M., Rakhmatova N., Karabayeva Z. Prospects for the use of oil shale in the Republic of Uzbekistan. E3S Web of Conferences. 2023. Vol. 371. ID 01006.
22. Ounam M., Abourriche A., Mansouri S., Mouiya M., Benhammou A. et al. Comparison of chemical and physical activation processes at obtaining absorbents from Moroccan oil shale. Oil Shale. 2020. Vol. 37, Iss. 2. pp. 139–157.
23. Yoruk C. R., Meriste T., Trikkel A., Kuusik R. Oxy-fuel combustion of Estonian oil shale: Kinetics and modeling. Energy Procedia. 2016. Vol. 86. pp. 124–133.
24. Sari A., Moradi A. V., Kulaksiz Y., Yurtoglu A. K. Evaluation of the hydrocarbon potential, mineral matrix effect and gas-oil ratio potential of oil shale from the Kabalar formation, Goynuk, Turkey. Oil Shale. 2015. Vol. 32, Iss. 1. pp. 25–41.
25. Mohammednoor M., Orhan, H. Organic geochemical characteristics and source rock potential of upper Pliocene shale in the Akcalar lignite basin, Turkey. Oil Shale. 2017. Vol. 34, Iss. 4. pp. 295–311.
26. Shakhrieh A., Hamdan M. A study on the Jordanian oil shale resources and utilization. Proceedings of the Sixth Global Conference on Power Control and Optimization. 2012. Vol. 1499, Iss. 1. pp. 145–150.
27. Qudaih R., Talab I., Syed S. R., Janajreh I., Hamdan M. A. Material characterization and gasification of Jordan oil shale. International Journal of Energy, Environment and Economics. 2011. Vol. 19, Iss. 4. pp. 339–354.
28. Bai J., Song K., Li K. The affinity of rare earth elements in Huadian and Luozigon oil shale of China. Oil Shale. 2018. Vol. 35, Iss. 2. pp. 154–167.
29. Birdwell J. E. Review of rare earth element concentrations in oil shale of the Eocene Green River Formation. Open-File Report 2012-1016.- U.S. Geological Survey, Reston, Virginia. 2012. 20 p.
30. Feshchenko R. Y., Erokhina O. O., Ugolkov V. L., Shabalov M. Y., Vasil’ev V. V. Thermal analysis of coal ash. Coke and Chemistry. 2017. Vol. 60, No. 1. pp. 17–22.
31. Yudovich Ya. E. Oil shale of the Komi Republic: Problems of development. Syktyvkar : Geoprint, 2013. 90 p.
32. Gerasimov A. M., Syroezhko A. M., Garabadzhiu A. V. Joint processing of shale of various genetic types with tar. News of St. Petersburg State Technical University (Technical University). 2014. No. 23(49). pp. 72–74.

Full content World reserves of oil shales: review
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