Annotation |
The article presents a study of the mineralogical and elemental composition of drill cuttings. Samples were selected from sludge pits of oil and gas condensate fields of the Irkutsk region – Yaraktinskoye and Markovskoye. The main aim of the research is to identify the geochemical and mineralogical particularity of drill cuttings, to determine the toxicity of this type of waste. The authors have used an integrated approach using such research methods as: X-ray powder diffraction, inductively coupled plasma mass spectrometry, scanning electron microscope, bioassay.
According to the results of the study, minerals such as quartz, calcite, dolomite prevail in the mineralogical composition of samples of drill cuttings. However, there are significant differences in the mineralogical composition of drill cuttings from wells with different types of drilling. The geochemical specificity of the studied drill cuttings was determined relative to the clark of the upper part of the continental crust. In general, the elemental composition of drill cuttings is different, but elements concentrated in elevated values relate mainly to heavy metals.
The value of the total pollution indicator calculated by the clark of concentration shows that the samples are of different degrees of pollution. A sample from the Yaraktinskoye field, taken at a well pad with production wells, has a high degree of contamination. A low degree of contamination includes a sample from the Markovskoye field.
The method of X-ray spectroscopy has revealed the mineral phases of elements such as Pb, Sn, Sr, Ba Fe, Ti. According to the results of toxicological analysis using the bioassay method, the studied drill cuttings are classified as moderately hazardous and low-hazardous wastes, as drill cuttings have a toxic effect on microalgae Scenedesmus quadricauda and crustaceans Daphia magna
|
References |
1. Balaba V. I. Burenie i neft (Drilling and oil), 2004, no. 1, pp. 18–21.
2. Grigoriev N. A. Raspredelenie himicheskih elementov v verhney chasti kontinentalnoy kory (Distribution of chemical elements in the upper part of the continental crust). Yekaterinburg: Uro RAS, 2009. 382 p.
3. Matvienko V. V., Kuznetsov V. A., Tsekhansky M. V. Neft i gaz Sibiri (Oil and gas of Siberia), 2017, no. 3, pp. 94–99.
4. Moskovchenko D. V., Dorozhukova S. L. Ekologiya i promyshlennost Rossii (Ecology and industry of Russia), 2002, no. 9, pp. 27–30.
5. Nepsko-Botuobinskaya antekliza – novaya perspektivnaya oblast dobychi nefti i gaza na Vostoke SSSR (Nepsko-Botuobinskaya antekliza – a new promising area of oil and gas production in the East of the USSR) / ed. A. E. Kontorovich, V. S. Surkov, A. A. Trofimuk. Novosibirsk: Nauka, 1986. 245 p.
6. Patin S. A. Neft i ekologiya kontinentalnogo shelfa = Oil and continental shelf ecology (Oil and ecology of the continental shelf = Oil and continental shelf ecology). Moscow: VNIRO, 2001. 247 p.
7. Pichugin E. A., Schoenfeld B. E. Ekologiya i promyshlennost Rossii (Ecology and industry of Russia), 2017, vol. 21, no. 7, pp. 14–19.
8. Popov D. D. Izvestiya Irkutskogo gosudarstvennogo universiteta. Seriya: Nauki o Zemle (News of the Irkutsk State University. Series: Earth Sciences), 2011, vol. 4, no. 1, pp. 173–189.
9. Saet Yu. E., Revich B. A., Yanin E. P., Smirnova R. S., Basharkevich I. L., Onishchenko T. L., Pavlova L. N., Trefilova N. Ya., Achkasov A. I., Sarkisyan S. Sh. Geohimiya okruzhayushchey sredy (Geochemistry of the environment). Moscow: Nedra, 1990. 335 p.
10. Soromotin A. V. Vozdeystvie dobychi nefti na taezhnye ekosistemy Zapadnoy Sibiri (Impact of oil production on taiga ecosystems in Western Siberia). Tyumen: Publishing house of the Tyumen State University, 2010. 320 p.
11. Soromotin A. V., Pislegin D. V. Geoekologiya. Inzhenernaya geologiya. Gidrogeologiya. Geokriologiya (Ecology. Engineering geology. Hydrogeology. Geocryology), 2015, no. 6, pp. 514–520.
12. Stratigrafiya neftegazonosnyh basseynov Sibiri. Rifey i vend Sibirskoy platformy i ee skladchatogo obramleniya = Stratigraphy of oil and gas basins of Siberia. Riphean and vendian of Siberian platform and plaited border (Stratigraphy of oil and gas basins in Siberia. Riphean and Wend of the Siberian platform and its folded frame = Stratigraphy of oil and gas basins of Siberia. Riphean and vendian of Siberian platform and plaited border) / ed. N. V. Melnikov. Novosibirsk: Geo, 2005. 428 p.
13. Baloyan M. B., Chudnova T. A., Shapovalov D. A. International agricultural journal (International agricultural journal), 2019, no. 1, pp. 50–55.
14. Kujawska J., Cel W. Mobility of metals from drill cuttings (Mobility of metals from drill cuttings). URL: https://www.longdom.org/open-access/mobility-of-metals-from-drill-cuttings-2252-5211-1000285.pdf (Date of access: 12.10.2019). Text: electronic.
15. Mikos-Szymańska M., Rusek P., Borowik K., Rolewicz M., Bogusz P. Environmental Science and Pollution Research (Environmental Science and Pollution Research), 2018, vol. 25, no. 36, pp. 35990–36001.
16. Nabhani N., Khaje E. International Journal of Mechanical And Production Engineering (International Journal of Mechanical And Production Engineering), 2015, vol. 3, no. 4, pp. 14–19.
17. Savichev O. G., Matveenko I. A., Savchenko D. V. Changes in chemical composition of drilling waste water in taiga zone of Western Siberia (the Russian Federation) on the basis of thermodynamic approach (Changes in chemical composition of drilling waste water in taiga zone of Western Siberia (the Russian Federation) on the basis of thermodynamic approach). URL: http://earchive.tpu.ru/bitstream/11683/35134/1/dx.doi.org-10.1088-1755-1315-43-1-012027.pdf (Date of access: 10.10.2019). Text: electronic.
|