Effects of Soil-Like Materials Mix from Drill Cuttings, Sewage Sludge and Sawdust on the Growth of Trifolium pratense L. and Transfer of Heavy Metals

• Autorzy: Kujawska J. , Pawłowska M.

Identyfikatory

DOI

10.12911/22998993/91884

• Języki publikacji: EN

Abstrakty

EN

Approximately 80000 tons of drilling waste is produced in Poland annually. This type of waste is relocated and deposited in waste neutralization plants or landfills. Eventually, it must be managed. Reuse of solid wastes might constitute a method of their utilization. The article investigates the use of drill cuttings, sewage sludge and sawdust for production of soil-like mixtures. The studies on evaluation of the possibility of economic application of soil-like materials were carried out. The assessment was conducted on the basis of metal content in soil-like materials and plants cultivated on substrates produced of soil-like materials. In accordance with the valid legal regulations, the concentration of metals in soil-like materials enables their application on class II soils, i.e. arable land. The concentration of heavy metals in the plants cultivated on the substrates produced with soil-like materials is low and does not exceed the concentration of metals determined in animal feeding standards.

Słowa kluczowe

EN

drill cuttings; wastes; landfarming; recultivation

• Wydawca: Polskie Towarzystwo Inżynierii Ekologicznej ; Lublin University of Technology
• Czasopismo: Journal of Ecological Engineering
• Rocznik: 2018
• Tom: Vol. 19, nr 6
• Strony: 225--230
• Opis fizyczny: Bibliogr. 22 poz., rys., tab.

Twórcy

autor

Kujawska J.

• Institute of Renewable Energy Engineering, Faculty of Environmental Engineering, Lublin University of Technology, 40B Nadbystrzycka Street, Lublin 20-618, Poland

autor

Pawłowska M.

• Institute of Renewable Energy Engineering, Faculty of Environmental Engineering, Lublin University of Technology, 40B Nadbystrzycka Street, Lublin 20-618, Poland

Bibliografia

• 1. Abbe E.O., Grimes M.S, Fowler D.G., Boccaccini R.A. 2009. Novel sintered glass – ceramics from vertified oil well drill cuttings. Journal Material Science, 60 (1), 4296–4302.
• 2. Bazrafshan E., Zarei A., Kord M.F., Poormollae N., Mahmoodi S., Zazouli M.A. 2015. Maturity and Stability Evaluation of Composted Municipal Solid Wastes. Health Scope, 5(1), e33202–33206.
• 3. Belyaeva O.N., Haynes R.J. 2009. Chemical, microbial and physical poperties of manufactured soils produced by co-composting municipal green waste with coal fly ash. Bioresorce Technology, 100, 5203–5209
• 4. Boruszko D. 2011. Research and Evaluation of Fertilizing Value of Composts and Vermicomposts. Annual Set The Environmental Protection/Rocznik Ochrona Środowiska (In Polish), 13, 1417–1428.
• 5. Cambardellaa C.A., Richardb T.L., Russella A. 2003. Compost mineralization in soil as a function of composting process conditions. European Journal of Soil Biology, 39(3), 117–127.
• 6. Chaineau C.H., Morel J.L., Oudot J. 1996, Land treatment of oil – based drill cuttings in an agricultural soil. Journal of Environmental Quality, 25(4), 858–867.
• 7. Czech T., Baran A., Wieczorek J. 2014. Content of heavy metals in soil and plants from an area Borzęcin Municipality (Malopolska Province) (In Polish). Journal of Ecological Engineering, 37, 89–98.
• 8. Gonet A., 2006. Elaboration of a method of organic-mineral drilling waste processing in the aspect of its management (In Polish). Faculty of Drilling, Oil and Gas, AGH, UST Cracow.
• 9. Kabata-Pendias A. and Szteke B. 2015. Trace elements in abiotic and biotic environments, CRC Press USA.
• 10. Kabata-Pendias A. and Pendias H. 2001. Trace elements in soils and plants, 3rd ed. CRC Press USA.
• 11. Kominko H., Gorazda K., Wzorek Z. 2017. The possibility of organo-mineral fertilizer production from sewage sludge. Waste and Biomass Valorization, 8(5), 1781–1791.
• 12. Leonard S.A., Stegmann J.A. 2010. Stabilization/solidification of petroleum drill cuttings. Journal of Hazardous Materials, 174, 463–472.
• 13. Macuda J., Bogacki M., Siemek J. 2017. Effect of drilling for shale gas on the quality of atmospheric air. Problems of Sustainable Development, 12(1), 91–100.
• 14. Market B. 1992. Establishing of 'reference plant' for inorganic characterization of different plant species by chemical fingerprinting. Water, Air, and Soil Pollution, 64, 533–538.
• 15. Mroczkowski W., Stuczyński T. 2016. Determination of total nitrogen in soils. Techniques and methods (In Polish), 2, 23–24.
• 16. Ozimek A., Kopeć M. 2012. Assessment of biological activity of biomass at different stages of composting process with use of the oxitop control measurement system. Acta Agrophysica (In Polish), 19(2), 379–390.
• 17. Report OSCR in Rzeszow. 2012. http://www.sokolow-mlp.pl/e107_files/downloads/Raport_o_stanie_gleb_2011.pdf date 18.06.2017 (In Polish).
• 18. Rattan L. 2016. Encyclopedia of Soil Science. London: CRC Press Taylor & Francis.
• 19. Woodard B and Curran I. 2006. Industrial Waste Treatment Handbook. Elsevier and Science Technology.
• 20. Zhaa X., Liaoa X., Zhaoa X., Liua F., Heb A.Q., Xiongca W.X. 2017. Turning waste drilling fluids into a new, sustainable soil resources for landscaping. Ecological Engineering, in press.
• 21. Zmora-Nahum S., Hadar Y., Chen Y. 2007. Physico-chemical properties of commercial compost varying in their source materials and country of origin. Soli Biology & Biochemistry 39, 1263–1276
• 22. Zvomuya F., Larney F.J., Willms W.D., Beck R.K., Olson A.F. 2011. Vegetation response to a one-time spent drilling mud application to semiarid, mixed-grass prairie. Rangeland Ecology Manage, 64, 375–383.

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).