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Tytuł artykułu

An Innovative Process for Efficient Data Evaluation in an Atmospheric Geochemical Survey of Contaminated Soil

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The article focuses on the field of innovative trends for efficient data processing in the conduct of research of organic soil pollution using a soil air analyzer for surveys of soil contamination in situ at industrial enterprises in Slovakia. The content of the article is a discourse of theoretical knowledge from the field of the geological environment; the authors’ own survey to monitor the processing and evaluation of the measured values obtained (e.g., CO2, CH4, NEL, BTEX). Currently, standard data processing procedures using the software that is supplied have basic or limited functionality, and the processing time is several hours, including manual and repetitive tasks. As we present in the article, the new Windows PowerShell tool is being used more efficiently, reducing the data processing time which represents an 86% time saving. There is currently no suitable or faster way of evaluating the measured data in Slovakia and the Czech Republic.
Rocznik
Strony
173--187
Opis fizyczny
Bibliogr. 30 poz., fot., rys.
Twórcy
  • Faculty of Mining, Ecology, Process Control, and Geotechnologies; Institute of Earth´s resources, Department of Mountainous Sciences, Technical University of Kosice
  • Faculty of Mining, Ecology, Process Control, and Geotechnologies; Institute of Earth´s resources, Department of Mountainous Sciences, Technical University of Kosice
  • Faculty of Mining, Ecology, Process Control, and Geotechnologies; Institute of Earth´s resources, Department of Mountainous Sciences, Technical University of Kosice
  • Faculty of Mining, Ecology, Process Control, and Geotechnologies; Institute of Earth´s resources, Department of Mountainous Sciences, Technical University of Kosice
  • Telegrafia a.s., Kosice
Bibliografia
  • 1. Alcani, M, Dorri, A and Maraj, A 2018. Estimation of energy recovery potential and environmental impact of Tirana landfill gas, Environment Protection Engineering, 44 (3), 117-128.
  • 2. Arpaia, P., De Matteis, E. and Inglese, V. 2015. Software for measurement automation: A review of the state of the art. Measurement, 66, 10-25.
  • 3. Arun, A., Raja, PP., Arthi, R., Ananthi, M., Kumar, KS. and Eyini, M. 2008. Polycyclic aromatic hydrocarbons (PAHs) biodegradation by basidiomycetes fungi, Pseudomonas isolate, and their cocultures: comparative in vivo and in silico approach. Applied Biochemistry and Biotechnology, 151, 132-142.
  • 4. Bartha R. and Bosser, I. 1984. The treatment and disposal of petroleum refinery wastes. In Petroleum Microbiology, Macmillan: New York, NY, USA, 553–577.
  • 5. Birnbaum, D. 2003. Microsoft Excel VBA Professional Projects. Cengage Learning.
  • 6. Covino, S. et al. 2016. Polycyclic aromatic hydrocarbons degradation and microbial community shifts during co-composting of creosote-treated wood. Journal of Hazardous Materials, 301, 17-26.
  • 7. Chang, W. and Wuj, J. 2016. An innovative optical-based method and automation system for rapid and non-destructive measurement of the web thickness of microdrills, Measurement 94, 388-405.
  • 8. Flegner, P., Kačur, J., Durdán, M., Leššo, I. and Laciak, M., 2014. Measurement and processing of vibro-acoustic signal from the process of rock disintegration by rotary drilling. Measurement, 56, 178-193.
  • 9. Flimel, M. 2012. Analysis of selected ergonomic problems of left- handed workers in production activity In: Annals of Faculty of Engineering Hunedoara. 10, 2, 83-86.
  • 10. Haritash, AK., Kaushik and CP. 2009. Biodegradation aspects of polycyclic aromatic hydrocarbons (PAHs), a review, Journal of Hazardous Materials, 169, 1-15.
  • 11. Harshul, P. 2016. Instant Windows PowerShell Guide. Puckt Publishing Ltd., India.
  • 12. Huo, D., Wu, J., Kong, Q., Zhang, GB., Wang, YY. and Yang, HY. 2018. Macromolecular toxins secreted by botrytis cinerea induce programmed cell death in arabidopsis leaves. Russian Journal of Plant Physiology, 65, 579-587.
  • 13. Kadri, T., Rouissi, T., Brar, SK., Cledon, M., Sarma, S. and Verma, M. 2017. Biodegradation of polycyclic aromatic hydrocarbons (PAHs) by fungal enzymes, A review, Journal of Environmental Sciences , 51, 52–74.
  • 14. Kapusta, K., Staňczyk, K., Wiatowski, M. and Chećko, J. 2013. Environmental aspects of a field-scale underground coal gasification trial in a shallow coal seam at the Experimental Mine Barbara in Poland, Fuel 113, 196–208.
  • 15. Kastlander, J., Aldener., M, Frittioff, T., Raghoo, L. and Purtschert, R. 2019. Measurement of radioxenon and radioargon in air from soil with elevated uranium concentration, Journal of Environmental Radioactivity, 197, 62-66.
  • 16. Kostecki, J., Greinert, A., Drab, M., Wasylewicz, R., Walczak, B. 2015. Chemical soil degradation in the area of the Głogów copper smelter protective forest. Civil and Environmental Engineering Reports, 2 (17), 67-71.
  • 17. Lee, T., Mitschke, K., Schill, M. and Tanasovski, T. 2011. Windows PowerShell 2.0 Bible, 1st ed.; John Wiley & Sons, UK.
  • 18. Liwarska-Bizukojc, E., Andrzejczak, O. and Solecka, M. 2019. Study on activated sludge flocs morphology and composition in a full-scale wastewater treatment plant in Poland. Environment Protection Engineering, 45 (2), 69-82.
  • 19. Lhotský, O. et al. 2017. Pharmaceuticals, benzene, toluene and chlorobenzene removal from contaminated groundwater by combined UV/H2O2 photooxidation and aeration, Water Research 120, 245-255.
  • 20. Murray, ML., Poulsen, SM. and Murray, M. 2020. Decontaminating Terrestrial Oil Spills: A Comparative Assessment of Dog Fur, Human Hair, Peat Moss and Polypropylene Sorbents. Environments 7, 52.
  • 21. Orin, T 2017. Windows Server 2016 Inside Out, (includes Current Book Service), 1st ed. Microsoft Press.
  • 22. Payette, B and Siddaway, R 2017. Windows PowerShell in Action, 3rd Edition; Manning Publications, USA.
  • 23. Pecorini, I, Baldi, F, Carnevale, EA and Corti, A 2016. Biochemical methane potential tests of different autoclaved and microwaved lignocellulosic organic fractions of municipal solid waste, Waste Management 56, 143-150.
  • 24. Polyakova, G, Pashenova, N, Senashova, V and Kudryashev, N 2020. Pine Stands as Bioindicators: Justification for Air Toxicity Monitoring in an Industrial Metropolis. Environments 7(4), 28.
  • 25. Radziemska, M 2017. Aided phytostabilization of copper contaminated soils with l. perenne and mineral sorbents as soil amendments, Civil and Environmental Engineering Reports, 3 (26), 79-89.
  • 26. Rimár, M, Kulikov, A, Fedák, M, Khovanskyi, S and Pavlenko, I. 2020. Application of the cfd software for modeling thermal comfort in sport hall, MM Science Journal. Prague, MM Publishing, 3723-3727.
  • 27. RS Dynamics, 2015. Ecoprobe5.
  • 28. Škvareková, E 2015. Prieskum pravdepodobnej environmentálnej záťaže na lokalitách: Strihovce, sklad chemikálií bývalého VD Vihorlat, Skrutkáreň EXIM a.s.- Stará Ľubovňa, Kovohuty a.s., Krompachy Správa-Atmogeochemické merania pôdneho vzduchu/ - Košice : TU, 115.
  • 29. Šofranko, M., Wittenberger, G. and Škvareková, E. 2015. Optimisation of technological transport in quarries using application software. Journal of Mining and Mineral Engineering 6, 1-13.
  • 30. Widory, D., Proust, E. and Bellenfant, G. 2012. Bour, O. Assessing methane oxidation under landfill covers and its contribution to the above atmospheric CO2 levels: The added value of the isotope (δ13C and δ 180 CO2; δ 13C and δ D CH4) approach. Waste Management 32, 1685-1692.
Uwagi
PL
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-95d4bdca-3533-46a3-9510-59c9961082ce
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