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Evaluation of the High-Pressure Gas Transmission Network Impact for Environmental – Construction Phase and Network Operation

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
This thesis pertains to the influence of underground technical infrastructure during the construction phase on the selected components of the natural environment. The subject of research is the DN1000 MOP 8.4 MPa high pressure gas transmission system, realized in Poland from ZZU Wierzchowice till Kiełczów node. Studies identified the impacts on particular components of the environment, including land surface, plants, animals, biodiversity, air, water resources and quality, landscape and acoustic climate. An assessment was made on the impact, scale, frequency, duration or the influence type in the two stages of the investment process. It was found that the stage of DN1000 gas pipelines caused a significant change in the prevailing balance of the natural environment in the assembly area mainly due to soil transformation and vegetation removal as assessed as long-term. The impact on other components analysed in terms of frequency is usually medium-term or short-term, and in terms of duration – momentary. During the operation of the gas pipeline, the negative impact of the network was strongly determined in relation to the forested areas and forests, where the negative impact was recorded not only during the implementation of the network but also in the phase of its use.
Rocznik
Strony
122--132
Opis fizyczny
Bibliogr. 34 poz., rys., tab.
Twórcy
  • Operator Gazociągów Przesyłowych GAZ-SYSTEM S.A. Oddział we Wrocławiu, Poland
  • Wroclaw University of Environmental and Life Sciences, Department of Spatial Economy, Poland
  • Wroclaw University of Environmental and Life Sciences, Institute of Landscape Architecture, Poland
Bibliografia
  • 1. Act of 16 April 2004 on nature conservation (Dz.U. z 2016 poz. 2134).
  • 2. Brueckner, J., Fansler, D. (1983). The economics of urban sprawl: Theory and evidence on the spatial sizes of cities. Review of Economicsand Statistics, 55, 479–482.
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  • 4. Engel, Z. (2001). Ochrona środowiska przed drganiami i hałasem (2nd edition). Wydawnictwo Naukowe PWN, Warszawa.
  • 5. Environmental impact report for the project (2014): Gazociąg wysokiego ciśnienia DN1000 MOP 8,4MPa na odcinkach od ZZU Czeszów do ZZU Wierzchowice oraz od ZZU Czeszów do węzła Kiełczów, TRACTEBEL ENGINEERING S.A., Katowice.
  • 6. Guidelines for Landscape and Visual Impact Assessment. (2013). Third edition. The Landscape Institute with the Institute of Environmental Management and Assessment. Routledge Taylor & Francis Group, New York.
  • 7. Han, Z.Y., Weng, W.G. (2010). An integrated quantitative risk analysis method for natural gas pipeline network. J. Loss Prevent. Process Ind, 23(3), 428–436.
  • 8. Hasheminasab, H., Gholipour, Y., Kharrazi, M., Streimikiene D. (2018). A novel metric of sustainability for petroleum refinery projects. Journal of Cleaner Production, 171,1215–1224.
  • 9. Hasse, J., Lathrop, R.G. (2003). Land resource impact indicators of urban sprawl, Applied Geography, 23,159–175.
  • 10. Hełdak, M., Raszka, B., (2011). Prognosis of the natural environment transformations resulting from spatial planning solutions. Polish Journal of Environmental Studies, 20(6) 1513–1518.
  • 11. Jaffee, A., Suardina, A., Mcphate, JR. J (2009). Fire and explosion assessment on oil and gas floating production storage offloading (FPSO): an effective screening and comparison tool. Process Safety Environ. Protection, 87(3), 147–160.
  • 12. Jawecki, B. (2017). Wizualna ocena roli czynnych kamieniołomów granitu w krajobrazie powiatu strzelińskiego (The visual evaluation of the role of working granite quarries in the landscape of Strzelin County). Prace Komisji Krajobrazu Kulturowego, 36, 79–97.
  • 13. Jawecki, B., Lorenc, M.W., Tokarczyk-Dorociak, K., Wei, X. (2019). Reducing the environmental and landscape impacts of quarries using windbreaks and green-isolation zones. In: Krakowiak-Bal A., Vaverkova M. (eds) Infrastructure and Environment. Springer, Cham., 184–192, https://doi.org/10.1007/978–3-030–16542–0_25.
  • 14. Jo, Y.-D., Ahn, B.J. (2002). Analysis of hazard area associated with highpressure natural-gas pipeline. Journal of Loss Prevention in the Process Industries, 15, 179.
  • 15. Jo, Y.-D., Crowl D.A. (2008). Individual risk analysis of high-pressure natural gas pipeline, Journal of Loss Prevention in the Process Industries, 21(6), 589–595.
  • 16. Jo, Y.-D., Park, K.-S., Ahn, B.J. (2004). Risk assessment for a high-pressure natural gas pipeline in an urban area. The Sustainable City III, N. Marchettini, C. A. Brebbia, E. Tiezzi & L. C. Wadhwa (Editors), WIT Press, www.witpress.com.
  • 17. Joel, K., Duncan S. (2003). A practical approach to fire hazard analysis for offshore structures. J. Hazard. Mater., 104, 107–122.
  • 18. Lowry, I. (1988). Planning for urban sprawl: Transportation Research Board Special Report, 220: 275–312. Washington, DC: Transportation Research Board.
  • 19. Ma, L., Cheng, L., Li, M. (2013). Quantitative risk analysis of urban natural gas pipeline networks using geographical information systems. Journal of Loss Prevention in the Process Industries, 26, 1183–1192.
  • 20. Ma, L., Li, Y., Liang L., Li, M., Cheng, L. (2013). A novel method of quantitative risk assessment based on grid difference of pipeline sections. Safety Science, 59, 219–226.
  • 21. Madungwe, E., Mukonzvi, T. (2012). Assessment of distribution and composition of quarry mine dust: case of Pomona stone quarries. Harare. Atmos. Clim. Sci. 2(1), 52–59.
  • 22. Maziarek, A., Krawczyk A (2015). Gleba jako środowisko odżywcze roślin. Wydawnictwo Opolski Ośrodek Doradztwa Rolniczego, Opole.
  • 23. Mazur, M. (2004). Air protection system. Wydawnictwo Naukowo-Dydaktyczne, AGH Kraków.
  • 24. Morgan, R.K. (1998). Environmental impact assessment: a methodological perspective. Dordrecht: Kluwer Academic.
  • 25. Morgan, R.K. (2012). Environmental impact assessment: the state of the art. Impact Assessment and Project Appraisal, 30(1), 5–14.
  • 26. Ordinance of the Minister of the Environment of 6 October 2014 on the protection of species of animals (Dz.U. 2016 poz. 2183)
  • 27. Rak, A. (2014). Budowlane przedsięwzięcia inwestycyjne. Środowiskowe uwarunkowania przygotowania i realizacji. [Construction investment projects. Environmental conditions of preparation and implementation] Wydawnictwo Naukowe PWN, Warszawa.
  • 28. Sas-Bojarska, A. (2007). Prediction of landscape changes in land use management, using environmental impact assessment with the example of roads. Przedsiębiorstwo Prywatne WIB, Gdańsk.
  • 29. Shen, L., Wu, Y., Zhang, X. (2011). Key assessment indicators for the sustainability of infrastructure projects. Journal of Construction Engineering and Management, 137(6), 441–451, https://doi.org/10.1061/(ASCE)CO.1943–7862.0000315.
  • 30. Sklavounos, S., Rigas F. (2006). Estimation of safety distances in the vicinity of fuel gas. J. Loss Prevent. Process Ind, 19, 24–31.
  • 31. Smaga, S., Włudyka, T (2012). Market economy institutions. Wydawnictwo Wolters Kluwer, Warszawa.
  • 32. Suchocka, M., Milanowska A. (2015). Greenery, Structural substrates and conflicts between trees and infrastructure. Wydawnictwo ABRYS sp. z o.o.
  • 33. Świąder, M. Szewrański, Sz., Kazak, J. (2016). Spatial – Temporal Diversification of Poverty in Wroclaw, World Multidisciplinary Civil Engineering-Architecture-Urban Planning Symposium 2016, WMCAUS Praga 2016, Procedia Engineering 161, 1596–1600.
  • 34. Tokarczyk-Dorociak, K., Kazak, J.K., Haładyj, A., Szewrański,Sz., Świąder, M. (2019). Effectiveness of strategic environmental assessment in Poland. Impact Assessment and Project Appraisal, 37(3–4), 279–291, DOI: 10.1080/14615517.2019.1601441
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-b964b385-ef04-4a71-ba13-d834198eb0d5
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