Dimensioning of port waterways for vessels handling offshore wind farms using the navigational risk analysis

Gucma, Stanisław; Gralak, Rafał

doi:10.17402/50

Artykuł - szczegóły

Tytuł artykułu

Dimensioning of port waterways for vessels handling offshore wind farms using the navigational risk analysis

Autorzy

Gucma Stanisław , Gralak Rafał

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.17402/50

Warianty tytułu

Języki publikacji

Abstrakty

This article indicates the development trends in the construction of offshore wind turbines worldwide, and the characteristics of existing and planned ships for wind turbine installation and maintenance; it presents an approach to design ports with their future operations in mind. Problem: The safety of navigation in port waterways is the basic restrictions for the construction of harbors (terminals) to handle ships used for the construction of OWT and for increasing their size. Navigational risk is a criterion of navigational safety assessment that allows its accurate estimation in port waterways. Method: The article presents the method for dimensioning port waterways for ships serving offshore sea wind turbine transport and construction. Furthermore, a method for determining the navigational risk of jack-up vessels navigating in port waterway areas is presented. Results: The authors have determined conditions for safe operation of these ships in restricted areas and defined the basic condition of navigational safety. The presented method of navigational risk analysis refers to the departure of a loaded ship carrying offshore wind turbine components in the presently designed port terminal in Świnoujście for handling offshore wind farm projects. Conclusion: These are universal methods that can be applied to the design of ports serving vessels that install offshore wind turbines in various types of waters.

Słowa kluczowe

offshore wind farm offshore wind turbine offshore wind turbine installation terminal wind turbine installation vessel wind turbine transport vessel dimensioning of waterways

Wydawca

Wydawnictwo Naukowe Akademii Morskiej w Szczecinie

Czasopismo

Zeszyty Naukowe Akademii Morskiej w Szczecinie

Rocznik

2022

Tom

nr 70 (142)

Strony

9--19

Opis fizyczny

Bibliogr. 31 poz., rys., tab.

Twórcy

autor

Gucma Stanisław

s.gucma@am.szczecin.pl

Maritime University of Szczecin 1-2 Wały Chrobrego St., 70-500 Szczecin, Poland

https://orcid.org/0000-0003-2286-8815

autor

Gralak Rafał

r.gralak@am.szczecin.pl

Maritime University of Szczecin 1-2 Wały Chrobrego St., 70-500 Szczecin, Poland

https://orcid.org/0000-0003-0330-2197

Bibliografia

1. Anju, M. (2017) Installation Vessel Design. WindEurope Conference & Exhibition, Innovations for LCOE reduction in offshore wind energy – technologies, models and strategies, 28th – 30th November, Amsterdam.
2. Cao, C. (2020). A study on influence of Putian Port offshore wind farm construction on navigation safety. Master Thesis, World Maritime University, Dalian, China.
3. COWI (2020) Joint study on wind farm port construction for fostering wind industries and creating jobs. Final report. Danish Energy Agency, Embassy of Denmark to Korea, Korean Energy Agency.
4. DNV GL (2017) Transport and installation of wind power plants. Standard DNVGL-ST-0054, Edition June 2017. DNV GL AS.
5. Douglas-Westwood (2013) Assessment of Vessel Requirements for the U.S. Offshore Wind Sector. 24th September 2013 U.S. Offshore Wind: Removing Market Barriers. UK Department of Energy.
6. Engel, J. (2021) Installation of world’s largest floating offshore wind farm completed. [Online] 25 August. Available from: www.renewableenergyworld.com/wind-power/installation-of-worlds-largest-floating-offshore-wind-farm-completed/ [Accessed: October 20, 2021].
7. General Electric (2020) GE Renewable Energy launches the uprated Haliade-X 13 MW wind turbine for the UK’s Dogger Bank Wind Farm. [Online] 21 September. Available from: https://www.ge.com/news/press-releases/ge-renewable-energy-launches-uprated-haliade-x-13-mw-wind-turbine-uk-dogger-bank [Accessed: October 20, 2021].
8. Gucma, L. (2009) Wytyczne do zarządzania ryzykiem morskim. Wydawnictwo Naukowe Akademii Morskiej w Szczecinie.
9. Gucma, S. (Ed.) (2015) Morskie drogi wodne. Projektowanie i eksploatacja w ujęciu inżynierii ruchu. Wydawnictwo: Fundacja Promocji Przemysłu Okrętowego i Gospodarki Morskiej, Gdańsk.
10. Gucma, S. (Ed.) (2017) Inżynieria Ruchu Morskiego. Wytyczne do projektowania morskich dróg wodnych i portów oraz warunków ich bezpiecznej eksploatacji. Wydawnictwo: Fundacja Promocji Przemysłu Okrętowego i Gospodarki Morskiej, Gdańsk.
11. Gucma, S. (Ed.) (2021) Dwuwariantowa analiza nawigacyjna dla projektowanego portu do obsługi morskich farm wiatrowych w Świnoujściu. Report. Maritime University of Szczecin.
12. Gucma, S. & Gralak, R. (2021) Projektowany port do obsługi morskich farm wiatrowych w Świnoujściu – analiza nawigacyjna. Inżynieria Morska i Geotechnika 2, pp. 76– 83.
13. Gucma, S., Gralak, R., Muczynski, B. & Bilewski, M. (2021) Navigational risk of ships proceeding through a fairway. European Research Studies Journal XXIV, 3, pp. 811– 832.
14. Gucma, S. & Ślączka, W. (2019) Navigational risk as a criterion for the assessment of the safe ship operation conditions in seaports. Międzynarodowa Konferencja Naukowa Transport XXI wieku. Czerwiec 2019, Ryn.
15. GWEC (2000) Global Offshore Wind Turbine Installation Vessel Database. [Online] September. Available from: https://infogram.com/global-offshore-wind-turbine-installation-vessel-database-1hzj4og9v8yp6pw [Accessed: October 20, 2021].
16. K&L Gates (2019) Offshore Wind Handbook, Version 2, October 2019. SNC Lavalin.
17. Letcher, T.M. (2017) Wind Energy Engineering: A Handbook for Onshore and Offshore Wind Turbines. London, San Diego CA: Elsevier.
18. Mehdi, R. A., Baldauf, M. & Deeb, H. (2020). A dynamic risk assessment method to address safety of navigation concerns around offshore renewable energy installations. Proceedings of the Institution of Mechanical Engineers, Part M: Journal of Engineering for the Maritime Environment 234 (1), pp. 231–244, doi: 10.1177/1475090219837409.
19. Musial, W., Beiter, P., Spitsen, P., Nunemaker, J., Gevorgian, V., Cooperman, A., Hammond, R. & Shields, M. (2020) 2019 Offshore Wind Technology Data Update. Report. NREL. Available from: https://www.nrel.gov/docs/ fy21osti/77411.pdf [Accessed: October 20, 2021].
20. Naschert, C. (2019) Global shortage of installation vessels could trouble waters for offshore wind. [Online] 16 December. Available from: https://www.spglobal.com/ marketintelligence/en/news-insights/latest-news-headlines/ global-shortage-of-installation-vessels-could-troublewaters-for-offshore-wind-56000511 [Accessed: October 20, 2021].
21. NEEC (2021). Fresh breezes for offshore installation vessels. [Online] 29 March. Available from: https://neec.no/ the-offshore-installation-vessels-market-meets-its-opportunities/ [Accessed: October 20, 2021].
22. NYSERDA (2017) New York State Offshore Wind Master Plan. Assessment of Ports and Infrastructure. Final Report 17-25b. Available from: https://nysl.ptfs.com/awweb/pdf opener?did=130238&fl=%2FLibrary1%2Fpdf%2F10218 58144.pdf [Accessed: October 20, 2021].
23. Porter, A. & Phillips, S. (2020). Port Infrastructure Assessment Report. California North Coast Offshore Wind Studies. Humboldt, CA: Schatz Energy Research Center.
24. Renewable Energy World (2021) Installation of world’s largest floating offshore wind farm completed. [Online] 25 September. Available from: www.renewableenergyworld. com/wind-power/installation-of-worlds-largest-floating-off shore-wind-farm-completed/ [Accessed: October 20, 2021].
25. Rystad Energy (2020) The world may not have enough heavy lift vessels to service the offshore wind industry post 2025. [Online] 25 November. Available from: https://www.rystad energy.com/newsevents/news/press-releases/the-world-may -not-have-enough-heavy-lift-vessels-to-service-the-offshore -wind-industry-post-2025/ [Accessed: October 20, 2021].
26. Sonal, P. (2020) POWER Offshore Wind Notebook: GE Boosts Haliade-X to 14 MW. [Online] 22 December. Available from: https://www.powermag.com/powerofshore-wind-notebook-ge-boosts-haliade-x-to-14-gwdominion-kicks-off-2-6-gw-virginia-project-vestasabsorbs-mhi-vestas/ [Accessed: October 20, 2021].
27. The Maritime Executive (2021) New York Wind Farms Will be Built with Giant 15 MW Turbines. [Online] 18 October. Available from: https://www.maritime-executive.com/article /new-york-wind-farms-to-get-giant-15-mw-turbines [Accessed: October 20, 2021].
28. Tufts University (2021) Wind Turbine Installation Vessels: Global Supply Chain Impacts on the U.S. Offshore Wind Market. Report No. OSPRE-2021-02, Medford.
29. Ulstein (2019) Securing your future in offshore wind. [Online] 31 May. Available from: https://ulstein.com/news/2019/ securing-your-future-in-offshore-wind [Accessed: October 20, 2021].
30. Uraz, E. (2011) Offshore wind turbine transportation & installation analyses planning optimal marine operations for offshore wind projects. Master Thesis, Gotland University.
31. Vestas (2021) Vestas to install V236-15.0 MW prototype turbine at Østerild in Denmark. [Online] 15 October. Available from: https://www.vestas.com/en/media/company-news?l=50&n=4089955#!NewsView [Accessed: October 20, 2021].

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu „Społeczna odpowiedzialność nauki” - moduł: Popularyzacja nauki i promocja sportu (2022-2023).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-fc886b87-15eb-49ca-a426-23feb9cd7879