Abstract
Fossil fuels such as marine diesel oil (MDO) account for a significant part of the shipping industry’s total operating costs and have a certain negative impact on the environment. Maritime transport emits around 1000 million tonnes of CO2 annually and is responsible for about 2.5% of global greenhouse gas emissions. To focus on fuel saving is therefore important for both economic and environmental reasons. It is indicative that ship owners are now using weather routeing to save fuel and reduce emissions, particularly on long passages. In coastal areas, navigation is limited by traffic rules. This study examines whether fuel consumption can be reduced with current routeing in confined coastal areas, in this case a relatively short voyage in the Oslo Fjord, Norway. An advanced bridge simulator is used, where different current fields from a high-resolution ocean model are implemented. The results reveal that if the voyage is conducted on a typical field with following currents, instead of a typical counter current field, the travel time will be reduced by 12% for a typical vessel with speed through water set to 16.7 knots. On following currents, the vessel speed can be reduced to 15.7 knots and the voyage is completed within the same time as if no currents are present. This implies approximately a 15% reduction in fuel consumption for the vessel tested. The results also reveal that fuel consumption can be reduced if the vessel is operated within most favourable or least unfavourable currents inside the main traffic lanes.
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References
Aulinger, A., Matthias, V., Zeretzke, M., Bieser, J., Quante, M., & Backes, A. (2016). The impact of shipping emissions on air pollution in the greater North Sea region–part 1: Current emissions and concentrations. Atmospheric Chemistry and Physics, 16, 739–758.
Bichou, K. (2013). Port operations, planning and logistics. Boca Raton: CRC Press.
Bode, S., Isensee, J., Krause, K., & Michaelowa, A. (2002). Climate policy: Analysis of ecological, technical and economic implications for international maritime transport. International Journal of Maritime Economics, 4(2), 164–184.
Buhaug, Ø., Corbett, J. J., Eyring, V., Endresen, Ø., Faber, J., Hanayama, S., et al. (2009). Prevention of air pollution from ships: Second IMO GHG study. London: International Maritime Organization. http://www.imo.org/en/OurWork/Environment/PollutionPrevention/AirPollution/Documents/SecondIMOGHGStudy2009.pdf
Corbett, J. J., & Köhler, H. W. (2003). Updated emissions from ocean shipping. Journal of Geophysical Research: Atmospheres, 108(D20), 4650.
Corbett, J. J., Winebrake, J. J., Green, E. H., Kasibhatla, P., Eyring, V., & Lauer, A. (2007). Mortality from ship emissions: A global assessment. Environmental Science & Technology, 41(24), 8512–8518.
Dalsøren, S. B., Eide, M. S., Endresen, Ø., Mjelde, A., Gravir, G., & Isaksen, I. S. (2009). Update on emissions and environmental impacts from the international fleet of ships: The contribution from major ship types and ports. Atmospheric Chemistry and Physics, 9(6), 2171–2194.
Delitala, A. M. S., Gallino, S., Villa, L., Lagouvardos, K., & Drago, A. (2010). Weather routing in long-distance Mediterranean routes. Theoretical and Applied Climatology, 102(1–2), 125–137.
DNV. (2007). Statement of compliance regarding the K-Sim navigation, bridge operation simulator. Norway: Det Norske Veritas.
Endresen, Ø., Sørgård, E., Sundet, J. K., Dalsøren, S. B., Isaksen, I. S., Berglen, T. F., et al. (2003). Emission from international sea transportation and environmental impact. Journal of Geophysical Research: Atmospheres, 108(D17), 4560.
European Commission. (2011). Roadmap for moving to a competitive low carbon economy in 2050. White Paper, COM 112. 8. March 2011.
Eyring, V., Köhler, H. W., Van Aardenne, J., & Lauer, A. (2005). Emissions from international shipping: 1. The last 50 years. Journal of Geophysical Research: Atmospheres, 110(D17).
Fagerholt, K., Laporte, G., & Norstad, I. (2010). Reducing fuel emissions by optimizing speed on shipping routes. Journal of the Operational Research Society, 61(3), 523–529.
Gralak, R., & Juszkiewicz, W. (2010). Analysis of Vessels Collision “m/v Ziemia Łódzka” and “m/v Vertigo” with Fullmission Bridge Simulator. In Proceedings of the 8th International Probabilistic Workshop (p. 101). Dirk Proske Verlag.
Haglund, K., Claremar, B., & Rutgersson, A. (2016). Deposition of sulfur, nitrogen and particles originating from shipping activities in the Baltic and North Seas. In Multiple drivers for Earth system changes in the Baltic Sea region, 197.
Harrould-Kolieb, E. (2008). Shipping impact on climate: A source with solutions. Washington, DC: Oceania.
Hjelmervik, K., Kristensen, N. M., Staalstrøm, A., & Røed, L. P. (2017). A simple approach to adjust tidal forcing in fjord models. Ocean Dynamics, 67, 949–958.
Hjelmervik, K., & Schøyen, H. (2015). Correlation between coastal tides and the speed of commercial vessels. In OCEANS 2015-Genova (pp. 1–5). IEEE.
Hjelmervik, K., Staalstrøm, A., Kristensen, N. M., & Røed, L. P. (2017). Evaluation of the FjordOs-model (MET Report 11/2017). Norway: Norwegian Meteorological Institute.
IMO. (1999). Resolution A.893 (21). Guidelines for voyage planning, A 2/Res. 893.
IMO. (2012). Resolution MEPC.213 (63). 2012 Guidelines for the development of a ship energy efficiency management plan (SEEMP).
IMO. (2014). Third International Maritime Organization (IMO) greenhouse gas study 2014. London, UK: IMO.
Johnson, H., & Styhre, L. (2015). Increased energy efficiency in short sea shipping through decreased time in port. Transportation Research Part A: Policy and Practice, 71, 167–178.
Lin, Y. H., Fang, M. C., & Yeung, R. W. (2013). The optimization of ship weather-routing algorithm based on the composite influence of multi-dynamic elements. Applied Ocean Research, 43, 184–194.
Norwegian Hydrographic Service. (2017). Norwegian pilot guide – Sailing direction, Vol. 1, general information (8th ed.). Stavanger, Norway: Norwegian Hydrographic Service.
Norwegian Mapping Authority. (2016). Tide tables from the Norwegian coast and Svalbard. Stavanger, Norway: Norwegian Mapping Authority.
Notteboom, T. E., & Vernimmen, B. (2009). The effect of high fuel costs on liner service configuration in container shipping. Journal of Transport Geography, 17(5), 325–337.
Oeder, S., Kanashova, T., Sippula, O., Sapcariu, S. C., Streibel, T., Arteaga-Salas, J. M., et al. (2015). Particulate matter from both heavy fuel oil and diesel fuel shipping emissions show strong biological effects on human lung cells at realistic and comparable in vitro exposure conditions. PLoS One, 10(6), e0126536.
Padhy, C. P., Sen, D., & Bhaskaran, P. K. (2008). Application of wave model for weather routing of ships in the North Indian Ocean. Natural Hazards, 44(3), 373–385.
Perera, L. P., & Soares, C. G. (2017). Weather routing and safe ship handling in the future of shipping. Ocean Engineering, 130, 684–695.
Porathe, T., Brodje, A., Weber, R., Camre, D., & Borup, O. (2015). Supporting situation awareness on the bridge: Testing route exchange in a practical e-Navigation study. Information, Communication and Environment: Marine Navigation and Safety of Sea Transportation, 85.
Porathe, T., de Vries, L., & Prison, J. (2014). Ship voyage plan coordination in the MONALISA project: user tests of a prototype ship traffic management system. In Proceedings of the Human Factors and Ergonomics Society Europe Chapter 2013 Annual Conference (pp. 1–11).
Røed, L. P., Kristensen, N. M., Staalstrøm, A., & Hjelmervik, K. B. (2016). A high-resolution, curvilinear ROMS model for the Oslofjord. MET Report 4/2016. Norway: Norwegian Meteorological Institute.
Ronen, D. (1982). The effect of oil price on the optimal speed of ships. Journal of the Operational Research Society, 33(11), 1035–1040.
Stopford, M. (2009). Maritime economics (3rd ed.). Oxon: Routledge.
Styhre, L., & Winnes, H. (2013, July). Energy efficient shipping–between research and implementation. In Proceedings of the IAME2013 Conference (pp. 3–5).
Takashima, K., Mezaoui, B., & Shoji, R. (2009). On the fuel saving operation for coastal merchant ships using weather routing. In Proceedings of International Symposium TransNav (Vol. 9, pp. 431–436).
Tsou, M. C. (2010). Integration of a geographic information system and evolutionary computation for automatic routing in coastal navigation. Journal of Navigation, 63(02), 323–341.
UNCTAD. (2016). Review of Maritime Transport 2016. No. UNCTAD/RMT/2016. United Nations Publication.
van Leeuwen, W. M., Kircher, A., Dahlgren, A., Lützhöft, M., Barnett, M., Kecklund, G., et al. (2013). Sleep, sleepiness, and neurobehavioral performance while on watch in a simulated 4 hours on/8 hours off maritime watch system. Chronobiology International, 30(9), 1108–1115.
Watson, R. T., Zinyowera, M. C., & Moss, R. H. (1996). Climate change 1995 impacts, adaptations and mitigation of climate change: Scientific-technical analysis. Cambridge: Cambridge University Press.
World Shipping Council. (2008). Record fuel prices place on ocean. Annual Report, 2008.
Acknowledgments
The experiments were part of a collaborative research project between Kongsberg Digital and the University College of Southeast Norway. The project was partly funded by the Regional Research Fund Oslofjordfondet (Research grant no. 248723). The project group would like to thank Theis Arvesen, Jens Ferdinand Karvel, Aksel Stuve, and Severin Bøe Synnevåg for performing the experiments.
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Hjelmervik, K., Schøyen, H., Wang, H., Osen, O. (2018). Fuel Saving in Coastal Areas: A Case Study of the Oslo Fjord. In: Ölçer, A., Kitada, M., Dalaklis, D., Ballini, F. (eds) Trends and Challenges in Maritime Energy Management. WMU Studies in Maritime Affairs, vol 6. Springer, Cham. https://doi.org/10.1007/978-3-319-74576-3_18
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