Ett batterihybridfartygs driftsmöjligheter : Hur Coey Viking bör operera / The operational conditions of a battery-hybrid-vessel : How Coey Viking should operate

Olausson, Axel, Prahl, Niclas

January 2021

Syftet med arbetet var att undersöka hur ett nyproducerat batterihybridfartyg av PSV-typ (plattform supply vessel) bör operera för att uppnå en så energieffektiv drift som möjligt utan att äventyra säkerhet eller redundanskrav. Att framföra ett fartyg så energieffektivt som möjligt är något som är av hög prioritet till sjöss, dels ur ett ekonomiskt perspektiv men även ur miljösynpunkt, då sjöfartsbranschen ständigt arbetar för en minskad miljöpåverkan. Även nyproducerade fartyg, byggda med modern teknik som ger goda förutsättningar för en energieffektiv drift ställer stora krav på att det tydligt framgår hur fartyget ska framföras för att nyttja fartygets fulla potential och uppnå optimal drift. För att ta fram procedurer över hur fartygen bör operera har loggade och teoretiska data från fartyget Coey Viking sammanställts, och presenteras i samråd med Viking Supply Ships. Resultatet innefattar generatorkombinationers specifika bränsleförbrukning, lågtrycks-dual-fuel-motorers generella miljöpåverkan med avseende på metanslip och fartygets loggade effektförbrukning till kaj. Resultatet visade att hög generatorlast resulterade i optimal specifik bränsleförbrukningen, att låga generatorlaster genererade stort metanslip samt att en förändrad elkraftstyrning tillsammans med fartygets energilagring möjliggör en förbättrad drift till kaj med en minskad miljöpåverkan. Arbetet öppnar upp för vidare forskning inom optimal peak-shaving-effekt, hur energilagringens storlek påverkar driftsmöjligheter och hur peak-shaving till kaj på ett stabilt sätt reglertekniskt bör styras. / The purpose of this undertaking was to investigate a new built battery-hybrid-vessel of PSV-type (platform supply vessel) and its operational ability to achieve the most energy efficient operation without jeopardizing safety or redundancy. The energy efficient operation of a vessel is of great priority in the maritime industry, not only because of economical profit but also based on environmental perspective, since the maritime industry is constantly aiming towards a decreased environmental impact. Newly built vessels containing modern technology opens up great opportunity in achieving energy efficient operation, though it sets high standard regarding correct operation of the vessel to use its full potential and achieve optimal running. To be able to present procedures regarding the vessel’s operation, logged and theoretical data from the vessel Coey Viking has been compiled and is presented in consultation with Viking Supply Ships. The results refered to different generator combination’s specific fuel consumption, the general environmental impact of low pressure dual fuel engines with respect to methane slip and the vessel’s logged power consumption in port.  The result indicated that a high generator load resulted in optimal specific fuel consumption, while low generator loads resulted in poor specific fuel consumption together with an increase in methane slip. The result also showed that the vessel’s energy storage together with a change in the PMS-system (Power Management System) would enable an improved power supply in port with shore connection. The paper raises questions to be answered in further research regarding optimal peak-shaving effect, what impact the size of the energy storage would have on operational capability and how peak shaving in port with shore connection appropriately should be regulated.

Shore power

Battery hybrid

Maritime LNG-running

Peak-shaving

Landströmsanslutning

Batterihybrid

Maritim LNG-drift

Peak-shaving

Energy Engineering

Energiteknik

Energy analysis and cost estimation of a potential On-shore Power Supply system in the Port of Gävle

Gutierrez Saenz, Juan

January 2019

The Port of Gävle is one of the most important harbours in Sweden as far as size and freight capacity is concerned. Marine traffic is increasing greatly, thus environmental pollution as well as noise and vibrations are of major concern in port cities. Shore to ship power supply systems might be a feasible solution to curtail emissions because the Auxiliary Engines are instead shut down while the ship stays alongside the quay. The literature review shows they are reliable and very appealing in all respects, thereby contributing to sustainable development. Taking into account the kind of vessels that call at the Port of Gävle, a High Voltage Shore Connection is recommendable, in compliance with the International Standards. An own technical survey is developed to gather all the information, as well as personal interviews to collect first-hand data. Technical issues such as the synchronisation procedure and the ground system with regard to safety are briefly discussed. Due to the lack of data, calculations consist of average values: peak and average demand, and fuel consumption during a typical call. Considering updated energy prices for both electricity and fuel, results show that an on‑shore power supply system make energy costs decrease by 71% at berth in comparison with burning marine fuel, which is saved by around 4 tonnes per call. Additionally, up to 5126 tonnes of CO2 are avoided per year, among other pollutants. Shore‑side power has proven to be profitable and appealing to the Port of Gävle; however, vessels need to be retrofitted, which implies relatively high investments. Collaboration agreements and shipping companies’ willingness to undergo changes are key issues that still need to be solved.

On shore Power Supply

Alternative Marine Power

High Voltage Shore Connection

Shore side Power

Ship’s emissions

Marine fuel

Annan elektroteknik och elektronik