This is a case study on the ‘Skoon Skipper’, a general cargo large Rhine vessel, with an average of 40 [kW] power demand while moored to which a shore battery is applied. Batteries can help you comply with shore power regulations where no infrastructure exists with limited to no CAPEX investments. CAPEX is €0 for this case study as the battery pack is rented at an estimated €400 dayrate. Purchase cost for battery pack are approx. €350.000. This case study is powered by our preferred partner Skoon.

The N997 has two propulsion motors with a capacity of 900 [kW] each and a total battery capacity of 50 [MWh] - best estimate currently available. The 120 meter long ship has a fully electric drive, can carry up to 700 TEU and is able to swap battery packs en route. The vessel is designed for Chinese inland and coastal waters, covering over 600 nautical miles of routes on the Yangtze River.

Maersk’s Stillstrom and North Star have signed a Memorandum of Understanding (MoU) to accelerate the adoption of offshore charging and vessel electrification technologies for Offshore Support Vessels (OSVs) in the offshore wind sector. Offshore charging hubs will enable the vessels to recharge their battery systems using wind energy while in the field.

This is a case study of a trailing hopper suction dredger with 14MW installed power - the ‘Happy Hopper’ - which is converted to methanol combustion. This case study is inspired by the amazing work done by Van Oord. With the given assumptions on emission factors for methanol, 93% CO2 reduction is achieved. CAPEX for a methanol refit of this size is approximately €6M+, of which roughly €5M is intended for engine refit only. OPEX will be greatly increased unless methanol price is below €500 per mT.

This is a case study on how to decarbonize a fishing trawler - the Jacobus Maria - using shore power, battery hybrid EES and biofuels. 20% CO2 reduction is achieved, half of which stems from the use of biofuels (HVO). The hybrid battery pack is economically not feasible with the assumptions used and the operational profile. The Jacobus Maria has 1 MW installed engine capacity. Total cost would be at least €1M. 10% CO2 reduction can be achieved with approx. €50k.

Neste Corporation calls its own HVO product “Neste Renewable Diesel”. The common acronym “HVO” comes from the terms “Hydrotreated Vegetable Oil”. It meets the requirements of EN 15940 for paraffinic diesel fuels and is allowed as a blending component in EN 590 B7 diesel fuel. It is a high quality fuel that can be used to enhance the properties of the final diesel blend. No modifications to vehicles required and it has the same torque and maximum power as with fossil diesel fuel in modern engines.

The Corvus BOB (Battery On Board) is a standardized, class-approved, modular battery room solution available in 10-foot and 20-foot ISO high-cube container sizes. The complete system comes with battery, monitoring system, HVAC , TR exhaust, plus firefighting and detection system. The plug and play battery room simplifies integration into any system integrator’s power management system on board a ship. The battery cells have passive thermal runaway protection, and are type-approved according to DNV.

On May 10th, Port of Amsterdam awarded the contract for the realization of shore power at Cruise Port Amsterdam (CPA) to Powercon A/S and with BAM as subcontractor. Dick van Veen and Rick van Akkeren - BAM Business Unit Heavy Duty Charging - explain in detail about the project and the challenges that they are facing. Building the infrastructure that can host large cruise vessels and support the heavy electrical equipment is therefore a daunting task, all of which is discussed in this video.

During the lunch and learn, current forum Director Syb ten Cate Hoedemaker will exchange knowledge and experience from the usage of batteries within the shipping and offshore industries. You will learn which batteries will suit your vessel, plus discover the costs and payback for different operational modes. Which battery suits your vessel, your needs, your operational profile? This is the key question discussed in this lunch and learn with Maritime Battery Forum.

This is a case study on how to decarbonize a ro-ro passenger vessel by applying Ecospeed to its hull. Ecospeed is a hard, non-toxic coating which provides long-lasting protection for all ship hulls. The hypothetic vessel is called ‘Lady Ice Cold’, a ro-ro operating in North-Western Europe with 33 MW installed engine capacity. Ecospeed reduces carbon emissions by 9% - 16% with a total CAPEX of €390.000.

This is a case study on how to decarbonize a tug by making it full electric. It is an homage to Damen’s electric tug ‘Sparky’. In practice, fully electrifying a vessel means to install a - very large - battery pack, in this case at least 3 MWh. This would also be the largest cost component, outweighing switchboard modifications, inverter and other electrical equipment. Cost reductions in OPEX/dayrate are high, between 50% to 90% in extreme cases.

Damen’s first all-electric harbour tug, the RSD-E Tug 2513, is a high-powered tug with 70-tonnes bollard pull, capable of manoeuvring even the largest vessels. It can undertake two or more assignments before being recharged, which takes just two hours. The battery pack size is 2,800 kWh, resulting an approximately 1,400 kW of charging power required. The battery pack is design for the vessel’s 30 year lifetime.

This video showcases a fuel switchover of an engine from regular diesel fuel to methanol by Arenared.

This is a case study on how to decarbonize an inland waterway ship with solar PV technology. Flexible solar PV panels from Wattlab are placed on an inland ship’s hatches in order to reduce fuel consumption while idling or moored. In some cases, the auxiliary generators can be switched off, resulting in an expected CO2 reduction of 26% - 100%.

Watch this lunch and learn by EOPSA together with General Electric, in which we discuss the onshore and vessel aspects of shore power, including microgrids and using the Decarbonizer to determine the costs for shore power for your vessel.

This blog is a state of the use of methanol as marine fuel as “quick” reference for shipowners. Key points include costs for retrofitting the ship and engine, range between € 250-€650 per kW, elaboration on IGF code for low flashpoint fuels and technical considerations for conversion and working with methanol. Availability for methanol is good, but bunkering for large vessels mostly non-existent. Methanol price per kilogram is historically lower than regular MGO.

Marine exhaust gas heat recovery systems can be a useful measure to reduce fuel consumption by 5% for typical cases, with up to 15% for favourable engine and ship characteristics. As a rule of thumb, heat exchangers become more efficient and cost-effective the larger your engine becomes. Conversion of heat to electricity is recommended for diesel-electric vessels, as well as the use of engine cooling water instead of exhaust gas heat.

Most ports have the ambition to become carbon neutral by 2050. This typically excludes vessel emissions and focusses on Scope 1/2 port operations only. A significant portion of ports around the world have signed shore power declarations to ‘deploy shore-side electricity by 2028 where possible’, including all large North Sea ports, Los Angeles, Montreal and all large Japanese ports. Cruise and container vessels are the primary target for most ports’ regulations and EU will start taxing vessels via EU ETS from next year onwards.

Four out of the five largest shipping companies have the ambition to be carbon neutral by 2050. Most shipping companies focus on alternative fuels for combustion. Preferred fuels that are currently considered are (bio)LNG and methanol.

Virtually all energy majors have 2050 as target date for carbon neutrality. Most focus solely on Scope I and II emissions. Ørsted and Equinor have the highest ambitions and most stringent targets. Repsol, Eni, Shell, TotalEnergies and BP are following suit.