A navigation method for a ship which includes: a plurality of main generators that feed power to navigation equipment used in normal navigation and appliances for the living quarters provided within a ship body; and an emergency generator that feeds power to emergency equipment in case of fire or flood. The navigation method includes: an emergency power feeding step for feeding power to the emergency equipment using the emergency generator when at least one of the plurality of main generators is disabled due to fire or flood; and a return-to-port power feeding step for feeding power to return-to-port equipment, required for navigation for returning to port, using the main generators and the emergency generator after the fire or flood has subsided.

A navigation method for a ship which includes: a plurality of main generators that feed power to navigation equipment used in normal navigation and appliances for the living quarters provided within a ship body; and an emergency generator that feeds power to emergency equipment in case of fire or flood. The navigation method includes: an emergency power feeding step for feeding power to the emergency equipment using the emergency generator when at least one of the plurality of main generators is disabled due to fire or flood; and a return-to-port power feeding step for feeding power to return-to-port equipment, required for navigation for returning to port, using the main generators and the emergency generator after the fire or flood has subsided.

The present disclosure provides power source assemblies aboard a watercraft. The power source assemblies can include: an engine having a crankshaft; a variable ratio drive assembly operably engaged with the crankshaft; and an engine powered accessory operably engaged with the variable ratio drive assembly. The present disclosure also provides methods for distributing power aboard a watercraft from a crankshaft of an engine. The methods can include: using a crankshaft of an engine to drive a variable ratio drive assembly; and using the variable ratio drive assembly to drive an engine accessory over a narrower RPM range while operating the crankshaft over a wider RPM range.

A ship desulfurization device for desulfurizing exhaust gas discharged from an exhaust gas generation device mounted to a ship includes: an absorber including an absorber body unit defining an interior space having a longitudinal direction and having an exhaust gas introducing port formed on an end portion of the absorber body unit with respect to the longitudinal direction, the exhaust gas introducing port being in communication with the interior space; and an exhaust gas introducing device for introducing exhaust gas discharged from the exhaust gas generation device to the absorber body unit. When L is a maximum length of the interior space of the absorber body unit with respect to the longitudinal direction, and W is a maximum width of the interior space of the absorber body unit with respect to a lateral direction that is orthogonal to the longitudinal direction, a ratio (W:L) of the maximum width W to the maximum length L is within a range of 1:over 1.1 and 1:6.0 or under 6.0.

The present disclosure provides power source assemblies aboard a watercraft. The power source assemblies can include: an engine having a crankshaft; a variable ratio drive assembly operably engaged with the crankshaft; and an engine powered accessory operably engaged with the variable ratio drive assembly. The present disclosure also provides methods for distributing power aboard a watercraft from a crankshaft of an engine. The methods can include: using a crankshaft of an engine to drive a variable ratio drive assembly; and using the variable ratio drive assembly to drive an engine accessory over a narrower RPM range while operating the crankshaft over a wider RPM range.

A drive system for a ship, including at least two propulsion units, each propulsion unit having a propeller and a drive engine with an above-water transmission connected downstream for driving the propeller. Each drive engine can be connected to and disconnected from the associated above-water transmission with a clutch and between the above-water transmissions, a switchable drive train is provided by which in one switching state, the above-water transmissions can be coupled and driven jointly and in another switching state, they can be decoupled from each other.

A drive system for a ship, including at least two propulsion units, each propulsion unit having a propeller and a drive engine with an above-water transmission connected downstream for driving the propeller. Each drive engine can be connected to and disconnected from the associated above-water transmission with a clutch and between the above-water transmissions, a switchable drive train is provided by which in one switching state, the above-water transmissions can be coupled and driven jointly and in another switching state, they can be decoupled from each other.

A ship desulfurization device includes an absorber including an absorber body unit defining an interior space having a longitudinal direction and having an exhaust gas introducing port on an end portion of the absorber body unit with respect to the longitudinal direction, the exhaust gas introducing port in communication with the interior space; and an exhaust gas introducing device for introducing exhaust gas discharged from the exhaust gas generation device to the absorber body unit. When L is a maximum length of the interior space of the absorber body unit with respect to the longitudinal direction, and W is a maximum width of the interior space of the absorber body unit with respect to a lateral direction that is orthogonal to the longitudinal direction, a ratio (W:L) of the maximum width W to the maximum length L is within a range of 1:X, where 1.1<X6.0.

A power system for supplying electric power from shore-side to a vessel is presented. The power system includes one or more shore-side converters (101-112) for receiving electric power from a shore-side alternating voltage network (137) and for producing one or more direct voltages. Each shore-side converter can be a controllable converter for controlling the produced direct voltage to be suitable for the vessel in accordance with a control signal received from the vessel, or the vessel may include a direct voltage converter for converting the direct voltage received from the shore-side to be suitable for the vessel. The vessel can be an electric vessel which includes a chargeable battery (132) for supplying electric power to the propulsion system (135) of the vessel.

A drive system for a ship, including at least two propulsion units, each propulsion unit having a propeller and a drive engine with an above-water transmission connected downstream for driving the propeller. Each drive engine can be connected to and disconnected from the associated above-water transmission with a clutch and between the above-water transmissions, a switchable drive train is provided by which in one switching state, the above-water transmissions can be coupled and driven jointly and in another switching state, they can be decoupled from each other.