A floating vessel with gearless pod propulsor and counter rotating propellers is secured to a hull, each pod having a lead propeller and a trailing propeller, each propeller connected to a shaft connected to either a stator and rotor or a hydraulic motor. A lead propeller turns in a first direction and a trailing propeller turns in an opposite direction simultaneously, generating thrust for the floating vessel along a thrust vector using the counter rotation of the trailing propeller to recover swirling energy from the lead propeller improving propulsive efficiency of the floating vessel. The pod is positioned below a water line of the floating vessel providing propulsion for the floating vessel without gears.

A floating vessel with gearless pod propulsor and counter rotating propellers is secured to a hull, each pod having a lead propeller and a trailing propeller, each propeller connected to a shaft connected to either a stator and rotor or a hydraulic motor. A lead propeller turns in a first direction and a trailing propeller turns in an opposite direction simultaneously, generating thrust for the floating vessel along a thrust vector using the counter rotation of the trailing propeller to recover swirling energy from the lead propeller improving propulsive efficiency of the floating vessel. The pod is positioned below a water line of the floating vessel providing propulsion for the floating vessel without gears.

A floating vessel with gearless pod propulsor and counter rotating propellers is secured to a hull, each pod having a lead propeller and a trailing propeller, each propeller connected to a shaft connected to either a stator and rotor or a hydraulic motor. A lead propeller turns in a first direction and a trailing propeller turns in an opposite direction simultaneously, generating thrust for the floating vessel along a thrust vector using the counter rotation of the trailing propeller to recover swirling energy from the lead propeller improving propulsive efficiency of the floating vessel. The pod is positioned below a water line of the floating vessel providing propulsion for the floating vessel without gears.

A floating vessel with gearless pod propulsor and counter rotating propellers is secured to a hull, each pod having a lead propeller and a trailing propeller, each propeller connected to a shaft connected to either a stator and rotor or a hydraulic motor. A lead propeller turns in a first direction and a trailing propeller turns in an opposite direction simultaneously, generating thrust for the floating vessel along a thrust vector using the counter rotation of the trailing propeller to recover swirling energy from the lead propeller improving propulsive efficiency of the floating vessel. The pod is positioned below a water line of the floating vessel providing propulsion for the floating vessel without gears.

The present disclosure is directed towards a power distribution system for a marine vessel. The power distribution system comprises auxiliary, first and second buses and first and second propulsors for propelling the marine vessel. A first power generation system is electrically connected to the first bus and operably connected to the first propulsor. A second power generation system is electrically connected to the second bus and operably connected to the second propulsor. The first and second buses are electrically connected to the auxiliary bus such that electrical power is transferable between the first and second power generation systems for driving the first and/or second propulsors.

A system includes a magnetic coupler. The magnetic coupler includes an inner coupling comprising at least two first sections, wherein the inner coupling is configured to be coupled to a drive shaft of a vessel. The magnetic coupler additionally includes an outer coupling comprising at least two second sections, wherein the outer coupling is configured to coaxially surround the inner coupling with a radial gap disposed therebetween. The system further includes a drive source configured to be coupled to the outer coupling of the magnetic coupler.

A system includes a magnetic coupler. The magnetic coupler includes an inner coupling comprising at least two first sections, wherein the inner coupling is configured to be coupled to a drive shaft of a vessel. The magnetic coupler additionally includes an outer coupling comprising at least two second sections, wherein the outer coupling is configured to coaxially surround the inner coupling with a radial gap disposed therebetween. The system further includes a drive source configured to be coupled to the outer coupling of the magnetic coupler.

A device for moving a fluid with magnetic gear includes two first balls each having a shape of sphere, respectively fixed to a rotating first shaft through respective centers of the sphere, each of the first balls having a first magnetic dipole in a direction orthogonal to the first shaft; and a second ball having a shape of sphere attaching a blade structure thereon to move the fluid, fixed to a freely rotatable second shaft through a center of the sphere, and having a second magnetic dipole in a direction orthogonal to the second shaft, wherein the centers of the first and second balls altogether form an isosceles triangle with a vertex angle ? being defined about the center of the second ball, satisfying

[00001]$?=2.Math.\arcsin ?\left(\frac{1}{\sqrt{3}}\right)?70.53.Math.?.$

A method and an apparatus (1, 11, 21, 31) for moving one or more loads (5, 15, 25, 35a, 35b,45), in which method loads are moved along a channel (2, 12, 22, 32a, 32b, 49, 49) on or in fluid, wherein the channel (2, 12, 22, 32a, 32b, 49, 49) extending substantially horizontally in lengthwise direction has a cross-section, which cross-section defines an open section (13, 33a, 33b) and a closed section (14, 34a, 34b), wherein the fluid in the open section is directly in contact with surrounding air, and the fluid in the channel can flow from the open section to the closed section and vice versa through opening or openings located below the surface level of the fluid in the open section, and the load or loads (5, 15, 25, 35a, 35b, 45) are moved by floating them at least partially inside the closed section.

A method and an apparatus (1, 11, 21, 31) for moving one or more loads (5, 15, 25, 35a, 35b,45), in which method loads are moved along a channel (2, 12, 22, 32a, 32b, 49, 49) on or in fluid, wherein the channel (2, 12, 22, 32a, 32b, 49, 49) extending substantially horizontally in lengthwise direction has a cross-section, which cross-section defines an open section (13, 33a, 33b) and a closed section (14, 34a, 34b), wherein the fluid in the open section is directly in contact with surrounding air, and the fluid in the channel can flow from the open section to the closed section and vice versa through opening or openings located below the surface level of the fluid in the open section, and the load or loads (5, 15, 25, 35a, 35b, 45) are moved by floating them at least partially inside the closed section.