Disclosed is a surface vessel with motorised mechanical propulsion including a fusiform hull and a keel in the bottom part of the hull, the hull having an elongate shape in a longitudinal direction of the vessel, the keel including, at the bottom end of same, a bulb linked to the hull by a linking part of the keel, the maximum width of the linking part being smaller than the maximum width of the bulb, the maximum length of the linking part being smaller than the maximum length of the bulb, the lengths and widths being considered respectively in the longitudinal direction of the vessel and a horizontal transverse direction perpendicular to the longitudinal direction. The hull has a total width to total length ratio of less than 0.2 and a maximum length of less than 20 metres.

Disclosed is a surface vessel with motorised mechanical propulsion including a fusiform hull and a keel in the bottom part of the hull, the hull having an elongate shape in a longitudinal direction of the vessel, the keel including, at the bottom end of same, a bulb linked to the hull by a linking part of the keel, the maximum width of the linking part being smaller than the maximum width of the bulb, the maximum length of the linking part being smaller than the maximum length of the bulb, the lengths and widths being considered respectively in the longitudinal direction of the vessel and a horizontal transverse direction perpendicular to the longitudinal direction. The hull has a total width to total length ratio of less than 0.2 and a maximum length of less than 20 metres.

A personal watercraft includes a front end section lying on a front portion of a deck, the front end section having a tapered shape, a first section lying in a region posterior to the front end section, and a second section lying in a region posterior to the first section, the second section including a surface inclining outward in a body width direction from a front to a rear by an angle larger than an angle of inclination of the first section.

A long, wide, and low-profile mono-hull vessel able to meet the requirements for an efficient, rapid, and reliable inland waterway container transport system. A shallow draft container carrier may comprise a self-propelled semi-monocoque mono-hull vessel having a double radius ogive bow and octet truss space frame structure. Additional features such as a forward bridge, full beam stern, and distributed electric propulsion system elements may be included. The design provides a vessel that is large, strong, ridged, and fast, able to operate in shallow water, resistant to debris accumulation, with large cargo capacity and low wind load, and potentially with zero-turn radius capability. The aspect ratio provides high capacity with high speed, low drag and fuel-efficient hull form. Integral bow and stern thrusters may provide enhanced safety, control, speed, maneuverability, and zero-turn radius capability. An electric propulsion system combined with traction motors and full beam stern layout may provide greater power while maintaining shallow draft operating capability and flexibility in cargo hold design.

A long, wide, and low-profile mono-hull vessel able to meet the requirements for an efficient, rapid, and reliable inland waterway container transport system. A shallow draft container carrier may comprise a self-propelled semi-monocoque mono-hull vessel having a double radius ogive bow and octet truss space frame structure. Additional features such as a forward bridge, full beam stern, and distributed electric propulsion system elements may be included. The design provides a vessel that is large, strong, ridged, and fast, able to operate in shallow water, resistant to debris accumulation, with large cargo capacity and low wind load, and potentially with zero-turn radius capability. The aspect ratio provides high capacity with high speed, low drag and fuel-efficient hull form. Integral bow and stern thrusters may provide enhanced safety, control, speed, maneuverability, and zero-turn radius capability. An electric propulsion system combined with traction motors and full beam stern layout may provide greater power while maintaining shallow draft operating capability and flexibility in cargo hold design.

A boat hull having a design water line, the boat hull including a bow, a stern, a starboard side having a starboard chine and a starboard gunwale, a port side having a port chine and a port gunwale, a hull center line, and a bottom surface formed between the bow, the stern, the starboard chine and the port chine. The bottom surface includes first, second and third portions. The first portion is proximate the bow and includes a first concave surface and a second concave surface, the first concave surface projects from the hull center line towards the starboard chine and the second concave surface projects from the hull center line towards the port chine. The second portion is proximate the stern and includes a first convex surface and a second convex surface.

A boat hull having a design water line, the boat hull including a bow, a stern, a starboard side having a starboard chine and a starboard gunwale, a port side having a port chine and a port gunwale, a hull center line, and a bottom surface formed between the bow, the stern, the starboard chine and the port chine. The bottom surface includes first, second and third portions. The first portion is proximate the bow and includes a first concave surface and a second concave surface, the first concave surface projects from the hull center line towards the starboard chine and the second concave surface projects from the hull center line towards the port chine. The second portion is proximate the stern and includes a first convex surface and a second convex surface.

A boat hull includes a bow section and a flat aft section to allow an air film to be introduced under the boat hull. At least one slot or round hole is arranged proximate a location where the bow section meets the flat aft section. The slot or round hole provides a low-pressure injection point for pumped or drawn-in air and/or exhaust gas, which lubricates an operative surface of the flat aft section.

This relates to vessels in general, but in particular to displacement vessels designed to be exposed from low to medium to high waves. Both for comfort of persons, animals or fragile goods, steady sailing is preferred, without causing the waves slamming in on the vessel hull or excessive pitching of the vessel. This is also the case for service and supply vessels performing operations in relation to offshore or subsea installations. To obtain a solution to the aforementioned issues the present invention provides a vessel, wherein a stern of the vessel extend below a design waterline (Tdwl), and wherein opposite side surfaces of the stern, when seen in an opposite direction of the vessels primary sailing direction, form an acute angle under and above the design waterline (Tdwl) to decrease the vessels displacement in the rear end and are adjoined along at a line of symmetry forming a stern centerline.

This relates to vessels in general, but in particular to displacement vessels designed to be exposed from low to medium to high waves. Both for comfort of persons, animals or fragile goods, steady sailing is preferred, without causing the waves slamming in on the vessel hull or excessive pitching of the vessel. This is also the case for service and supply vessels performing operations in relation to offshore or subsea installations. To obtain a solution to the aforementioned issues the present invention provides a vessel, wherein a stern of the vessel extend below a design waterline (Tdwl), and wherein opposite side surfaces of the stern, when seen in an opposite direction of the vessels primary sailing direction, form an acute angle under and above the design waterline (Tdwl) to decrease the vessels displacement in the rear end and are adjoined along at a line of symmetry forming a stern centerline.