A flat catamaran watercraft construction is provided having a bow that defines a “split V” configuration in which the bottom surface of each of the two asymmetrical catamaran hull portions at the forward section of each hull portion slope upward from the inboard side of the hull portion to the outboard side of the hull portion. Such upward slope of the bottom of each hull portion sheds water and waves to the outboard sides of the vessel as it travels through the water in order to minimize the amount of water and spray that is directed upward between the individual hull portions towards the passengers. The rear portions of each such hull portion define an angled slope along both inboard and outboard sides, which angled slopes allow the rear portion of the watercraft to slide and drift sideways along the surface of the water as the watercraft turns. The flat catamaran hull portions and deck of the watercraft are preferably of unibody construction, such that they are formed (e.g., molded or otherwise machined) in a single, one-piece assembly.

A flat catamaran watercraft construction is provided having a bow that defines a “split V” configuration in which the bottom surface of each of the two asymmetrical catamaran hull portions at the forward section of each hull portion slope upward from the inboard side of the hull portion to the outboard side of the hull portion. Such upward slope of the bottom of each hull portion sheds water and waves to the outboard sides of the vessel as it travels through the water in order to minimize the amount of water and spray that is directed upward between the individual hull portions towards the passengers. The rear portions of each such hull portion define an angled slope along both inboard and outboard sides, which angled slopes allow the rear portion of the watercraft to slide and drift sideways along the surface of the water as the watercraft turns. The flat catamaran hull portions and deck of the watercraft are preferably of unibody construction, such that they are formed (e.g., molded or otherwise machined) in a single, one-piece assembly.

A floating connection assembly of a bulkhead to at least one element of constraint includes a projection integral to the element of constraint and at least one first longitudinal sealing bead. At least one projecting element protrudes from the bulkhead. The assembly has at least a second flexible seal and at least one closure plate, arranged in such a way that the bulkhead and the element of constraint are separated along an edge of the bulkhead. The one first longitudinal sealing bead is interposed between the bulkhead and the projection, on which is present at least one through hole through which passes the projecting element, integral with a respective closure plate, so that the bulkhead remains cantilevered on the protrusion, avoiding a different support, and so that the projecting element is free to oscillate inside the hole.

A floating connection assembly of a bulkhead to at least one element of constraint includes a projection integral to the element of constraint and at least one first longitudinal sealing bead. At least one projecting element protrudes from the bulkhead. The assembly has at least a second flexible seal and at least one closure plate, arranged in such a way that the bulkhead and the element of constraint are separated along an edge of the bulkhead. The one first longitudinal sealing bead is interposed between the bulkhead and the projection, on which is present at least one through hole through which passes the projecting element, integral with a respective closure plate, so that the bulkhead remains cantilevered on the protrusion, avoiding a different support, and so that the projecting element is free to oscillate inside the hole.

A ship (1) includes a hull (2) having side shells (3A, 3B) formed at both sides in athwart ship direction, a pair of watertight compartments (6A, 6B) installed along the side shells (3A, 3B) of both sides in the athwart ship direction in the hull (2) and portions of which are divided and formed by the side shells (3A, 3B), a connection section (7) configured to bring the pair of watertight compartments (6A, 6B) in connection with each other, an opening/closing valve (8) installed at the connection section (7), and a control device (9) configured to control the opening and closing of the opening/closing valve (8), wherein the control device (9) switches the opening/closing valve (8) in an open state into a closed state when a predetermined condition is satisfied after receiving a signal indicating damage to the side shell (3A) has occurred.

A ship (1) includes a hull (2) having side shells (3A, 3B) formed at both sides in athwart ship direction, a pair of watertight compartments (6A, 6B) installed along the side shells (3A, 3B) of both sides in the athwart ship direction in the hull (2) and portions of which are divided and formed by the side shells (3A, 3B), a connection section (7) configured to bring the pair of watertight compartments (6A, 6B) in connection with each other, an opening/closing valve (8) installed at the connection section (7), and a control device (9) configured to control the opening and closing of the opening/closing valve (8), wherein the control device (9) switches the opening/closing valve (8) in an open state into a closed state when a predetermined condition is satisfied after receiving a signal indicating damage to the side shell (3A) has occurred.

A modular compartment bulkhead assembly is provided that includes a first external body, a bulkhead, and a second external body. The first external body segment may include a first end portion. The first end portion may be coupled to an external seal body and the external seal body may include a first internal channel. The bulkhead may include an internal seal body. The internal seal body may be configured to be inserted into the first internal channel of the external seal body to form an internal seal between the bulkhead and the first external body segment. The second external body segment may include a second end portion. The second end portion may include a second internal channel, and the external seal body may be configured to be inserted into the second internal channel to form an external seal between the external seal body and the second external body segment.

A hopper barge is disclosed. The hopper barge comprises a hopper compartment for carrying a plurality of containers, the hopper compartment comprising a hopper compartment deck. The hopper barge comprises an inner-bottom portion defined in part by the hopper compartment deck and a bottom portion of the hopper barge. A plurality of longitudinal bulkheads are arranged in parallel within the inner-bottom portion of the hopper barge. A plurality of transverse bulkheads are arranged in parallel within the inner-bottom portion of the hopper barge, the plurality of transverse bulkheads running perpendicular to the plurality of longitudinal bulkheads. A plurality of pedestal supports are affixed to the hopper compartment deck, wherein at least one of the plurality of longitudinal bulkheads intersects at least one of the plurality of transverse bulkheads at a position beneath at least one of the plurality of pedestal supports.

A hopper barge is disclosed. The hopper barge comprises a hopper compartment for carrying a plurality of containers, the hopper compartment comprising a hopper compartment deck. The hopper barge comprises an inner-bottom portion defined in part by the hopper compartment deck and a bottom portion of the hopper barge. A plurality of longitudinal bulkheads are arranged in parallel within the inner-bottom portion of the hopper barge. A plurality of transverse bulkheads are arranged in parallel within the inner-bottom portion of the hopper barge, the plurality of transverse bulkheads running perpendicular to the plurality of longitudinal bulkheads. A plurality of pedestal supports are affixed to the hopper compartment deck, wherein at least one of the plurality of longitudinal bulkheads intersects at least one of the plurality of transverse bulkheads at a position beneath at least one of the plurality of pedestal supports.

A method for constructing a hull of an offshore structure includes (a) welding a plurality of plates together to form a plate assembly. The method also includes (b) passing the plate assembly through a rolling machine with the plate assembly in a vertical orientation. In addition, the method includes (c) bending the plate assembly into a cylinder during (b). The cylinder includes a pair of circumferentially adjacent free ends. Further, the method includes (d) welding the free ends of the cylinder together after (c) to form a cylindrical external wall.