Abstract: The present invention is a water wings device used in combination with a watercraft that includes a plurality of water wings attached to the sides of the watercraft with attachment arms and directing fins that are placed into the water that the watercraft is traveling in. There is also an embodiment of the water wings device that includes a boat tail with a tapering protrusion that is placed into the water the watercraft is traveling in. Another embodiment is the water tail device that includes a plurality of water tails that attach to the rear of portion of a watercraft used in conjunction with water wings on the side of the watercraft that are all placed into the water the watercraft is traveling in.

Abstract: To measure salinity and water temperature in a marine surface layer using data obtained by a marine radar, a deviation ?S' between effect of an ocean wave on received power RSI0? in a reference time zone and effect of the ocean wave on received power RSIm? in a measurement time zone is estimated, a deviation ?s? between effect of the ocean wave on the received power RSI0? in the reference time zone and effect of the ocean wave on the received power in an electrical conductivity variable time zone is estimated, a regression function f(?) of a relationship between received power obtained by subtracting the deviation ?s? from the received power in the electrical conductivity variable time zone and electrical conductivity ? in the electrical conductivity variable time zone is estimated, and a value of electrical conductivity ?c in a measurement time zone is estimated, thereby calculating practical salinity.

Abstract: The invention described herein teaches that one drilling barge can be employed in two different areas. The standard drilling practice requires two vessels to perform the same work as one drilling barge invention. Standard drilling rigs require that one unit will drill well locations in water depths of 8?-18?. A second drilling unit must be provided to drill in water depths of 18?-60?. As a result of this invention, water depths of 8?-60? can be provided by use of the one vessel employing the novel stabilization system. The service area's coverage is increased greatly by use of the invention thereby creating excellent cost reduction and improved drilling procedures in remote and harsh drilling areas. The invention's cost is slightly more than the standard drilling barge however; coverage of the service area can be 500% greater than the standard vessel's coverage.

Abstract: An improved displacement hull form for ships and boats, in one of many possible embodiments includes a transom stern hull form (100F) having a hull underside (120A) that is substantially horizontal in transverse orientation along the aft-most portion of said hull form (100F), a pair of endplates (300D) having a substantially vertical orientation along the aft half of said hull form (100F) waterline length, a pair of cambered rudders (502J) located near the stern of said hull form (100F) with said cambered rudders (502J) having pressure faces oriented towards said hull form longitudinal centerplane (110A), and stern buttock-line shaping defined by a supercavitating hydrofoil (700M) shape. The hydrodynamics of said hull form (100F) are improved in terms of reduced resistance, reduced trim and draft aft, and reduced ship wave train. Other embodiments are described and shown.

Abstract: A hull (1) for a marine vessel (10) comprising an elongate body (2) that tapers outwardly from a foremost location, the bow (3), and tapers inwardly toward the aft (4) such that the aft (4) of the body (2) is significantly reduced in profile with respect to a point in the hull at which the inward taper commences.

Abstract: An improved displacement hull form for ships and boats, in one of many possible embodiments includes a transom stern hull form (100F) having a hull underside (120A) that is substantially horizontal in transverse orientation along the aft-most portion of said hull form (100F), a pair of endplates (300D) having a substantially vertical orientation along the aft half of said hull form (100F) waterline length, a pair of cambered rudders (502J) located near the stern of said hull form (100F) with said cambered rudders (502J) having pressure faces oriented towards said hull form longitudinal centerplane (110A), and stern buttock-line shaping defined by a supercavitating hydrofoil (700M) shape. The hydrodynamics of said hull form (100F) are improved in terms of reduced resistance, reduced trim and draft aft, and reduced ship wave train. Other embodiments are described and shown.

Abstract: The various embodiments disclosed and pictured herein illustrate a universal depth boat that is easy to operate and may be controlled by a single operator. A universal depth boat and hull design that comprises a hull having a bow, stern, sides, a V-hull portion and a flat bottom is disclosed. In the exemplary embodiment, a V-hull portion for spreading water is centrally located at a forward portion of the watercraft. The V-hull portion may include a keel as a forward apex, which forms a substantially perpendicular or vertical leading wedge with respect to the plane of water. The V-hull portion transitions to a flat bottom toward the stern. Accordingly, the watercraft will more easily traverse waves instead of riding over them, while the watercraft is simultaneously capable of accessing areas with extremely shallow water.

Abstract: A multi-hull speedboat hull design suitable for racing craft. The apparatus is a polygonal boat hull apparatus having a bow and stern wave penetrating feature. The bow has an additional triangular section to add strength and wave penetration capability. The hull is made from triangular-shaped essentially flat panels which provides for substantially stability and strength. The invention includes a drive pod system having a plurality of propulsion units. Each engine has a pair of hydro pneumatic cylinders that adjust the angle of attack of the propulsion unit. Each engine also has a pair of synchronized rudders. A top deck mounted aircraft-type of “tail assembly” having a rudder, elevators and/or ailerons assist in maneuvering the craft.

Abstract: A ship hull includes at least one float (10) and a centre of buoyancy (CB) situated behind the centre of flotation (CF), the distance between the centre of buoyancy and centre of flotation is greater by 5% than the waterline length L of the hull.

Abstract: A dualistic stern-appendant device comprises, in integrated form, at least two gate-supportive bodies and at least one flap-hydrodynamic body. The device is characterized by an alternating arrangement of bodies (totaling an odd number of at least three bodies) whereby no two consecutive gate-supportive bodies are next to each other and no two consecutive flap-hydrodynamic bodies are next to each other. Each gate-supportive body has an upper surface which is a gate-supportive surface, all of the gate-support surfaces together representing a cumulative gate-supportive surface. Each flap-hydrodynamic body has a lower surface which is a flap-hydrodynamic surface, all of the flap-hydrodynamic surfaces together representing a cumulative flap-hydrodynamic surface. The geometric plane defined by the cumulative gate-support surface is not encroached upon by any flap-hydrodynamic body.

Abstract: A hull form which operates in the speed ranges where both planing and wave making affect hull resistance is presented with a configuration which reduces wave drag and improves performance in very fast and ultra-faste speed ranges. The specific distribution of immersed cross-sectional area minimizes bow wave making and optimizes the closing wake. Bow wave impedes forward motion of a hull form. Stern closing wake pushes the hull forward and enhances the forward motion. The bow sections are designed so that they have a “hollow” entrance configuration which decreases the effort to spread the water and in turn diminishes the wave making as the hull pushes through the water. The stern sections are designed to be of such a configuration that as the water spread by the bow (34) now must close in around the stern (35) of the hull, the wave height is increased so that the closing wake exerts a forward thrust on the hull.