Patent Grant
8534211
The present invention relates generally to a system for controlling the roll of a ship, and more specifically, relates to extending or retracting a portion of a stabilizing fin of a ship depending on whether the ship is at rest or making headway.
A floating ship has six degrees of freedom, roll, pitch, yaw, heave, surge, and sway. Roll is generally the most objectionable as it is easily magnified by sea conditions, it affects sea keeping, operation of the ship, and the ship's course, and can damage cargo being stored on the ship. It is also unpleasant for passengers and the crew by causing motion induced sickness. All vessels have their own natural roll period depending on hull shape, loading, and other factors. Wave motions initiate this roll and, if the wave encounter frequency is in close synchronization with the vessel's natural period, roll motion may build to uncomfortable or even dangerous proportions. A vessel will naturally exhibit wave-induced roll both while making headway (“underway”) and while drifting, holding position or on anchor at zero forward speed (“at rest”).
Many types of stabilizing systems have been developed to dampen wave-induced roll motion. The most prevalent type of stabilizing system involves the use actively-controlled underwater fins to generate the forces used to stabilize a vessel making headway. When used underway, fins are rotated about the shaft stock axis presenting an angle to the onrushing water which generates a hydrodynamic lift force.
More recently, active underwater fin stabilizer systems have also been utilized to dampen vessel roll motion while the vessel is at rest (zero forward speed). When used at rest, fins are rotated about the shaft stock axis and act on the surrounding water in such a way, not unlike a paddle, to create a useful force. Fin systems that are designed to operate at zero forward speed are commonly referred to as “stabilization at anchor”, “at rest”, or “zero speed” systems. Because these stabilizer systems attempt to satisfy the vessel's roll reduction requirements both while underway and at rest, a design compromise exists. A fin planform geometry optimized to suit one requirement (e.g. at rest) will not be well-configured for the other requirement (e.g. underway). Moreover, the fin area required to stabilize a vessel at rest is typically larger (often significantly larger) than the fin area required to stabilize the same vessel underway. The smaller area required for underway stabilization is due to the hydrodynamic benefits which stem from the fin's movement during forward motion through the water. Consequently, a large fin area sized and shaped for at rest stabilization causes significant inefficiencies, including higher total drag and a poor lift-to-drag ratio, when the same shape is also used to satisfy underway stabilization requirements.
Prior art systems, such as U.S. Pat. No. 7,451,715 to Koop et al., have attempted to overcome this problem by introducing a fin stabilization system where the fin has an extension portion that extends the body of the fin; the extension is deployed from inside of the fin itself. However, this fin design suffers from at least one major problem. Since the extension is perfectly flat, there is minimal drag, and it is inefficient at trapping water. This creates an inefficient mechanism of controlling the roll of the ship at rest as the water can readily pass over the extension.
What is desired, therefore, is a variable geometry fin designed to more efficiently adjust the flow of water and readily create a greater amount of drag for a given rotational speed and area, and which facilitates ship stabilization at rest or at slow speeds underway more efficiently, while also allowing for efficient stabilization underway at higher speeds.
The variable geometry fin is a unique underwater fin system that is variable in area to suit the different area and planform requirements of underway and at rest stabilization. Due to the unique ability of the variable geometry fin to change area in a manner more closely optimized for both needs, the variable geometry fin is much more efficient when used underway than a fin designed for performance at rest, and much more efficient when used at rest than a fin designed for performance underway. For the compromise reasons explained above, a single non-variable area fin is not capable of this result. Moreover, even a variable area fin capable of changing its planform geometry in other ways, for example increasing the effective span of the fin to gain area for use at rest, would not match the superior efficiency, both underway and at rest, of the variable geometry fin of this invention.
A superior feature of the variable geometry fin is that its variable area is deployed in such a way so as to avoid increasing the span of the fin (the outreach dimension of the fin, as measured from the surface of the hull), which remains the same in both the retracted and deployed modes of use. This is a major advantage for a ship since stabilizer fins are protruding hull appendages making them particularly vulnerable to grounding or other impact from floating debris or marine life, which can result in fin damage and loss of use and/or potentially hull damage and associated safety concerns. Once the fin is deployed, the variable geometry fin employs a vortex generator, composed of protrusions and/or detents, and geometrically shaped trailing edge, and a support guide. This creates a recessed area that is capable of trapping, and adjusting the flow of water against the variable geometry fin, which provides a superior roll stabilization system to that of U.S. Pat. No. 7,451,715 to Koop et al., detailed above.
In accordance with a first embodiment of the present invention, a variable geometry fin comprises a stabilization element adapted to extend below the water line and a deploy mechanism. The stabilization element has a foil body and a trailing edge assembly extending from the foil body. The trailing edge assembly includes an extension body having two opposing surfaces, a trailing edge attached to an end of the extension body, a vortex generator having protrusions and/or recesses on the two opposing surfaces, and at least one support guide located on an outboard side of the extension body. The deploy mechanism is attached to the foil body and the trailing edge assembly. The trailing edge assembly extends rearwardly with respect to the foil body producing an additional surface area of the stabilization element.
In some of these embodiments, the trailing edge is shaped as a triangle, a wedge, a knife, a fixed interceptor, or an adjustable interceptor. In some of these embodiments, the deploy mechanism is a mechanical mechanism, an oil-based hydraulic actuator, an oil-based motor, a water-based hydraulic actuator, a water-based motor, an electrical actuator, an electrical motor, a pneumatic actuator, or a pneumatic motor. In certain of these embodiments, the vortex generator is a through-structure orifice with sharp or angled entry and exit edges, a cup shape, a straight edge, a surface indentation or groove, a saw tooth, or a bonded coating. In certain of these embodiments, the support guide is shaped as a circle, a square, a rectangle, or an I-beam.
In accordance with another embodiment of the present invention, a variable geometry fin comprises a stabilization element adapted to extend below the water line and a deploy mechanism. The stabilization element has a foil body and a trailing edge assembly extending from the foil body. The trailing edge assembly includes an extension body having two opposing surfaces, a trailing edge attached to an end of the extension body, a vortex generator on the two opposing surfaces, and at least one support guide located on an outboard side of the extension body, the support guide deployed when the extension body is deployed. The deploy mechanism is attached to the foil body and the trailing edge assembly. The trailing edge assembly extends rearwardly with respect to the foil body producing an additional surface area of the stabilization element.
In some of these embodiments, the trailing edge is shaped as a triangle, a wedge, a knife, a fixed interceptor, or an adjustable interceptor. In some of these embodiments, the deploy mechanism is a mechanical mechanism, an oil-based hydraulic actuator, an oil-based motor, a water-based hydraulic actuator, a water-based motor, an electrical actuator, an electrical motor, a pneumatic actuator, or a pneumatic motor. In certain of these embodiments, the vortex generator is a through-structure orifice with sharp or angled entry and exit edges, a cup shape, a straight edge, a surface indentation or groove, a saw tooth, or a bonded coating. In certain of these embodiments, the support guide is shaped as a circle, a square, a rectangle, or an I-beam.
In accordance with another embodiment of the present invention, a variable geometry fin comprises a stabilization element adapted to extend below the water line and a deploy mechanism. The stabilization element has a foil body and a trailing edge assembly extending from the foil body. The trailing edge assembly includes an extension body having two opposing surfaces, a trailing edge attached to an end of the extension body, a vortex generator having protrusions and/or recesses located on the two opposing surfaces, and at least one support guide located on an outboard side of the extension body, the support guide deployed when the extension body is deployed. The deploy mechanism is attached to the foil body and the trailing edge assembly. The trailing edge assembly extends rearwardly with respect to the foil body producing an additional surface area of the stabilization element.
In some of these embodiments, the trailing edge is shaped as a triangle, a wedge, a knife, a fixed interceptor, or an adjustable interceptor. In some of these embodiments, the deploy mechanism is a mechanical mechanism, an oil-based hydraulic actuator, an oil-based motor, a water-based hydraulic actuator, a water-based motor, an electrical actuator, an electrical motor, a pneumatic actuator, or a pneumatic motor. In certain of these embodiments, the vortex generator is a through-structure orifice with sharp or angled entry and exit edges, a cup shape, a straight edge, a surface indentation or groove, a saw tooth, or a bonded coating. In certain of these embodiments, the support guide is shaped as a circle, a square, a rectangle, or an I-beam.
In accordance with another embodiment of the present invention, a variable geometry fin comprises a stabilization element adapted to extend below the water line and a deploy mechanism. The stabilization element has a foil body and a trailing edge assembly extending from the foil body. The trailing edge assembly includes an extension body having two opposing surfaces, a trailing edge extending perpendicularly from the extension body forming a recessed area between the trailing edge and the foil body, a vortex generator having protrusions and/or recesses located on the two opposing surfaces, and at least one support guide located on an outboard side of the extension body, the support guide deployed when the extension body is deployed. The deploy mechanism is attached to the foil body and the trailing edge assembly. The trailing edge assembly extends rearwardly with respect to the foil body producing an additional surface area of the stabilization element.
In some of these embodiments, the trailing edge is shaped as a triangle, a wedge, a knife, a fixed interceptor, or an adjustable interceptor. In some of these embodiments, the deploy mechanism is a mechanical mechanism, an oil-based hydraulic actuator, an oil-based motor, a water-based hydraulic actuator, a water-based motor, an electrical actuator, an electrical motor, a pneumatic actuator, or a pneumatic motor. In certain of these embodiments, the vortex generator is a through-structure orifice with sharp or angled entry and exit edges, a cup shape, a straight edge, a surface indentation or groove, a saw tooth, or a bonded coating. In certain of these embodiments, the support guide is shaped as a circle, a square, a rectangle, or an I-beam.
The invention and its particular features and advantage will become more apparent from the following detailed description considered with reference to the accompanying drawings.
a-5g is a view of the various surface roughness of a variable geometry fin according to
e is a view of the various support guides of a variable geometry fin according to
a-7f is a view of the various trailing edge designs of a variable geometry fin according to
The system for controlling the roll of a ship includes a variable geometry fin with an extension capable of increasing the surface area of the fin.
As best seen in
Variable geometry fin 100 has a foil body 105 and a trailing edge 110. When the ship is underway, the trailing edge 110 is retracted into the foil body 105 and does not provide for any extension of the surface area of the variable geometry fin 100. Trailing edge 110 is triangular in shape, forming the point in the air foil shape of variable geometry fin 100. The pointed design allows for a decreased drag against the water as the ship is underway.
Referring now to
Movable trailing edge assembly 205 has a support guide 210. Movable trailing edge assembly 205 may have a single support guide 210, or movable trailing edge assembly 205 may have a plurality of support guides 210 depending on the size of the variable geometry fin 100, and the size of the ship being stabilized.
Variable geometry fin 100 may be manually operated by the operator of the ship. The operator may deploy or retract the mechanism using a manually controlled mechanism, or the operator may input commands into a control panel or a computer terminal to deploy or retract the variable geometry fin 100. The variable geometry fin 100 may also be completely computer controlled. The computer may have sole control of the deploy/retract mechanism 215 to extend or retract the trailing edge 110 to the most efficient surface area depending on the speed of the ship. As a computer can more quickly, and accurately compute the most efficient surface area, the variable geometry fin 100 is preferably computer controlled, however a manual override may be used to correct any computer related problems.
Referring now to
When the trailing edge assembly 205 is in the retracted position, the variable geometry fin 100 has a smaller effective surface area exposed to the water, the surface being designated by element 315, and the cross-hatched area of
Referring now to
The deploy mechanism moves the center of pressure from 310 to 405. This movement of the center of pressure further aft allows greater useful forces to develop during at rest usage for a given slew rate. When the variable geometry fin 100 is rotated while at rest, using fin stock shaft 305, it reacts against the mass of water to generate forces which are transmitted to the fin stock shaft 305 and into the vessel structure allowing a righting moment to be developed in opposition to the vessel's roll motion. Conversely, during underway operation, the reduced fin aspect ratio is not desirable as it reduces the hydrodynamic efficiency of the fin.
While underway, a higher fin aspect ratio produces a higher lift-to-drag ratio, resulting in a more useful lift for a given drag (penalty) or less drag for a given lift. Generally, the surface area required for underway operation is less than the surface area required for at rest operation. During underway operation, the movable trailing edge assembly 205 is retracted into the foil body 105, allowing for a smooth hydrofoil surface and a higher aspect ratio for efficient lift force generation.
Referring now to
Various textured surfaces may be used in the vortex generation, as depicted in
Referring now to
Referring now to
The unique design and configuration of the variable geometry fin allows at rest stabilization fin area and planform geometry (low aspect ratio) efficiency combined with an efficient (higher aspect ratio) underway fin. Because the underway fin shape and section is not compromised, the variable geometry fin is suitable for an extremely wide range of fin section profiles, including but not limited to NACA sections, IfS sections, Schilling sections, Tail Wedge and HSVA sections, and other custom profile sections.
It would be appreciated by those skilled in the art that various changes and modifications can be made to the illustrated embodiment without departing from the spirit of the present invention. All such modifications and changes are intended to be covered hereby.
The present application claims the benefit under 35 U.S.C. §119 (e) of U.S. Provisional Patent Application Ser. No. 61/276,949 filed on Sep. 18, 2009.
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| Number | Date | Country | |
|---|---|---|---|
| 61276949 | Sep 2009 | US |
