This invention relates to a steering mechanism for a boat having a planing hull.
Water sports, such as water skiing and wakeboarding, are typically performed at high speeds, and many recreational sport boats used for these sports have planing hulls, which are designed for efficient high-speed operation. In addition, many of these recreational sport boats are also inboards, having a propeller positioned beneath the hull, forward of the transom. This configuration is generally safer for water sports, as compared to outboards or stemdrives, for example, where the propeller extends behind the transom of the boat. But inboards, which typically have a single rudder positioned behind a stationary propeller, may be more difficult to handle, particularly in reverse, than an outboard where the propeller turns along with the motor when the boat turns. In reverse, inboards have a tendency to pull in one direction even if the rudder is turned hard over to turn the boat the other way. There is thus desired a planing hull boat with an inboard motor having improved handling characteristics.
In one aspect, the invention relates to a boat including a planing hull, a propeller, a main rudder, and a pair of flanking rudders. The planing hull has port and starboard sides, a transom, a hull bottom, and a centerline running down the middle of the boat, halfway between the port and starboard sides. The propeller is positioned forward of the transom and beneath the hull bottom. The main rudder is positioned aft of the propeller. The main rudder has a rotation axis about which the main rudder rotates. The flanking rudders are positioned forward of the propeller. One of the flanking rudders is positioned on the port side of the centerline, and the other flanking rudder is positioned on the starboard side of the centerline. Each flanking rudder has a rotation axis about which that flanking rudder rotates.
In another aspect, the invention relates to a boat including a planing hull, a propeller, a main rudder, and a pair of flanking rudders. The planing hull has port and starboard sides, a transom, a hull bottom, and a centerline running down the middle of the boat, halfway between the port and starboard sides. The propeller is positioned forward of the transom and beneath the hull bottom. The main rudder is positioned aft of the propeller. The main rudder has a rotation axis about which the main rudder rotates. The flanking rudders are positioned forward of the propeller. One of the flanking rudders is positioned on the port side of the centerline, and the other flanking rudder is positioned on the starboard side of the centerline. Each flanking rudder has an aft edge and a rotation axis about which that flanking rudder rotates. When the aft edge of each flanking rudder is rotated to port, the starboard flanking rudder is configured to rotate at a rotation rate that is different than a rotation rate at which the port flanking rudder is configured to rotate. When the aft edge of each flanking rudder is rotated to starboard, the port flanking rudder is configured to rotate at a rotation rate that is different than a rotation rate at which the starboard flanking rudder is configured to rotate.
In a further aspect, the invention relates to a boat including a planing hull, a propeller, a main rudder, a pair of flanking rudders, at least one actuator and a controller. The planing hull has port and starboard sides, a transom, a hull bottom, and a centerline running down the middle of the boat, halfway between the port and starboard sides. The propeller is positioned forward of the transom and beneath the hull bottom. The main rudder is positioned aft of the propeller. The main rudder has a rotation axis about which the main rudder rotates. The flanking rudders are positioned forward of the propeller. One of the flanking rudders is positioned on the port side of the centerline, and the other flanking rudder is positioned on the starboard side of the centerline. Each of the flanking rudders has (i) a rotation axis about which that flanking rudder rotates, (ii) a neutral position, and (iii) a forward edge that has an angle of toe in the neutral position. The at least one actuator is configured to rotate each flanking rudder about its rotation axis and change the angle of toe. The controller is configured to actuate the at least one actuator and change the angle of toe.
In still another aspect, the invention relates to a boat including a planing hull, a propeller, a main rudder, and a flanking rudder. The planing hull has port and starboard sides, a transom, a hull bottom, and a centerline running down the middle of the boat, halfway between the port and starboard sides. The propeller is positioned forward of the transom and beneath the hull bottom. The main rudder is positioned aft of the propeller. The flanking rudder is positioned forward of the propeller and offset from the centerline.
These and other aspects of the invention will become apparent from the following disclosure.
The hull 110 is a planing hull. When planing hull boats reach a certain speed, the resistance of the hull dramatically drops as the boat is supported by hydrodynamic forces instead of hydrostatic (buoyant) forces. This is referred to as planing. To achieve planing, the boat must overcome the drag produced by the hull and any appendages, such as the propeller and rudders. Appendages increase the drag of the hull. In general, the more appendages there are, the greater the drag. Some characteristics of the hull 110 that are typical of planing hull boats include lifting strakes 212, a chine 214 that is a hard chine, and a deadrise from 0° to 30°.
The boat 100 shown in
The inboard motor includes an engine 610 (see
Also in this embodiment, the propeller 342 is a left-handed propeller, but any suitable propeller, including a right-handed propeller, may be used. The propeller 342 has a propeller radius 404 and a corresponding propeller diameter. Suitable propellers include propellers with a diameter from 12 inches to 18 inches. The propeller 342 accelerates a stream of water both in the forward and reverse directions, depending on its direction of rotation. As the propeller 342 rotates in the counterclockwise direction when viewed from the stern, the boat 100 moves forward, and the propeller 342 generates a forward race 410, which is an accelerated a stream of water. The forward race 410 has outer edges, shown generally between line 410p and line 410s in
In this embodiment, the engine 610 and the propeller 342 may be operated by a user at a control console 120 (see
The rudder assembly 300 includes three rudders: a main rudder 310 and a pair of flanking rudders 320, 330. The main rudder 310 includes a main rudder post 312 (better seen in
The main rudder 310 is positioned behind (aft) of the propeller 342 and preferably is positioned laterally within the outer edges 410p, 410s of the forward race 410. The main rudder post 312 may be positioned on the centerline 202 of the boat 100, when viewed from above (see
The neutral position of a rudder 310, 320, 330 is its position when the boat 100 is moving straight and not turning. In this embodiment, when the main rudder 310 is in its neutral position, the chord 310b of the main rudder 310 is parallel to the centerline 202 of the boat 100 when viewed from above or below the boat 100. In embodiments where the main rudder post 312 is positioned on the centerline 202 of the boat 100, the chord 310b is preferably aligned with the centerline 202.
The flanking rudders 320, 330 are positioned forward of the propeller 342. One of the flanking rudders 320 is positioned on the port side of the centerline 202 of the boat 100, and the other flanking rudder 330 is positioned on the starboard side of the centerline 202 of the boat 100. Each flanking rudder 320, 330 includes a flanking rudder post 322, 332 (better seen in
Preferably, the flanking rudders 320, 330 are positioned to intersect the reverse race 420 when rotated from their neutral positions. More preferably, the flanking rudder posts 322, 332 are laterally positioned within the outer edges 420p, 420s of the reverse race 420, and even more preferably, within the radius 404 of the propeller 342. Preferably, both flanking rudders 320, 330 are symmetrical to each other. The posts 322, 332 of each flanking rudder 320, 330 are thus preferably located the same distance from the centerline 202 of the boat 100 and preferably positioned the same distance forward of the propeller 342. The flanking rudders 320, 330 are also preferably located close to the propeller 342 because the speed of the water and the lifting force of the reverse race dissipates the farther forward from the propeller 342 the flanking rudders 320, 330 are positioned. The flanking rudders 320, 330 are preferably positioned a distance forward of the propeller 342 that is equal to or less than three times the diameter of the propeller 342, more preferably a distance equal to or less than two times the diameter of the propeller 342, and even more preferably a distance equal to or less than the diameter of the propeller 342.
The neutral position of the flanking rudders 320, 330 is preferably set to balance the rudder load and drag to create a neutral feel in steering at all speeds. For some boats 100, the chord 320b, 330b of each flanking rudder 320, 330 is parallel to the centerline 202 in the neutral position. In other boats 100, the inventors have surprisingly found that the neutral position of the flanking rudders 320, 330 should be either toed-in or toed-out, relative to the forward direction of the boat 100. In a toed-in configuration (shown in
The inventors have found that the angles of toe α, β are preferably greater than 0° and less than 10°, and more preferably greater than 0° and less than 5°. As discussed above, the flanking rudders 320, 330 are preferably symmetrical about the centerline 202 and thus the angle of toe α of the port flanking rudder 320 is preferably the same as the angle of toe 13 of the starboard flanking rudder 330. One way of finding the neutral position for each flanking rudder 320, 330 is to disconnect the flanking rudders 320, 330 from their respective turning mechanisms and allow the flanking rudders 320, 330 to align naturally with the flow of water when the boat 100 is operated forward through the water at speed, for example from 5 mph to 50 mph.
In the preferred embodiment, all three rudders 310, 320, 330 are rotated in concert and about their respective rotation axes 310a, 320a, 330a to maneuver the boat 100. The rudder assembly 300 may be operated as follows to turn the boat 100 as it moves forward. To turn to port, the forward edge 314, 324, 334 of each rudder 310, 320, 330 is rotated to starboard from the neutral position, and correspondingly, the aft edge 316, 326, 336 of each rudder 310, 320, 330 is rotated to port from the neutral position. When the flanking rudders 320, 330 are toed-in, the starboard flanking rudder 330 is preferably rotated through line 330c to generate a force that assists in turning the boat 100 and not one that resists, and when the flanking rudders 320, 330 are toed-out, the port flanking rudder 320 is preferably rotated through line 320c. Conversely, to turn to starboard, the forward edge 314, 324, 334 of each rudder 310, 320, 330 is rotated to port from the neutral position, and correspondingly, the aft edge 316, 326, 336 of each rudder 310, 320, 330 is rotated to starboard from the neutral position. When the flanking rudders 320, 330 are toed-in, the port flanking rudder 320 is preferably rotated through line 320c to likewise generate a force to assist in turning the boat 100 and not one that resists, and when the flanking rudders 320, 330 are toed-out the starboard flanking rudder 330 is preferably rotated through line 330c.
When the boat 100 is moving in reverse, the rudders 310, 320, 330 are rotated in a manner similar to the way the rudders 310, 320, 330 are rotated when the boat 100 is moving forward. To turn to port, the aft edge 316, 326, 336 of each rudder 310, 320, 330 is rotated to port from the neutral position, and correspondingly, the forward edge 314, 324, 334 of each rudder 310, 320, 330 is rotated to starboard from the neutral position. Conversely, to turn to starboard, the aft edge 316, 326, 336 of each rudder 310, 320, 330 is rotated to starboard from the neutral position, and correspondingly, the forward edge 314, 324, 334 of each rudder 310, 320, 330 is rotated to port from the neutral position. As in the forward direction when the flanking rudders 320, 330 are toed-in, the starboard flanking rudder 330 is preferably rotated through line 330c when turning to port and the port flanking rudder 320 is preferably rotated through line 320c when turning to starboard. Likewise, when the flanking rudders 320, 330 are toed-out, the port flanking rudder 320 is preferably rotated through line 330c when turning to port and the starboard flanking rudder 330 is preferably rotated through line 323c when turning to starboard.
Rudders work best when there is high-velocity flow over the surfaces of the rudder. As a result, a boat having only a main rudder 310 positioned aft of the propeller 342 may not generate enough lift in reverse to overcome lateral forces generated by the propeller 342 rotation because the main rudder 310 is outside of the reverse race 420 and the boat is typically operating at low speed. Thus, the rear of the boat may pull to starboard, even if the main rudder 310, in a main rudder-only configuration, is rotated hard over to turn the boat to port. The inventors have found that using the flanking rudders 320, 330 may counteract this adverse effect, especially if the flanking rudders 320, 330 are positioned as discussed above.
Each of the rudders 310, 320, 330 may have a rotation angle γ, δ, ε. In this embodiment, the rotation angle γ of the main rudder 310 may be measured from the neutral position of the main rudder 310. Thus the rotation angle γ of the main rudder 310 is relative to the centerline 202 of the boat 100 when the main rudder post 312 is aligned with the centerline 202 of the boat 100 as shown in
During a turn, the rotation angles γ, δ, ε may be the same, but in some instances, it may be advantageous for each rudder 310, 320, 330 to be rotated to different angles. The inventors have also found that it may be beneficial for the rotation angles δ, ε of the flanking rudders 320, 330 to be greater than the rotation angle γ of the main rudder 310 during a turn. Although it may also be beneficial in other situations for the rotation angle γ of the main rudder 310 to be greater than the rotation angles δ, ε of the flanking rudders 320, 330. In addition, it may also be beneficial for the rotation angles δ, ε of the flanking rudders 320, 330 to be different. In particular, it may be beneficial for the rotation angle δ, ε of the flanking rudder 320, 330 on the outside of the turn (for example, rotation angle ε of the starboard flanking rudder 330 during a turn to port) to be less than the rotation angle δ, ε of the flanking rudder 320, 330 on the inside of the turn (for example, rotation angle δ of the port flanking rudder 320 during a turn to port). Although, again, in other instances it may be beneficial for the rotation angle δ, ε of the flanking rudder 320, 330 on the inside of the turn to be less than or equal to the rotation angle δ, ε of the flanking rudder 320, 330 on the inside of the turn.
In this embodiment, the flanking rudders 320, 330 are linked to the main rudder 310 such that they all rotate together.
The hydraulic cylinder 816 is connected to a first tiller arm 822 of the main rudder 310. In the configuration shown in
A first linkage 830 is used to couple the flanking rudders 320, 330 to the main rudder 310. In the configuration shown in
The port flanking rudder 320 has a first tiller arm 842 that is connected to the post 322 and extends outboard from the post 322. The first linkage 830 is connected the first tiller arm 842 of the port flanking rudder 320 at a connection point 834. Each connection point 832, 834 of the first linkage 830 is located on the same side relative to the rudder post 312, 322 to which it corresponds. In this embodiment, both connection points 832, 834 are located on the port side of their corresponding rudder posts 312, 322. When the main rudder 310 is turned to port, the second tiller arm 824 of the main rudder 310 moves forward, pushing the first linkage 830 forward. When the first linkage 830 moves forward, it pushes the first tiller arm 842 of the port flanking rudder 320 forward and rotates the aft edge 326 of the port flanking rudder 320 to port. Conversely, when the first linkage 830 moves aft, it pulls the first tiller arm 842 of the port flanking rudder 320 aft and rotates the aft edge 326 of the port flanking rudder 320 to starboard.
A second linkage 850 is used to couple the flanking rudders 320, 330 to each other. In the configuration shown in
The starboard flanking rudder 330 has a tiller arm 862 that is connected to the post 332 and also extends forward from the post 332. The second linkage 850 is connected the tiller arm 862 of the starboard flanking rudder 330 at a connection point 854. Each connection point 852, 854 of the second linkage 850 is located on the same side relative to the rudder post 322, 332 to which it corresponds. In this embodiment, both connection points 852, 854 are located forward of their corresponding rudder post 322, 332. As with the first linkage 830, the second linkage 850 of this embodiment is a rod with adjustable length that can transmit force to turn the starboard flanking rudder 330 either by pushing or pulling, although any suitable linkage may be used.
As the aft edge 326 of the port flanking rudder 320 rotates to port (i.e., when the first linkage 830 moves forward), the second tiller arm 844 rotates to starboard pushing the second linkage 850 to starboard. As the second linkage 850 moves to starboard, it pushes the tiller arm 862 of the starboard flanking rudder 330 to starboard and rotates the aft edge 336 of the starboard flanking rudder 330 to port. Conversely, as the aft edge 326 of the port flanking rudder 320 rotates to starboard (i.e., when the first linkage 830 moves aft), the second tiller arm 844 rotates to port pulling the second linkage 850 to port. As the second linkage 850 moves to port, it pulls the tiller arm 862 of the starboard flanking rudder 330 to port and rotates the aft edge 336 of the starboard flanking rudder 330 to starboard.
As discussed above, the flanking rudders 320, 330 may be rotated to a different rotation angle δ, ε than the main rudder 310 during a turn. The different rotation angles may be achieved by having a different relative rate of rotation between a drive rudder and a rudder being driven. For example, in the configuration shown in
Angling the two tiller arms, which are connected by a linkage 830, 850, relative to each other also adjusts the relative rotation rates between the two rudders. Each connection point 832, 834, 852, 854 may be associated with a vector that originates at the corresponding rotation axis 310a, 320a, 330a and is perpendicular to that rotation axis 310a, 320a, 330a when the rudder 310, 320, 330 is in its neutral position. In the embodiment shown in
In an embodiment where the tiller arms 824, 842, 844, 862 are straight, such as
When two linked tiller arms, such as the second tiller arm 824 of the main rudder 310 and the first tiller arm 842 of the port flanking rudder 320 shown in
As also discussed above, it is beneficial for the flanking rudder 320, 330 on the outside of the turn (for example, the starboard flanking rudder 330 during a turn to port) to pass through line 320c or line 330c. In the configuration shown in
In the embodiment shown in
In the configuration shown in
In the configuration shown in
As shown in
The controller 1140 provides an input control signal to the power distribution module 1132, which then provides power to the first and second remotely adjustable linkages 1110, 1120 to drive them in the appropriate direction. In
The controller 1140 may be any suitable controller including a microprocessor based controller that has a processor and a memory. The controller 1140 may be responsive to an input device 126. The input device 126 may be preferably located at the control console 120 (see
The controller 1140 may also have a plurality of programmed angles of toe α, β stored its memory. For example, no toe (an angle α, β of zero), toed-in 5°, toed-in 10°, toed-out 5°, toed-out 10°. A user may then select one of these programmed positions through the input device 126, and in response to the user's selection, the controller 1140 sends the appropriate control signal to power distribution module 1132 to drive the first and second remotely adjustable linkages 1110, 1120 to the programmed positions.
The controller 1140 does not need to be responsive to an input device 126 operated by the user. Instead, the controller 1140 may be responsive to various other switches and sensors that monitor or are activated by various operating conditions of the boat. For example, one angle of toe α, β may be preferred when the boat is operating in the forward direction (e.g., toed-in at 5°), and another angle of toe α, β may be preferred when the boat is operating in the reverse direction (e.g., toed-out at 5°). Thus, the controller 1140 may be responsive to the control lever 122, such that controller 1140 sets the angle of toe α, β from one of the plurality of programmed angles of toe α, β based on the direction the boat 100 is being driven. Other operational conditions that the controller 1140 may be programmed to adjust the angle of toe α, β include, for example, a speed range, an engine RPM range, gear positions, or steering compensation.
The rams 1112, 1122 of the first and second remotely adjustable linkages 1110, 1120 are preferably moved both concurrently and the same distance. As discussed above, the port and starboard flanking rudders 320, 330 are preferably symmetrical about the centerline 202, and moving the rams 1112, 1122 concurrently the same distance may be desirable to maintain this symmetry. However, those skilled in the art will recognize that the controller 1140 and associated input device 126, such as touch screen 126, may be configured to operate each of the first and second remotely adjustable linkages 1110, 1120 independently and to extend and retract the rams 1112, 1122 different distances.
In the embodiments discussed above, the flanking rudders 320, 330 are turned in concert with the main rudder 310. Under some operational conditions, it may be preferable to decouple the flanking rudders 320, 330 from the main rudder 310. For example, it may be beneficial for the flanking rudders 320, 330 to turn in concert with the main rudder 310 during reverse operation, but remain fixed during high speed forward operation. A suitable configuration for decoupling the flanking rudders 320, 330 from the main rudder 310 is shown in
The embodiments discussed above include a pair of flanking rudders 320, 330. Having a pair of flanking rudders 320, 330 is desirable for a number of reasons, including for example, maintaining a balanced load on either side of the boat's centerline 202 when the flanking rudders are angled relative to the forward and aft direction of the boat 100. However, a single flanking rudder 320, 330 positioned forward of the propeller 342, may also be suitable.
The single flanking rudder 320, 330 is positioned to intersect the reverse race 420 when rotated from its neutral position and sized to generate sufficient lift to counteract any yaw moment generated by the propeller 342 in when the boat 100 is operated in reverse. As a result, the single flanking rudder 320, 330 is preferably offset from the centerline 202 of the boat 100. An embodiment having a single flanking rudder 320 positioned on the port side of the boat is shown in
The embodiments discussed herein are examples of preferred embodiments of the present invention and are provided for illustrative purposes only. They are not intended to limit the scope of the invention. Although specific configurations, structures, etc. have been shown and described, such are not limiting. Modifications and variations are contemplated within the scope of the invention, which is to be limited only by the scope of the issued claims.
This application is a continuation of U.S. patent application Ser. No. 16/106,881, filed Aug. 21, 2018, now U.S. Pat. No. 10,464,655. U.S. patent application Ser. No. 16/106,881 is a continuation of U.S. patent application Ser. No. 15/477,862, filed Apr. 3, 2017, now U.S. Pat. No. 10,065,725. U.S. patent application Ser. No. 15/477,862 is a continuation of U.S. patent application Ser. No. 15/184,340, filed Jun. 16, 2016, now U.S. Pat. No. 9,611,009. U.S. patent application Ser. No. 15/184,340 claims the benefit under 35 U.S.C. § 119(e) of U.S. Provisional Patent Application No. 62/347,313, filed Jun. 8, 2016, and titled “Steering Mechanism for a Boat having a Planning Hull.” The forgoing applications are incorporated herein by reference in their entireties.
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Number | Date | Country | |
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Parent | 16106881 | Aug 2018 | US |
Child | 16672898 | US | |
Parent | 15477862 | Apr 2017 | US |
Child | 16106881 | US | |
Parent | 15184340 | Jun 2016 | US |
Child | 15477862 | US |