Patent Grant
10501156
The invention relates to a device for modifying the wake of a boat, as well as a boat equipped with one or more such devices.
Recreational sport boats are often used to tow water sports performers such as water skiers, wakeboarders, wake surfers, and the like. These boats often have a horizontal platform attached to the transom of the boat to make it easier for the performer to get into the water from the boat or out of the water into the boat. This platform is commonly referred to as a swim platform or a boarding platform.
The optimal wake depends on the water sport a boat is used for, as well as the preferences and skill level of the performer. Water skiers generally prefer a relatively smooth water surface, while wakeboarders and wake surfers desire bigger wakes and wakes with more defined shapes. In recent years, boats have been equipped with various means for modifying the wake of the boat depending on how the boat is being used.
One example of a conventional means used to modify a boat's wake is a trim tab. Trim tabs originally were designed to adjust the trim of a boat. For example, when a boat is overloaded on the port side causing the boat to list to port, a trim tab may be deployed on the port side to cause the boat to return to an even keel. More recently, trim tabs have been used to purposefully modify the wake of a boat. One way to do so is to use one or more trim tabs to lift the stern of the boat. Lifting the stern minimizes the wake of a boat, resulting in a relatively smooth water surface, which is desirable for water skiing. Another way that trim tabs have been used is to increase the displacement of one side of the boat, which increases the size of the wake on the side of the boat with the increased displacement.
Each of the aforementioned trim tabs 10, 20, 30 is pivotable between a non-deployed position and a deployed position. In
In the embodiment shown in
Even with the trim tabs described above, wakeboarders and wake surfers desire larger wakes with improved shapes. For surfing in particular, wake surfers desire a wake with a large surfable area. The surfable area is the portion of the wake that pushes the surfer forward. This area generally extends from the curl of the wake to the swim platform.
In one aspect, the invention relates to a wake-modifying device adapted to be attached to a boat, aft of the boat's transom, on either a port or starboard side of the boat's centerline.
In another aspect, the invention relates to a recreational sport boat including a hull, having starboard and port sides and a transom, and a pair of wake-modifying devices positioned aft of the transom. One of the wake-modifying devices is positioned on a port side of the boat's centerline and another of the wake-modifying devices is positioned on a starboard side of the boat's centerline. Preferably, each wake-modifying device is pivotably attached directly to the transom. Alternatively, one or both of the wake-modifying devices may be attached to other portions of the boat, such as the bottom or sides of the hull or a generally horizontal platform.
In a further aspect of the invention, each wake-modifying device includes a plate-like member and at least one downturned surface at a trailing portion of the plate-like member. Each wake-modifying device is pivotable between a non-deployed position and a deployed position about a pivot axis that is horizontal or inclined no more than about 35° from horizontal. In the deployed position, the downturned surface is lower than it is in the non-deployed position so as to be able to modify the boat's wake.
The plate-like member and the downturned surface of each wake-modifying device may be an integral piece or separate pieces joined together. The downturned surface may be at a trailing edge of the plate-like member, for example, when they are an integral piece. Or the downturned surface may be inward of the trailing edge, for example, when the downturned surface is a separate piece attached to a lower surface of the plate-like member.
Preferably, an angle between the downturned surface of each wake-modifying device and a lower surface of a central portion of the plate-like member is between about 120° to about 135°, and the downturned surface extends between about 1 inch to about 2¼ inches below the lower surface of the plate-like member. The downturned surface may be oriented such that it intersects the plate-like member along a line that is generally parallel to the pivot axis, or along a line that is at an oblique angle relative to the pivot axis. The downturned surface and the plate-like member need not intersect along a straight line, and may instead intersect along a curved line.
Preferably, each wake-modifying device includes not one but two (or more) downturned surfaces at a trailing portion of the plate-like member. A first one of the downturned surfaces may intersect the plate-like member along a line that is generally parallel to the pivot axis, and a second one of the downturned surfaces may intersect the plate-like member along a line that is at an obtuse angle relative to the line along which the first downturned surface and the plate-like member intersect. Preferably, the obtuse angle is between about 135° to about 150°, and the first downturned surface is outboard of the second downturned surface.
Each wake-modifying device may also include at least one upturned surface at an outboard portion of the plate-like member, between the downturned surface and the pivot axis. The plate-like member and the upturned surface may be an integral piece or separate pieces joined together, and the upturned surface may be at an outboard edge of the plate-like member or inward of the outboard edge. An angle between the upturned surface and an upper surface of a central portion of the plate-like member preferably is between about 30° to about 150°, and more preferably is about 90°. The upturned surface preferably extends at least about 1 inch above an upper surface of the plate-like member.
At least one of the wake-modifying devices may include another downturned surface at an inboard portion of the plate-like member, between the first downturned surface and the pivot axis. An angle between this downturned surface and the lower surface of a central portion of the plate-like member preferably is between about 30° to about 150°, and more preferably is about 90°. The plate-like member and this downturned surface may be an integral piece or separate pieces joined together, and the downturned surface may be at an inboard edge of the plate-like member or inward of the inboard edge.
At least one of the wake-modifying devices may also include at least one fin attached to the lower surface of the plate-like member. An angle between the fin and the lower surface of the plate-like member preferably is between about 30° to about 150°, and more preferably is about 90°. The fin preferably extends at least about 1 inch below the lower surface of the plate-like member. The fin and the plate-like member preferably intersect along a line that is at an angle between about 15° and about 75° relative to the pivot axis, and more preferably between about 30° and about 60° relative to the pivot axis, and extends in a direction aft and outboard from the pivot axis. In some cases, it may be desirable to have at least two fins, which preferably are parallel to each other.
In still a further aspect, the invention relates to a recreational sport boat. The boat includes a hull having starboard and port sides and a transom. The boat also includes a generally horizontal platform extending aft of the transom and configured to support a human weighing at least 100 lbs. on an upper surface thereof. In this aspect of the invention, a pair of wake-modifying devices are pivotably attached to the platform. One of the wake-modifying devices is positioned on a port side of the platform's centerline, and another of the wake-modifying devices is positioned on a starboard side of the platform's centerline. Preferably, each wake-modifying device is pivotable between a non-deployed position in which the wake-modifying device is oriented generally parallel to the platform and a deployed position in which the wake-modifying device is pivoted downwardly at an angle relative to its non-deployed position.
In still another aspect, each wake-modifying device attached to the platform is moveable between a non-deployed position and a deployed position in which the wake-modifying device is angled downwardly at an angle relative to the top surface of the generally horizontal platform. In this aspect of the invention, a pair of wake-modifying devices are pivotably attached to the platform.
The aspects of the invention are not mutually exclusive. Instead various aspects of the invention may be used in combination with other aspects of the invention or other means to modify the boat's wake. For example, in yet another aspect, the invention relates to a recreational sport boat. The boat includes a hull having starboard and port sides and a transom. The boat also includes a generally horizontal platform extending aft of the transom and configured to support a human weighing at least 100 lbs. on an upper surface thereof. In this aspect of the invention, a first pair of wake-modifying devices is preferably attached to the transom with one of the wake-modifying devices positioned on a port side of the boat's centerline and another of the wake-modifying devices positioned on a starboard side of the boat's centerline. A second pair of wake-modifying devices is preferably attached to the underside of the generally horizontal platform with one of the wake-modifying devices positioned on a port side of the platform's centerline, and another of the wake-modifying devices positioned on a starboard side of the platform's centerline.
Each wake-modifying device preferably is capable of assuming multiple deployed positions. In each different deployed position the wake-modifying device is pivoted downwardly at a different angle relative to the non-deployed position. The boat may include a plurality of linear actuators, each operable to move a respective one of the wake-modifying devices between its non-deployed position and its deployed position. The boat also preferably includes an operator station with a controller configured to control the operation of each linear actuator.
These and other aspects of the invention are further described and illustrated in the following description and accompanying drawings.
Exemplary preferred embodiments of the invention will now be described with reference to the accompanying figures. Like reference numerals refer to the same or similar elements throughout the figures and description.
The boat 100 has a centerline 150 running down the center of the boat, halfway between the port and starboard sides 123, 124. A conventional trim tab 20 is pivotably attached to the transom 122 along the centerline 150. The wake-modifying devices 111, 112 are pivotably attached to the transom 122 on port and starboard sides of the centerline 150, respectively.
Each wake-modifying device 111, 112 includes a plate-like member 200 that is pivotably attached to the transom 122 of the boat 100. The plate-like member 200 pivots about a pivot axis 210 to move between a non-deployed position and a deployed position. In this embodiment, the pivot axis 210 is a hinge and is flush with the transom 122 of the boat 100. Here, the hinge is a piano hinge that is welded to a leading portion L of the plate-like member 200 and attached to the transom of the boat 100 using screws. However, any suitable pivotable connection may be used and it may be affixed to the wake-modifying device 111, 112 and transom 122 of the boat 100 using any suitable means, including but not limited to bolts, screws, rivets, welding, and epoxy. In addition, the wake-modifying device 111, 112 may be attached to the transom 122 such that the pivot axis 210 is not flush with the transom 122, for example, the pivot axis may be spaced further aft of the transom 122. The wake-modifying devices 111, 112 also may be attached to portions of the boat other than the transom 122. For example, the wake-modifying devices 111, 112 could be attached to the bottom of the hull 120, to the port and starboard sides 123, 124 of the hull 120, or to a swim platform (not shown). The pivot axis 210 preferably is parallel to the transom 122, but it may be oriented at an oblique angle relative to the transom 122 so long as the wake-modifying device 111, 112 provides an upward force on the boat 100 as the boat 100 travels forward through the water.
In the embodiment shown, the pivot axis 210 is parallel to the deadrise (the angle of the hull from the keel to the chine at the transom 122) of the boat 100. But the pivot axis 210 may instead be at an angle relative to the deadrise. Some boats, for example, have little or no deadrise. In such cases, it may be advantageous to orient the pivot axis 210 at an angle relative to the deadrise. Preferably, the pivot axis is inclined no more than about 35° from horizontal, more preferably no more than about 20° from horizontal, and most preferably no more than about 15° from horizontal. This inclination is preferably in the direction from the chine to the keel. Preferably, the pivot axis is inclined no more than about 15° more than the deadrise.
The plate-like member 200 has a trailing portion T that is aft of the leading portion L. The trailing portion T is the aft half of the plate-like member 200, and the leading portion L is the forward half of the plate-like member 200. The plate-like member 200 also has an inboard portion I and an outboard portion O. The inboard portion I is the inboard half of the plate-like member, and the outboard portion O is the outboard half of the plate-like member. Thus, the plate-like member may be divided into quadrants as shown in
In the embodiment shown, there are two downturned surfaces 310, 320 at the trailing portion T of the plate-like member 200. The first downturned surface 310 intersects the plate-like member 200 along a line that is generally parallel to the pivot axis 210. The second downturned surface 320 intersects the plate-like member 200 along a line that is oriented at an angle α relative to the pivot axis 210. In this embodiment, the first downturned surface 310 is outboard of the second downturned surface 320, which is at the trailing, inboard portion T, I of the plate-like member 200. The second downturned surface 320 may extend into adjacent quadrants without deviating from the scope of the invention. The first and second downturned surfaces 310, 320 preferably are at the edge of the plate-like member 200, but they may be inward of the edge.
The inventors believe that the combination of the plate-like member 200 and one or both of the downturned surfaces 310, 320 improves the size and shape of the wake. The side of the boat 100 with the desirable wake is referred to as the surf side. The surf side is the side of the boat 100 opposite a deployed wake-modifying device. The side with the deployed wake-modifying device is referred to as the non-surf side.
As the boat 100 moves through the water, the hull displaces water both downward under the hull 120 and outward of the sides 123, 124 of the hull 120. This creates a cavity immediately behind the boat 100. The displaced water recovers behind the boat 100 to fill the cavity. As the displaced water recovers, the water converges from under the boat 100 and from the sides 123, 124 of the hull 120. When the convergence occurs with sufficient force, it creates a v-shaped wave crest or “rooster tail” at the point of convergence. This v-shaped crest then propagates outward behind the boat 100 creating a wake that is suitable for wakeboarding, wake surfing, and the like. When one of the wake-modifying devices 111, 112 is in the deployed position, the downturned surfaces 310, 320 direct the water sharply downward. This sharp redirection of water results in an additional upward force to roll the boat 100 toward the surf side to a greater degree than the prior art trim tabs discussed above and shown in
The downturned surface 310, 320 should extend far enough in a downward direction to cause redirection of the water. The downturned surface 310, 320 should also be short enough that the downturned surface does not interact with the water when in the non-deployed position. Preferably, the downturned surface 310, 320 extends from about 1 inch to about 2¼ inches below a lower surface 220 of the plate-like member 200, and more preferably about 1½ inches below the lower surface 220 of the plate-like member 200. The downturned surface 310, 320 forms an angle β with a lower surface 220 of a central portion of the plate-like member 200. The inventors have found that this angle β should be sufficient to redirect the water, but not so sharp as to result in excessive force on the wake-modifying device 111, 112. Preferably, the angle β between the downturned surface 310, 320 the lower surface 220 of the central portion of the plate-like member 200 is between about 120° and about 135°.
The water converging behind the boat 100 from the sides 123, 124 of the hull 120 forms an angle with the sides of the hull 123, 124. The inventors have found that orienting a downturned surface 320 to intersect this angle improves the wake on the surf side. Accordingly, the line where the second downturned surface 320 intersects the plate-like member 200 is oriented at an angle α relative to the pivot axis 210. This angle α preferably is perpendicular to the angle formed between the recovering water and the side 123, 124 of the hull 120. The angle α preferably is between about 30° to about 45°.
In the embodiment shown, the wake-modifying device 111, 112 has two upturned surfaces 410, 420 between the first downturned surface 310 and the pivot axis 210. These upturned surfaces 410, 420 are at the outboard portion O of the plate-like member 200, preferably at the edge of the plate-like member, but they may be inward of the edge. An angle γ between the upturned surfaces 410, 420 and an upper surface 230 of the central portion of the plate-like member 200 preferably is between about 30° to about 150°, and more preferably is about 90°. The inventors believe that these upturned surfaces 410, 420 delay the water on the non-surf side from converging behind the boat 100 and further shift the point of convergence aft of the transom 122 and toward the non-surf side. The upturned surfaces 410, 420 should extend far enough in an upward direction to delay the water. The upturned surfaces 410, 420 preferably extend at least about 1 inch above the upper surface 230 of the plate-like member 200, more preferably at least about 2 inches above the upper surface 230 of the plate-like member 200, and even more preferably at least about 2.5 inches above the upper surface 230 of the plate-like member 200. In this embodiment, the first upturned surface 410 intersects the plate-like member along a line that is generally parallel to either the port side 123 of the hull 120 or the starboard side 124 of the hull 120. The second upturned surface 420 is positioned between the first upturned surface 410 and the first downturned surface 310 and intersects the plate-like member along a line that is oriented at an oblique angle δ with respect to the pivot axis 210. The angle δ preferably is between about 60° to about 90°, and more preferably is about 75°.
A third downturned surface 330 between the second downturned surface 320 and the pivot axis 210 can further improve the wake on the surf-side. An angle ε between the third downturned surface 330 and the lower surface 220 of the central portion of the plate-like member 200 preferably is between about 30° to about 150°, and more preferably is about 90°. The inventors believe this third downturned surface 330 further delays the water on the non-surf side from converging with the water on the surf side. In the embodiment shown, the third downturned surface 330 is positioned along the inboard portion I of the plate-like member 200 and intersects the plate-like member 200 along a line that is generally perpendicular to the pivot axis 210. The third downturned surface 330 preferably is at an inboard edge of the plate-like member, but it may be inward of the edge. Similar to the other downturned surfaces 310, 320, the third downturned surface 330 should extend far enough in a downward direction to delay or redirect the water. As with the other downturned surfaces 310, 320, the third downturned surface 330 is preferably short enough that the third downturned surface 330 does not interact (or at least minimizes interaction) with the water when in the non-deployed position. The third downturned surface 330 preferably extends between about ½ inch to about 3 inches below the lower surface 220 of the plate-like member 200, and more preferably extends about 1 inch below the lower surface 220 of the plate-like member 200.
The boat 100 of this embodiment uses a left-handed propeller 170, which causes the prop wash to be offset towards the starboard side. To balance the desirability of the surf wakes on both sides of the boat 100, the port wake-modifying device 111 of this embodiment provides more delay of the water than does the starboard wake-modifying device 112. In this embodiment, the port wake-modifying device 111 has the third downturned surface 330 while the starboard wake-modifying device 112 does not. However, the third downturned surface 330 may be provided on either the port or starboard wake-modifying device 111, 112, both, or neither.
In the embodiment shown, a linear actuator 510 is used to move the wake-modifying device 111, 112 between the deployed and non-deployed positions. The linear actuator 510 preferably is an electric linear actuator, such as one available from Lenco Marine. One end of the linear actuator 510 is screwed to the transom 122 of the boat 100. The other end of the linear actuator is connected to a u-shaped bracket 202 by a pin 204. The u-shaped bracket 202 is then bolted to the plate-like member 200. Any suitable means may be used to move the wake-modifying device 111, 112 between the deployed and non-deployed positions, including but not limited to hydraulic linear actuators and mechanical levers.
The size of the wake-modifying device 111, 112 may be varied depending upon the characteristics of the boat 100 and the desired wake. The lift provided by the wake-modifying device 111, 112 is generally proportional to the angles α, β, the surface area of the first and second downturned surfaces 310, 320, and the surface area of the plate-like member 200. In this embodiment, the wake-modifying device 111, 112 is about 17 inches long and about 14.5 inches wide. Preferably, the wake-modifying device 111, 112 is at least about 10 inches long and at least about 9 inches wide.
Because the wake-modifying device 111, 112 is used in a marine environment, it preferably is made of materials suitable for that environment. In this embodiment, these materials are primarily corrosion-resistant metal alloys such as stainless steel. The wake-modifying device 111, 112, including the plate-like member 200, preferably should not deform during operation. Preferably, the wake-modifying device 111, 112 will have sufficient rigidity to maintain its shape at all speeds and especially at speeds suitable for surfing (approximately 9 mph to 12 mph). In the preferred embodiment, the wake-modifying device 111, 112 is made from 12 gauge stainless steel plate. Other suitable materials may be used instead, such as wood, plastic, fiber reinforced composites, or other metals including aluminum.
Boat design plays an important role in establishing the wake shape. Design factors include, for example, the hull design and the weight of the boat. The wake-modifying device 111, 112 preferably is customized based on the boat design in order to produce the desired wake.
As an example of how hull design affects the boat's wake, a first boat having a steeper deadrise than a second boat will typically allow the water to recover closer to the transom of the boat. The shape of the corners between the sides of the hull and the transom also impact the recovery of the water. A boat with smooth corners (e.g., having a radius) will allow the water to recover faster than will a boat with square corners. The wake-modifying devices 111, 112 of the second embodiment are designed to provide greater lift to the boat on the non-surf side and further delay and direct the water on the non-surf side.
As with the first embodiment, the port and starboard wake-modifying devices 111, 112 of the second embodiment are not symmetrical with one another. Here, the port wake-modifying device 111 includes two fins 340, 350 attached to the lower surface 220 of the plate-like member 200. These fins 340, 350 extend at a downward angle η relative to the lower surface 220 of the plate-like member 200. The downward angle η preferably is between about 30° and about 150°, and more preferably is about 90°. The fins 340, 350 intersect the plate-like member 200 along lines that are oriented at an angle θ relative to the pivot axis 210. This angle θ preferably is between about 15° and about 75°, and more preferably is between about 30° and about 60°. In the embodiment shown, the fins 340, 350 are parallel to each other and at an angle θ of 60° relative to the pivot axis 210. The inventors believe these fins 340, 350 redirect the water outboard, further shifting the point of convergence aft from the transom 122 and toward the non-surf side. As with the downturned surfaces 310, 320, 330 and the upturned surfaces 410, 420, the fins 340, 350 should extend far enough away from the plate-like member 200 to redirect the water flow. The fins 340, 350 preferably should extend at least about 1 inch below the lower surface 220 of the plate-like member 200, and more preferably should extend at least about 2 inches below the lower surface 220 of the plate-like member 200. In the embodiment shown, the fins 340, 350 have different lengths. The fins preferably are about 4 inches to about 16 inches long, and more preferably are about 8 inches to about 12 inches long. The fins preferably do not extend beyond the edges of the plate-like member.
In the second embodiment, the third downturned surface 330 intersects the plate-like member along a line that is oriented at an oblique angle ϕ relative to the pivot axis 210. The angle ϕ preferably is between about 45° to about 90°, and more preferably is about 70°. All three of the downturned surfaces 310, 320, 330 form an angle α, ε with respect to the lower surface 220 of the central portion of the plate-like member 200 of about 135°. The wake-modifying devices 111, 112 of this embodiment preferably are about 17 inches wide and about 16 and ½ inches long.
The port and starboard wake-modifying devices 111, 112 in the previous two embodiments are asymmetrical with each other, but the wake-modifying devices 111, 112 can be symmetrical. Symmetrical wake-modifying devices 111, 112 may be used, for example, with heavy boats where the propeller 170 has less of an impact on the boat's wake. The third preferred embodiment shown in
As discussed above, the wake-modifying devices do not have to be attached to the transom 122 of the boat 100. Instead, the wake-modifying devices may be attached further aft of the transom 122, such as to a swim platform. While the wake-modifying devices 111, 112 of the first, second, and third embodiments may be suitably used to modify the boat's wake when mounted to a swim platform, wake-modifying devices having alternate designs may also be suitably used to modify the boat's wake when mounted to the swim platform. Such alternate wake-modifying devices suitable for modifying a boat's wake when mounted to a swim platform are described in the fourth, fifth, sixth, and seventh embodiments.
In this embodiment, the platform 700 is attached to the transom 122 of the boat 100. Two brackets 710, 720 are attached to the bottom surface 704 of the platform 700. In this embodiment, the brackets 710, 720 are L-shaped. One leg portion 712, 722 of each bracket 710, 720 extends aft of the transom 122 along the bottom surface 704 of the platform 700 and is attached to the bottom surface 704 using fasteners. The other leg portion 714, 724 of each bracket 710, 720 is attached to the transom 122 of the boat 100 using fasteners. In this embodiment, the fasteners used to attach the brackets to the platform 700 and the transom 120 are screws; however, any suitable means of attachment known in the art may be used including but not limited to bolts, rivets, welding, adhesive, and the like. Alternatively, the brackets 710, 720 may be integrally formed into either the platform 700 or the transom 122 of the boat. Similarly, the platform 700 may be attached to the transom 122 by any suitable means and is not limited to the use of brackets 710, 720. While the platform 700 is described as an attachable/detachable platform, it is not so limited. For example, the platform 700 may be integrally formed in the stern of the boat.
The platform 700 has a leading edge 742, a port edge 744, a starboard edge 746, and a trailing edge 748. The platform also has a centerline 750, which is coincident with the boat's centerline 150 in this embodiment. While
Attached to the underside (bottom surface 704 in this embodiment) of the platform 700 is at least one wake-modifying device 802, 804. In this embodiment, two wake-modifying devices 802, 804 are attached to the platform 700. A port wake-modifying device 802 is positioned on a port side of the platform's centerline 750, and a starboard wake-modifying device 804 is positioned on a starboard side of the platform's centerline 750.
As discussed above, a v-shaped wave crest propagates outward and aft behind the boat. Each wake-modifying device is positioned on the platform 700 so that it can interact with the wave crest. In this embodiment, each wake-modifying device 802, 804 is independently moveable between a non-deployed position and a deployed position. The port wake-modifying device 802 is shown in the non-deployed position in
In this embodiment, each wake-modifying device 802, 804 includes a plate-like member 810, 820. The plate-like members 810, 820 have a preferably straight edge 812, 822 where they are attached to the platform and an outer contour 814, 824. In this embodiment, the outer contour 814, 824 is a parabolic shape, although the outer contour may have other shapes, such as those discussed below. The plate-like members 810, 820 also have a lower surface 816, 826 and an upper surface 818, 828. In this embodiment, the lower surfaces 816, 826 and upper surfaces 818, 828 are generally flat, but they may also be contoured as discussed below.
In the non-deployed position, the wake-modifying devices 802, 804 are positioned in a plane that is generally parallel to platform 700. In the deployed position, the deployed wake-modifying device is able to modify or sculpt the wake. Unlike the wake-modifying devices 111, 112 of the first, second, and third embodiments, the wake-modifying devices 802, 804 of the fourth embodiment are deployed on the surf side of the boat. When a water sports performer is surfing, for example, on the port side of the boat 100, the port wake-modifying device 802 is deployed, as shown in
The wake-modifying devices 802, 804 move between the non-deployed position and the deployed position by pivoting about a pivot axis 832, 842. The pivot axis 832, 842 in this embodiment is a hinge. Here, the hinge is a piano hinge that is welded to the edge 812, 822 of each wake-modifying device 802, 804 and attached to the bottom surface 704 of the platform using screws. Any suitable means known in the art may be used to connect the pivot axis 832, 842 to the plate-like members 810, 820 and the bottom surface 704 of the platform 700, including but not limited to rivets, bolts, adhesive, and the like. In pivoting about its respective pivot axis 832, 842, each wake-modifying device 802, 804 is capable of assuming multiple deployed positions. Each different deployed position is a different downward angle λ relative to the wake-modifying device's non-deployed position. Preferably the downward angle λ is from about 10 degrees to about 80 degrees, more preferably from about 30 degrees to about 60 degrees.
In the embodiment shown, a linear actuator 510 is used to independently move each wake-modifying device 802, 804 between the deployed and non-deployed positions. The linear actuator 510 preferably is an electric linear actuator, such as one available from Lenco Marine. One end of each linear actuator 510 is screwed to the bottom surface 704 of the platform 700. The other end of each linear actuator 510 is connected to a u-shaped bracket 836, 846 by a pin 838, 848. The u-shaped bracket 836, 846 is bolted to the lower surfaces 816, 826. Any suitable means may be used to move the wake-modifying devices 802, 804 between the deployed and non-deployed positions, including but not limited to hydraulic linear actuators, mechanical levers, and motors.
The wake-modifying devices 802, 804 are not limited to moving between the non-deployed and deployed positions by pivoting about the pivot axis 832, 842. For example, the wake-modifying devices 802, 804 may move between the non-deployed and deployed positions by linearly translating at the downward angle λ relative to the platform 700.
By positioning the wake-modifying devices 802, 804 on the platform, the inventors believe they can obtain at least two benefits. First, by positioning the wake-modifying devices 802, 804 at an oblique angle μ, ν relative to the platform's centerline 750, energy of the wake that is naturally shaped by the hull and would have blended into the wave crest is redirected, by the lower surface 816, 826, inboard and aft, thereby lengthening the surfable area of the wake. Preferably, the oblique angle μ of the port wake-modifying device 802 is an acute angle rotated counterclockwise relative to the platform's centerline 750 when viewed from above, more preferably the oblique angle μ is from about 10 degrees to about 80 degrees, and even more preferably from about 30 degrees to about 60 degrees. In this embodiment, the pivot axis 832 is set at the oblique angle μ. Preferably, the oblique angle ν of the starboard wake-modifying device 804 is an acute angle rotated clockwise relative to the platform's centerline 750 when viewed from above, more preferably the oblique angle ν is from about 10 degrees to about 80 degrees, and even more preferably from about 30 degrees to about 60 degrees. In this embodiment, the pivot axis 832 is set at the oblique angle ν.
The second benefit is that the shape of the outer contour 814, 824 of the wake-modifying devices 802, 804 sculpts or shapes the wake. The outer contour 814, 824 may be divided into a leading edge 814a, 824a and a trailing edge 814b, 824b. The inventors believe that the trailing edge 814b, 824b of the wake-modifying devices 802, 804 shapes the wake as the wave crest moves past the trailing edge 814b, 824b. The outer contour 814, 824 and trailing edge 814b, 824b, in particular, may take any number of shapes. In this embodiment, the outer contour 814, 824 has a parabolic shape, which may include a semi-circular shape.
The wave crest may be rough and frothy for a distance starting at the rooster tail but then change to a sharp, clean wave crest that is desirable for surfing. The inventors have found that the wake-modifying devices 802, 804 “clean-up” the wave crest by increasing the distance that the wave crest sharp and clean.
Preferably, each wake-modifying device 802, 804 is positioned proximate the trailing edge 748 of the platform 700. By positioning the wake-modifying devices proximate the trailing edge 748, the distance below the bottom surface 704 of the platform 700 that each wake-modifying device 802, 804 must extend to interact with the wave crest can be minimized. Preferably, the leading edge 814a, 824a of each wake-modifying device 802, 804 is from about 1 foot to about 3 feet behind the transom 122 of the boat 100. Each wake-modifying device 802, 804 is preferably positioned on the outboard third of the platform 700, and more preferably the port wake-modifying device 802 is positioned proximate the port edge 744 of the platform 700 and the starboard wake-modifying device 804 is positioned proximate the starboard edge 746.
Each wake-modifying device 902, 904 has an upper surface 918, 928 that is substantially co-planar with the top surface 702 of the platform 700 when the wake-modifying device is in the non-deployed position. The wake-modifying devices 902, 904 move between the non-deployed position and the deployed position by pivoting about a pivot axis 932, 942 through the use of a linear actuator 510. The port wake-modifying device 902 is shown in the non-deployed position in
The linear actuator 510 is connected to both the bottom surface 704 of the generally horizontal platform 700 and a top face 934, 944 of the wake-modifying devices. The pivot axes 932, 942 are positioned at an oblique angle μ, ν relative to the platform's centerline 750, as discussed above in the fourth embodiment.
In this embodiment, the outer contour 912, 922 of each of the wake-modifying devices corresponds to the outer contour of the platform 700. The outer contour 912 of the port wake-modifying device 902 has a leading edge 912a that corresponds to the port edge 744 of the platform 700. The outer contour 922 of the starboard wake-modifying device 904 has a leading edge 922a that corresponds to the starboard edge 746 of the platform 700. A trailing edge 912b, 922b of each wake-modifying device 902, 904 corresponds to the trailing edge 748 of the platform 700. As discussed above, this outer contour 912, 922, in particular trailing edge 912b, 922b, is beneficial in modifying the wake. In this embodiment, the trailing edge 912b, 922b preferably forms an angle ρ with the pivot axis 932, 942 that is less than about 90°, and the outer contour 912, 922 and the pivot axis 932, 942 form a generally triangular shape. Preferably, the generally triangular shape is an obtuse generally triangular shape, more preferably the obtuse angle σ is between about 90° and about 150°, and even more preferably about 135°.
The outer contour 912, 922 is not limited to a triangular shape, and may have, for example, a parabolic shape such as discussed above in the fourth embodiment. Likewise, the platform 700 may have a shape other than a pentagonal shape and the outer contour 912, 922 of the wake-modifying devices 902, 904 may take on a shape corresponding to the shape of the platform. Several examples of these platforms 700 with alternative shapes are shown in
Instead of having a flat lower face (such as the wake-modifying devices 802, 804 described in the fourth embodiment), the wake-modifying devices 902, 904 may have a generally convex shape. In this embodiment, the convex shape is generally triangular with two faces: a leading face 914, 924 and a trailing face 916, 926. Instead of being a sharp point, the intersection of the leading face 914, 924 and the trailing face 916, 926 is rounded or curved. The angle between the leading face 914, 924 and the trailing face 916, 926 is preferably less than 180°, more preferably between about 100° and about 170°, and even more preferably between about 140° and about 160°. Other suitable convex shapes may be used for the leading face 914, 924 and the trailing face 916, 926, including, for example, a parabolic shape. Such convex shapes and smooth intersections between surfaces help keep the water flow laminar as it flows past the wake-modifying devices 902, 904. A wake-modifying device 902, 904 on the platform 700 that maintains laminar flow may result in a wake that is more desirable to a wake surfer than a wake-modifying device that imparts turbulence to the wake. The angled leading and trailing faces 914, 916, 924, 926 may also be used to direct the energy of the propagating wake. In particular, the trailing faces 916, 926 may be used to redirect the energy of the wake that is naturally shaped by the hull and would have blended into the wave crest. By angling these trailing faces 916, 926 at an oblique angle relative to the centerline of the platform 750, the energy of the wake may be directed inboard and aft, thereby lengthening the surfable area of the wake.
Although the wake-modifying devices have been described as having either a flat lower face (e.g., wake-modifying devices 802, 804 described in the fourth embodiment) or a convex shape, as in this embodiment, the wake-modifying devices may have other suitable shapes that can be used to direct the energy of the wake and shape the wake. Suitable shapes include but are not limited to a concave shape, a triangular shape having a right angle, or an asymmetrical shape such as an asymmetrical triangle. These shapes may be particularly apparent in the top faces 934, 944 of the wake-modifying devices 902, 904. With an asymmetrical shape, how the energy of the wake is redistributed may be varied, for example, a greater percentage can be directed aft instead of inboard.
Each wake-modifying device 1002, 1004 is a portion of the platform 700. Above each wake-modifying device 1002, 1004 is a portion of the platform that remains stationary (stationary portions 1012, 1014). The top surface 702 of the platform corresponding to the stationary portion 1012, 1014 does not move as the wake-modifying devices 1002, 1004 are moved between the non-deployed and deployed positions.
Unlike the wake-modifying devices of the fourth, fifth, and sixth embodiments, the wake-modifying devices 1102, 1104 of the seventh embodiment are stationary. That is, the wake-modifying devices 1102, 1104 are attached to an underside (bottom surface 704) of the platform 700 in such a way that the contour 912, 922, and leading and trailing faces 914, 916, 924, 926 modify the boat's wake as discussed above.
The boat's wake, and in particular the v-shaped wave crest, is relatively small when the boat is moving slowly or lightly loaded. Thus, the wake-modifying devices 1102, 1104 may project downward from the bottom surface 704 of the platform 700 a distance such that they only modify the boat's wake when it is operating above a predetermined speed or with ballast greater than a predetermined amount. Additionally, when the wake-modifying devices 1102, 1104 are used with trim tabs 10, 30 or the wake-modifying devices 111, 112 of the first, second, or third embodiment, the wake-modifying devices 1102, 1104 may interact with the boat's wake because the boat will roll toward the surf side, thus lowering the wake-modifying devices 1102, 1104 into the boat's wake.
Operation
Each of the seven embodiments of the wake-modifying devices described above may be individually used to modify the boat's wake. For example, the wake-modifying devices 111, 112 of the first embodiment may be mounted to the transom 122 and used to modify the boat's wake without other wake-modifying devices. Likewise, the wake-modifying devices 802, 804 of the fourth embodiment may be used to modify the boat's wake without other wake-modifying devices. However, the wake-modifying devices described in each of the embodiments above are not limited to individual use and may instead be used in combination with other wake-modifying devices or means to modify the wake.
In one example, the center trim tab 20 may be used with boats equipped with any one of the wake-modifying devices described. Additionally, the wake-modifying devices of one of the embodiments described above may also be used with a wake-modifying device of another embodiment. For example, the wake-modifying devices 111, 112 of the first embodiment may be mounted to or near the transom 122. These wake-modifying devices may then be used in combination with additional wake-modifying devices, such as the wake-modifying devices 902, 904 of the fifth embodiment, that are mounted to or are part of the platform 700.
The wake-modifying devices described herein, whether used individually or in combination with other wake-modifying devices, may also be used, for example, with means to increase the displacement of the boat 100. Those skilled in the art understand that the weight and displacement of the boat has a significant impact on the size and shape of the wake. As a result, many recreational sport boats that are used for wakeboarding and wake surfing accommodate additional weight or ballast. The addition of ballast increases the displacement of the boat. When the ballast is added to the stern of the boat, in particular, the wake of the boat may be increased. Many boats are also designed to have ballast added to the surf side of the boat to increase the displacement of that side of the boat. This weight may be added by any number of ways known to those skilled in the art. One way is to position more people in a particular portion of the boat, such as in the stern as compared to the bow or on the surf side of the boat as compared to the non-surf side. Another way is to add ballast through the use of ballast bags or ballast sacks. Yet another way to add weight is through ballast tanks installed in the boat. Preferably, two ballast tanks are positioned in the stern of the boat near the bottom of the hull, one on each side of the boat, and a third ballast tank is positioned along the boat's centerline near the bottom of the hull, forward of the two rear ballast tanks. If ballast bags are used in addition to ballast tanks, the ballast bags may be plumbed into the ballast system of the boat. Both the ballast tanks and the ballast bags operate similarly in that water may be pumped into the tank or bag by ballast pumps to add weight. In some boats, both ballast tanks and ballast bags may be used simultaneously. For example, all three ballast tanks may be filled to increase the displacement of the stern of the boat, and a ballast bag on the surf side of the boat may be filled to further increase the displacement on the surf side.
Control System
A control system is used to operate the wake-modifying devices 111, 112, 802, 804, 902, 904, 1002, 1004, 1102, 1104. When the wake-modifying devices 111, 112, 802, 804, 902, 904, 1002, 1004, 1102, 1104 are used with plumbed-in ballast, the control system preferably controls both the ballast and the wake-modifying devices 111, 112, 802, 804, 902, 904, 1002, 1004, 1102, 1104. This control system preferably includes a controller that controls the linear actuators 510 and the ballast pumps. The controller may be any suitable controller known in the art including a controller comprising a CPU, ROM, and RAM. The control system also includes an input device. In the preferred embodiment, the input device is a touchscreen located at the control console 140 of the boat 100. Also in this embodiment, the controller is co-located with the touchscreen. Those skilled in the art will recognize that any suitable input device, including but not limited to buttons, switches, dials, or the like may be used. The controller may operate the linear actuators 510 and ballast pumps by sending control signals to a power distribution module. This power distribution module may individually supply power to the linear actuators 510 and the ballast pumps upon receipt of a supply power command. The power distribution module may also stop supplying power to the linear actuators 510 or ballast pump upon receipt of a command to stop.
An exemplary touchscreen 610 is shown in
Another exemplary touchscreen 660 is shown in
As another option, the wake-modifying devices, ballast, and boat speed may be controlled using user-defined programmed settings. A user can manually set each of the parameters in the manual mode as described above and then save these settings as a user-defined profile. In operation, a touch location 610, shown in
In addition to or instead of the foregoing, the control system can include preprogrammed settings established by the boat manufacturer. After one of the preprogrammed settings has been selected by a user, a cruise control screen 630 may be displayed, such as shown in
The embodiments described and shown 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, materials, 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 claims.
This application is a continuation of U.S. patent application Ser. No. 16/152,588, filed Oct. 5, 2018. U.S. patent application Ser. No. 16/152,588 is a continuation of U.S. patent application Ser. No. 15/782,954, filed Oct. 13, 2017. U.S. patent application Ser. No. 15/782,954 is a continuation of U.S. patent application Ser. No. 14/634,790, filed Feb. 28, 2015. U.S. patent application Ser. No. 14/634,790 claims the benefit under 35 U.S.C. § 119(e) of U.S. Provisional Patent Application No. 61/946,531, filed Feb. 28, 2014, and titled “Wake-Modifying Swim Platform.” U.S. patent application Ser. No. 14/634,790 is also a continuation-in-part of U.S. patent application Ser. No. 14/458,427 filed Aug. 13, 2014. U.S. patent application Ser. No. 14/458,427 is a continuation of U.S. patent application Ser. No. 14/194,355 filed Feb. 28, 2014. U.S. patent application Ser. No. 14/194,355 claims the benefit under 35 U.S.C. § 119(e) of U.S. Provisional Patent Application No. 61/889,752, filed Oct. 11, 2013, and titled “Wake-Modifying Device for a Boat.” The foregoing applications are hereby incorporated by reference in their entireties and are made a part of this specification for all that they disclose.
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| Number | Date | Country | |
|---|---|---|---|
| 61946531 | Feb 2014 | US | |
| 61889752 | Oct 2013 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 16152588 | Oct 2018 | US |
| Child | 16538199 | US | |
| Parent | 15782954 | Oct 2017 | US |
| Child | 16152588 | US | |
| Parent | 14634790 | Feb 2015 | US |
| Child | 15782954 | US | |
| Parent | 14194355 | Feb 2014 | US |
| Child | 14458427 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 14458427 | Aug 2014 | US |
| Child | 14634790 | US |
