The present disclosure relates to marine wake enhancement systems. More particularly, the present disclosure relates to a system for producing a wake pattern from pontoon boats for providing a surfable wake for wake surfing, wake boarding, and towable devices.
Recreational marine vessels are in common use and include a variety of boat types directed to different recreational activities. For example, there are recreational boats tailored for speed and for towing a water-skier or for towing an inflatable device at a generally high speed. Another type of boat is a wake-boat or wake creating boat, that has a specific hull and transom shape that produces a surfable wake behind the boat, allowing for wake surfing or wake boarding, in which a user is towed behind the boat, similar to a speed boat, and the wake boarder or wake surfer may direct themselves toward the wake pattern created by the boat. Wake boats typically operate at a slower speed than a speedboat that tows a water skier.
Pontoon boats are in common use as a leisure boat or pleasure craft capable of carrying a relatively large number of passengers. Pontoon boats may travel at various speeds, but are often utilized at slower speeds, such as cruising speeds, where the passengers may enjoy a relatively stable boat position at a variety of speeds. Pontoon boats may include multiple pontoons that float on the water, with the pontoons supporting a platform on which the passengers are carried. Unlike a traditional boat hull, the pontoons will define an open area laterally between them, with the platform supported on top of the pontoons and above the open area.
Pontoon boats may be utilized at higher speeds and may be able to operate to tow an inflatable or other similar device behind the boat, but are typically less efficient that other watercraft.
Accordingly, there are different boat styles directed to different types of recreational activity. Due to expense and/or storage limitations, consumers may typically choose a boat style directed to their primary recreational activity. However, in choosing such a boat style, consumers may be limited in other types of recreational activity. In some cases, a consumer may have to purchase more than one type of boat in order to be able to enjoy all of the recreational activities that they desire. For example, a consumer may desire the more relaxed recreational benefits of a pontoon boat, but may also desire the benefits of a speed boat or wake boat to enable wake surfing or water skiing. In this case, the consumer is forced to purchase more than one boat or is forced to compromise on the type of boat they choose, foregoing the benefits of another boat style.
Pontoon boats are particularly popular in that they provide many recreational benefits and are capable of carrying a large number of passengers, which is desirable in many social settings. However, the wake pattern provided by the traditional pontoon boat is unsatisfactory for users interested in wake surfing or wake boarding, because the wake pattern is inconsistent and generally small.
A desirable wake characteristic for wake surfing and wakeboarding includes the shape, the height, and energy of the wake pattern that is created. A wake boat can produce a large wake pattern, both in shape and height, enabling a maximization of tricks and other maneuvers that can be performed. Pontoon boats are typically designed to produce small wakes, which are undesirable for wake boarding or wake surfing enthusiasts. Additionally, pontoon boats do not include a transom like wake boats.
In view of the above, improvements can be made to recreational marine vessels.
In one aspect, a wake enhancement system for a pontoon boat is provided. The system includes a pair of ramps, including a first ramp and a second ramp, each ramp being moveable between a first position and a second position, the ramps having a ramp body extending between a front end and a rear end, wherein the ramps are configured to provide directional ducting. In the first position, the ramp body extends at a first angle relative to a horizontal direction. In the second position, the ramp body extends at a second angle relative to the horizontal direction, wherein the second angle is greater than the first angle and the rear end is below the front end.
The system may further include a wake plate associated with each of the ramps and disposed rearwardly relative to each of the ramps in a first position of the wake plate. The wake plate includes a faceted portion having an upper surface and a lower surface extending between a front edge and a rear edge and defining an angle of inclination of the wake plate. In the first position of the wake plate, the front edge is disposed below the rear edge and the front surface faces forward and upward.
The ramps are configured to displace water downward when the ramps are in the second position, and the wake plate is configured to provide a downforce and wake curl when the wake plate is in the first position.
In another aspect, a pontoon boat having enhanced wake-creating ability is provided. The boat includes at least two pontoons extending in a longitudinal direction and at least one platform attached to and supported by the pontoons at a position above the surface of the water in operation, the platform having a front end and a rear end.
The boat includes a pair of ramps having a ramp body with a first end pivotably attached to the platform and a second end moveable between a first position and a second position, wherein the second position is below the first position. The first end of the ramp body is disposed at a middle portion of the platform between the first and second ends thereof, and the second end of the ramp body is disposed below a rear portion of the platform. In the second position, water flowing inboard of the pontoons is displaced downward by the ramps.
In another aspect, a method of enhancing a wake pattern produced by a pontoon boat is provided. The method includes conveying a pontoon boat in a forward direction, the pontoon boat having at least two pontoons, including a first pontoon and a second pontoon, the pontoons supporting a platform and defining a first wake profile. The method further includes displacing water into an area between the at least two pontoons and defining a displaced water flow.
The method further includes positioning a pair of ramps, including a first ramp and a second ramp, at an oblique angle relative to the platform and positioning the ramps into the displaced water flow and directing the displaced water flow downward. The method also includes providing a downforce on the pontoon boat to counteract an upward force received by the ramps. The method further includes defining a second wake profile in response to positioning the ramps at an oblique angle, wherein the second wake profile is higher than the first wake profile.
With reference to the
The DD ramps 14 may be provided as a pair, as described above, and may be independently actuatable and positioned relative to each other and the boat 12. Put another way, one of the DD ramps 14 may be actuated to a different position relative to the boat 12 than the other of the DD ramps 14. Thus, one of the DD ramps 14 could be positioned higher or lower than the other DD ramp 14. However, it will be appreciated that the DD ramps 14 could be also be actuated to the same height. The DD ramp 14 is coupled to a bottom surface of the boat 12, and is preferably actuatable via an associated mechanism relative to fixed structure of the boat 12. The wake plate 16 may be coupled to the structure of the boat 12, or alternatively, to the structure of the DD ramp 14. The DD ramp 14 and the wake plate 16 enhance the wake generated by the boat 12 to shape the resulting wake and produce an enhanced wake pattern and wake characteristic sufficient for wake boarding or wake surfing. As further described below, the wake plate 16 may be separately mounted to the boat 12, or may be mounted to the DD ramp 14. However, in some approaches, the system 10 may optionally operate without a wake plate for additional enhancements.
With reference to
The platform 20 includes an upper surface 20a and a lower surface 20b. The upper surface 20a is typically the surface on which the passengers of the boat will sit or stand, and the lower surface 20b faces the water. The lower surface 20b and the pontoons 18 thereby define an open space 22 above the surface of the water that extends below the platform 20 and between the pontoons 18 when the boat 12 is floating on the water.
As described above, the boat 12 may include at least two pontoons 18, where the pontoons 18 will be disposed generally laterally symmetrical relative to a longitudinal centerline of the boat 12. In one aspect, the boat 12 may include a third pontoon 18a disposed generally along the longitudinal centerline of the boat 12. In this approach, a pair of open spaces 22 are disposed between the third pontoon 18a and the laterally outboard pontoons 18.
The open space(s) 22 may also be referred to as a channel or channels, which is where the DD ramps 14 are disposed. The DD ramps 14 may therefore channel or direct water along their lengths in a duct-like manner. In the case of three pontoons 18, the pontoons 18 may operate to help channel the water along the DD ramps 14.
In one approach, the pontoons 18 may resemble traditional pontoons in that the pontoons 18 have an elongate shape with a generally circular cross-section and a diameter. The pontoons 18 may be generally hollow, thereby providing buoyancy when disposed in the water and allowing the boat 12 to float. As further described below, the pontoons 18 may have additional shape characteristics, such as shapes that are not circular in cross-section or having different trailing end profiles. In a traditional pontoon shape, the leading edge of the pontoon may be tapered to decrease resistance when the boat is being propelled through the water. The trailing end of the pontoon 18 may be generally blunt or may have a slight curvature to reduce drag.
Traditional pontoon boats are designed to produce reduced resistance in the water such that the pontoons 18 will float high on the surface of the water, thereby displacing a smaller or minimal amount of water. As passengers are added to the pontoon boat, the weight thereby increases, displacing an additional amount of water. Increasing the water displacement will increase the wake produced by the pontoon boat. However, the wake produced is typically very unorganized and turbulent around the pontoons. During operation of the traditional pontoon boat, a non-organized wake is produced within the channel between the pontoons as well as behind the pontoons. Typically, it is desirable to reduce water displacement, drag, and wake produced by a pontoon boat, such that the boat may be more energy efficient and require less power to propel the boat through the water. In the present improved system 10, wake and drag may be desirable, and the system 10 will produce an increased amount of water displacement, wake, and drag, which is the opposite of a traditional pontoon boat.
In the present improved system 10, the system 10 operates to control and organize the wake produced by the pontoon boat 12, and in particular the wake produced between the pontoons 18. As described above, the system includes the pair of DD ramps 14. The DD ramp 14 may be in the form of an elongated panel, plate, sheet, plank, board, or the like, which is attached to a forward pivot point located under the platform 20, such that the DD ramp 14 extends rearward from the pivot point.
As described above, the DD ramp 14 may be attached to the lower surface 20b of the platform 20 and between the pontoons 18. Put another way, the DD ramp 14 is disposed in the open space(s) or channel(s) 22 that are defined between the pontoons 18. The DD ramp 14 may include a first end 14a and a second end 14a. The first end 14a may be the forward end and the second end 14b may be the rearward end, relative to the forward direction of travel for the boat 12.
As shown in
The second end 14b of the DD ramp 14 is configured to move upward and downward relative to the platform 20 of the boat in response to actuating and pivoting the DD ramp 14 about the first end 14a. The second end 14b therefore may have a variety of positions relative to the platform 20. In a first position (
In the first position, which may also be referred to as the stowed position, the DD ramp 14 may not make contact with the water when the boat 12 is floating or travelling. In this position, the boat 12 may operate in a manner resembling a traditional pontoon boat. In the second position, which may be described as an angled position or extended position and which may be deployed at a variety of angles relative to the stowed position, the DD ramp 14 will make contact with the water, thereby displacing and directing an additional volume of water relative to a traditional pontoon boat that is not otherwise displaced.
With the DD ramp 14 being actuatable and moveable between the first position and the second position, it will be appreciated that the DD ramp 14 may have a plurality of intermediate positions between the first position and the second position. For the purposes of the discussion, the second position will be understood to mean the desired, optimum, or target position for enhancing the wake profile characteristic. It will be understood that other positions relative to the second position, including intermediate positions or positions further downward from the second position, may also be used that enhance the wake pattern relative to the first position.
The DD ramp 14 may be actuated by one or more actuator mechanisms 30. The actuator mechanism 30 may be a linear actuator extending between the DD ramp 14 and the platform 20, or between the DD ramp 14 and other supporting structure of the boat 12. It will be appreciated that other types of actuators may also be used that are capable of moving the DD ramp 14 between the first position and the second position. The actuator may be attached to a laterally central portion of the DD ramp 14, and may be attached to a point near the second end 14b. However, in another approach, the actuator 30 may be attached to the DD ramp 14 at a lateral edge or at a longitudinally middle portion of the DD ramp 14. In another approach, multiple actuators 30 may be attached to the DD ramp 14.
When the DD ramp 14 is in the second position, the DD ramp 14 will extend downward into the water and will direct the previously unorganized and turbulent water flow between the pontoons 18 in a controlled manner, organizing the water flow and directing it downward and rearward along the DD ramp 14, where the flow may then exit from the end of the DD ramp 14 near the rear of the boat 12. Thus, the DD ramp 14 operates to displace an addition amount of water relative to a traditional pontoon boat, which creates additional drag on the boat 12.
The second end 14b of the DD ramp 14 may be disposed near the rear of the boat 12, and can be disposed rearward from the ends of the pontoons 18. In one aspect, as shown in
The ramps 14 may be attached to the platform 20 at a point that is generally near the longitudinal midpoint of the boat 12, as shown in
In a preferred form, the DD ramp 14 is attached to a point 40-60% rearward, and when actuated downward, the DD ramp 14 defines a 15-25 degree angle relative to the platform 20. In one approach, the DD ramp 14 is angled 20 degrees relative to the platform 20.
By disposing the DD ramps 14 into the water, and displacing and directing more water, the DD ramps 14 thereby create additional surface area that contacts the water, similar to other boat types that displace water over a greater surface area than a traditional pontoon boat. The increase of surface area (and optional directional vanes or ribs that are further described below) is desirable for creating an enhanced wake pattern behind the boat 12. As described previously, the DD ramps 14 may be individually controlled and actuated, meaning that the DD ramps 14 may be at different angles relative to each other for producing the desired wake characteristic. In addition to the ramps 14, there are other manners of increasing the surface area in contact with the water to provide an enhanced wake pattern. For example, ballast may be added to the boat 12 in different ways, thereby increasing the weight of the boat 12 and increasing the amount that the pontoons 18 extend into the water.
The ramps 14 may have different shapes to further tailor and shape the direction that the water displaced by the ramps 14 will flow. In one approach, shown in
In one aspect, as shown in
While the DD ramps 14 have been generally described as having an elongated plate-type structure, it will be appreciated that the ramps 14 may have various edge shapes or trailing shapes that can alter the wake profile, as desired. In one approach, the rear end of the DD ramp may extend between 12-24 inches, and in one aspect approximately 15 inches, from the rear edge of the pontoons 18. The rear end of the DD ramp 14, being extended beyond the end of the pontoons 18, may wrap outwardly around the rear end of the pontoons 18 and define a rear portion 14a.
The rear portion 14a, due to wrapping around the rear of the pontoon 18, therefore may have a greater lateral width than the portion of the DD ramp 14 that extends longitudinally between the pontoons 18. The end of the DD ramp 14 and the rear portion 14a thereof may wrap to the most outboard edge of the pontoons 18. In one form, the DD ramp 14 may extend approximately 12 inches on the inboard side of the pontoon 18 and may extend approximately 14-15 inches on the outboard side of the pontoon 18. Accordingly, the trailing edge of the rear portion 14a may be angled when viewed from above. In one approach, the rear portion 14a of the DD ramp 14 may be approximately 36 inches wide in the lateral direction. The rear portion 14a may also extend laterally inward.
When extended downward, the DD ramp 14 contacts the water and forces the water downward in accordance with the angle of the DD ramp 14. However, the water also provides an upward reaction force on the DD ramp 14. Accordingly, in order to increase the amount of water displacement causes by the DD ramp 14, it is desirable to provide additional downward force on the boat 12. In one aspect, additional downforce may be provided by the wake plate 16.
As shown in
The wake plate 16 may be in the form of a pair disposed on opposite lateral sides of the boat 12. For the purposes of discussion, only one wake plate 16 will be discussed in further detail, unless otherwise noted. In the case of two wake plates 16, they may be symmetrical in overall shape relative to a center axis of the boat 12.
The wake plate 16 may have a T-shape, with a vertically extending post portion 16a and a generally laterally extending faceted portion 16b. In another approach, multiple post portions 16a may be used, such as two post portions 16a. The faceted portion 16b is disposed at the bottom of the post portion 16a, and the faceted portion 16b is the portion that is intended to remain within the water during operation. The post portion 16a may intersect the faceted portion 16b at the approximate center of the faceted portion 16b in one approach. However, in an alternative approach, the post portion 16a may be offset to one lateral side of the faceted portion 16b, and may be attached to a lateral end of the faceted portion 16b in some cases (forming an L shape rather than a T shape).
The faceted portion 16b may have a generally flat profile, such as a plate or the like. The faceted portion 16b may therefore have a rectangular profile. However, the faceted portion 16b may have other profile shapes, such as a square, oval, diamond, or other polygonal profile. The faceted portion 16b defines a surface area corresponding to the size and shape of the profile, and the surface area acts on the water that flows onto the faceted portion 16b during operation.
The post portion 16a may also be in the form of a plate, with the thin edge of the plate preferably facing the direction of the water flow, such that the surface area defined by the plate is generally not exposed to the direction of flow, thereby reducing drag produced by the post 16a. The post 16a may also be in the form of a rod or the like, because the lateral surface area of the post 16a is generally insignificant in the operation of the wake plate 16. Indeed, it is preferable to reduce the drag caused by the post 16a. The primary function of the post 16a is to support the faceted portion 16b that is disposed in the water during operation.
In one approach, the post portion 16a has a generally fixed length, and may be pivotable relative to its connection to the boat 12 via a hinge or pin mechanism. The post portion 16a may be connected to an actuator, which may be a linear actuator, to change the position of the wake plate 16 relative to the boat 12, for instance to lower the wake plate 16 into the water and to raise the wake plate 16 out of the water. In an alternative approach, the post 16a may be in the form of a telescoping mechanism with a built in actuator that may raise and lower and the faceted portion 16b relative to the water. It will be appreciated that other mechanism for raising and lowering the faceted portion 16b may also be used.
The faceted portion 16b may be generally flat in the lateral direction, or its lateral tips may be upturned or downturned relative to the middle portion of the faceted portion 16b. The faceted portion 16b may have tapered or chamfered corners. As shown in the
The faceted portion 16b may be attached to the post portion 16a in a variety of manners, such as via welding, bonding, bolts, rivets, or other robust fixing mechanisms. The post 16a and faceted portion 16b may be coextruded or integrally formed, such as via casting, sintering, molding, or the like.
When deployed in the water, the wake plate 16 may be oriented such that the faceted portion is angled downward (approximately 10-40 degrees) relative to the direction of travel. The downward angle of the faceted portion 16b exposes the surface area of the faceted portion 16b to the direction of water flow that is exiting from the channels 22 as directed and organized by the DD ramps 14. Accordingly, the wake plate 16 will provide a downforce on the boat 12 via its connection to the boat 12. Put another way, the water impacting the wake plate 16 will force the wake plate 16 downward, which will thereby pull the wake plate 16 down into the water and provide downforce, which pulls the rear of the boat 12 into the water.
In addition to the downforce provided by the wake plate 16, the wake plate 16 further creates a final wake shape characteristic for enhanced surfing and boarding by forcing the water in an upward direction and creating an exit roll form or curl from the wake plate 16.
The downforce provided by the wake plate 16 thereby contributes to the displacement of the water caused by the pontoons 18 and DD ramps 14 and counteracts the reaction force of the water that tends to urge the boat upward out of the water in response to contacting the DD ramps 14.
The wake plate 16 may be oriented at a desirable angle depending on the size and weight of the boat 12 and other aspects affecting the flow and displacement of the water. In one approach, the angle of the wake plate 16 when the boat is oriented horizontally is 30 degrees. However, other angles may also be set.
The wake plate 16 and/or the faceted portion 16b thereof may be actuatable to adjust the angle of orientation depending on feedback or other inputs affecting the water flow to provide a desirable efficiency and downforce. Sensors may be placed on the wake plate 16 to detect the forces or water flow rates being applied to the wake plate 16 for this purpose.
In addition to the actuator for adjusting the height of the wake plate 16, the wake plate 16 may also be actuated or adjusted manually. For example, the post 16a may be pivotable relative to its connection to the boat 12, and the post 16a may then be fixed when the wake plate 16 is angled in the desired location. A plurality of mounting holes or passthroughs may be provided on a flange or similar structure, with a pin or screw inserted into the flange to hold the wake plate in the desired orientation relative to a fixed bracket.
Thus, with the wake plate 16 disposed in the water and angled downward, and located in the path of the water that is organized and displaced by the DD ramp 14, the wake plate 16 will provide a substantial downforce on the boat 12, increasing the water displacement and thereby increasing the height of the wake produced and enhancing the wake profile characteristic. As a result of the downforce that is produced by the water flow impacting the wake plate 16, the water is also directed upward by the wake plate 16 and toward the surface. By directing the water upward, the height of the wake may increase.
The wake plate 16 has been described herein as being attached to the rear platform 20c or otherwise being a separate structure relative to the DD ramp 14, but the wake plate 16 may alternatively be attached to the DD ramp 14.
With reference to
The gussets 17 may have a plate-type structure and extend generally longitudinally between the DD ramp 14 and the wake plate 16. The wake plate 16 remains spaced away from the end of the DD ramp 14, such that water flowing past the end of the ramp 14 may impact the upper front surface of the wake plate 16 and provide the necessary downforce. In one approach, when the DD ramp 14 is disposed at a 20 degree angle from the platform 20, the wake plate 16 is disposed at an opposite 30 degree angle. Accordingly, the wake plate 16 and DD ramp 14 may be disposed at 120 degrees relative to each other.
The actuators 30 described above, in this approach, can be attached to the gussets 17, and in particular, the laterally outmost gussets 17, to raise and lower both the ramp 14 and the wake plate 16 together. Of course, it will be appreciated that the actuator 30 or actuators 30 could be attached to the middle gusset 17, to the DD ramp 14, or to the wake plate 16, and may still raise and lower the DD ramp 14 and wake plate 16 together.
In addition to providing the wake plates 16 at the rear of the boat 12, additional wake plates 16 may be disposed under the platform 20 of the boat 12 at a middle portion of the boat 12, such as near the longitudinal center of the boat 12. It will be appreciated that the wake plates 16 in this location need not be at the exact center of the boat 12, and can be located forward or rearward from the center. The additional wake plates may provide an additional downforce on the boat 12, thereby increasing the displacement of the water and further altering the wake profile.
The system 10 may include further components to alter the wake profile and water displacement and direction, which may be used along with the DD ramps 14 and/or wake plates 16. In one approach, shown in
The rear portion 40 may include a rear tip 40a that is generally disposed at the rear-most end of the rear portion 40. The rear portion 40 will taper down toward the tip from a wider shape that will typically correspond to the profile of the pontoon 18. In one approach, the rear tip 40a is disposed at an inboard side of the pontoon, as shown in
In another approach, the rear tip 40a may be disposed at a laterally middle portion of the rear portion 40, such that both the inboard and outboard sides of the rear portion 40 taper down toward the rear tip 40a. The outboard and in board portion may have a taper that is the same size and shape, or they may taper at different profiles. The rear tip 40a may be disposed at the lateral center of the pontoon 18, or the rear tip 40a may be offset from the center.
The lateral side of the pontoon 18 to which the rear tip 40a is offset will control the direction in which water is directed around the rear portion 40 of the pontoon 18. In one approach, with the rear tip 40a shifted inward relative to the center of the pontoon 18, the water flowing on the outboard side of the pontoon 18 will thereby be directed inwardly as it flows along the tapered outer side of the rear portion 40. This inwardly directed water that is displaced by the pontoon 18 may therefore combine with the water that is displaced on the inboard side of the pontoon 18, such as the water that is displaced by the DD ramp 14, resulting in a further modified wake profile trailing the boat 12.
It will be appreciated that various shapes and profiles of the rear portion 40 may be used to alter the direction of flow of the water displaced by the pontoon 18. In one form, the rear portion 40 may be attached to the pontoon 18 such that it may be actuated (by an actuator or manually) and rotated relative to the pontoon 18 to change the position of the rear tip 40a relative to the pontoon 18.
With reference to
The body of the scoop may be disposed on the outboard side of the pontoon 18, and may pivot about a generally vertical axis disposed at a center of the rear end of the pontoon 18. Thus, the scoop 44 may be disposed on the outboard half of the pontoon 18. The body of the scoop 44 may be in the form of a sidewall 44a having a partial cylinder shape. The scoop 18 may have a leading edge 44b that corresponds to a “half-tube” or “half-cylinder” shape, and may therefore define an approximate semi-circle. The scoop 44 may include a trailing edge 44c having a partial elliptical cross-sectional shape, such as that of a half-cylinder with a transverse cut at an oblique angle. Accordingly, the body of the scoop 44 may have a curved outer surface with a curved perimeter that reduces in a rearward direction.
The scoop 44 may have a neutral position, an inwardly canted position, and an outwardly canted position, each shown in
In the inwardly canted position (
In the outwardly canted direction (
With the scoop 44 in a neutral position, the scoop 44 may function as an extension of the outboard side of the pontoon 18. With the scoop 44 in the inward position, the scoop 44 will direct water flowing on the outboard side of the pontoon 18 inwardly, thereby increasing the wake energy, similar to the offset rear portion 40 of the pontoon 18 described above. With the scoop 44 in the outward position, the scoop 44 will direct the water flowing on the outboard side of the pontoon 18 further outward, therefore increasing the length of the water path, interrupting the symmetry of the water flow of the boat 12 and providing a desired wake characteristic.
In one approach, the scoop 44 on one side of the boat 12 may be canted outwardly while the scoop 44 on the opposite side of the boat 12 may be canted inwardly. The result of this arrangement causes the wake energy to be enhanced on the side of the boat 12 where the scoop 44 is canted inwardly, and the length of the water path is increased on the opposite side, thereby increasing the length of the path of the water on the outwardly canted side. Thus, the wake profile may be better enhanced on a selected side (the side that is inwardly canted) to account for differing styles and preferences of the wakeboarder or wakesurfer. The scoops 44 on each side can then be switched to enhance the wake on the other side if preferred by a subsequent wakeboarder or wakesurfer.
Thus, the rear or aft scoop 44 allows for adjusting the wake profile dependent on the position of the scoop 44 to create different wake profiles depending on the needs of the user. The scoop 44 may be actuatable via a linear actuator or other controllable actuation mechanism, and may be controlled by an onboard controller via closed-loop control with feedback or open-loop control. The scoop 44 may also be actuated or positioned manually. The scoop 44 may be fixable in a desirable position for repeated use, if desired.
In another aspect, shown in
The flap 46 may have a generally triangular profile when viewed from the side of the boat 12, where the front end of the flap is narrower than the rear end. The flap 46 may pivot about a pivot point or hinge disposed near the front end, and may be actuated by an actuator disposed about 75% rearward from the front end.
When stowed, the flap 46 may be generally continuous with the outboard surface of the pontoon 18, and effectively replaces the outboard surface in the area in which the flap overlaps the pontoon 18. The flap 46 may be generally flat along its length, in contrast to the curved outer surface of the pontoon 18. Thus, the due to the flat triangular shape of the flap 46, the flap 46 will extend inwardly relative to the curved outer surface of the pontoon 18, as shown in
When actuated to the extended position, the flap 46 is canted outwardly, and will provide the increased water path length functionality, creating a longer path for the water flowing along the outboard side and along the extended flap 46.
Thus, to enhance the wake on a desired side of the boat 12, one of the flaps 46 may be actuated and extended outwardly from the stowed position, while the opposite flap 46 may remain stowed. The water on the stowed side will flow inwardly and enhance the wake profile on that side, and the water on the opposite extended side will be forced outwardly and will increase the water path length on that side. To switch the side where wake is enhanced, the extended flap 46 may be stowed, and the stowed flap 46 may be extended.
When wake enhancement or an increased water path length is not desired, both flaps 46 may be stowed to define a generally continuous outer surface of the pontoon 18. In this arrangement, the water be directed inwardly based on the inwardly surface of the stowed flaps 46. With the water being inwardly directed on both sides, the wake may effectively cancel itself out at the rear of the boat 12.
The actuation mechanism and related structure, such as the hinge or other mounting brackets, may be disposed within a pocket 46a or similar structure formed on the inside of the pontoon 18. The pocket 46a may be sized and shaped to a degree sufficient to make the flap 46 flush with the outer surface of the pontoon 18, and large enough to hold actuation mechanisms or the like.
In one example, the flap 46 may be about 4 feet in length, with the front end being about 4 inches wide and the rear end being about 14 inches wide. The flap 46 may be pivotable between 0 and about 60 degrees.
The scoops 44 and flaps 46 may also be referred to as laterally outboard wake adjustment mechanisms. Both the scoops 44 and the flaps 46 operate to adjust either by directing the water flowing on the outboard side of the pontoons 18 inwardly or outwardly.
In yet another aspect, as shown in
The ballast mechanism 50 may be disposed at different locations on the boat 12. For example, the ballast mechanism 50 may be disposed at both rear and middle locations of the boat 12 and on both lateral sides of the boat 12. Typically, the ballast mechanism 50 may not be disposed near the front of the boat 12.
The degree or amount of ballast material used in the ballast mechanism 50, and at which location on the boat 12, may depend on the particular boat size and expected use conditions. Accordingly, the ballast mechanisms 50 may be used to specifically tailor the boat 12 for ideal usage conditions depending on the needs of the user. In one case, it may be desirable for no ballast to be used, while in another, it may be desirable for ballast to be used at both front and rear locations and on both sides. In another case, ballast may only be desirable on one side of the boat 12. It will be appreciated that various combinations of amount and location of ballast may be used. The location and amount of ballast may depend on the number of expected passengers, or the side of the wake profile where the wake surfer or wake boarder prefers to perform. The use of the ballast 50 may in some cases be sufficient to provide the necessary downforce to counteract the upward reaction on the DD ramps 14, such that the wake plates 16 may not be used.
Many of the above-described components of the system 10 include the ability to be actuated by an associated actuation mechanism. The system 10 may include a controller 60 (
The motor and propeller used for propelling the boat 12 may be a traditional motor and propeller commonly used for pontoon boats 12 or other boat types, such as inboard drives or outboard drives with a rear mounted propeller, or an inboard/outboard (stern) drive may be used. The propeller on an outboard or inboard/outboard drive may be pivoted up out of the water when not in use.
In one aspect, shown in
Thus, in view of the above, the system 10 may be installed on the boat 12 in the manner described above to provide the above-described benefits of increased water displacement and control of the wake produced by the boat 12 to alter the wake profile and create a more surfable wake profile. The above-described components may be used in combination with one or more of the other components affecting the wake profile. For example, the DD ramps 14 may be used in combination with the wake plate system. The contoured rear portion 40, the scoops 44, or the flaps 46 may also optionally be used to direct water inwardly or outwardly to enhance the wake of increase the water path length. Similarly, the ballast mechanisms 50 may be used, with or without the contoured rear portion. The fins or ribs 34 may be included on the DD ramps 14 to direct the water, if desired. In yet another approach, the DD ramps 14 may be used without the wake plates 16, and downforce may be provided by the ballast mechanisms 50 or drive 70. It will be appreciated that various combinations of the above-described components may be used to achieve the desired result of an improved wake profile.
Obviously, many modifications and variations of the present invention are possible in light of the above teachings and may be practiced otherwise than as specifically described while within the scope of the appended claims. These antecedent recitations should be interpreted to cover any combination in which the inventive novelty exercises its utility.
This application claims the benefit of and priority to U.S. Provisional Patent Application Ser. No. 62/615,614, filed Jan. 10, 2018, the entire content of which is hereby incorporated by reference in its entirety.
Number | Date | Country | |
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62615614 | Jan 2018 | US |