The present disclosure relates generally to recreational watercraft, and more particularly, to a recreational watercraft with ballast system.
Recreational watercraft represent a major portion of the boating industry. Potential users of recreational watercraft, however, may have various purposes for using them. Each of these various purposes may influence how a particular recreational watercraft is physically structured and how the potential user decides which recreational watercraft to purchase, rent, borrow, etc. One purpose includes providing transportation within and across waterways. A recreational watercraft used primarily for such transportation can include an engine to propel the watercraft and a deck surface to provide leisure and comfort for passengers. In addition to transportation, recent trends in popularity of water sports, such as wake surfing, wake boarding, and water skiing, have further altered the functionality and structure of recreational watercraft.
The present disclosure includes recreational watercraft, and more particularly, recreational watercraft configured having a panel drop down boarding point. In the following detailed description of the present disclosure, reference is made to the accompanying drawings that form a part hereof, and in which is shown by way of illustration how a number of embodiments of the disclosure can be practiced. These embodiments are described in sufficient detail to enable those of ordinary skill in the art to practice the embodiments of this disclosure, and it is to be understood that other embodiments can be utilized and that process, electrical, and structural changes can be made without departing from the scope of the present disclosure.
As used herein, designators such as “N,” etc., particularly with respect to reference numerals in the drawings, indicate that a number of the particular feature so designation can be included. It is also to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting. As used herein, the singular forms “a,” “an,” and “the” can include both singular and plural referents, unless the context clearly dictates otherwise. In addition, “a number of,” “at least one,” and “one or more” refer to one or more of a structure, whereas a “plurality of” is intended to refer to more than one of such things. Furthermore, the words “can” and “may” are used throughout this application in a permissive sense (i.e., having the potential to, being able to), not in a mandatory sense (i.e., must). The term “include,” and derivations thereof, means “including, but not limited to.”
The figures herein follow a numbering convention in which the first digit or digits correspond to the figure number and the remaining digits identify an element or component in the figure. Similar elements or components between different figures can be identified by the use of similar digits. For example, 106 can reference element “06” in
According to various embodiments, the recreational watercraft 100 includes a single hull 104 (e.g., single v-hull or other unitary geometry shaped hull) located at the bottom of the recreational watercraft 100 to provide structural integrity and buoyancy for the recreational watercraft 100. In one or more embodiments, the single hull 104 may be fabricated from metal or a composition alloy of metal. In at least one embodiment, the single hull is an aluminum metal v-hull. For ease of illustration in the present disclosure, reference may be made to an aluminum hull as the single hull 104. Advantages of using an aluminum metal single hull 104 over other materials such as fiberglass include providing proper structural integrity to support the luxury of having a spacious open layout in the open platform passenger deck 102 and other functional features to the recreational watercraft 100 such as a panel drop down boarding point 170, as will be further described herein. For example, by contrast, many recreational or inboard water-sports boats are formed using fiberglass hulls made from hull molds. Such watercraft are designed and fabricated for their sleek lines, turning agility, drag coefficients, and speed performance and responsiveness. Typically, the frame of such watercraft are assembled from multiple molds and then the fiberglass joined together at different sections (e.g., base hull mold joined to multi-stepped deck platform molds and separate rail cap molds for the watercraft). Such a construction approach does not allow for the open platform passenger deck 102 and other functional features to the recreational watercraft 100 such as the panel drop down boarding point 170, as will be further describe herein. Embodiments, however, are not intended to be limited to any single hull example given herein and other single hull 104 geometries and/or materials are intended to be covered by embodiments disclosed herein.
The single hull 104 further includes a ballast system (e.g., an enclosed, interior ballast system to the single hull 104 as shown and described in connection with
The recreational watercraft 100 can further comprise of a plurality of sides that extend continuously from the single hull 104. In aluminum metal single hull 104 embodiments, the plurality of sides that extend continuously from the single hull 104 can also be constructed of aluminum. The plurality of sides may form a bow side 106-1, a stern side 106-2, a port side 106-3, and a starboard side 106-4 that surround and enclose a perimeter of an upper surface of the open platform passenger deck 102 of the recreational watercraft 100. In some embodiments, the interior of the recreational watercraft 100 on the bow side 106-1 portion may be enclosed by the plurality of sides in a rectangular orientation. As used herein, a rectangular orientation may refer to a rectangular orientation (e.g., having a rounded corner near the port side 106-3 and near the starboard side 106-4), an elongated oblong shape, and/or other examples where neither the internal nor external walls on the bow side 106-1 meet at a fixed apex.
As noted, the bow side 106-1 can include an opening 129 in a side of the single hull 104, where a portion of an interior surface of a panel drop down boarding point 170 (discussed further below) may overlap the bow side 106-1 and cover the opening 129 when in the closed position. The panel drop down boarding point 170 may be hingedly attached horizontally to the single hull 104, for ingress and egress of persons to the recreational watercraft (e.g., as shown and described in connection with
In some embodiments, the panel drop down boarding point 170 may be located on the bow side 106-1 of the recreational watercraft 100, however embodiments are not so limited. For example, the panel drop down boarding point 170 may alternatively, be singularly located on either the stern side 106-2, port side 106-3 or starboard side 106-4. Further, a plurality of panel drop down boarding points 170 may be located on more than one of the plurality of sides, such that multiple panel drop down boarding points 170 may be located on varying sides at the same time (e.g., a panel drop down boarding point located at the bow side 106-1 and another panel drop down boarding point located at the stern side 106-2). For example, although not shown in the figures herein, panel drop down boarding points may be located on two sides, three sides, or all four sides of the plurality of sides of the recreational watercraft 100 where each side of the plurality of sides may incorporate one or more panel drop down boarding points.
In some embodiments, the plurality of sides may include a number of cleats 123 on an upper surface of the plurality of sides to provide a fitting structure (e.g., docking line or other line may be fastened). Further, the upper surface of the plurality of sides may also include railing structures 125 located from the bow side 106-1 that extend toward the stern side 106-2 to provide a handrail for users when on or entering the recreational watercraft 100. In further embodiments, an exterior surface of the plurality of sides may include a rub rail 116 that extends from the bow side 106-1 to the stern side 106-2 along a length of the recreational watercraft 100 to provide protection of the exterior surface of the recreational watercraft 100 from abrasions from docks, wharfs, pilings, rocks, other watercrafts, among other potential hazards.
In some embodiments, the stern side 106-2 of the recreational watercraft 100 may have a swim platform 127 that may either be integral or removably coupled to the stern side 106-2. The swim platform 127 may provide a drop down mechanism that enables it to alternate between an open and closed position. Further, when open, the swim platform 127 may be parallel in relation to the plane of the open platform passenger deck 102 and, when closed, the swim platform 127 may be perpendicular to the open platform passenger deck, although examples are not so limited. For example, the swim platform may be angled downward or upward in relation to the plane of the open platform passenger deck 102 and when in the downward angle, will have its surface at least partially beneath a waterline (as shown at 115 in
Recreational watercraft 100 further includes the open platform passenger deck 102 that acts as an integral upper surface to the aluminum hull 104 wherein the perimeter of the open platform passenger deck 102 is surrounded by the plurality of sides 106-N. The recreational watercraft 100 may further comprise an external length (not shown in
The interior length 130 of the open platform passenger deck 102 may be longer or shorter depending on the respective external length. For example, a 23′ external length recreational watercraft 100, may comprise an open platform passenger deck 102 comprising an internal length ranging from 270″-302″ with the upper range being achieved when both the drop down boarding point 170 and swim platform 127 are in the open position. In a 21′ external length embodiment of the recreational watercraft 100, the interior length 130 of the open platform passenger deck 102 may range from 246″-278″. In a 25′ external length embodiment of the recreational watercraft 100, the interior length 130 of the open platform passenger deck 102 may range from 294″-326″. While these lengths are defined, they are not so limited and in further embodiments, similar ratios and measurements of an internal length 130 of the open platform passenger deck 102 to the external length of the recreational watercraft 100 may be employed.
As described above, the open platform passenger deck 102 may include the surfaces of the drop down boarding point 170 and swim platform 127 when in an open position. Advantages of employing an open platform passenger deck 102 such as this include ease of ingress and egress of a user to and from the recreational watercraft 100 from the water, land, dock, and among other user locations. For example, the ease of ingress of a user from the water to the recreational watercraft 100 provided by more access points by the drop down boarding point 170 and swim platform 127 may provide for greater safety by allowing a fatigued swimmer to board more easily. In yet another example, the open platform passenger deck 102 may further provide for ease of ingress and egress for disabled users (e.g., wheelchair access points).
The recreational watercraft 100, regardless of its external length, may further comprise a maximum external width between the external surfaces of the port side 106-3 and the starboard side 106-4 ranging between 90″ and 102″ to allow the recreational watercraft 100 to be stored on a towing platform, garage, docking area, among other locations. The open platform passenger deck 102, regardless of external length, further comprises an interior bow width 107-1 ranging from around 50″ to around 84″, an interior stern width 107-3 ranging from around 70″ to around 90″, and a maximum interior width 107-2 ranging from around 70″ to around 90″. The open platform passenger deck 102 may have these widths to facilitate an open layout for a user to maneuver throughout the open platform passenger deck 102. As used herein, open layout refers to a continuous structurally unimpeded walkway 103 from the stern side 106-2 of the open platform passenger deck 102 to the bow side 106-1 of the open platform passenger deck 102. As used herein, continuous structurally unimpeded walkway 103 refers to a platform wherein a user is able to freely traverse the plane of the open platform passenger deck 102 from the stern side 106-2 to the bow side 106-1 and/or from the port side 106-3 to the starboard side 106-4 without the need to remove any structures (e.g., a removable windshield, an internal gate, collapsible wall, among other barriers), without having to pass through any enclosed cabins or structuresk, and without the need to physically traverse over any such structures.
The open platform passenger deck 102 has an open layout comprising a control console 112 responsible for controlling various mechanisms and features of the recreational watercraft 100, as will be further described herein. The control console 112 may be located along the starboard side 106-4 and in between the bow side 106-1 and stern side 106-2. In some embodiments, the control console 112 may be located instead along the port side 106-3. The control console 112 may further include control elements, where the control elements may be buttons, levers, switches, and/or display elements (e.g., icons) of a displayed interface (e.g., a touch screen, monitor, etc.). A user may physically interact with the control elements to control various mechanisms. In other examples, the control console 112 may control the various mechanisms independently from user control. Such examples may include having a timer sequence of the control console 112 that is responsive to a desired specific time or desired passing of an amount of time, and in response to the desired time or desired amount of passed time being met, the control console 112 may control the various mechanisms. Other examples may employ a sensor system to detect either physical structures, users, water level or depth, among other examples, and in response to the sensor system detecting the respective stimuli, the control console 112 may control the various mechanisms.
The control console 112 may be associated with or include a steering mechanism 113 facing the stern side 106-2 to allow a user to control direction of the recreational watercraft 100 and may include control elements to control various mechanisms of the recreational watercraft 100. Examples of a steering mechanism 113 include but are not limited by: a rotating steering wheel, a pivotable control stick, or a plurality or combination of both. In some embodiments, the steering mechanism 113 may be controlled mechanically (e.g., by a user) or electronically (e.g., via a GPS system, sensor system, voice activated system, etc.) The steering mechanism 113 may be adjustable longitudinally, vertically, or a combination thereof and may be adjusted either electrically from the control console 112 or physically through an adjustment mechanism to be used by a user, such as a lever, latch, screw, or rotational mechanism. In some embodiments, the steering mechanism 113 may be removable or may be retracted to be flush with the control console when not in use.
The control console 112 may include a windshield 114 affixed to the top of the control console 112 to prevent wind, water, and/or debris from reaching the user when driving the recreational watercraft 100. The windshield 114 may span across only a portion of the maximum width 107-2 of the recreational watercraft 100 in order to facilitate the longitudinal open layout of the continuous unimpeded walkway of the open platform passenger deck 102. That is, the windshield 114 does not encumber or block the open platform passenger deck 102 from having a continuous structurally unimpeded walkway from the stern side 106-2 to the bow side 106-1. In some embodiments, the windshield 114 may be formed from of glass, plexiglass, plastic, tinted material, fiberglass, and/or metal. The windshield 114 may contain wiper blades (not shown) to remove water and debris from the exterior of the windshield 114. Further, the windshield 114 may be removable either physically by a user and/or electrically through retracting back into the control console 112 when not in use.
The control console 112 may control the opening and closing of the panel drop down boarding point 170. In some embodiments, a first control element may be configured to control operation of extending the retractable pistons, thereby opening the panel drop down boarding point 170, and a second control element may be configured to control operation of retracting the retractable pistons thereby, closing the panel drop down boarding point 170. In some embodiments, such controls may be located near the panel drop down boarding point 170, such as on the bow side 106-1 or port side 106-3, etc.
In other embodiments, the control console 112 may further control the ballast system described herein. In some embodiments, a series of control elements can be configured to control operation of the ingress and egress of water to and from each ballast tank of the ballast system, either together or independently, as will be described further herein. In some embodiments, each ballast tank may allow pump-less ingress and egress of water.
The open platform passenger deck 102 includes an open layout comprising a plurality of seats from the bow side 106-1 to the stern side 106-2. The plurality of seats may, in various embodiments, include a plurality of elongated seats 108-1 at the bow side 106-1 of the recreational watercraft 100, for example, to allow sufficient room for a user to lay comfortably across with their legs up on the elongated seats 108-1, among other benefits. The plurality of seats may further include a plurality of non-elongated seats 108-2 between the bow side 106-1 and stern side 106-2 of the recreational watercraft 100. The non-elongated seats 108-2 may provide more upright seating and may be of an L-shape, square shape, among other examples.
Further, the plurality of seats may include a number of partially elongated seats 108-3 at the stern side 106-2 that allow for seating of users to overlook the water at the stern side. The partially elongated seating 108-3 may further serve as a power hatch to access the inboard power plant within the aluminum hull 104. That is, the partially elongated seating 108-3 may be opened and/or closed either by the control console 112 or physically by a user via a drop down or flip up mechanism. In some embodiments, the plurality of seats may optionally comprise a removable seat 108-4 that may be removably coupled to the bow side 106-1, stern side 106-2, port side 106-3, and/or the starboard side 106-4. The removable seat 108-4 may be removably coupled through various mechanisms such as latching, magnetic, slide and lock, or wedge fit, among other examples. As described herein, the removable seat 108-4 may be optionally employed to the recreational watercraft 100 and when discussing the open layout of the open platform passenger deck 102, it is to be understood that the removable seat 108-4 is not coupled to the bow side 106-1. The open platform passenger deck 102 may include one or more charging ports, power supply outlets, lights (e.g., light-emitting diodes (LEDs), red, green, blue (RGB) LEDs, etc.), cameras, heated seats, and/or heaters. In some embodiments, the open platform passenger deck 102 may include a plurality of cylindrical holders 109 located from the bow side 106-1 to the stern side 106-2 to provide housing for beverages, keys, wallets, and other user items. Further, the cylindrical holders 109 may allow for a cooling mechanism to keep a user's beverage cold or a heating mechanism to keep a user's beverage hot. In further embodiments, the open platform passenger deck 102 may further comprise a plurality of audio systems 111 located throughout the bow side 106-1 to the stern side 106-2 to provide audio output either wirelessly (e.g., via Bluetooth) or from a user device to be connected to the control console 112. The plurality of audio systems 111 may be further located in an interior surface of the plurality of sides, an exterior surface of the plurality of sides, a surface beneath the plurality of seats, where the plurality of audio systems 111 may further be recessed in the respective surfaces.
The recreational watercraft 100 may comprise all of the aforementioned features in
In some embodiments, the continuous planar drive shaft 119 extends from an inboard power plant (220 in
In the embodiment of a single aluminum hull 204, the plurality of sides 206 may be fabricated from aluminum continuous from the aluminum hull 204. For example, a bow side 206-1, stern side 206-2, port side 206-3, and a starboard side 206-4 of the plurality of sides (collectively referred to as “plurality of sides 206”) are continuous from the aluminum hull 204. That is, the plurality of sides 206 extend directly from the aluminum hull 204 such that the aluminum hull 204 and plurality of sides are bent, folded, and/or welded together, to form a single cohesive skeleton upon which to house the open platform passenger deck (102 in
In the aluminum hull 204 embodiment, the recreational watercraft 200 further comprises a plurality of cross members 222 within the aluminum hull 204 to provide structural support for the aluminum hull 204 (e.g., instead of using an internal fiberglass liner for the structural support). The plurality of cross members 222 may further provide support for the open platform passenger deck 102. That is, in some embodiments, the open platform passenger deck 102 is placed on and affixed to a top surface of the cross members 222 (e.g., via welding, gluing, bolting, among other attachment mechanisms).
As shown in
In some embodiments, the watercraft 200 can include three ballast apparatuses 250, however, more or less apparatuses can be used. In some embodiments, two of the ballast apparatuses 250 can be located toward a stern 206-2 of the watercraft 200 (e.g., in a back half of the watercraft 200) and one of the ballast apparatuses 250 can be located towards a bow 206-1 of the watercraft 200 (e.g., in a front half of the watercraft 200), though embodiments herein are not so limited.
As described further herein, a ballast apparatus 250 can include a ballast tank 252 having a plurality of openings and a valve 253 configured to selectively close and/or open a top one of the openings. For instance, as described below in connection with
Control of the ballast apparatuses 250 can be provided via a control console (e.g., the control console 112 previously described in connection with
To enable performance of wake sports and towed watersports, a sufficient wake may be created behind the recreational watercraft 200. This may be achieved by adjustably filling one or more of the ballast tanks of the ballast apparatuses 250 with water, to regulate water displacement in the body of water (101 in
In various embodiments, the aluminum hull 204 may have the inboard power plant (220 in
In some embodiments, the inboard power plant 220 may be an internal combustion gas or diesel engine, an electric engine, or a jet propulsion mechanism, among other examples of propulsion powering to provide sufficient towing power to pull a user in the water behind the recreational watercraft 200. For this, the inboard power plant 220 may be selected to have sufficient horsepower to enable performance of wake sports and towed watersports. In various embodiments the inboard power plant 220 has horsepower output capability in a range from 400 horsepower to 1000 horsepower, or similar equivalent. Although not illustrated, the recreational watercraft 200 may include additional propulsion devices, for example, one or more thrusters located at the stern 206-2 and/or bow 206-1 of the recreational watercraft 200 to increase maneuverability of the recreational watercraft 200.
As described herein, a ballast apparatus (e.g., the ballast apparatus 350-1) can include a ballast tank (e.g., ballast tank 352-1) having a plurality of openings and a valve (e.g., valve 353-1) configured to selectively close and/or open one of the openings. Three ballast tanks are illustrated 352-1, 352-2, and 352-3 (collectively referred to as “ballast tanks 352”), at least one to each of the ballast apparatuses 350, respectively. Similarly, three valves are illustrated 353-1, 353-2, and 353-3 (cumulatively referred to as “valves 353”), at least one to each of the ballast apparatuses 350, respectively. Embodiments, however, are not limited to this example number of ballast tanks 352 or valves 353 for the ballast apparatuses 350. The ballast tanks 352 and the valves 353 in accordance with the present disclosure are discussed in more detail below in connection with
In some embodiments, the ballast tanks 352 can all be a same size. In other embodiments, one or more ballast tanks 352 can be of different sizes. In some embodiments, the first ballast tank 352-1 and the second ballast tank 352-2 can be a same size and the third ballast tank 352-3 can be a different size. In some embodiments, ballast tanks 352 in accordance with the present disclosure have a volume in a range between 10 and 30 cubic feet. In some embodiments, ballast tanks 352 in accordance with the present disclosure have a volume in a range between 10 and 50 cubic feet. In some embodiments, ballast tanks 352 in accordance with the present disclosure have a volume between 5 and 100 cubic feet.
As shown in more detail in
According to various embodiments, the bottom openings 462 are fixed permanently open. Stated differently, in some embodiments the bottom openings 462 are not designed to be or intended to be closable, sealable, and/or stoppable. Water can be selectively allowed to enter the ballast tank(s), be retained in the ballast tank(s), and/or drained from the ballast tanks via the control of one or more of the valves (553 in
The ballast tank 552 can include a first surface 558 defining a top opening 559 on the ballast tank 552. The top opening 559 can extend via a conduit 564 from an interior 554 of the ballast tank 552 through a valve 553 to a hull side opening (457 in
The top opening 559 connects the ballast tank 552 to the conduit 564. The conduit 564 is an elongate member extending between the ballast tank 562 and the exterior of the hull that allows the passage of air therein. The conduit can be a pipe, hose, duct, tube, or other type of material for a conduit 564. In some embodiments, the conduit 564 can be flexible. In other embodiments, the conduit 564 may be rigid. The conduit 564 can be formed from any suitable material including, for instance, aluminum, steel (e.g., stainless steel), polymer (e.g., polyvinyl chloride (PVC), polyethylene, etc.), and/or rubber. The conduit 564 can be coupled to the ballast tank 552 via any suitable coupling including, for instance, welding, adhesive(s), and/or mechanical fastening.
The passage of air through the top opening 559 can be regulated closed (or opened) via a valve 553 connected in the path formed by the conduit 564 from the exterior of the hull (404 in
The ballast tank 552 can include a second surface 561 defining a bottom opening 562. The bottom opening 562 can extend from the interior 554 of the ballast tank 552 through a bottom portion of the hull to an exterior of the bottom portion of the hull. The bottom opening 562 can define a path for the passage of water from a body of water (e.g., 101 in
The ballast tank 552 can include a sensing device 565. In some embodiments, the sensing device 565 can determine a ballast water level and/or ballast water volume within the ballast tank 552. In some embodiments, the sensing device 565 can be configured to determine when the ballast tank 552 is full of ballast water. The sensing device 565 can communicate with the control console in either a wired and/or wireless manner using radio or other frequencies for communication. Accordingly, an operator of the watercraft can be notified of the status of the ballast tank 552(s) fluid level in the ballast apparatuses 550 of recreational watercraft (400 in
In
At 668, the method 666 includes operating the watercraft in a body of water with the valve (553 in
At 669, the method 666 includes causing the valve to change to a second position such that the valve (553 in
At 670, the method 666 includes causing the valve to return to the first position such that the passage of air and/or liquid (e.g., water) via the conduit (564 in
In some embodiments, the valve (553 in
At 674, the method 671 can include causing the valve to return to the first position such that the valve (553 in
It is noted that removal of the watercraft from the body of water may cause the ballast tank to drain, even if the valve is in the closed position. in some embodiments, when both the top and bottom opening are above the surface of the water, the downward force of gravity on the ballast water can be sufficient to cause the ballast water to drain out of the ballast tank via the bottom opening. As a result, even if the operator fails to drain the ballast tank before trailering the watercraft, the ballast water will drain by itself. This drainage, even in the face of operator error or negligence, is desirable in more than one respect. For example, the operator can be saved from the costs and danger associated with towing an over-weighted watercraft, the spread of aquatic invasive species through ballast water can be avoided, and governmental agencies can be relieved of the need to painstakingly inspect the ballast tank(s) of such embodiments of the present disclosure.
Other watercraft using ballast systems may employ mechanical and/or manual pumps with their ballast systems. These are less advantageous than the present disclosure because such systems require additional electrical systems and consume valuable power supply resources such as batteries. Manual systems require exertion of measurable effort by an operator of those systems. Hence, the pump-less ballast apparatuses (550 in
As shown in
As described herein, the panel drop down boarding point 770 can be hingedly attached horizontally to the hull of the recreational watercraft for ingress and egress to the recreational watercraft. The panel drop down boarding point can be hingedly attached horizontally to the hull via one or more hinges. As used herein, the term “hinge” refers to a movable joint device on which the panel drop down boarding point can extend and/or unextend. In some embodiments, the panel drop down boarding point can include a telescoping piston, as further described herein.
As shown in
As shown in
The panel drop down boarding point can be trapezoidal in shape. The trapezoidal shape of the panel drop down boarding point can facilitate docking to a specific surface and/or at a preferred angle. The panel drop down boarding point can be used for ingress and egress of persons to the recreational watercraft.
The panel drop down boarding point can be adjusted according to a user's preference. For example, a user can adjust the panel drop down boarding point to be at a 90-degree angle from a vertical reference line to facilitate a device with wheels (e.g., wheelchair, etc.) to ingress and/or egress the recreational boarding point. In some embodiments, the user can adjust the panel drop down boarding point to be parallel to a dock to make ingress and/or egress easier from the dock. Yet, in some embodiments, the user can adjust the panel drop down boarding point based on the depth of the water to board back onto the recreational watercraft after a swim. The range of the panel drop down boarding point from a fully closed to fully deployed position can be 180-degrees from the vertical reference line.
Control of the panel drop down boarding point can be provided via the control console. The control elements can be buttons, levers, switches, and/or display elements (e.g., icons) of a displayed interface. In some embodiments, a manual switching mechanism can be used to control the opening and closing of the panel drop down boarding point. In some embodiments, the manual switching mechanism can be located in the bow side of the hull of the recreational watercraft.
In some embodiments, the first surface 772-1 can include a plurality of boarding grip points. The boarding grip points, as further described herein, can be fabricated in the first surface of the panel drop down boarding point 770. The boarding grip points can be beneficial in assisting a person getting into or out of the water and act as a transition between the ladder and the interior of the watercraft.
In some embodiments, the first surface 772-1 can include a first portion and a second portion, opposite to the first portion. The first surface 772-1 can include a first portion and a second portion. Similarly, second surface 772-2 can include a first portion and a second portion, opposite to the first portion.
In some embodiments, the first portion of the first surface 772-1 of the panel drop down boarding point 770 and a first portion of the second surface 772-2 of the panel drop down boarding point 770 are joined together at a first edge 775-1. Similarly, a second portion of the first surface 772-1, of the panel drop down boarding point 770 and a second portion of the second surface 772-2 of the panel drop down boarding point are joined together at a second edge 775-2. The first portions and the second portions of the first surface 772-1 and the second surface 772-2 can be joined by any suitable joinder process. In some embodiments, for example, the first surface 772-1 and the second surface 772-2 can be joined via techniques such as welding, soldering, brazing, riveting, using adhesives, etc.
As discussed above, the panel drop down boarding point 770 can include an aperture 774 formed between the first surface 772-1 and the second surface 772-2. The aperture 774 can have an opening 776 in an end surface 773 of the panel drop down boarding point 770. In some embodiments, the aperture 774 can be sized and shaped to house a retractable ladder 778 and the ladder can extend out through the opening 776.
The retractable ladder 778 of the panel drop down boarding point 770 can have at least two sections arranged so that they fit together or extend on a sliding mechanism. In some embodiments, the retractable ladder 778 can include a telescoping ladder. The retractable ladder 778 can include a telescoping ladder that telescopes from a first length to a second length when extended out of the aperture 774 in the panel drop down boarding point 770. For instance, the retractable ladder 778 can telescope from a first length of two feet to a second length of six feet when extended out of the aperture.
The retractable ladder 778 can include multiple rungs 779. In some embodiments, the retractable ladder 778 can include recesses that provide boarding grip points aligned with the multiple rungs when the retractable ladder extends out of the aperture in the panel drop down boarding point 770. In some embodiments, the retractable ladder 778 can be affixed into the aperture 774 permanently. In some embodiments, the retractable ladder 778 can be removably affixed from the aperture 774 to completely remove the ladder from the aperture.
As described in
As discussed above, the retractable ladder 778 can be stored in aperture 774 and extend out through the end surface 773 via the opening 776, as described herein, and extend to, at, and/or below the waterline 715. The panel drop down boarding point 770 can include a telescoping piston 780. In some embodiments, the telescoping piston 780 can be located on each side of the panel drop down boarding point 770, as shown in
The telescoping piston 780 can be attached between the first surface 772-1 and the hull 704 to adjust the panel drop down boarding point 770 as the telescoping piston 780 moves between an extended and/or an unextended condition. The piston 780 can be mounted to the hull 704 in any suitable manner. As the piston 780 articulates between an extended condition and an unextended condition, the panel drop down boarding point 770 rotates along a rotational path 789. The range of angles (from a vertical reference point such as reference line 787 or a closed position of the panel drop down boarding point 770 can, for example, have a range of between 0 degrees and 180 degrees.
The telescoping piston 780 can be electrically driven. This can be beneficial, for example, as electrically driven pistons (as opposed to hydraulically driven pistons) can be more precisely lengthened which may be helpful in aligning the panel drop down boarding point during when preparing to board or disembark. This precision is possible because electrically driven pistons utilize a screw drive system wherein the electric motor turns a screw mechanism inside the piston to extend or retract the length of the piston and thereby can be stopped at any point along its range from unextended to extended.
As discussed above, the panel drop down boarding point 770 can rotate via hinges 788 about a lateral axis 792. The lateral axis 792 can be an defined by a line parallel to the direction of elongation of a side of the recreational watercraft. In some embodiments, when the panel drop down boarding point 770 is to be opened, the hinges 788 can rotate from a bottom 771 of the panel drop down boarding point around the lateral axis 792 to extend the panel drop down boarding point 770 toward waterline 715, as shown in
Further, in some embodiments, when the panel drop down boarding point 770 is to be closed, the hinges 788 can rotate around the lateral axis 792 to retract the panel drop down boarding point 770 from the waterline 715 toward the hull 704. As described herein, when the panel drop down boarding point 770 is retracted and in a closed position, the panel drop down boarding point 770 can overlap with a portion of the hull 704 on either side (at 790 of
In some embodiments, the first surface 772-1 of the panel drop down boarding point 770 can include a plurality of boarding grip points 793. The boarding grip points 793 can be provided in the first surface 772-1 of the panel drop down boarding point 770.
The grip points 793 can include hand/foot contacting portion 795 for the placement of a hand or foot to assist users in ingress and egress to the recreational watercraft 770 from the water. In some embodiments, the hand/foot contacting portion can have a non-slip surface. The non-slip surface can be created, for example, by adding texture to the surface and/or by applying a non-slip material to the surface of the hand/foot contacting portion.
The recreational watercraft, as shown in
As described herein, the first surface of the panel drop down boarding point 770 is sized such that a portion of the first surface overlaps a portion of a bow surface of the hull of the recreational watercraft 770. One benefit of having this overlap can be that the end of the piston can be positioned on the overlapped portions of the side (e.g., bow side 706-1) and the panel drop down boarding point 770. Another benefit is that a sealing mechanism can be positioned on the side or the panel drop down boarding point to reduce the passage of water between the panel drop down boarding point and the side. This can be helpful in keeping riders, seats, and belongings kept on the recreational watercraft dry.
For example, in some embodiments, the portion of the first surface of the panel drop down boarding point that overlaps the portion of the bow surface of the hull can include a sealant material. The sealant material 796 can be on at least part of the portion of the first surface of the panel drop down boarding point to reduce passage of water when the panel drop down boarding point is in the closed position. Any suitable sealant material (e.g., a rubberized coating, silicon coating, etc., applied to one or both surfaces) that can reduce the passage of water between the panel drop down boarding point and the side can be utilized. In some embodiments, the portion of the first surface that overlaps the portion of the bow surface of the hull includes a resilient gasket 794 attached thereto. The resilient gasket 794 can act as a seal that fills the space between the portion of the first surface and portion of the side surface that overlap. As used herein, a resilient material can be compressed, will deform, and will return to its original shape when uncompressed. Examples, of resilient materials include: rubberized material, silicone material, etc.
As shown in
As shown in the example 7C, the retractable ladder 778 is in an extended position from the end surface 773 of the panel drop down boarding point 770. As described herein, the retractable ladder 778 can be housed in the aperture 774. Aperture 774 can have an opening 776 in an end surface 773 of the panel drop down boarding point 770. In some embodiments, the aperture 774 can be sized and shaped to house a retractable ladder 778. The retractable ladder 778 can extend out through the opening 776. In some embodiments, the retractable ladder 778 may be configured to extend out through the opening 776 when the panel drop down boarding point 770 is in an open position. Further, the extended retractable ladder 778 may be configured to retract into the opening 776 when the panel drop down boarding point 770 is in a closed position and/or moving towards a closed position. In some embodiments, the retractable ladder 778 can rotate at an angle 797. This can be beneficial where a person entering or exiting the water may want a more vertical ladder than could be provided, for example where the panel drop down boarding point 770 does not open to a large enough angle.
As shown in
The retractable ladder 778 can, as shown in
In some embodiments, the panel drop down boarding point can be used as swim platform and/or the swim platform (e.g., 127 of
Although specific embodiments have been illustrated and described herein, those of ordinary skill in the art will appreciate that an arrangement calculated to achieve the same results can be substituted for the specific embodiments shown. This disclosure is intended to cover adaptations or variations of a number of embodiments of the present disclosure. It is to be understood that the above description has been made in an illustrative fashion, and not a restrictive one. Combination of the above embodiments, and other embodiments not specifically described herein will be apparent to those of skill in the art upon reviewing the above description. The scope of a number of embodiments of the present disclosure includes other applications in which the above structures and processes are used. Therefore, the scope of a number of embodiments of the present disclosure should be determined with reference to the appended claims, along with the full range of equivalents to which such claims are entitled.
In the foregoing Detailed Description, some features are grouped together in a single embodiment for the purpose of streamlining the disclosure. This method of disclosure is not to be interpreted as reflecting an intention that the disclosed embodiments of the present disclosure have to use more features than are expressly recited in each claim. Rather, as the following claims reflect, inventive subject matter lies in less than all features of a single disclosed embodiment. Thus, the following claims are hereby incorporated into the Detailed Description, with each claim standing on its own as a separate embodiment.