The present invention relates generally to use of a hydrofoil with a watercraft, such as a surfboard, windsurf board, kite board, or the like. More particularly, aspects of the disclosure focus on techniques for securing components of the hydrofoil together in a robust, reliable and expedited manner.
Hydrofoils are wings that are adapted to function in water as opposed to air but share many similar attributes. Notably, a hydrofoil provides a significant amount of lift, even at relatively slow speeds. Accordingly, the benefits of a hydrofoil may be extended to any number of applications involving movement through the water. For example, nearly any recreational pursuit that involves riding a board may take advantage of a hydrofoil, including kitesurfing, wind surfing, stand up paddle boarding, wake boarding, water skiing, tow-in surfing, conventional surfing and others. For context,
In conventional designs, the various components of the hydrofoil assembly 12 are secured together with threaded fasteners such as screws or bolts, allowing for disassembly and for interchanging components that may have different performance characteristics. It should also be appreciated that the connections must be sufficiently robust to withstand the forces developed during use, as the foil is supporting the body weight of the user and board 10 as well as being subject to dynamic loads associated with turning, jumping, pumping and/or others when being ridden. Moreover, it is desirable for the connections between the foil components to be as tight as possible with minimal or no play when secured. As one illustration, a number of conventional designs utilize bolts 22 (shown in phantom) to secure fuselage 16 to mast 14. Despite their common use, it is well-recognized that such threaded, metallic connections suffer from a number of drawbacks. Notably, threads are a common failure point in foils as they are prone to corrosion and seizing due to salt water and sand. Ionic reactions between the metallic alloys used for the threaded connections may cause them to fuse together, making disassembly difficult or impossible. Screws also tend to snap or break due to heavy use. Further, employing threaded connectors requires the user to carry appropriate tools in order to assemble or disassemble the foil.
One attempt to address some of these issues is disclosed in U.S. Pat. No. 9,278,739, which uses a male connector on the front wing that fits within a female receptacle carried by the mast. A threaded rod extends through a central bore and engages the rear portion of fuselage so that tightening the rod draws the male and female portions together to form a rigid connection. Although this design provides a secure attachment of the front wing to the mast, it must be noted that no direct engagement between front wing assembly and the stabilizer assembly is provided, as it is the female receptacles on the mast that receive the respective assemblies. As another consequence of this design, the stresses are constrained to relatively small overall portions of the mast engagement. Further, this design requires the use of a threaded connection to provide a substantial amount of the force needed to secure the components as well as the necessity of a separate tool to assemble and disassemble the foil.
As such, it would be desirable to provide a foil and mast system that allows assembly and disassembly but nevertheless results in a robust connection between all the separate components. Similarly, it would be desirable to optimize engagement among the separate components to distribute forces more effectively. In some situations, it may also be desirable to provide a foil system that allows relative fore and aft adjustment of the front wing and stabilizer relative to the mast to vary performance characteristics. Still further, it would be desirable to employ a foil system that enables tool free foil assembly, in some cases without requiring threaded connectors while still providing a robust connection between the front wing, mast and other components of the foil.
This disclosure includes hydrofoil system with a first fuselage portion having a tapered section, a second fuselage portion having a tapered section, a collar having an inner passageway dimensioned to encompass and retain the tapered section of the first fuselage portion and the tapered section of the second fuselage portion when overlapped in a stacked wedge configuration and an actuator configured to draw the first fuselage portion and the second fuselage portion together longitudinally so that the collar frictionally engages the stacked tapered sections.
In one aspect, the actuator may be a manually-operated lever that imparts a force that pulls the first fuselage portion and second fuselage portion towards each other. A relative movement imparted to the first fuselage portion and second fuselage portion by the actuator may be adjustable.
In one aspect, the tapered section of the first fuselage portion and the tapered section of the second fuselage portion each have an equivalent length. The equivalent lengths of the tapered section of the first fuselage portion and the tapered section of the second fuselage portion may be at least as long as a length of the collar passageway.
In one aspect, a position of the stacked tapered sections may be longitudinally adjustable within the collar.
In one aspect, at least one of the first fuselage portion and the second fuselage portion may be a hydrofoil wing. One of the first fuselage portion and the second fuselage portion may be a fore wing and another of the first fuselage portion and the second fuselage portion may be an aft wing.
In one aspect, the actuator may engage the first fuselage portion and the second fuselage portion.
In one aspect, the actuator may engage the collar and one of the first fuselage portion and the second fuselage portion and the collar may resist longitudinal movement of another of the first fuselage portion and the second fuselage portion.
In one aspect, the tapered sections of the first fuselage portion and the second fuselage portion may have a planar profile. Alternatively, the tapered sections of the first fuselage portion and the second fuselage portion may have a three-dimensional profile.
In one aspect, the actuator comprises a lever secured to one of the first fuselage portion and the second fuselage portion and wherein the lever is configured to apply tension to a line secured to another of the first fuselage portion and the second fuselage portion.
In one aspect, the actuator may be a threaded rod.
This disclosure also includes a fuselage portion for a hydrofoil system having a tapered section configured to overlap with a tapered section of another fuselage portion to form a stacked wedge such that the stacked tapered sections are configured to be retained by an inner passageway of a collar, wherein the fuselage portion further comprises at least one of actuator and a means for engaging an actuator, wherein the actuator is configured to draw the fuselage portion and the another fuselage portion together longitudinally. The fuselage portion may have a hydrofoil wing.
This disclosure also includes a collar for a hydrofoil system having an inner passageway dimensioned to encompass and retain a tapered section of a first fuselage portion and a tapered section of the second fuselage portion when overlapped in a stacked wedge configuration.
This disclosure also includes a method for assembling a hydrofoil system. The method may involve providing a first fuselage portion having a tapered section, providing a second fuselage portion having a tapered section, overlapping the tapered section of the first fuselage portion and the tapered section of the second fuselage portion in a stacked wedge configuration within a collar having an inner passageway and drawing the first fuselage portion and the second fuselage portion together longitudinally so that the collar frictionally engages the stacked tapered sections.
In one aspect, drawing the first fuselage portion and the second fuselage portion together may involve manually operating an actuator to impart a force that pulls the first fuselage portion and second fuselage portion towards each other.
In one aspect, drawing the first fuselage portion and the second fuselage portion together may involve tightening a threaded connection.
Further features and advantages will become apparent from the following and more particular description of the preferred embodiments of the disclosure, as illustrated in the accompanying drawings, and in which like referenced characters generally refer to the same parts or elements throughout the views, and in which:
Before describing the present invention in detail, it is to be understood that this invention is not limited to particularly exemplified materials, methods or structures as such may, of course, vary. Thus, although a number of materials and methods similar or equivalent to those described herein can be used in the practice of the present invention, the preferred materials and methods are described herein.
It is also to be understood that the terminology used herein is for the purpose of describing particular embodiments of the invention only and is not intended to be limiting.
Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one having ordinary skill in the art to which the invention pertains.
Further, all publications, patents and patent applications cited herein, whether supra or infra, are hereby incorporated by reference in their entirety.
Finally, as used in this specification and the appended claims, the singular forms “a, “an” and “the” include plural referents unless the content clearly dictates otherwise.
Described herein are certain exemplary embodiments. However, one skilled in the art that pertains to the present embodiments will understand that the principles of this disclosure can be extended easily with appropriate modifications to other applications.
To help illustrate aspects of the disclosure, reference is first made to
Particularly as shown in the exploded view of
As will be appreciated, the straight profile of aperture 48 of collar 44 allows engagement along its entire length, such that when tapered portions 46 and 47 are at least as long as the collar, forces from each component can be distributed along their respective lengths, providing a superior connection. For example, the load forces can be transmitted from the front wing to the mast over the entire length of the collar to resist breakage or failure especially during high load cases such as jumping or pumping.
The necessary compressive tension is applied by actuator 42, which in one embodiment is a cam latch that engages fitting 50 and may be spring-loaded as desired. In other embodiments, any suitable connection between front fuselage 34 and rear fuselage 36 that generates a compressive longitudinal force may be used, such as clips, bungees or lever and line or wire systems. Further, threaded connections can also be employed. Even though they suffer from certain drawbacks as discussed above, they still enable the other benefits provided by the techniques of this disclosure. When threaded connections are used, they may optionally have a portion configured to allow manual manipulation and hand tightening to avoid the need for a tool during assembly or disassembly. The straight configuration of collar 44 also facilitates manufacture, such as by allowing the collar to be formed by extrusion.
In one aspect, the techniques of this disclosure allow front fuselage 34 and rear fuselage 36 to have adjustable longitudinal positions relative to mast 32 as schematically depicted in
As discussed above, the outer profile of stacked tapered portions 46 and the complementary inner profile of aperture 48 may be relatively straight along their respective length but in cross section may have a variety of different configurations, examples of which are depicted in
In some embodiments, tapered portions 46 have the relatively planar configuration shown in
Other suitable variations include the positioning of a clamping actuator to provide the desired longitudinal compression. In the embodiment shown in
Illustrative implementations of actuator 42 are provided in
The various components may be formed using any suitable technique, such as injection molding, three-dimensional printing, computer number controlled (CNC) milling and others. Moreover, any suitable material can be employed. In some embodiments, composite materials are used that can optionally be reinforced by embedding components in a binder matrix. For example, the reinforcing components may be formed from fibers, fabrics or the like of any suitable material, including carbon, glass, boron, basalt, Nylon, Kevlar and the like. The binder matrix may be formed from suitable polymeric materials, including polyester and epoxy. The reinforcing members may be “wet out” or saturated with the polymer prior to curing to achieve desired structural characteristics. In some embodiments, the reinforcing member may have a three-dimensional structure such as a honeycomb configuration or the like. By employing such materials, the various hydrofoil components may exhibit increased structural integrity and can be adapted based on the expected forces. Moreover, avoiding the use of metals or alloys minimizes or eliminates the risk of corrosion. However, any or all the components of the hydrofoil assembly may also be formed from other materials, such as metal, alloys or others to create a component having sufficient structural strength.
Described herein are certain exemplary embodiments. However, one skilled in the art that pertains to the present embodiments will understand that the principles of this disclosure can be extended easily with appropriate modifications to other applications.
This application claims priority from and benefit of U.S. Provisional Patent Application Ser. No. 63/339,828, filed May 9, 2022, entitled “MODULAR FOIL SYSTEM FOR WATERCRAFT,” which is incorporated by reference in its entirety.
Number | Date | Country | |
---|---|---|---|
63339828 | May 2022 | US |