The disclosure relates to watercraft rowed by a person in the standing position while facing the direction of travel.
Standup paddle boarding is a popular recreational sport involving a rider standing atop a floating craft and using an unmounted oar to paddle the craft. Traditional paddle boarding utilizes one oar, which is not affixed to the craft, and the rider's body, as the sole source of propulsion. Propulsion is provided by replicating a paddling stroke similar to that of a canoer. Generating propulsion with a paddle when the paddle is not mounted to the craft is inefficient as no mechanical leverage is utilized. Additionally, propulsion provided by a single paddle requires a rider to alternate strokes on either side of the craft to maintain a straight course. Traditional sculling boats utilize a fixed fulcrum and sliding seat to provide more efficient propulsion. In traditional sculling, however, one must face rearwards and utilize a sliding seat mechanism. The sliding seat mechanism of a sculling or rowing boat provides mechanical leverage, but is not practical for use in a standing position. Accordingly, there has been a long-felt need for improved efficiency and performance of watercraft, and in particular for a craft powered by forward-facing rowing in a standing position and including a fixed fulcrum and slide to provide mechanical leverage.
One aspect of the disclosed watercraft features a hull having first and second opposed ends; a deck affixed to the hull, the deck including a surface for supporting a rider; and an outrigger attached to the deck, the outrigger including a pivot point that extends outwardly from the deck, the pivot point being capable of accepting an oar. In one such embodiment, the oar is capable of rotating in the pivot point so as to allow a rider to employ a “j-stroke” to provide forward course correction when powering the watercraft with one oar. As will be evident to one of ordinary skill in the art having the benefit of this summary, the outrigger can be adapted to include a second pivot point extending outwardly from the deck, the second pivot point being capable of accepting a second oar.
In one embodiment, the watercraft includes a footboard attached to the deck for receiving the foot of a rider. The footboard may be any surface that allows a rider to apply force thereto with the rider's foot. In some embodiments, the footboard may also include a foot strap to restrain a rider's foot to the footboard.
In another embodiment, the outrigger, including pivot points, is adapted to be removable from the deck of the watercraft. In such an embodiment, the outrigger is removably attached to the deck of the watercraft by any suitable means, including screws, clips, or a recess formed in the deck of the watercraft.
In various embodiments, the watercraft includes a slide assembly affixed to the deck of the watercraft. The slide assembly includes a first rail and a second rail mounted longitudinally to the deck of the watercraft and configured to allow longitudinal movement between the first rail and second rail. In such embodiments, the outrigger with pivot point, and footboard are attached to the second rail of the slide assembly. It will be evident to one of ordinary skill in the art having the benefit of this summary that the outrigger may include a second pivot point capable of accepting an oar. In one preferred embodiment, the slide assembly includes a set of first rails and a set of second rails.
In one embodiment, the watercraft includes a brake mechanism attached to the second rail of the slide assembly that interacts with the first rail of the slide assembly to prevent movement as between the first rail and the second rail. In some embodiments, the brake mechanism includes a contact surface connected to a boss, which may include a post or other support structure, which is inserted in a recess formed in the second rail of the slide assembly. In such an embodiment, a spring, which may surround the post, may interact with the post and the second rail to urge the brake mechanism in a disengaged position relative to the first rail. In another embodiment that also includes a spring, the spring interacts with the second rail and the contact surface to urge the brake mechanism in a disengaged position relative to the first rail. Upon application of pressure to the contact surface, the spring is compressed, and the post engages a brake receiving recess formed in the first rail of the slide assembly. The engagement of the post in the recess prevents relative movement between the first rail and the second rail of the slide assembly.
In alternative embodiments, the brake mechanism is capable of maintaining an engaged position relative to the brake receiving recess.
In other embodiments, the brake mechanism includes a contact surface, and may include a friction surface connected to the contact surface. That connection may include a boss inserted into a recess formed in the second rail. A spring attached to the friction surface urges the brake mechanism in a disengaged position relative to the first rail. Upon application of pressure to the contact surface, the spring is compressed, and the friction surface contacts the first rail of the slide assembly. The contact of the friction surface with the first rail of the slide assembly restricts movement between the first and second rails.
In another embodiment, the brake mechanism further includes a caliper retaining friction surfaces connected to the contact surface. Upon application of pressure to the contact surface, a caliper urges a friction surface into contact with the first rail.
In another embodiment, the invention includes a paddle board configured for a standing rower that includes a surface for supporting the rower, a slide assembly with a first rail and a second rail configured for longitudinal movement as between each other, an outrigger with at least one pivot point and a footboard with a restraining strap both attached to the second rail of the slide assembly. The first rail and second rail are configured to allow longitudinal movements as between the first rail and second rail. In a preferred embodiment, the slide assembly includes a set of first rails and a set of second rails.
In some embodiments, a first rail of the slide assembly includes a plurality of bearings retained in the first rail, and a second rail adapted to receive the first rail so as to allow longitudinal movement as between the first rail and the second rail. In still other embodiments, the bearings are retained in carriages attached to a second rail, and the carriages are adapted to receive a first rail of the slide assembly.
In yet another embodiment, the slide assembly, including the outrigger, pivot points, and footboard, are adapted to be removable from the deck and hull. In such an embodiment, the slide assembly, including the outrigger, pivot points, and footboard, are removably attached to the deck of the watercraft by any suitable means, including screws, clips, or a recess formed in the deck of the watercraft.
In some embodiments, the hull and deck may comprise a unitary assembly. Such unitary assemblies may include surfboards, sculling boats, paddleboards, skiffs, dories, and other composite watercraft.
The following detailed description of exemplary embodiments of the novel watercraft is for purposes of illustration and enablement only, but is not intended to limit the scope of the appended claims. Various changes may be made in the function and arrangement of the elements described in these embodiments without departing from the scope of the appended claims. The description herein may be adapted and employed with alternatively configured devices having different shapes, components, mechanisms, structures, materials and the like
In an alternate embodiment of watercraft 100, outrigger 116 is attached directly to deck 104 with or without need for slide assembly 110. Without the slide assembly, outrigger 116 does not move relative to deck 104. Outrigger 116 may be attached to deck 104 with conventional fastening systems including, but not limited to, threaded and non-threaded fasteners, or adhesives. It is further contemplated that outrigger 116 may be attached to deck 104 with attachable or integral clips, or recess formed in deck 104 of watercraft 100.
In one embodiment, slide assembly 110 is substantially permanently attached to deck 104. Slide assembly 110 may be attached to deck 104 with conventional fastening systems including, but not limited to, threaded or non-threaded fasteners, or adhesives. In alternative embodiments, slide assembly 110 is removably attached to deck 104 to allow watercraft 100 to be used as a traditional paddle board. In such an embodiment, outrigger 116 is removably attached to deck 104 of watercraft 100 by, for example, screws, clips, a recess formed in deck 104 of watercraft 100, or by other suitable means.
With reference to
In an alternative embodiment, first rail 112 is adapted with a recess (not shown) sufficient to retain a plurality of bearings (not shown). Second rail 114 is adapted to contact bearings retained in first rail 112 so as to allow longitudinal movement as between first rail 112 and second rail 114. In an alternative embodiment, second rail 114 is adapted with recess (not shown) to retain a plurality of bearings (not shown) and first rail 112 is adapted to contact bearings retained in second rail 114 so as to allow longitudinal movement as between first rail 112 and second rail 114.
In some embodiments, bearings 125 may be of different types including, but limited to, rolling element bearings, linear bearings, fluid bearings, or magnetic bearings.
It is further contemplated that other methods of allowing movement as between first rail 112 and second rail 114 of slide assembly 110 are useful, including the use of lubricated rails.
It is further contemplated that bearings 125 contained in bearing carriages 124 may be composed of various materials including, but not limited to metal, steel, aluminum, carbon fiber, plastic, plastic composite, or other durable materials suitable to the chosen environment for use of watercraft 100.
In some embodiments, set of first rails 112 and set of second rails 114 of slide assembly 110 may each be composed of various materials including, but not limited to metal alloys, steel, aluminum, plastic, plastic composite, nylon, carbon fiber, fiberglass or other durable materials suitable to the chosen environment for use with watercraft 100. Similarly, in various embodiments described herein, hull 102, deck 104, and outrigger 116 may be composed of various materials including, but not limited to, wood, aluminum, plastic composite, plastic, carbon fiber, fiberglass or other durable materials suitable to the chosen environment for use in watercraft 100. In certain embodiments hull 102 and deck 104 constitute a singular unitary assembly. In various embodiments, hull 102 and deck 104 are a unitary assembly, including a surfboard, paddleboard, sculling boat, or other composite watercraft.
With reference to
With reference to
In alternative embodiments of watercraft 100, brake mechanism 200 includes a friction surface (not depicted) attached to post 204. In such embodiments, the friction surface may each be composed of various materials including, but not limited to rubber, metal, plastic, a composite material, or other durable friction surfaces suitable to the chosen environment for use on watercraft 100. In such an embodiment, it is not necessary to adapt first rail 112 to interact with a friction surface (not depicted) attached to post 204. This embodiment does not require brake receiving recess 208. In this embodiment, brake mechanism 200 is engaged by application of force to contact surface 202, compressing spring 210 and forcing a friction surface (not depicted) attached to post 204 into contact with first rail 112. In some embodiments, contact surface 202 is attached to footboard 118.
In alternative embodiments, brake mechanism 200, including a friction surface attached to post 204, and spring 210, is attached to footboard 118. In one such embodiment, brake mechanism 200 is engaged by application of force to contact surface 202, compressing spring 210 and forcing a friction surface into contact with deck 104. In other embodiments, brake receiving hole 212 is formed in deck 104. Application of force to contact surface 202, engages brake mechanism 200 and moves post 204 into brake receiving hole 212 formed in deck 104.
In another alternative embodiment, brake mechanism 200 includes a caliper (not depicted) activated by application of force to contact surface 202. Friction pads (not depicted) installed on the caliper interact with first rail 112 to restrict movement as between first rail 112 and second rail 114. The friction pads may be composed of any suitable material based on the intended environment for watercraft 100 including, but not limited to, rubber, metal, plastic, a composite material, or other durable friction surfaces suitable to the chosen environment for use on watercraft 100.
While the invention has been described above with reference to various exemplary embodiments, many changes, combinations and modifications may be made to the exemplary embodiments without departing from the scope of the invention. For example, the various components may be implemented in alternative ways. These alternatives can be suitably selected depending upon the particular application or in consideration of any number of factors associated with the operation of the device. In addition, the techniques described herein may be extended or modified for use with other types of devices. These and other changes or modifications are intended to be included within the scope of this invention.
Number | Name | Date | Kind |
---|---|---|---|
4052951 | Farr | Oct 1977 | A |
4623314 | Waugh | Nov 1986 | A |
4776821 | DuPont | Oct 1988 | A |
4889509 | Pohlus | Dec 1989 | A |
5127859 | Rantilla | Jul 1992 | A |
5215482 | Henry | Jun 1993 | A |
5647782 | Henry | Jul 1997 | A |
6109988 | Dunn, Jr. | Aug 2000 | A |
6113447 | Roy et al. | Sep 2000 | A |
6817913 | Witham | Nov 2004 | B1 |
7070470 | Bleicken | Jul 2006 | B2 |
9376176 | Holden | Jun 2016 | B1 |
9428253 | Morgan et al. | Aug 2016 | B1 |
20080302293 | Nesseth | Dec 2008 | A1 |
20140245943 | Swan | Sep 2014 | A1 |
20160280338 | Parkinson et al. | Sep 2016 | A1 |
Number | Date | Country | |
---|---|---|---|
20180297671 A1 | Oct 2018 | US |