PADDLEBOARD PROPULSION SYSTEM AND METHOD

Abstract

A system for propelling a paddleboard or surfboard along the surface of a body of water, comprising a controller motor coupled to a propeller, a rechargeable battery, a controller which may be wearable on the wrist of a user, and a housing structure that is adapted to be attached to the fin box of a paddleboard without the need to remove the fin. The apparatus presents a low-drag profile, has a long battery life for extended range, and is able to be controlled so that user may operate the paddleboard at any desired speed, and in a forward or rearward direction, or in a controllable direction of thrust. The housing structure is adaptable to various fin box T-bolt separation distances.

Claims

1. A controllable apparatus for propelling a paddleboard along the surface of a body of water, comprising: a structure adapted to be attached to a water-facing surface of a paddleboard, said structure comprising a housing having an opening therethrough allowing a fin mounted in a fin box of the paddleboard to protrude through the structure; a controllable electric motor attached to said structure, said controllable motor having a rotable shaft with a propeller attached thereto, said controllable electric motor operable to rotate the propeller such that thrust is developed when the paddleboard is floating on a body of water, said thrust tending to motivate said paddleboard in a direction of travel along the surface of the body of water; and a controller in communication with said controllable electric motor, said controller having a user interface for receiving input commands from a user for controlling the controllable electric motor shaft rotation speed; and a battery in electrical communication with said controllable electric motor for providing electric power to said motor; wherein the amount of thrust produced when said propeller is rotated is controllable by a user inputting commands for controlling the controllable electric motor shaft rotation speed into the controller user interface; and wherein the structure is adapted to be attached to a water-facing surface of said paddleboard without requiring said fin to be removed.

2. The apparatus of claim 1, wherein a direction of rotation of said controllable electric motor shaft is controllable by a user inputting commands into said controller user interface such that the direction of thrust generated by said propeller is reversible upon command by a user.

3. The apparatus of claim 1 further comprising a strap passing through said structure and extending around the paddleboard so as to retain the structure to a water-facing surface of the paddleboard.

4. The apparatus of claim 1, wherein said structure is attached to said water-facing surface of the paddleboard by one or more T-bolts, wherein said one or more T-bolt heads are captured in a receiving grooves in said fin box.

5. The apparatus of claim 1, wherein said battery is contained within said housing.

6. The apparatus of claim 1, wherein said controller is defined as a handheld controller, and wherein said controller is in wired electrical communication with said controllable electric motor.

7. The apparatus of claim 1, in which said controller is wearable on the wrist of a user, and wherein said controller is in wired electrical communication with said controllable electric motor.

8. The apparatus of claim 1, further comprising a processor in communication with said motor, and wherein said controller is defined as a mobile device in wireless communication with said processor, wherein said commands input into said controller by a user are communicated by controller to said processor, and where said processor communicates said commands to said motor such that the motor is responsive to user commands for controlling the motor shaft rotation speed.

9. The apparatus of claim 1, further comprising one or more light sources disposed in said housing, said lights disposed so as to illuminate the water underneath the apparatus.

10. The apparatus of claim 9, wherein each of said one or more light sources is controllable as to intensity, and wherein said one or more light sources is in communication with said controller, and where said controller is adapted to receive commands input into said controller's input interface for controlling the intensity of said one or more light sources.

11. The apparatus of claim 1, further comprising a controllable servo motor or rotary actuator interposed between the controllable electric motor and the housing, such that the direction of thrust of the controllable electric motor is able to be controllably rotated in a plane that is parallel to a plane formed by surface of the body of water, and wherein said controllable servo motor or rotary actuator is in communication with said controller such that the user is able to control the direction of the angle of thrust vector produced by the propeller by inputting commands into the user interface of the controller.

12. A controllable apparatus for propelling a paddleboard along the surface of a body of water, comprising: a structure adapted to be attached to a water-facing surface of a paddleboard, said structure comprising a housing having an opening therethrough allowing a fin mounted in a fin box of the paddleboard to protrude through the structure; a controllable electric motor attached to said structure, said controllable electric motor having a rotable shaft with a propeller attached thereto, said controllable electric motor operable to rotate the propeller such that thrust is developed when the paddleboard is floating on a body of water, said thrust tending to motivate said paddleboard in a direction of travel along the surface of the body of water; a controller in communication with said controllable electric motor, said controller having a user interface for receiving input commands from a user for controlling the controllable electric motor shaft rotation speed; and a battery in electrical communication with said motor for providing electric power to said controllable electric motor; wherein the amount of thrust produced when said propeller is rotated is controllable by a user inputting commands for controlling the controllable electric motor shaft rotation speed into the controller user interface; wherein a direction of rotation of said controllable electric motor shaft is controllable by a user inputting commands into said controller user interface such that the direction of thrust generated by said propeller is reversible upon command by a user; wherein the structure is adapted to be attached to a water-facing surface of said paddleboard without requiring said fin to be removed.

13. The apparatus of claim 12, wherein a direction of rotation of said controllable electric motor shaft is controllable by a user inputting commands into said controller user interface such that the direction of thrust generated by said propeller is reversible upon command by a user.

14. The apparatus of claim 12, further comprising a strap passing through said structure and extending around the paddleboard so as to retain the structure to a water-facing surface of the paddleboard.

15. The apparatus of claim 12, wherein said structure is attached to said water-facing surface of the paddleboard by one or more T-bolts, wherein said one or more T-bolt heads are captured in a receiving grooves in said fin box.

16. The apparatus of claim 12, wherein said battery is contained within said housing.

17. The apparatus of claim 12, wherein said controller is defined as a handheld controller, and wherein said controller is in wired electrical communication with said controllable electric motor.

18. The apparatus of claim 12, in which said controller is wearable on the wrist of a user, and wherein said controller is in wired electrical communication with said controllable electric motor.

19. The apparatus of claim 12, further comprising one or more light sources disposed in said housing, said lights disposed so as to illuminate the water underneath the apparatus.

20. The apparatus of claim 12, further comprising a controllable servo motor or rotary actuator interposed between the controllable electric motor and the housing, such that the direction of thrust of the controllable electric motor is able to be controllably rotated in a plane that is parallel to a plane formed by surface of the body of water, and wherein said controllable servo motor or rotary actuator is in communication with said controller such that the user is able to control the direction of the angle of thrust vector produced by the propeller by inputting commands into the user interface of the controller.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0033] The accompanying drawings, which are incorporated into and form a part of the specification, illustrate one or more embodiments of the present invention and, together with the description, serve to explain the principles of the invention. The drawings are only for the purpose of illustrating the preferred embodiments of the invention and are not to be construed as limiting the invention. In the drawings:

[0034] FIG. 1 depicts a perspective top view of a paddleboard having an embodiment of the invention removably attached thereto, showing the apparatus of the invention attached to a water facing surface of a paddleboard as it would be attached in normal operation.

[0035] FIG. 2 depicts a perspective bottom view of a paddleboard having an embodiment of the invention removably attached thereto, showing the apparatus of the invention attached to a water facing surface of a paddleboard as it would be attached in normal operation.

[0036] FIG. 3 depicts an exploded view of an embodiment of the invention as well as an exploded view of an exemplary embodiment of a paddleboard, fin and fin box.

[0037] FIG. 4 depicts a perspective view of an embodiment of the invention, assembled, from slightly above the invention. In this view, a paddleboard is not depicted, but a paddleboard fin and fin box are shown for reference.

[0038] FIG. 5 depicts a perspective view of an embodiment of the invention from above the invention. In this view the top plate is not depicted so that the structure of the housing is more clearly viewable.

[0039] FIG. 6 depicts an orthogonal rearview of an embodiment of the invention.

[0040] FIG. 7 depicts an exemplary block diagram of an embodiment of the invention.

[0041] In the figures, like callouts refer to like elements.

DETAILED DESCRIPTION OF THE INVENTION

[0042] The following documentation provides a detailed description of the invention.

[0043] As used herein, “paddleboard” includes within its meaning any structure that is adapted to be motivated along the surface of a body of water, and to accommodate a person so that the person may be disposed on the upward facing surface of the paddleboard while the paddleboard is being motivated along the surface of the body of water. Thus, “paddleboard” includes within its meaning standup paddleboards (SUPs), surfboards, and all other structures that are adapted to be motivated along the surface of a body of water such as, for example, kayaks and canoes. Such structures may comprise any type of material suitable for constructing a structure that is adapted to be motivated along the surface of a body of water such as for example fiberglass, roto-molded plastic, molded plastic, soft closed cell foam, drop-stitched materials, and other structural composite materials such as carbon fiber, wood, and any other material, in any combination. Also included within the definition of “paddleboard” are structures that include materials that in and of themselves may be of a higher density than that of water, that when used in combination with less dense materials including gasses such as air, result in a structure that has a density less than the density of water such that the structure is adapted to float on the surface of a body of water. Such structures may include, for example and not by way of limitation, hollow sections, or may include open sections that allow the structure to carry a mass, while still floating on the body of water by displacing an appropriate amount of water to account for the mass of the structure plus its load. Thus, included within the definition of “paddleboard” are structures such as a common boat structure.

[0044] As used herein, “fin box” includes within its meaning an elongated rectangular structure having an opening for receiving a fin. The fin box may be fixedly attached, or removably attached, to an underneath, i.e., water-facing, surface of the paddleboard. The elongated rectangular structure may be aligned along a lengthwise centerline, or longitudinal axis, of the paddleboard. The fin box may be attached to the paddleboard such that a fin inserted into and retained by the fin box provides directional control of the paddleboard in a direction aligned with a desired direction of travel of the paddleboard along the surface of a body of water; such desired direction is typically, but is not always, aligned with a centerline or longitudinal axis of the paddleboard. The fin box may be attached to and retained within a cavity disposed in an underneath, or water-facing, surface of the paddleboard; in other words, the surface of the paddleboard that is in contact with the surface of the water when the paddleboard is placed onto the surface of a body of water in normal operation in which a person may be disposed on an upward facing surface of the paddleboard. The fin box may be attached to the paddleboard by any means known in the art, such as, for example and not by way of limitation, chemical bonding such as using adhesives and two-part epoxies.

[0045] As used herein, the “water facing” surface of paddleboard is the surface of the paddleboard that, in normal use while paddling with a person disposed on an upward facing surface of the paddleboard, rests in the water in a substantially horizontal orientation, with the fin mounted in the fin box extending down into the water. I.e. the water facing surface of the paddleboard is the underneath surface, when the paddleboard is resting on the surface of a body of water and is oriented for normal use, with the fin extending down into the water.

[0046] As used herein, the “upward facing” surface of a paddleboard is the surface of the paddleboard upon which a person would be disposed while using the paddleboard in normal operation, i.e., while the water facing surface of paddleboard is disposed in the water in a substantially horizontal orientation, with the fin extending down into the water.

[0047] As used herein, “mobile device” includes within its meaning any electronic device that is usable in a handheld or wearable fashion by a user, typically having a processor in communication with a computer readable memory that has stored upon it non-transitory computer readable and executable instruction this is in communication with the processor; a user data output interface such as a visual display or speaker, or both, that is in communication with the processor; and a device for receiving user input such, for example, a soft keyboard, a touchscreen display, a mouse or external keyboard or microphone that is in communication with the processor. The mobile device processor may be in communication with a controller 1000 of the invention, which may be housed in the housing structure 108, or directly with the motor of the propulsion assembly, either wirelessly through, for example, radio frequency (RF) signals, or via electrical wiring, so that a user of the paddleboard is able to input commands into the mobile device that are then communicated to controller 1000 such that the user is able to control the motor as to speed of rotation, including stopping the motor completely, and to commend any other functions and features of the invention as described herein. Non-limiting examples of a mobile device are smart phones, smart watches, and electronic tablets. The computer readable memory may comprise non-transitory computer readable and executable instructions for carrying out the steps and functions of receiving input from a user, providing output to a user.

[0048] Referring now to FIG. 1, a perspective top view of an embodiment of a paddleboard 102 having an embodiment of the invention 200 attached to the water facing side of the paddleboard, is depicted. The invention 200 and the paddleboard 102 may form a system for motivating a person 100 along the surface of a body of water. In this view, optional strap 101 wraps around the paddleboard and passes through the paddleboard housing structure 108 (not shown in FIG. 1, but depicted in FIGS. 3-5), and may be used, in embodiments, to help secure the invention to the water facing side of the paddleboard 102. Strap 101 is optional. Fin 103 can be seen protruding from the water facing side of the paddleboard. The paddleboard may have a longitudinal axis 500 that runs lengthwise of paddleboard 102 along a centerline of paddleboard 102, along which the paddleboard tends to be motivated by paddling or by embodiments of the invention, as directed by fin 103.

[0049] Still referring to FIG. 1, the forward and reverse directions of propulsion are indicated.

[0050] Referring now to FIG. 2, a perspective bottom view of a paddleboard 102 having an embodiment of the invention 200 attached thereto, on the water facing side of the paddleboard, is depicted. In this view, optional strap 101 wraps around the paddleboard and passes through the paddleboard housing structure 108, and may be used, in embodiments, to help retain the paddleboard propulsion device 200 to the water facing side of the paddleboard. Strap 101 is optional. Fin 103 can be seen protruding from the water facing side of the paddleboard. The paddleboard may have a longitudinal axis 500, along which the paddleboard 102 tends to be motivated by paddling or by the thrust provided by embodiments of the invention. Removable cover 112 is shown for reference.

[0051] Referring now to FIG. 3, an exploded view of an embodiment of the paddleboard propulsion system 200 of the invention is depicted. Fin box 104 is shown in exploded fashion from paddleboard 102, however it is to be understood that fin box 104 is an integral part of paddleboard 102 and is received by and retained in an opening, or recess, 500 in paddleboard 102 and is a part of paddleboard 102. Thus, fin box 104, while it may be supplied in some instances with paddleboard propulsion system 200, is typically an integral part of a paddleboard 102 to which the paddleboard propulsion system 200 is attached. Paddleboard T-bolts 114 have elongate T-bolt heads that are able to slide lengthwise along receiving grooves 501 that are formed lengthwise in fin box 104. Paddleboard T-bolt heads 114 are retained in receiving grooves 501 in fin box 104 by operation of the elongate head of paddleboard T-bolts 114 being received by the lengthwise grooves 501 in fin box 104. Paddleboard T-bolts 114 may have a threaded male portion 502 extending outward from the water facing surface of paddleboard 102, and they are of sufficient length to extend through propulsion system plate 105 to be received by mating female threaded fasteners that are captured in paddleboard bolt retaining brackets 109 and 110. Thus, when paddleboard T-bolts 114 are tightened in their threaded engagement in in paddleboard bolt retaining brackets 109 and 110, the paddleboard propulsion system 200 is retained and pulled against paddleboard 102 water-facing surface. Paddleboard bolt retaining brackets 109 and 110 are able to slide lengthwise in housing structure 108 along a track that is parallel to the longitudinal axis 500 of paddleboard 102 such that they may be positioned to receive paddleboard T-bolts 114 at various distances between paddleboard T-bolts 114 so as to accommodate different lengths of fin boxes as well as accommodate fins 103 of various dimensions. The paddleboard propulsion system of the invention 200 is retained onto the water facing surface of paddleboard 102 by operation of paddleboard T-bolts 114 having elongate heads that retained in the lengthwise slots, or grooves, 501 of fin box 104, extending through paddleboard mounting plate 105, plate 106, through housing 108 and into a threaded engagement in receiving female threaded fastener structures that may be retained in paddleboard bolt retaining brackets 109 and 110, or may form part of nuts that are tightened down against a surface of retaining brackets 109 and 110. Optional strap 101 may further be used to retain the paddleboard propulsion system of the invention 200 onto the water facing surface of paddleboard 102 by extending around paddleboard 102 and having a portion thereof molded to fit the exterior dimensions and shape of paddleboard housing structure 108, or, alternatively, may pass through paddleboard housing structure 108, such that, when optional strap 101 is in place it snugly holds the paddleboard propulsion system 200 onto the water facing surface of paddleboard 102. Strap 101 is an optional feature and may not be present in all embodiments of the invention. Strap 101 may have an adjustable length that is adjustable so as to be tightened to snugly hold the paddleboard propulsion system 200 onto the water facing surface of paddleboard 102 by any means known in the art, such as, for example, cam-action tighteners. Alternatively, optional strap 101 may comprise an elastic material that is stretchable to allow propulsion system 200 to be assembled onto the water facing surface of paddleboard 102 as shown, and then, when released, optional strap 101 may, by its elastic nature, attempt to return to its un-stretched state, snugly holding paddleboard propulsion system 200 onto the water facing surface of paddleboard 102 by elastic forces.

[0052] Still referring to FIG. 3, propulsion system plate 105, plate 106, and housing structure 108 may comprise openings 504, 503, and 500 (opening 500 is not shown in FIG. 3 but is shown in FIG. 5), respectively, through which fin 103 is able to protrude, such that fin 103 may be mounted into fin box 104 with fin 103 extending away from the water facing side of paddleboard 102, through opening 504 in propulsion system plate 105, through opening 503 in plate 106, and through opening 500 in paddleboard housing structure 108, such that fin 103 extends into the water underneath paddleboard 102 to provide directional control of the paddleboard, as the fin would normally do when the paddleboard 102 is used without propulsion system 200 installed. Thus, in this manner, paddleboard propulsion system 200 may be installed onto a paddleboard 102 without requiring fin 103 to be removed from the paddleboard. This allows for easy installation and removal of propulsion system 200 as desired by a user.

[0053] Still referring to FIG. 3, battery or electronics, or both, 111 may be disposed in a cavity 506 formed in housing structure 108 which is enclosed by cover 112. In embodiments, cover 112 may be a watertight cover, but in alternate embodiments it is not necessary that cover 112 be a watertight cover. In embodiments, the cavity 506 may be made watertight by operation of watertight cover 112 and gasket 115, which may be an O-ring gasket that may seal the interface between housing structure 108 and plate 106. Battery or electronics, or both 111 may be electrically connected to additional batteries or electronics, or both 116, which may in turn be electrically connected to controllable electric motor/propeller 107. Controllable electric motor/propeller 107 may comprise a controllable electric motor attached, the controllable motor having a rotable shaft with a propeller attached thereto. The electrical connections of the invention may be accomplished by electrically conductive wiring and electrical connectors such as connector 119. The non-power connections of the invention, may, in embodiments, be wireless connection such as, but not necessarily radio frequency (RF) connections. Electrical connectors 118 may be watertight connectors and may be used to electrically connect propulsion system 200 to the electrical cable of a controller held, for example, by a user standing, sitting or kneeling on the upper surface of paddleboard 102 such that a user may control the speed of the paddleboard.

[0054] Still referring to FIG. 3, cover 112 may be removeably attached to paddleboard housing structure 108.

[0055] Still referring to FIG. 3, in embodiments, controllable electric motor/propeller 107 may be attached to housing structure 108 in an attachment that may be a controllable rotating attachment comprising an optional controllable servo motor or angular actuator 1008 allowing for the adjustment of the angle of the direction of thrust vector C produced by controllable electric motor/propeller 107 in a plane that is parallel to a plane formed by the surface of a body of water upon which the paddleboard 102 is disposed. The adjustment of thrust vector C may sweep a range of angles as depicted by arc A. Generally, thrust vector C produced by the rotating propeller of controllable electric motor/propeller 107 is directed in a rearward direction, propelling paddleboard 102 in a forward direction. However, in the embodiment that comprise a controllable rotating attachment between controllable electric motor/propeller 107 and housing structure 108, a user may adjust the direction of the thrust vector C over a range of angles A, allowing the user to apply thrust having a component transverse to paddleboard longitudinal axis 500. This may be useful for controlling the paddleboard in a turn, or offsetting currents in the body of water. Thus, controllable electric motor/propeller 107 may be attached to paddleboard housing structure 108 in a controllable, rotating attachment that allows a user to control the angle of the thrust vector relative to the paddleboard longitudinal axis 500.

[0056] Referring now to FIGS. 4 and 5, perspective views of an embodiment of a paddleboard propulsion system 200 is depicted standalone, in other words, not assembled onto a paddleboard 102. In FIG. 4, fin 103 and fin box 104 is depicted for reference in order to show its relationship to propulsion system plate 105. However, it is to be understood that normally fin box 104 forms an integral part of paddleboard 102. Optional strap 101 is shown for reference, as well as electrical wiring 118 which may be used to connect the battery and/or motor control and electronics contained within housing structure 108 to a controller to be held by the user. Paddleboard T-bolts 114 may be used to retain propulsion system 200 to the water facing surface of a paddleboard 102 as hereinbefore described. Electrical connector 119, which may be a watertight connector, is shown for reference. Housing structure 108 and optional strap 101 are shown for reference.

[0057] Referring now to FIG. 6, a rear view of an embodiment of propulsion system 200 is depicted. In embodiments, controllable electric motor/propeller 107 may be disposed underneath the water-facing side of a paddleboard 102 such that it provides a direction of thrust along axis 500 of paddleboard 102. The centerline of controllable electric motor/propeller 107, and the orientation of the directional control of fin 103, may be directed along paddleboard axis 500. Fin box 104, which normally is an integral part of paddleboard 102, is depicted for reference. Receiving grooves 501 in fin box 104, which receive and retain the elongate heads of paddleboard T-bolts 114, are shown for reference. Electrically conductive wiring 118 may be utilized to attach the controller electronics, battery, and electric motor 107 to a handheld controller to be held by a user standing, kneeling, or sitting on an upward facing surface of paddleboard 102.

[0058] In operation, a propulsion system 200 of the invention may be removably attached to a water facing surface of the paddleboard 102. The propulsion system 200 may be attached to the water facing surface of the paddleboard 200 without requiring removal of fin 103 from fin box 104. In typical use, a user may place a paddleboard 102 on a horizontal surface, such as the ground or a table, with the normally-upper-facing surface of paddleboard 102 facing downward. In other words, during assembly of the paddleboard propulsion system 200 onto a paddleboard 102, the paddleboard 102 may be flipped upside down such that fin 103 is protruding in an upward direction. A user may then motivate propulsion system 200 against the water facing surface of paddleboard 102, orienting propulsion system 200 such that fin 103 protrudes through fin-receiving openings 504, 504, and 500 in propulsion system plate 105, plate 106 and paddleboard propulsion system housing structure 108, respectively. A user may then slide paddleboard T-bolts 114 along their receiving slots in fin box 104 such that they align with mating holes for receiving them disposed in paddleboard retained brackets 109 and 110. Female threaded fasteners may then be tightened onto the male threaded portion 502 of paddleboard T-bolts 114, thereby attaching the paddleboard propulsion system 200 to the water facing surface of paddleboard 102 and a removable attachment.

[0059] If desired, optional elastic or length-adjustable strap 101 may be utilized to snugly fit around paddleboard 102 and pass through housing structure 108, further retaining paddleboard system 200 to the water facing side of paddleboard 102. Thus paddleboard system 200 may be removably attached to the water facing side of paddleboard 102. A user may then connect electrical wiring 118 to a handheld or wrist-worn controller 1002 to be held or worn by the user as the user sits, stands or kneels on an upper surface of paddleboard 102. The controller 1002 may comprise a user interface having, for example, buttons, switches or other user interface elements such that the user is able to input commands to controller 1002 for controlling the speed, and, in embodiments, the direction, of the paddleboard 102 along the body of water by controlling the amount and direction thrust produced by controllable electric motor/propeller 107. Controllable electric motor/propeller 107 may be controlled by the user inputting commands into the controller 1002 for controlling the speed of rotation of controllable electric motor/propeller 107 or the direction of spin of controllable electric motor/propeller 107 thus allowing forward or reverse operation, or both. Further, in embodiments, a user may control the angular direction of thrust of controllable electric motor/propeller 107 in a plane that is parallel to a plane formed by surface of the body of water by controlling the rotation of controllable electric motor/propeller 107 along arrow A, thus enabling angular rotation of a thrust vector of controllable electric motor/propeller 107 for providing thrust having a transverse component. In such embodiments, the rotation of controllable electric motor/propeller 107 along arc A, and thus the controlling of the angular direction of the thrust vector produced by controllable electric motor/propeller 107 may be enabled by a controllable servo motor, controllable rotary actuator or other device for rotating the motor/propeller along arrow A that may be a part of the attachment of controllable electric motor/propeller 107 to housing 108 or other structure or the propulsion system of the invention. A user may input commands for controlling the angle of thrust vector produced by controllable electric motor/propeller 107 by inputting commands into the controller 1002 user interface, whereupon the commands may be communicated 1002 to the controllable servo motor or rotary actuator for controlling the thrust vector angle. Alternatively, a user may input commands for controlling the angle of thrust vector produced by controllable electric motor/propeller 107 by inputting commands into the controller user interface, whereupon the commands may be communicated to processor 1000, which then communicates the commands to the controllable servo motor or rotary actuator for controlling the thrust vector angle.

[0060] In any of the embodiments, a user may control the paddleboard to be propelled in a forward or reverse direction by controlling direction of rotation of controllable electric motor/propeller 107 by inputting commands into the controller 1002 user interface.

[0061] Referring now to FIG. 7, in embodiments comprising a processor 1000, processor 1000 may be in wired or wireless communication 1006 with controller 1002, and commands input by the user into the controller 1002 may be communicated to processor 1000 by the controller. Processor 1000 may read and execute computer readable and computer executable instructions stored in physical storage media 1001, and then may communicate commands to controllable electric motor/propeller 107 and other system elements such as optional light sources 1005 or optional servo motor or rotary actuator 1008 as needed to carry out the functions of the invention described herein. Processor 1000 and physical storage media 1001 are optional, and need not be present in all embodiments.

[0062] Still referring to FIG. 7, in embodiments, controller 1002 may be in direct wired or wireless communication 1007 with controllable electric motor/propeller 107, and commands for controlling the speed of propeller rotation (thus controlling amount of thrust), and direction of propeller rotation, that are input into the user interface of controller 1002 are directly communicated to the controllable electric motor/propeller 107 such that the speed of propeller rotation, and direction of propeller rotation of the controllable electric motor/propeller 107 are controllable by a user as desired. Further, controller 1002 may be in direct wired or wireless communication 1007 with optional controllable lights 1005 and optional controllable servo motor or rotary actuator 1008 such that user commands for controlling angular direction of trust that are input into the user interface of controller 1002 may be directly communicated to optional controllable servo motor or rotary actuator 1008, and that user commands for controlling intensity of light sources 1005 that are input into the user interface of controller 1002 may be directly communicated to optional light sources 1005.

[0063] In embodiments, any battery forming a part of 111 or 116, or any battery comprising the system, may be removable or rechargeable, or both, and may be in electrical communication with each component of the invention that requires electrical power to operate.

[0064] In embodiments, the controller 1002 may be used by the user to control the speed of rotation, and, in embodiments, direction of rotation, of controllable electric motor/propeller 107, thus controlling the amount of thrust, and, in embodiments, the direction of thrust, applied to paddleboard 102. In embodiments, the controller may take the form of a wireless or wired wearable controller that is worn for example on the wrist of the user. In this embodiment, the wearable controller may comprise a wireless receiver/transmitter in communication with processor 1000 and a user interface, all comprising the wearable controller. The wearable controller user interface may be for example a touchscreen comprising soft switches, or it may be physical buttons or switches, or it may be a microphone in communication with a processor for recognizing audio commands for controlling the controllable elements of the invention as described herein. The receiver/transmitter of the wearable controller may be in wireless data communication with a compatible receiver/transmitter in communication with, or forming a part of, processor 1000. In this configuration, control of the amount thrust and, in embodiments, the direction of thrust of produced by controllable electric motor/propeller 107 may be accomplished wirelessly by a user inputting commands into the user interface of the wearable controller.

[0065] In embodiments, the propulsion system may comprise one or more controllable light sources 1005, such as, for example, Light Emitting Diodes (LEDs) disposed in the housing structure. The intensity of light, or color of light, or both, emitted by the light sources 1005 may be controllable by a user by inputting commands into the user interface of controller 1002 that are communicated directly to the controllable light sources wirelessly or in a wired fashion. In embodiments, the commands may be communicated by the controller to a processor 1000, which in turn communicates the commands for controlling the intensity of light, or color of light, or both, emitted by the light sources 1005 to the light sources. In such cases the light sources may be in communication with processor 1000. In embodiments, the light sources 1005 may be oriented so as to direct their radiated light energy away from the water-facing side of paddleboard 102 such that the water underneath paddleboard 102 is illuminated when the paddleboard is in normal use on a body of water. In embodiments the light sources 1005 may only be controllable user as to ON or OFF state. In embodiments, the intensity of the light radiated light sources 1005 may be controllable by the user.

[0066] In embodiments, any of the claimed features may be present, or may not be present, in any quantity and in any combination.

[0067] Although a detailed description as provided in the written description and drawings contains many specifics for the purposes of illustration, anyone of ordinary skill in the art will appreciate that many variations and alterations to the following details are within the scope of the invention. Accordingly, the following preferred embodiments of the invention are set forth without any loss of generality to, and without imposing limitations upon, the claimed invention. Thus the scope of the invention should be determined by the appended claims and their legal and structural equivalents, and not merely by the preferred examples or embodiments given.