Patent Grant
7150662
The present invention relates to docking systems, watercraft having docking systems installed thereon, and propulsion assemblies adaptable for use in watercraft docking systems.
A need exists for a more effective and versatile system for docking pontoon boats, large deck boats, deep “V” boats, amphibious airplanes, floatplanes, and other watercraft and for maneuvering such watercraft in tight situations. A need particularly exists for such a system which can be conveniently installed on existing watercraft, preferably without the need for making any significant structural modifications to the hull or pontoons of the watercraft, and which can be readily adapted for trolling or other operations. A need further exists for a system of this type wherein the system propulsion units can be conveniently moved out of the water to stowed positions such that they will not interfere with the operation of the primary propulsion system of the watercraft.
Pontoon boats and other watercraft commonly have large and/or high powered propulsion systems (e.g., outboard motors, inboard motors, or stern drive systems) which are well suited for travel in open water. However, such propulsion systems typically are not highly maneuverable at low speeds and/or in tight or congested locations. Consequently, they can be difficult to use when docking the watercraft, particularly in high traffic areas or under adverse conditions such as high winds or strong currents. As a result, docking the watercraft can require considerable time and several attempts and can present a significant risk for equipment damage or personal injury.
In U.S. Pat. No. 6,234,853, a system is provided which seeks to enhance the maneuverability of the primary propulsion system of a watercraft for docking operations. To employ the system of U.S. Pat. No. 6,234,853, the boat's primary propulsion system must consist of at least two rearward primary propulsion units attached to the transom of the watercraft. The two primary propulsion units can be outboard motors, inboard motors, or stern drive systems and must be operable in both forward and reverse. The system of U.S. Pat. No. 6,234,853 comprises an engine control unit which calculates thrust requirements for each of the primary propulsion units responsive to the operator's control commands and then controls and changes the speed, pitch, and/or direction of each of the primary propulsion units in accordance therewith.
Of greater interest to the present invention, other docking systems developed heretofore have not depended upon the primary propulsion unit(s) of the watercraft. Unfortunately, such docking systems typically (a) have required that the watercraft have a specially adapted hull, (b) have required the use of special docking motors which fit in the hull, and (c) have not been suitable for installation on an existing craft. For example, U.S. Pat. No. 6,142,841 discloses a docking system wherein a plurality of propeller assemblies must be installed, in stationary position, in flow passageways or other recesses formed in the hull. The stationary propeller assemblies are operated in a coordinated manner for docking and maneuvering the craft. The entire disclosure of U.S. Pat. No. 6,142,841 is incorporated herein by reference. In one embodiment, flow conduits perpendicular to the longitudinal centerline of the craft are formed through the hull across the fore and aft ends thereof. In another embodiment, the docking system comprises one lateral flow passage through the front of the hull and two angled flow passages which are formed through the aft portion of the hull. In a third embodiment, stationary propeller assemblies are installed in a pair of curved side recesses formed in the fore portion of the hull and in an opposing pair of curved side recesses formed in the aft portion of the hull.
U.S. Pat. No. 6,325,683 discloses a docking system wherein four stationary propeller assemblies are installed in angled passageways or angled recesses formed in either the hull or the pontoons of a watercraft. The entire disclosure of U.S. Pat. No. 6,325,683 is incorporated herein by reference. The system utilizes either a radio frequency remote-control or a keypad control which is connected by an electrical cable. In response to the user's commands, the control system coordinates the operation of the four stationary propeller assemblies such that they are actuated individually or in combination as necessary to move the watercraft in a desired direction and manner.
In contrast to the special stationary propulsion assemblies required by the docking systems developed heretofore, U.S. Pat. No. 5,892,338 discloses a common trolling motor comprising: a steering head having a fixed tube extending from the bottom thereof, a rotatable tube or other rotatable column having a proximal end which is received in the control head and a distal end which projects from the distal end of the fixed tube; an electric propulsion motor and propeller assembly secured on the distal end of the rotatable column; an electrical cable extending through the rotatable tube from the control head to the propulsion motor for operating and for controlling the speed of the motor; a steering motor and gear assembly provided in the control head for turning the rotatable column, and thereby also turning the propulsion motor and propeller assembly for steering the watercraft; and a mounting linkage which is attached to the upper portion of the boat for receiving and holding the fixed tube component of the trolling motor assembly. The entire disclosure of U.S. Pat. No. 5,892,338 is incorporated herein by reference. The mounting linkage can be pivoted upwardly for pulling the trolling motor assembly to a stowed position. The trolling motor can be operated by radio frequency remote control or by direct cable connection.
The radio frequency control described in U.S. Pat. No. 5,892,338 includes: a control pad having a plurality of actuatable switches and/or other controls thereon which the user can employ to operate the trolling motor; a radio frequency transmitter unit which is contained within the housing of the remote and which interfaces directly with the user controls; and a receiver unit which is contained within the control head of the trolling motor assembly and which interfaces, via electrical cable, with the propulsion motor electronics in the housing of the propulsion motor and propeller assembly. The transmitter unit contained within the remote control housing comprises a micro-controller, a radio frequency transmitter, conventional support hardware, and a battery. The radio frequency transmitter produces and transmits message packets, each including an address sequence unique to the transmitter and a data sequence corresponding to the user's control command. The radio frequency receiver unit includes a radio frequency receiver circuit, a micro-controller, and appropriate conventional support hardware. The receiver unit decodes the radio frequency commands from the transmitter and produces corresponding output signals effective for controlling the trolling motor assembly. The specific trolling motor assembly functions controlled or provided by the radio frequency system include: propulsion motor on/off; left steering; right steering; propulsion motor speed; constant on or momentary on; high-bypass; verification indicators; and status indicators.
Another radio frequency controller for a trolling motor is described in U.S. Pat. No. 5,859,517, the entire disclosure of which is incorporated herein by reference. U.S. Pat. No. 5,859,517 discloses a compact remote control device which can be placed on the user's finger or on a fishing pole.
U.S. Pat. No. 6,468,117 describes a foot pedal apparatus for controlling a trolling motor. The entire disclosure of U.S. Pat. No. 6,468,117 is incorporated herein by reference. The assembly comprises a foot pedal which is pivotably attached to a base using an offset hinge. The offset hinge includes a detent mechanism which releasably engages when the pedal is moved to a midpoint position. The midpoint position corresponds to a straight ahead steering position of the trolling motor. From the midpoint position, the user will typically push the heel portion of the pedal downward to make a right turn and will push the toe portion of the pedal downward to make a left turn.
The present invention satisfies the needs and addresses the problems discussed above. The present invention provides a highly maneuverable and versatile system for docking and other operations which can be installed on generally any existing pontoon boat or other craft and does not require any significant modification of the hull or pontoons thereof. The inventive system can be conveniently operated by wireless remote control and will allow even a relatively inexperienced pilot to quickly and safely maneuver and quickly dock the watercraft in congested areas and under adverse conditions.
The inventive docking system employs a plurality of propulsion assemblies which are mounted on the watercraft. If desired, these can be traditional trolling motor assemblies of the type described above. However, each of the propulsion assemblies will preferably be a novel propulsion assembly of a type provided by the present invention. The inventive propulsion assembly is similar to a traditional trolling motor in some respects but is particularly well suited for use in the inventive docking system and for other operations. The inventive propulsion assembly can be quickly attached or removed and can be conveniently moved to a stowed position such that it will not interfere with the normal operation of the craft. The inventive propulsion assembly preferably utilizes a plug and play type connection so that it can be activated or taken out of service as desired without affecting the operation of any of the remaining propulsion assemblies used in the inventive docking system.
In one aspect, there is provided an improved docking system for a watercraft operable on a body of water, the docking system including a plurality of propulsion assemblies which are operable in a coordinated manner effective for steering the watercraft. The improvement comprises (a) each of the propulsion assemblies comprising a steering column and a motor and propeller assembly on a distal end of the steering column and (b) each of the propulsion assemblies being removably mountable in an operating position such that the motor and propeller assembly and the distal end of the steering column will extend into the body of water and the steering column and the motor and propeller assembly can be turned for steering the watercraft.
In another aspect, there is provided an improved watercraft operable on a body of water and having a docking system including a plurality of propulsion assemblies which are operable in a coordinated manner effective for steering the watercraft. The improvement comprises: (a) each of the propulsion assemblies including a steering column and a motor and propeller assembly on a distal end of the steering column and (b) each of the propulsion assemblies having an operating position wherein the motor and propeller assembly and the distal end of the steering column will extend into the body of water and the steering column and the motor and propeller assembly can be rotated for steering the watercraft.
In another aspect, there is provided a propulsion assembly for a watercraft operable on a body of water comprising: a steering column; a motor and propeller assembly on a distal end of the steering column; a steering head, in which a proximal end of the steering column is received, for turning the steering column and the motor and propeller assembly; and a bracket attachable to the watercraft. The steering head is removably connectable to the bracket. The bracket preferably includes a keyhole slot for removably receiving a corresponding attachment member provided on the steering head.
Further aspects, features, and advantages of the present invention will be apparent to those of ordinary skill in the art upon examining the accompanying drawings and upon reading the following Detailed Description of the Preferred Embodiments.
An embodiment of the inventive docking system installed on a watercraft 1 is depicted in
The embodiment of the inventive docking system depicted in
Each of the propulsion assemblies 24 and 28 employed in the inventive docking system can generally be any type of traditional trolling motor assembly (such as, e.g., a trolling motor assembly of the type described in U.S. Pat. No. 5,892,338 or U.S. Pat. No. 6,468,117) having a motor and propeller assembly which can be turned in different directional orientations for steering the craft. However, each of the propulsion assemblies 24 and 28 is preferably an inventive propulsion assembly as shown in
As with a traditional trolling motor assembly of the type described in U.S. Pat. No. 5,892,338 or U.S. Pat. No. 6,468,117, the inventive propulsion assembly 24, 28 preferably comprises: a steering head 40; a fixed tube 42 extending downwardly from the bottom of steering head 40; a rotatable steering column 44 which extends through the fixed tube 42 and has an upper proximal end which is received in steering head 40 and a lower distal end 46 which projects from the bottom of the fixed tube 42; and a motor (preferably electric) and propeller assembly 48 secured on the distal end 46 of steering column 44. As used herein and in the claims, the term “propeller” includes propellers, impellers, and any similar type of rotating propulsion structure. The steering head 40 contains a steering motor and appropriate gear assembly for turning the steering column 44 and the motor and propeller assembly 48 in order to steer the watercraft. An electrical cable extends through the rotatable steering column 44 from the steering head 40 to the motor and propeller assembly 48 for activating and for controlling the speed of the propulsion motor.
Unlike a traditional trolling motor assembly, the steering head 40 of the inventive propulsion assembly 24, 28 is preferably configured and adapted for being directly attachable, preferably in a removable manner, to a mounting bracket 50 which can be installed at any convenient location on the watercraft 1. The mounting bracket 50 preferably comprises a mounting plate 52 for attachment to the deck 20 or other portion of the watercraft 1 and a motor plate 54 which extends from the mounting plate and is preferably configured for directly receiving and attaching the steering head 40 of the inventive propulsion assembly. The mounting plate 54 preferably includes a keyhole slot 56 for removably receiving and retaining a correspondingly shaped attachment member 58 which is provided on the exterior of the steering head 40. The attachment member 58 preferably comprises a cylindrical neck portion 60 having an enlarged, flat attachment head 62 on the outer end thereof. The attachment head 62 is sized and configured such that it can be removably inserted into the keyhole slot 56 and will operate to secure the steering head 40 to the motor plate 54 when turned to a rotated position in the keyhole slot 56 and/or when the neck 60 of the attachment member 58 is pushed downward into the narrow lower end 64 of keyhole slot 56.
After the attachment member 58 is positioned in the keyhole slot 56 such that the propulsion assembly 24, 28 is in a desired operating or stowed position, the steering head 40 of the propulsion assembly can be locked in place on the mounting bracket 50, using, for example, a removable ball detent push pin 65. The push pin 65 is inserted into a locking slot 66 formed by a corresponding pair of matching elongate grooves 68 and 69 formed, respectively, in the attachment face of steering head 40 and in the face of the mounting bracket motor plate 54. The elongate grooves 68 and 69 have interior indentations 71 or slots formed therein for removably receiving and retaining the detent ball(s) 73 of the push pin 65. A plurality of appropriately oriented grooves 68 and/or 69 are preferably provided in the steering head attachment face and/or the motor plate 54 for selectively locking the propulsion assembly 24, 28 in different rotated positions for operation and stowing.
As illustrated in
The steering head 40 of the inventive propulsion assembly preferably has a rectangular box shape. In addition, each of the four side faces of the box steering head 40 preferably has its own attachment member 58 projecting therefrom and corresponding locking groove(s) 68. The provision of appropriate mounting features on each side of the steering head 40 allows the inventive propulsion assembly to be mounted and used interchangeably at any desired fore, aft, port side, starboard side, or other position on the watercraft.
The embodiment of the inventive docking system illustrated in
As will be understood by those of ordinary skill in the art, the multi-motor connector 10 employed in the inventive docking system preferably employs simple parallel connections between the connectors such that the same amount of power from the power source 32 and the same control signals from the foot pedal control 3 and/or from the radio frequency remote control 13 are delivered to each of the individual propulsion assemblies 24, 28. The power and control signals are delivered by the electrical cables 12 simultaneously to each of the propulsion assembly steering heads 40 wherein the control signals are implemented in each of the respective propulsion assemblies 24, 28 such that the propulsion assemblies act in coordination with each other to perform the desired docking operation. The propulsion assemblies 24 and 28 will preferably be tuned to operate at equal propulsion speed but could be set to operate at different speeds if desired. It will also be apparent, however, that for steering the watercraft 1 to the right or to the left, the propulsion assembly or assemblies 24 at the front 26 of the craft and the propulsion assembly or assemblies at the back 30 of the craft will turn in opposite directions.
The cables 12 extending from the propulsion assembly steering heads 40 to the multi-motor connector 10 are preferably removably connected to the connector 10 using known plug and play or similar type connections. Consequently, any of the propulsion assemblies 24 or 28 used in the inventive docking system can be unplugged without affecting the operation of any of the other propulsion assemblies 24 or 28 which remain plugged in to the connector 10. As a result, for example, by simply having just one of the propulsion assemblies plugged in to the connector 10, the activated propulsion assembly can be operated and used in the same manner as a traditional trolling motor. The plug and play connections also facilitate the interchangeable use of the inventive propulsion assemblies at different locations and further allows each propulsion assembly to be conveniently removed for storage elsewhere.
The foot pedal control 3 employed in the inventive docking system can generally be any type of foot pedal control device used in the art. The foot pedal control device 3 will most preferably be an offset hinge pedal assembly of the type described in U.S. Pat. No. 6,468,117. As will be understood by those in the art, the foot pedal control 3 preferably includes: an on/off switch 4; a knurled wheel 7 for adjusting the operating speed of the propulsion assemblies 24 and 28; a power on or constant on switch 8 which operates to power up all of the propulsion assemblies 24 and 28; at least a pair of momentary on/off switches 6 which can be depressed for, e.g., activating or deactivating only one of the trolling assemblies 24 or 28 or for activating or deactivating all of the trolling assemblies on either the port side or the starboard side of the craft.
If the pilot desires to use only one motor to spin the boat, make minor adjustments in any direction, or make minor adjustments in speed, then either of the momentary on/off switches 6 can be depressed. If the constant on switch 8 is off, then depressing one of the momentary on/off switches 6 will activate the particular propulsion assembly or assemblies corresponding thereto. If the constant on switch 8 is on, depressing one of the momentary on/off switches will operate to stop the propulsion assembly or assemblies corresponding thereto. For safety purposes, it will preferably be necessary that the momentary on/off switch be quickly tapped twice in order to turn the motor(s) back on.
As described in U.S. Pat. No. 6,468,117, the foot pedal preferably has a centered position which corresponds to a straight ahead orientation of the boat and the foot pedal will preferably be capable of rotating 15° up and 15° down from the centered position (i.e., a combined arc range of 30°). As mentioned above, each of the propulsion motor and propeller assemblies will preferably be capable of rotating both 200° clockwise and 200° counterclockwise, totaling 400°. Consequently, there is a direct relationship between the foot pedal position and the propulsion assembly position wherein each 1° change in the position of the foot pedal produces a 13.33° change in the rotational position of each propulsion assembly 24 and 28.
Similar to the foot pedal control 3, the remote control device 13 employed in the inventive system preferably comprises: a right turn button 14; a left turn button 16; a prop speed increase button 15; a prop speed decrease button 18; and an on/off button 17. The radio frequency remote control operates in generally the same manner as the radio frequency control device described in U.S. Pat. No. 5,892,338 or in U.S. Pat. No. 5,859,517. For convenience, the remote control will preferably be in the form of a key fob device similar to those commonly used for automobile keyless entry systems. It will also be understood by those in the art that, although a radio frequency transmitter is preferred, the remote control could alternatively employ an infrared transmitter or any other type of wireless transmission system known in the art.
The control signals produced by both the foot pedal control 3 and the remote control 13 are each received by the receiver unit 11. As with the prior art foot pedal and remote control systems discussed above, the foot pedal 3 and the remote control 13 each transmit control signals comprising a transmission source identification sequence and a control data sequence. In the inventive system, the foot pedal 3 will preferably be the master control which will override the remote control 13 in the event that the user happens to operate both the foot pedal 3 and the remote control 13 simultaneously.
Thus, the present invention is well adapted to carry out the objects and attain the ends and advantages mentioned above as well as those inherent therein. While presently preferred embodiments have been described for purposes of this disclosure, numerous changes and modifications will be apparent to those skilled in the art. Such changes and modifications are encompassed within the spirit of this invention as defined by the appended claims.
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