Locking mechanism for an outboard motor

Information

  • Patent Grant
  • 6283806
  • Patent Number
    6,283,806
  • Date Filed
    Monday, May 22, 2000
    24 years ago
  • Date Issued
    Tuesday, September 4, 2001
    23 years ago
Abstract
A locking mechanism for an outboard motor is provided which prevents a moveable segment of the outboard motor from rotating about a steering axis relative to a stationary segment of the outboard motor. A slidable rod is disposed within a tilt tube of the outboard motor and is connected by a connecting link to the moveable segment of the outboard motor. If a locking device, such as a pin, is inserted through holes in the tilt tube and the rod, relative movement of the tilt tube and the rod can be prevented. If this relative movement is prevented, the moveable segment of the outboard motor is locked in position relative to the stationary segment of the outboard motor to which the tilt tube is attached.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention generally relates to a locking mechanism for an outboard motor and, more particularly, to a locking mechanism that includes a sliding rod within a tube in combination with a locking pin that prevents the rod from sliding within the tube and, since the rod is attached to a movable segment of the outboard motor, also prevents movement of the movable segment of the outboard motor relative to a stationary segment of the outboard motor or to the transom of a boat to which the outboard motor is attached.




2. Description of the Prior Art




Outboard motors are well known to those skilled in the art. Typically, outboard motors are provided with a bracket and at least one mechanism that allows the outboard to be tilted relative to its bracket and relative to the transom of a boat and also allows the outboard motor to be swiveled about a generally vertical centerline to allow steering of the boat.




Under certain circumstances, boat operators tilt the outboard motor up to a maximum position when the outboard motor is not in use. This situation can occur when the outboard motor is used as an auxiliary propulsion system, such as on sailboats or on boats powered by another outboard motor. Also, outboard motors are typically tilted to a maximum position when the boat operator is towing the boat on a trailer. During this type of operation, with the outboard motor tilted to its maximum upward position, the movable segment of the outboard motor, comprising the engine, cowl, driveshaft housing, and lower gearcase, can move to a rotated position relative to its steering axis and to a stationary segment of the outboard motor which comprises a bracket that is attachable to a transom of a boat. With the movable segment of the outboard motor turned to non central extreme position while tilted upward to a maximum position, shock loads can exert potentially damaging forces on various components of the outboard motor. For example, repeated shock loads can cause fatigue of certain support and structural members such as support brackets. These shock loads can either be caused by wave action if the boat is in operation on water or, alternatively, by undulations in a road surface if the boat is being transported on a trailer behind an automobile.




Various types of locking mechanisms are known to those skilled in the art. U.S. Pat. No. 5,868,591, which issued to Kleeman et al on Feb. 9, 1999, discloses a swivel lock for an outboard motor. First and second latch mechanisms are provided that allow a boat operator to prevent the movable and stationary portions of an outboard motor from moving relative to each other. This device can be used during shipping, transportation, or use of an outboard motor in conjunction with a sailboat in which the rudder of the sailboat is used for steering, and it is desirable to maintain the movable and stationary portions of an outboard motor rigidly with respect to each other. A first latch mechanism is attached to the movable portion of the outboard motor, and a second latch mechanism is attached to the stationary portion of an outboard motor. The second latch portion is rotatable to place a receptacle into a region where a locking device can retain it.




U.S. Pat. No. 4,863,505, which issued to Hervat et al on Sep. 5, 1989, describes an outboard motor tilt lock device. The marine propulsion device comprises a transom bracket adapted to be mounted on the transom of a boat and having a side and upper surface. It also comprises a swivel bracket mounted on the transom bracket for pivotal movement relative to the transom bracket about a generally horizontal tilt axis and between an operating position and a raised position. A tilt lock shaft has first and second ends extending through the swivel bracket along a second generally horizontal axis spaced rearwardly from and substantially parallel to the tilt axis. A lever member mounted on the shaft and including a contact pad extending parallel to and radially offset from the second axis and further including at least one leg extending substantially perpendicularly relative to the contact pad are also provided.




U.S. Pat. No. 5,582,527, which issues to Nakamura on Dec. 10, 1996, describes a steering system for an outboard motor. The steering device for the outboard motor retains the motor under constant, although adjustable, pressure to releasably hold it in a plurality of secured positions. Moreover, the releasable restraining device permits rotation of the motor about the tilt and trim axis while the retaining device is in any of a plurality of retained positions.




U.S. Pat. No. 5,328,394, which issued to Onoue et al on Jul. 12, 1994, described a steering system for a marine propulsion unit. A hydraulic assisted mechanism for marine propulsion drives wherein the hydraulic assist is operated by a control valve having its valve element actuated by a wire actuator that is operated by the steering mechanism. The actuating element that interconnects the wire actuator to the control valve element is supported for movement in a variety of embodiments so as to confine the movement in the same direction as the valve element.




U.S. Pat. No. 4,961,392, which issued to Ballard on Oct. 9, 1990, describes a self locking mechanical steering helm. The steering helm for a boat includes a worm gear set having a worm fixed on the steering wheel shaft and a worm gear clustered with a cable sprocket for controlling the movement of the steering which extends to the outdrive of the boat.




U.S. Pat. No. 3,808,851, which issued to Kargus et al on May 7, 1974, describes an outboard motor lock. The invention relates to an improved locking device for preventing the theft or accidental dislodgment during use of outboard motors. The device consists of a one piece slotted tubular member which is adapted to slide over and to engage and lock against member the heads of the clamp screws for the motor supporting bracket. This tubular member is provided with a series of aligned holes adapted to receive the shackle of a padlock or equivalent locking means in such manner that removal of the tubular member from locking engagement with the heads of the clamping screws is effectively prevented.




U.S. Pat. No. 4,521,201, which issued to Watanabe on Jun. 4, 1985, describes a steering device for an outboard motor. The steering device for an outboard motor releasably restrains the motor in a predetermined position which can be automatically released upon the exertion of more than a predetermined force to the motor to steer it in the event of an emergency. The releasable restraining device is also automatically engageably upon return of the motor to its first position and can be manually released.




U.S. Pat. No. 3,382,837, which issued to Aumack on May 14, 1968, describes an outboard motor steering control mechanism that relates generally to a device to maintain an outboard motor boat on a previously determined course and more particularly to such a device that adjustably and mechanically determines the positional relationship between the outboard motor steering rod and a boat carrying such motor.




U.S. Pat. No. 1,451,452, which issued to Williams on Apr. 10, 1923, describes a tiller lock. The tiller lock is usable in conjunction with an outboard motor.




U.S. Pat. No. 2,846,896, which issued to Allen on Aug. 12, 1958, describes an outboard motor steering stabilizer. The device is adapted to be utilized in conjunction with an outboard motor and more particularly to a device for holding the tiller in a selected position against movement of the tiller due to vibrations so that a fisherman or other user of the outboard engine need not tend the tiller but may be engaged in fishing or be occupied elsewhere.




U.S. Pat. No. 1,593,823, which issued to Gleason on Jul. 27, 1926, describes a tiller positioning device. The device is usable in conjunction with an outboard motor.




U.S. Pat. No. 4,372,241, which issued to Tritt on Feb. 8, 1983, describes a rudder assembly for sailboats and the like which comprises a rudder support frame pivotally attached to the stern portion of a boat, a substantially horizontal tiller fixedly attached to the upper portion of the rudder support frame, a rudder blade pivotally coupled to the rudder support frame, a rudder blade control mechanism including kickup control arm pivotally coupled to the upper portion of the rudder blade and an interconnecting kickup control member pivotally coupled between the kickup control arm and the substantially horizontal tiller to selectively move the rudder blade between a first or lower position and a second or upper position. The mechanism further includes a lock member fixedly attached to the kickup control arm disposedly to selectively engage the substantial horizontal tiller to lock the rudder blade in the lower or upper position.




The patents described above are hereby explicitly incorporated by reference in the description of the present invention.




In view of the prior art, it would be significantly beneficial if an outboard motor could be provided with a simple and generally inexpensive mechanism that allows the boat operator to lock the outboard in a preselected position, such as a central position.




SUMMARY OF THE INVENTION




A locking mechanism for an outboard motor made in accordance with the present invention comprises a tube, such as a tilt tube, attached to a stationary segment of the outboard motor, wherein the stationary segment is attachable to a transom of a boat. It also comprises a rod that is slidably disposed at least partially within the tube and a connecting link attached to the rod and to the moveable segment of the outboard motor, whereby movement of the movable segment relative to the stationary segment causes the rod to slide within the tube. A locking device, such as a pin, is disposable in contact with both the tube and the rod to prevent relative movement between the tube and the rod when the locking device is simultaneously in contact with both the tube and the rod.




The present invention can incorporate a tube which is the tilt tube of the outboard motor about which the moveable segment can pivot relative to the stationary segment. The connecting link can be attached to a swivel head of the moveable segment of the outboard motor. A ball and socket connector can be connected between the connecting link and the moveable segment of the outboard motor and the connecting link can be rotatable relative to the rod. This can be accomplished by a ball and socket device. The connecting link can also be rotatably connected to the moveable segment of the outboard motor. The precise connection mechanisms between the connecting link and either the rod or the moveable segment of the outboard motor can be of various designs that are appropriate to allow the required freedom of movement of the components relative to each other while maintaining the components in contact with each other.











BRIEF DESCRIPTION OF THE DRAWINGS




The present invention will be more fully and completely understood from a reading of the description of the preferred embodiment in conjunction with the drawings in which:





FIG. 1

shows a front view of an outboard motor incorporating the present invention;





FIG. 2

is an exploded view of certain selected components of an outboard motor showing the relative positions of the outboard motor components and the present invention; and





FIG. 3

is another exploded view of selected components of an outboard motor showing relative positions between those components and components of the present invention.











DESCRIPTION OF THE PREFERRED EMBODIMENT





FIG. 1

shows a preferred embodiment of the present invention associated with an outboard motor. Screw clamps


10


are supported by clamp brackets


12


which is rigidly attached to a tilt tube


14


. The rotatable connection between a moveable segment


20


of the outboard motor and a stationary segment to which the clamp brackets


12


are attached allows the moveable segment


20


to rotate about axis


22


and tilt the moveable segment upward. This allows the moveable segment


20


to rotate relative to both the stationary segment of the outboard motor and the transom


24


of a boat to which the outboard motor is attached. A lifting handle


28


is attached to the moveable segment


20


of the outboard motor by two bolts identified by reference numerals


30


. The configuration described immediately above is well known to those skilled in the art.




With continued reference to

FIG. 1

, it can be seen that a rod


40


is inserted into the tilt tube


14


and, as indicated by arrow


42


, is slideably within the central opening of the tilt tube


14


in a direction along the central axis of the tilt tube. The moveable segment


20


of the outboard motor is rotatable about steering axis


46


. A connecting link


50


is attached to the rod


40


and to the moveable segment


20


of the outboard motor. More specifically, a first end


51


of the connecting link is attached to a bracket


54


that is bolted to the handle by bolts


30


. A hole extending through a portion of the bracket


54


allows the first end


51


of the connecting link


50


to be rotatably attached to the bracket


54


by a bolt or rivet, as shown. The second end


58


of the connecting link


50


is attachable to the rod


40


through a hole formed through the rod. In certain embodiments of the present invention, the second end


58


of the connecting link


50


can be threaded to receive a bolt


60


which retains the relationship between the connecting link


50


and the rod


40


.




It can be seen that rotation of the moveable segment


20


about steering axis


46


will cause the bracket


54


to move with the moveable segment


20


. This, in turn, causes the first end


51


of the connecting link


50


to move with the bracket


54


and the moveable segment


20


. As a result, the second end


58


of the connecting link


50


also moves since it is attached to rod


40


. This causes the rod


40


to move relative to the tilt tube


14


and slide relative to the tilt tube


14


. The relative connections between the connecting link


50


and both the bracket


54


and the rod


40


can be of various types. For example, in

FIG. 1

, the first end


51


is attached to the bracket


54


by the simple rivet or bolt. This allows relative pivoting of the first end


51


relative to the bracket


54


about the vertical axis in FIG.


1


. Similarly, the insertion of the second end


58


through a hole in the rod


40


, as shown in

FIG. 1

, allows a simple rotation of the second end


58


relative to the rod


40


as represented by axis


70


. It should be understood that the first and second ends of the connecting link


50


can be attached to their respective associated components in alternative manners, such as with a ball and socket arrangement that allows additional freedom of movement of these components relative to each other.




With continued reference to

FIG. 1

it can be seen that a hole


80


is formed radially through the tilt tube


14


at a preselected location. Similarly, a hole is formed through rod


40


. This hole in rod


40


is not shown in

FIG. 1

, but will be described in greater detail below. When the hole in rod


40


is aligned with the hole


80


in the tilt tube


14


, a pin


84


can be inserted through both holes. The pin


84


shown in

FIG. 1

is provided with a tether


86


that has a end loop


88


. After the pin


84


, which operates as a locking device, is inserted into hole


80


and through the hole in rod


40


, the end loop


88


can be attached around the inserted end of the pin


84


to retain the pin in position. It should be understood by those skilled in the art that many different mechanisms can be used to retain the pin


84


in its position through hole


80


and through the hole in the rod


40


. When pin


84


is inserted through the two aligned holes in the tube


14


and the rod


40


, relative sliding movement between the rod


40


and the tilt tube is prevented. Because of the connection of the connecting link


50


between rod


40


and bracket


54


, rotation of the moveable segment


20


is prevented as long as the pin


84


remains in its position relative to the hole


80


and the hole through the rod


40


. This locks the moveable segment


20


of the outboard motor in its central position and prevents rotation of the moveable segment


20


about steering axis


46


.





FIG. 2

is an exploded view of certain relevant parts of an outboard motor showing the relative positions of the components and the elements of the present invention. A rotatable tube


100


is insertable into a stationary tube


102


to allow the moveable segment of the outboard motor to pivot about its steering axis


46


. The bracket


54


is attachable to the rotatable component


110


by the bolts


30


described above in conjunction with FIG.


1


. Clamp brackets


12


are attachable to the transom


24


of a boat and are part of the stationary segment of the outboard motor. Axis


112


is aligned with axis


113


to allow the segment identified by reference numeral


116


to be disposed between the clamp brackets with the tilt tube


14


aligned with axis


113


. The first end


51


of the connecting link


50


is attached to the bracket


54


by providing a connector through the hole (e.g.) a bolt, rivet, or ball) in the first end


51


and the hole


120


in bracket


54


. This allows the connecting link


50


to remain attached to the bracket


54


, but be pivotable about axis


130


. The second end


58


of the connecting link


50


is attached to the rod


40


which is, in turn, inserted through the central opening of the tilt tube


14


. The second end


58


of the connecting link


50


can be inserted through a hole


134


in the rod


40


to allow relative rotation between the connecting link and the rod


40


while maintaining contact between these two components. A hole


150


is formed through the rod


40


and is alignable with hole


80


in tilt tube


14


when the rod


40


is inserted into the tilt tube


14


and the moveable segment is centered relative to the stationary segment. Alignment between holes


80


and


150


allows the pin


84


to be inserted through the tilt tube


14


and the rod


40


to lock these two components together and prevent further sliding of the rod


40


within the tilt tube


14


. This, in turn, prevents further rotation of the tube


100


and its rotatable component


110


about the steering axis


46


.





FIG. 3

shows an exploded view of an alternative embodiment of the present invention that is only slightly changed in comparison to the embodiments described above in conjunction with

FIGS. 1 and 2

. Although shaped slightly differently, the clamp brackets


12


and the rotatable tube


100


function in a manner similar to that described above. The bracket


54


is attachable to the rotatable component


110


by providing bolts extending through the holes in the bracket and through the holes identified by reference numeral


172


. The bracket


54


is slightly rotated from its position in FIG.


3


and attached to the rotatable member


110


by those bolts through holes


172


and the first end


51


of the connecting link


50


is attached to hole


120


in bracket


54


. A socket component


184


provides certain additional freedom of movement of the connecting link


50


relative to the bracket


54


, but the basic function of the first end


54


is to maintain contact between the bracket


54


and the connecting link


50


with sufficient freedom of movement to allow the moveable segment


20


of the outboard motor to pivot about the steering axis


46


when the pin


84


is not inserted through holes


80


and


150


. The second end


58


is threaded to receive the nut


60


after the threaded end is inserted through hole


134


in rod


40


. This provides the connection between the rod


40


and the rotatable component


110


by the connecting link


50


. The second end


58


of the connecting link


50


is rotatable within hole


134


to allow the necessary freedom of movement of the moveable segment


20


of the outboard motor when pin


84


is not extended through holes


80


and


150


. As in the embodiments described above, rod


40


is slidable within tilt tube


14


and hole


150


is alignable with hole


80


when the moveable segment of the outboard motor is in its central position.




It should be understood that the embodiments shown in

FIGS. 2 and 3

are functionally identical, but implore certain components that are distinctly different from each other. As an example, the connecting link


50


in

FIG. 2

is shaped differently than the connecting link


50


in FIG.


3


. This difference is a function of the particular style and model of outboard motor for which they are to be used. In addition, the brackets


54


in

FIGS. 2 and 3

are shaped differently and are attached to the rotatable member


110


in a slightly different manner. This difference is provided to accommodate slightly different designs of rotatable members


110


that are used in different outboard motor designs. Described functionally, the connecting link


50


serves the function of coordinating the movement of the rod


40


to the rotation of the moveable segment


20


. In other words, rotation of the moveable segment about its steering axis


46


causes an associated sliding movement of the rod


40


within the tilt tube


14


. These movements are coordinated with each other because of the attachment of the connecting link


50


to both the rod


40


and the moveable segment


20


. In this way, the presence of the locking device or pin


84


through holes


80


and


150


not only prevents the sliding movement of rod


40


in tilt tube


14


but, more importantly, prevents further rotation of the moveable segment


20


about its steering axis


46


.




One of the most advantages of the present invention, in addition to fixing the position of the moveable segment


20


about its steering axis


46


to prevent damage as described above, is the simplicity of the apparatus. The bracket


54


, the tilt tube


14


, and the connecting link


50


are all standard components that are presently available in commercial quantities from various manufacturers of outboard motor, such as the Mercury Marine division of Brunswick Corporation. The connecting link


50


and its associated hardware are used in remote steering applications in which the outboard motor is steered from a position other than close to the position of the outboard motor at the transom of a boat. The rod


40


is custom made for the present invention, but is similar to the end of a steering actuator used in other applications. As a result, most of the individual components necessary to provide the advantages of the present invention are already commercially available. The provisions of holes,


80


and


150


, and the pin


84


allow an effective locking mechanism to be provided when combined with the commercially available connecting link


50


and bracket


54


in combination with the custom rod


40


. As a result, a locking mechanism can be provided for virtually any style of outboard motor by simply incorporating the connecting link


50


and bracket


54


that would normally be used to provide a remote steering application for that style of outboard motor and providing a custom rod


40


that is equivalent to the end segment of a steering actuator rod that would be used if a remote steering application is provided for that style of outboard motor.




In all of the embodiments of the present invention, a rod


40


is slidably disposed at least partially within tube


14


and a connecting link


50


is attached to the rod


40


and to the moveable segment


20


of the outboard motor. This connection, because of the configuration of the first and second ends,


51


and


58


, of the connecting link


50


, allows the moveable segment


20


of the outboard motor to rotate about its steering axis


46


. A locking device, such as pin


84


, is disposable in contact with both the tube


14


and rod


40


to prevent relative movement between the tube


14


and the rod


40


when the locking device


84


is simultaneously in contact with both the rod


40


and tube


14


. This is accomplished by inserted pin


84


through holes


80


and


150


simultaneously. In order to implement the concepts of the present invention, very few additional parts are needed to adapt the outboard motor for these purposes. The tilt tube


14


is a standard part of the outboard motor as are the other components in

FIGS. 2 and 3

except the rod


40


, connecting link


50


, and pin


84


. If a hole


80


is provided in the tilt tube


14


and a hole


150


is provided in the rod


40


, the advantages of the present invention can be realized.




Although the present invention has been described with particular specificity and illustrated to show a preferred embodiment, it should be understood that alternative embodiments are also within its scope.



Claims
  • 1. A locking mechanism for an outboard motor having stationary and movable segments, comprising:a tube attached to said stationary segment of said outboard motor, said stationary segment being attachable to a transom of a boat; a rod slidably disposed at least partially within said tube; a connecting link attached to said rod and is attached to said movable segment of said outboard motor by a rotatable connector which allows relative rotation to occur between said connecting link and said movable segment of said outboard motor, whereby movement of said movable segment relative to said stationary segment causes said rod to slide within said tube; a locking device being disposable in contact with both said tube and said rod to prevent relative movement between said tube and said rod when said locking device is simultaneously in contact with both said tube and said rod.
  • 2. The mechanism of claim 1, wherein:said tube is a tilt tube of said outboard motor.
  • 3. The mechanism of claim 1, wherein:said connecting link is attached to a swivel head of said movable segment of said outboard motor.
  • 4. The mechanism of claim 1, wherein:said rotatable connector is a ball and socket connector between said connecting link and said movable segment of said outboard motor.
  • 5. The mechanism of claim 1, wherein:said connecting link is rotatably connected to said rod.
  • 6. A locking mechanism for an outboard motor having stationary and movable segments, comprising:a tube rigidly attached to a transom of a boat, said stationary segment of said outboard motor being attachable to said transom of said boat; a rod slidably disposed at least partially within said tube; a connecting link attached to said rod and is attached to said movable segment of said outboard motor by a rotatable connector which allows relative rotation to occur between said connecting link and said movable segment of said outboard motor, whereby movement of said movable segment relative to said stationary segment causes said rod to slide within said tube; a locking device being disposable in contact with both said tube and said rod to prevent relative movement between said tube and said rod when said locking device is simultaneously in contact with both said tube and said rod.
  • 7. The mechanism of claim 6, wherein:said tube is directly attached to said stationary segment of said outboard motor.
  • 8. The mechanism of claim 7, wherein:said tube is a tilt tube of said outboard motor.
  • 9. The mechanism of claim 8, wherein:said connecting link is attached to a swivel head of said movable segment of said outboard motor.
  • 10. The mechanism of claim 9, further comprising, wherein:said rotatable connector is a ball and socket connector between said connecting link and said movable segment of said outboard motor.
  • 11. The mechanism of claim 9, wherein:said connecting link is rotatably connected to said rod.
  • 12. A locking mechanism for an outboard motor having stationary and movable segments, comprising:a tube rigidly attached to a transom of a boat, said stationary segment of said outboard motor being attachable to said transom of said boat, said tube being directly attached to said stationary segment of said outboard motor, said tube being a tilt tube of said outboard motor; a rod slidably disposed at least partially within said tube; a connecting link attached to said rod and is attached to said movable segment of said outboard motor by a rotatable connector which allows relative rotation to occur between said connecting link and said movable segment of said outboard motor, whereby movement of said movable segment relative to said stationary segment causes said rod to slide within said tube; a locking device being disposable in contact with both said tube and said rod to prevent relative movement between said tube and said rod when said locking device is simultaneously in contact with both said tube and said rod.
  • 13. The mechanism of claim 12, wherein:said connecting link is attached to a swivel head of said movable segment of said outboard motor.
  • 14. The mechanism of claim 12, wherein:said rotatable connector is a ball and socket connector between said connecting link and said movable segment of said outboard motor.
  • 15. The mechanism of claim 14, wherein:said connecting link is rotatably connected to said rod.
  • 16. The mechanism of claim 15, wherein:said connecting link is rotatably connected to said movable segment of said outboard motor.
US Referenced Citations (14)
Number Name Date Kind
1451452 Williams Apr 1923
1593823 Gleason Jul 1926
2846896 Allen Aug 1958
3382837 Aumack May 1968
3808851 Karqus et al. May 1974
4372241 Tritt Feb 1983
4521201 Watanabe Jun 1985
4863405 Hervat et al. Sep 1989
4961392 Ballard Oct 1990
5240211 Anderson Aug 1993
5328394 Onoue et al. Jul 1994
5582527 Nakamura Dec 1996
5868591 Kleeman et al. Feb 1999
6045188 Schooler Apr 2000