Stern drive and outboard locks

Information

  • Patent Grant
  • 6322308
  • Patent Number
    6,322,308
  • Date Filed
    Wednesday, July 26, 2000
    24 years ago
  • Date Issued
    Tuesday, November 27, 2001
    23 years ago
Abstract
A locking device for securing outboard motors and stern drives mounted on a plurality of exposed studs on the stern of a boat, and construction equipment on a plurality of exposed studs inset in concrete or other media. The invention consists of a stainless steel lock nut, a lock body, and a lock assembly having a lock catch.
Description




BACKGROUND OF THE INVENTION:




1. Field of the Invention




This invention relates generally to locking devices and more particularly to a locking system for securing outboard motors, stern drives, construction equipment, building equipment, trucking equipment, or commercial and residential premises against theft or intrusion.




2. Description of the Prior Art




The marine industry is experiencing an escalation in the number of thefts of stern drives and outboard motors from boats stored in marinas or private docks or wherever a thief may have occasion to work undetected for a brief period. As motors and stern drives become more sophisticated and thus more expensive, the market for stolen units is increasing. It takes only minutes for a thief using battery powered tools, to release a motor or stern drive and remove it Besides the inconvenience of replacing the stolen motor, filing an insurance claim is time consuming and increases the cost of premiums.




Locking means for out board motors and stern drives that are commonly available, are only a minor deterrent to theft. Thieves can defeat such systems in a variety of ways, mostly by either gripping said lock with special tools to unthread the lock or by simply cutting a face into its surface making it accessible to normal wrenches. Most locking devices now available, rely upon a special keys or tools for installation and removal, and while such tools are meant only for legitimate access, thieves can simply obtain sets of said tools or keys for their own use. Construction equipment is often secured by simply hoisting it in the air beyond the reach of thieves, this is possible only with an available crane. Truckers secure rear roll doors with a variety of standard padlocks. Such locks are subject to removal by cutting with bolt cutters as are security gates or any other protective system which utilizes them.




Thus, an object of the instant invention is to provide the boat owner, homeowner, trucker, construction company for example with a means of securing an out board motor, stern drive, propeller, trucking container or perimeter gate for example, using a unique combination of simple components which, when used together provide a secure and tamper-proof attachment means.




SUMMARY OF THE INVENTION




The essence of the instant invention is the use of very tough (304 stainless) components which attach to the normal mounting bolts of a stern drive, outboard, or other equipment as described herein and are locked together to form a secure, difficult to remove, attachment unit. Removal of said attachment unit is only necessary in the case of marine engines when a motor is changed or, in the case of a stern drive, whenever work has to be done on the drive shaft or upper gear system, all other service can be accomplished with either unit in situ. The instant invention in each of its embodiments can be installed using simply a socket or wrench and a small hammer to tap locking pins in place (when required). Any moderately skilled individual can easily install the lock. The instant invention, in its “keyless” embodiment, once assembled on the mounting studs of the stern drive or outboard motor, can only be removed by destroying the lock with the appropriate shop tools, such as, for example, a diamond edged saw. By reason of its construction from 304 work-hardened stainless, and the fact that over 1.25 inches of the steel must be cut to effect its removal and that the removal must be done in a special sequence of cuts, the time thus involved is sufficient to deter a thief from taking the motor or stern drive. The instant invention in its “keyed” embodiments uses the same 304 stainless for its main components but is secured to the stern drive, outboard, construction, residential or trucking equipment by a pin, tumbler or other design of keyed lock.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a side view of the top section of a typical out drive unit with the invention shown installed in accordance with the invention.





FIG. 2

is an exploded side view of the locking device showing the component parts in accordance with the invention.





FIG. 3

is a top view of the assembled device showing the locking pins.





FIG. 4

is a side view partly in section showing the internal features of the device as they appear when assembled.





FIGS. 5-10

are a series of side views of a typical out drive showing in sequence, the assembly procedure of the instant invention.





FIG. 11

is an exploded side view of the locking device showing the component parts in accordance with the invention.





FIG. 12

is side view of the locking device showing the component parts assembled and mounted to a typical outboard motor mount assembly in accordance with the invention.





FIG. 13

is an isometric exploded view in section showing a further embodiment of the invention.





FIG. 14



a


is a side exploded view in section showing a further embodiment of the invention.





FIG. 14

is a side view in section showing a further embodiment of the invention assembled in accordance with the invention.





FIG. 15

is a side view in section showing a further embodiment of the invention assembled in accordance with the invention and mounted to a typical outboard mount assembly.





FIG. 16

is a side view in section showing a further embodiment of the invention assembled in accordance with the invention and mounted to a typical outboard mount assembly.





FIG. 17

is a side view in section showing a further embodiment of the invention assembled in accordance with the invention and mounted to a typical stern drive assembly.





FIG. 18

is an exploded side view in section showing a further embodiment of the invention assembled in accordance with the invention.





FIGS. 18



a


and


18




b


are top views of the same embodiment shown in FIG.


18


.





FIG. 19

is a side view in section showing a further embodiment of the invention assembled in accordance with the invention and mounted to a typical assembly wherein two plates are bolted together.





FIG. 20

is a side view showing a further embodiment of the invention assembled in accordance with the invention and mounted to a typical stern drive assembly.





FIG. 21

is a side view showing a further embodiment of the invention assembled in accordance with the invention and mounted to a typical outboard mount assembly.











DESCRIPTION OF A FIRST EMBODIMENT




Referring now to the drawings wherein like numerals designate like and corresponding parts throughout the several views, numerals


10


(

FIGS. 1

,


12


),


145


(

FIG. 16

) and


245


(

FIG. 21

) generally designate the locking device assemblies of the invention. In

FIG. 1

the overall locking device assembly is fitted to out drive


60


and motor body


61


.




In

FIG. 2

, the component parts of the locking assembly are shown in an exploded view with the entire assembly designated by numeral


11


. The lock


10


consists of two, one inch diameter,


304


work-hardened stainless steel lock nuts


12


and


15


with through hole


21


(lock


15


) drilled at 90° to a center line drawn through the lock nut


15


, and blind hole


20


(lock


12


) drilled at 90° to a center line drawn through the lock nut


12


, ¾ Hex heads


30


and


31


, a ½ inch diameter, 304 work-hardened stainless steel pin


14


, a ⅝ inch diameter 304 work-hardened stainless steel sleeve


13


and two tempered steel roll pins


40


and


40


′ (FIG.


3


).

FIG. 2

shows detailed drawings of pin


14


having two ⅛ inch wide grooves


16


and


17


formed near each end. Sleeve


13


has an outside diameter of ⅝ inches and an inside diameter of ½ inch.

FIG. 3

is a top view partially in section of the assembled lock


10


showing steel pins


40


and


40


′ prior to their installation through blind hole


18


drilled in lock


12


, at 90° to the center line and intersecting blind hole


20


with one half of the hole


18


passing through hole


20


, and blind hole


19


drilled in lock


15


, at 90° to the center line and intersecting through hole


21


drilled in lock


15


(FIG.


2


).





FIG. 4

is a side view, partially in section, of the assembled lock showing {fraction (7/16)} inch threaded holes


22


and


22


′ which are screwed into exposed studs


51


and


52


. Pin


14


is held in position within holes


20


and


21


and is secured by lock pins


40


and


40


′ which engage grooves


16


and


17


.





FIG. 5

is the first of the series of illustrations of the assembly sequence of the lock, wherein lock nuts


50


and


52


are removed. Stud


51


is now exposed ready for the mounting of the locking assembly


10


.





FIG. 6

shows the exposed stud


51


and


51


′ and nut


60


being offered up for threading onto the stud


51


′. Spacer/shim


23


is interposed between the face of nut


12


and the face of out drive


60


the shim


23


allows nut


60


to be tightened while keeping its hole


20


in the correct vertical plane for the later installation of pin


14


. Blue dot


60


on the dorsal surface of nut


12


is used as a reference point to show the user which way the nut


12


should be positioned. In

FIG. 7

both locks


12


and


15


are in position with their through holes,


20


and


21


respectively, lined up ready to receive sleeve


13


.





FIG. 8

shows sleeve


13


in position ready for pin


14


positioned for fitment and locking pills


40


′ and


40


are ready to be inserted as a final step.





FIG. 9

shows pin


14


positioned for fitment and locking pins


40


′ and


40


ready to be inserted as a final step.





FIG. 10

is a view partially in section showing the lock assembly in position. From this view it is possible to visualize the difficulty that would be encountered in removing said assembly, nuts


12


and


15


cannot be unthreaded because pin


14


prevents their rotation. Locking pins


40


and


40


′ prevent the removal of pin


14


. Sleeve


13


is rotatably attached to pin


14


and any effort to cut it is thwarted by its tendency to spin on pin


14


, Similarly, pin


14


cannot be cut or drilled easily because it too can spin away from a cutting device. In actual removal, sleeve


13


is clamped and slit down its length using a


2


inch diameter diamond wheel. A larger wheel cannot get in to reach sleeve


13


because it hits on nuts


12


or


15


. The sleeve


13


is then rotated


180


degrees and clamped again and slit lengthwise to remove it from pin


14


. Pin


14


is then clamped and cut close to nut


12


, clamped again and cut close to nut


15


. Nuts


12


and


15


can now be unthreaded.




Description of a Second Embodiment




In

FIG. 11

, the component parts of the locking assembly are shown in an exploded view with the entire assembly designated by numeral


11


and


304


stainless coach bolts


151


are in position awaiting installation of locking assembly


11


.




In

FIG. 12

, locking assembly


10


is shown clamping together using coach bolts


151


, transom


161


and outboard mount


160


. Coach bolt head


152


is pulled tightly against transom


161


simultaneously securing outboard mount


160


to transom


161


allowing no removal access to coach bolt


151


.




Description of a Third Embodiment




FIG.


13


. shows lock pin


131


in position ready to enter lock body


141


. Coach bolt


151


is in position ready to be screwed into internal thread


122


. Face


115


is located at the end of lock pin


131


at the opposite end to groove


117


so as to avoid during assembly, its interference with lock catch


142


on lock assembly


140


. Face


115


and its adjacent faces permit the use of a wrench to tighten together lock pin


131


and coach bolt


151


. Lock body


141


consists of ends


147


,


148


, holes


143


,


144


and gap


144




a.







FIG. 14

shows how the components shown in

FIG. 14



a


are assembled to form lock assembly


145


. Lock catch


142


, once snapped in position inside groove


117


prevents coach bolt


151


from being unscrewed. Once assembled, lock assembly


145


can spin freely around the axis of coach bolt


151


by reason of groove


117


which prevents longitudinal movement, and thus removal, of the assembly. Once assembled in position as shown, lock assembly


145


is only removable by using key


146


of lock assembly


145


to depress lock catch


142


.





FIG. 15

shows a typical use of lock assembly


145


in securing outboard mounting components


200


from being separated without the lock assembly being removed.





FIG. 16

shows a typical use of lock assembly


145


in securing outboard mounting components


200


from being separated without the lock assembly being removed. In this instance, lock assembly


145


has been fitted on top of lock nut


153


to prevent its removal.





FIG. 17

shows a typical use of lock assembly


145


preventing out drive


60


and motor body


61


from being separated without the lock assembly being removed. In this view, lock nut


50


has been replaced by lock assembly


145


.




Description of a Fourth Embodiment





FIG. 18

shows lock pin


215


in place to slide inside cover


216


. Lock pin


215


is threaded internally with thread


222


. Groove


217


is positioned so that it will align with hole


218


once cover


216


is slid into position over lock pin


215


.





FIGS. 18



a


shows from a top view, cover


216


with hole


218


shown in broken section. Carbide core


220


is in position ready to be tapped inside roll pin


219


which in turn is in position ready to be tapped into hole


218


.

FIG. 18



b


shows a top view of lock pin


215


showing groove


217


and square section


231


.





FIG. 19

shows lock assembly


245


in position to secure together plates


260


and


261


. Cover


216


has been slid over lock pin


215


and carbide core


220


and roll pin


219


have been fitted. Groove


217


aligns with roll pin


219


preventing cover


216


from being removed longitudinally while allowing it to revolve around its axis. Once assembled in this fashion, lock assembly


245


prevents the removal or separation of threaded components secured by thread


222


and which abut cover


216


and lock pin


215


. Cover


216


can be removed only by cutting it through with an abrasive cutting wheel to remove roll pin


219


and carbide core


220


. Neither roll pin


219


or carbide core


220


can be removed by drilling and cannot be punched through as hole


218


in cover


216


is blind. Cover


216


cannot be removed by rotating it as it simply spins around its axis and lock pin


215


cannot be unscrewed because there is no access to it once cover


216


is pinned in place. Cover


216


and lock pin


215


are made with the same work hardened


304


stainless as the other embodiments of this lock system and are therefore not subject to removal using simple hand tools such as files or saw blades. 304 stainless cannot be cut with normal gas cutting equipment because it contains no carbon, neither can it be frozen and cracked.





FIGS. 20 and 21

show typical uses for locking assembly


245


on a stern drive unit and outboard motor mount respectively.



Claims
  • 1. A locking device for securing outboard motors and stern drives mounted on a plurality of exposed studs on the stern of a boat, and construction equipment on a plurality of exposed studs inset in concrete or other media, and other items which can be mounted with exposed studs upon which the locking device can be mounted, said device consisting of:a lock pin having a first end and a second end, said lock pin having a threaded blind hole therein along a center line of said lock pin, parallel to a center line drawn through said lock pin, said first end having a plurality of flat surfaces for gripping and turning said lock pin, and a circular groove formed around the periphery of said second end of said lock pin, a locking cover having a first end and a second end, a first blind hole formed in said first end along a center line of said locking cover and a second blind hole formed in said second end, perpendicular to said first blind hole, said locking cover being assembled on said lock pin, and a roll pin having a hole formed therein being inserted in said second blind hole and a carbide core being inserted in said roll pin, said roll pin and carbide core being aligned with and locking said locking cover thereby preventing removal of said lock pin.
RELATED APPLICATION

This application claims benefit of Provisional Application Ser. No. 60/155,576 Filed Sep. 24, 1999 which is a Divisional of patent application Ser. No. 09/496,419 Filed Feb. 2, 2000 now U.S. Pat. No. 6,176,661.

US Referenced Citations (8)
Number Name Date Kind
1530521 Robinson Mar 1925
1796517 Ganz Mar 1931
1818373 Beach Aug 1931
1828658 Henke, Jr. Oct 1931
1877545 Wise Sep 1932
4904145 Koutsoupidis Feb 1990
5630687 Robinson May 1997
6161402 Moore Dec 2000
Provisional Applications (1)
Number Date Country
60/155576 Sep 1999 US