The present invention relates to the art of gun or firearm safety. It finds particular application in conjunction with barrel locks or plugs, and will be described with particular reference thereto. However, it is to be appreciated that the present invention is also amenable to other like applications.
Firearm safety is a concern for most gun owners. In general, gun owners desire a way to secure their firearms from unauthorized use and/or accidental discharge. Accordingly, devices have been developed to achieve this goal. However, many of the prior art devices suffer from various drawbacks and/or limitations.
For example, trigger locks have been developed which when properly installed on a gun prevent an unauthorized user from squeezing the gun's trigger. While these trigger locks may prevent a gun's firing mechanism from being intentionally activated, trigger locks generally do not prevent a gun from being loaded. Accordingly, a live round can still be positioned in the firing chamber and a sudden jarring of the gun and/or faulty ammunition can potentially result in the accidental discharge of the weapon.
Another safety device for securing firearms is the so called barrel plug which is designed to wedge in and/or otherwise obstruct the gun's barrel. The previously developed barrel plugs also have drawbacks and/or limitation. Many of the prior art barrel plugs cannot easily and quickly be installed and removed. Others are not sufficiently tamper resistant and/or secure. That is to say, the security of some prior art barrel plugs can be frustrated with relative ease by an unauthorized user, e.g., pulling or pushing or otherwise removing the plug from the barrel. Furthermore, prior art barrel plugs tend to be of limited use insomuch as each only fits one preset caliber or bore size.
While obstructing the barrel, often barrel plugs do not prevent loading of the firearm. This is particularly hazardous when the barrel plug is completely hidden within the barrel. For example, a unsuspecting user, not knowing the barrel plug is installed and not seeing any external evidence of its installation, may load and attempt to fire the gun. Of course, the gun will potentially backfire or otherwise injure the user and/or damage either the firearm or the barrel plug or both.
The present invention contemplates a new and improved gun barrel safety lock with hand ratcheting wrench which overcomes the above-referenced problems and others.
A gun safety device includes a barrel plug assembly having a first compression member, a second compression member, an expansion member, a joining member, and an adjustable extension rod assembly. The expansion member is sandwiched between the first compression member and the second compression member. The joining member is operatively linking the first compression member to the second compression member. The joining member is adapted to draw at least one of the compression members towards the other compression member. The adjustable extension rod assembly extends from the second compression member.
A gun safety device includes a barrel plug assembly having an adjustable rod assembly and a selectively expandable portion. The adjustable rod assembly adjusts the length of the barrel plug assembly. The selectively expandable portion selectively engages the barrel of an associated gun. The adjustable rod assembly includes a tubular extension and a slidable rod received in the tubular extension.
The invention may take form in various components and arrangements of components, and/or in various steps and arrangements of steps. The drawings are only for purposes of illustrating preferred embodiments and are not to be construed as limiting the invention.
With reference to the FIGURES, in particular
The barrel plug assembly A is installed in the bullet exit end or muzzle of a gun barrel. As best seen in
In a preferred embodiment, the bolt 10 includes a bushing 10c which has a diameter larger than the bolt shaft 10d on which the threads 10a are formed. Preferably, the bold 10 is formed from stainless steel or other similar metal or material. The bolt head 10b includes a hexagonal of other key shaped region 10b′ which lies beneath a protrusion or smooth stub 10b″. Consequently, for the socket 90b to mate with the key portion 10b′ of the bolt head 10b it has a matching recess which accepts the smooth stub 10b″ when the bolt head 10b is received in the socket 90b.
A flanged bolt-retaining plug 12 is bonded to an expansion tube 14 which is in turn bonded to a threaded rear compression base 16. With respect to a central longitudinal axis z, the flanged bolt-retaining plug 12 includes a longitudinally extending cylindrical member 12a and a radially extending flange 12b at a first end thereof. The flanged bolt-retaining plug 12 is sized to and does receive and retain the bolt 10. An inner diameter of the cylindrical member 12a is two tiered. That is, the inner diameter of the cylindrical member 12a is tiered or stepped down to create an annular surface which is substantially normal to the axis z. The larger inner diameter of the cylindrical member 12a is sized to and does receive the bushing 10c of the bolt 10. The smaller inner diameter of the cylindrical member 12a is less than the outer diameter of the bushing 10c. The smaller inner diameter is sized to and does receive the shaft 10d of the bolt 10. In this manner, when the bolt 10 is inserted through the flanged bolt-retaining plug 12, the normal annular surface (created by the two tiered inner diameter of the cylindrical member 12a) abuts the bushing 10c thereby restricting the bolt 10 from passing longitudinally beyond a designated point with respect to the flanged bolt-retaining plug 12.
Preferably, the flanged bolt-retaining plug 12 is made of brass or other like metal or other similarly hard, durable and/or rigid material. The flange 12b is preferably a plate which is substantially normal to the axis z. The perimeter and thickness of the plate are shaped and sized to be selectively engaged non-rotatably with a flange receiving portion 50a of a lower handle mount 50 included in the wrench assembly B (see, e.g.,
It is to be noted that the combinations of wrench assemblies B and plug assemblies A that will permit the selective installing and uninstalling of any given plug assembly A in a firearm barrel is able to be limited insomuch as for the combination to cooperate both the flange 12b and flange receiving portion 50a have to match and the bolt head 10b and the socket 90b have to match.
The expansion tube 14 is a cylindrical member preferably made of rubber or other like material which expands radially when compressed longitudinally and contracts radially when stretched longitudinally. A first end of the expansion tube 14 is bonded to the second end 12c of the cylindrical member 12a opposite the flange 12b. A first end of the compression base 16 is bonded to the second end of the expansion tube 14 opposite the flanged bold retaining plug 12. In this manner, the flanged bolt-retaining plug 12, the expansion tube 14 and the compression base 16 are all rotationally fixed with respect to one another. The bolt shaft 10d extends entirely through the inner diameter of the expansion tube 14 such that the threads 10a may be engaged with the compression base 16. The length of the bolt shaft 10d is preferably at least long enough to allow the expansion tube 14 to be longitudinally-uncompressed while the threads 10a are still engaged with the compression base 16 and the bushing 10c abuts the annular surface created by the two tiered inner diameter of the cylindrical member 12a.
The compression base 16 is also preferably made from brass or another suitable metal or like material. The first end of the compression base 16 (i.e., the end proximate the expansion tube 14) has a threaded inner diameter arranged to receive the threaded end 10a of the bolt 10. The second end is threaded or otherwise arranged to receive a screw-on expansion tube adapter 18 if the slide-on expansion tube 20 is being employed. Alternately, the plug extension 24 may be affixed to the second end of the compression base 16.
When the caliber, bore or otherwise the inner diameter of the barrel in which the plug assembly A is to be installed is essentially the same or some determined amount larger than the outer diameter of the longitudinally-uncompressed expansion tube 14 (which is substantially equal to the outer diameter of the compression base 16 and the cylindrical member 12a), then the bore adjusting components C (i.e., one-way locking push nut 22, slide-on expansion tube 20 and screw-on expansion tube adapter 18) are not used. Alternately, if the barrel bore is significantly larger, then the bore adjusting components C are used.
Essentially, there is a set of bore adjusting components C for each caliber or barrel bore diameter in which the plug assembly A may be installed. After determining the caliber or bore of the barrel in which the plug assembly A is to be installed, a user simply selects the set of bore adjusting components C designate for that barrel's inner diameter size or caliber. The outer diameters of the bore adjusting components C are substantially equal to or less than the inner diameter of the barrel in which they are intended to be used. The inner diameters of the one-way locking push nut 22 and slide-on expansion tube 20 allow them to fit snuggly over the outer diameters of the cylindrical member 12a, the longitudinally-uncompressed expansion tube 14 and the compression base 16.
Preferably, the expansion tube 14 and the sets of bore adjusting components C each fit a range of calibers or bore sizes. That is to say, as compared to O-rings and the like, the tubes 14 and 20 have a greater range of and/or capacity for radial expansion when longitudinally compressed. Accordingly, each individual tube size can fit and wedge into a number of different calibers or bore sizes.
Most preferably, between the tube 14 and one set of bore adjusting components C all calibers or bore sizes can be accommodated. In this case, the maximum radial expansion of the tube 14 is large enough to sufficiently wedge the plug assembly A in all barrels having inner diameters substantially equal to or less than the longitudinally-uncompressed outer diameter of the tube 20. The bore adjusting components C are therefore used when the inner diameter of the barrel is substantially equal to or greater than the outer diameter of the tube 20.
The one-way locking push nut 22 is preferably bonded to the first end of the slide-on expansion tube 20. When used, the combination is slid over the outside of the cylindrical member 12a, the longitudinally-uncompressed expansion tube 14 and the compression base 16. The combined length of the one-way locking push nut 22 and the slide-on expansion tube 20 is substantially equal to the combined length of the cylindrical member 12a, the longitudinally-uncompressed expansion tube 14 and the compression base 16. The bulbous screw-on expansion tube adapter 18 is sized so as not to fit through the inner diameter of the slide-on expansion tube 20, and the adapter 18 is preferably screwed onto the second end of the compression base 16 behind the second end of the slide-on expansion tube 20. Optionally, the adapter 18 may otherwise be attached to the compression base 16. When the bore adjusting components C are used then the plug extension 24 is affixed to the adapter 18.
Preferably, the adapter 18 is made out of brass or another metal or like material and the slide-on expansion tube 20 is made of the same or similar material as the expansion tube 14. The one-way locking push nut 22 is preferably made from spring steel or the like and the plug extension 24 is preferably a vinyl coated steel tension spring or the like. Alternately, the plug extension 24 may be a rigid member.
To affect installation, the distal end of the plug assembly A (with the expansion tube 14 and optional slide-on expansion tube 20 both being longitudinally uncompressed) is inserted into the bullet exit end of the barrel or muzzle of the firearm which is to be secured. As used herein the distal end of the plug assembly A refers to the end of the plug assembly A opposite the flange 12b. Preferably, the flange 12b is larger than the inner diameter of the barrel and hence limits the depth to which the plug assembly A is inserted. That is to say, the flange 12b remains outside the barrel, preferably, abutting the end of the barrel through which the plug assembly A was inserted.
Using the hand ratcheting wrench assembly B, the bolt 10 is rotated in a first direction (e.g., clockwise) relative to the flanged bolt-retaining plug 12 which is held rotationally fixed with the flange receiving portion 50a of a lower handle mount 50 included in the wrench assembly B. Insomuch as the expansion tube 14 and the compression base 16 are rotationally fixed with respect to the flanged bolt-retaining plug 12, they are also rotationally fixed relative to the rotating bolt 10. Accordingly, due to the threaded engagement between the compression base 16 and the bolt 10 and the bushing 10c abutting the substantially normal annular surface created by the two tiered inner diameter of the cylindrical member 12a, the relative rotation of the bolt 10 with respect to the compression base 16 causes the compression base 16 and the flanged bolt-retaining plug 12 to be drawn together thereby longitudinally compressing the expansion tube 14 therebetween. Likewise, if the bore adjustment components C are being used, the screw-on expansion tube adapter 18 is drawn with the compression base 16 toward the flanged bolt-retaining plug 12 thereby longitudinally compressing the slide-on expansion tube 20 therebetween.
The longitudinal compression of the expansion tube 14 causes the expansion tube 14 to bulge or radially expand and/or wedge against the inner diameter of the barrel in which it was inserted thereby securing the plug assembly A in the same. Alternately, if the slide-on expansion tube 20 is being employed, the expansion tube 14 bulges and/or applies a radially extending force outwardly against the inner diameter of the slide-on expansion tube 20. At the same time, the slide-on expansion tube 20 will bulge or radially expand and/or wedge against the inner diameter of the barrel in which it was inserted. The dual wedging of the expansion tubes 14 and 20 prevents the barrel plug assembly A from being removed. In either case, the hand ratcheting wrench assembly B may then be removed, and absent access to the corresponding wrench assembly B, the firearm is now secured from unauthorized use.
To uninstall the plug assembly A from a barrel, the hand ratcheting wrench assembly B is re-engaged with the plug assembly A and used to rotate the bolt 10 in a second direction opposite the first (e.g., counterclockwise) while the flanged bolt-retaining plug 12 is held rotationally fixed with the flange receiving portion 50a of a lower handle mount 50 included in the wrench assembly B. Again, insomuch as the expansion tube 14 and the compression base 16 are rotationally fixed with respect to the flanged bolt-retaining plug 12, they are also rotationally fixed relative to the rotating bolt 10. This time, however, the opposite relative rotation of the bolt 10 with respect to the compression base 16 releases the longitudinal compression applied to the expansion tube 14. Likewise, if the bore adjustment components C are being used, the longitudinal compression applied to the slide-on expansion tube 20 is also released. Upon the release of the longitudinal compression to the expansion tube 14 and/or the slide-on expansion tube 20, the bulge or radially expansion therein and/or the radial force exerted thereby subsides and the plug assembly A is no longer wedge against the inner diameter of the barrel in which it was inserted thereby freeing it for extraction from the same by pulling on the flange 12b with the hand ratcheting wrench assembly B. Then, if desired, the wrench assembly B may be detached from the plug assembly A. Alternately, the wrench assembly B may be detached prior to extracting the plug assembly A and the plug assembly A extracted by pulling on the flange 12b by hand. In either case, the firearm is now unsecured and ready for use.
It is to be appreciated that to prevent unwanted twisting and/or turning of various components while the bolt 10 is being rotated, the threaded rear compression base 16 and the flanged bolt-retaining plug 12 are bonded to the expansion tube 14. The screw-on expansion tube adapter 18 is also mechanically connected to the compression base 16 and therefore it is also rotationally fix with respect to the flanged bolt-retaining plug 12 which is held against rotation while the bolt 10 is being turned. Preferably, the slide-on expansion tube 20 is bonded to the screw-on expansion tube adapter 18 and the one-way locking push nut 22 is bonded to the slide-on expansion tube 20. All of the above mentioned bonded and affixed points cooperate not only to prevent each part from twisting and/or turning undesirably, they also give the barrel plug assembly's expansion tubes 14 and/or 20 the ability to be stretched and/or elongated when the bolt 10 is rotated to remove the barrel plug assembly A from the barrel. The aforementioned stretching and/or elongating is advantageous insomuch as it encourages the radial contraction of the expansion tubes 14 and/or 20 which might otherwise remain completely or partially expanded due to the shape memory characteristics of the material from which they are made. That is to say, if an elastic tube is longitudinally compressed for an extended period of time and then released, the elastic tube may not immediately relax and/or return to its original radial dimension on its own. Accordingly, there may be a tendency for the plug assembly A to remain somewhat wedged in the barrel and therefore its extraction from the barrel may be correspondingly hampered. However, in accordance with a preferred embodiment of the present invention, the relative bonding of the plug assembly components ensures that loosening of the bolt 10 will elongate and/or longitudinally stretch the expansion tubes 14 and/or 20 thereby encouraging their radial contraction which in turn facilitates quick and easy extraction of the plug assembly A from the barrel.
Of course, the longitudinal stretching is only achieved when the compression between the flanged bolt-retaining plug 12 and the base 16 is released via a loosening of the blot 10. That is to say, so long as the bolt 10 continues to hold the flanged bolt-retaining plug 12 and the base 16 drawn together, pulling on the flange 12b will not stretch or elongate the expansion tubes 14 and/or 20. In this manner, the degree to which the plug assembly A is wedged in the barrel is not lessened by merely pulling on the flange 12b without first untightening the bolt 10. Accordingly, security is not compromised by this feature.
It is to be appreciated that with the extension rod 90 locked in the extended position and the tabs 54 (described later herein) holding the flange 12b in the receiving portion 50a of the lower handle mount 50, the bolt 10 is kept from pushing out of the bolt-retaining plug 12 when it is loosened. The bushing 10c acts as a step such that the top of the bushing 10c will press against the bottom of the extraction rod's socket 90b. Consequently, loosening of the bolt 10 pushes the bolt-retaining plug 12 and the compression base 16 apart from one another and longitudinally elongates the tube 14 (and tube 20 if used) thereby radially contracting the same.
The flanged bolt-retaining plug 12 serves a number of purposes. It is used to prevent the barrel plug assembly A from being forced through the barrel, and it keeps the bolt 10 and the slide-on expansion tube 20 aligned within the assembly. The flanged bolt-retaining plug 12 also prevents the bolt 10 from being tampered with insomuch as the bolt 10 is recessed therein. The flange 12b also provides a means to hold desired plug assembly parts rotationally fixed while the bolt 10 is being turned. The flanged bolt-retaining plug 12 gives both the expansion tube 14 and the slide-on expansion tube 20 a compression point. The flange 12b is also used as an attachment point for the hand ratcheting wrench assembly B.
In addition to wedging the plug assembly A into the muzzle end of the firearm's barrel, the rest of the barrel will contain and/or be blocked by the plug extension 24 which may be optionally a rigid member or a tension spring (optionally, vinyl coated) or the like. Preferably, the plug extension 24 is long enough to extend into and/or through the loading chamber or the action/receiver portion of the firearm. Consequently, after the barrel plug assembly A has been locked into place, the plug extension 24 will not permit the firearm to be loaded.
Consider, for example, a revolver 200 having a barrel 202 and cylinder 204 (see, e.g.,
Preferably, the plug extension 24 is mechanically connected to the end of the compression base 16 (or the end of the screw-on expansion tube adapter 18, if used) so that it cannot be forcibly removed from the barrel.
As noted previously, the specially keyed bolt 10 prevents an individual from loosening the plug assembly A without the designated wrench assembly B. In a preferred embodiment, the bolt 10 has a head 10b which is designed with a smooth stud 10b″ that protrudes from above the hexagonal or otherwise keyed potion 10b′. This combination of stud and keyed portion prevents an individual from loosening or unscrewing the bolt 10 and releasing plug assembly A from the barrel without the socket 90b that fits over the stud 10b″ while mating up with keyed portion 10b′.
The bolt's bushing 10c also serves a number of purposes. For example, it facilitates easy engagement of the hand ratcheting wrench's extraction rod 90 (see, e.g.,
Preferably, there is a close tolerance fit between the outer diameter of the bushing 10c and the larger inner diameter of the cylindrical member 12a and between the bushing's interface with the normal annular surface created by the two tiered inner diameter of the cylindrical member 12a. This helps prevent the expansion tube 14 and the rear compression base 16 from bending out of alignment when the expansion tube 14 is compressed. The bushing 10c is also used as a contact point as it presses against the normal annular surface created by the two tiered inner diameter of the cylindrical member 12a when the bolt 10 is tightened to lock or wedge the barrel plug assembly A in the barrel.
The flanged bolt-retaining plug 12 has a number of noteworthy features. The flange 12b serves as a stop, is preferably slim line and compact, can fit any barrel size and is tamper resistant. The flange 12b is used as a “stop.” The flange 12b will not permit the barrel plug assembly A to be forcibly pushed through the barrel's bore. It will also visually indicate if the barrel plug assembly A has been installed, and it ensures installation at the proper depth in the barrel's bore. Preferably, when properly installed, the bottom or under side of the flange 12b butt against the firearm's mussel or flash guard. As used here, the bottom or under side refers to the side of the flange 12b which is proximate the cylindrical member 12a.
The flange's shape mates with and is held by the hand ratcheting wrench's lower handle mount 50 (see, e.g.,
In a preferred embodiment, the flange 12b has a slim line and/or compact face, so that two or more of the barrel plug assemblies A, with the same or different calibers, can be mounted side by side in firearms with double barrels. See, e.g., the short dimension w shown in
If an excessive prying force or torque is applied to the flange 12b, the flange 12b is preferably designed to break away from the rest of the flanged bolt-retaining plug 12. This breakaway design is achieved in one preferred embodiment by machining a small groove 12b′ (e.g., 0.500 inch in diameter, 0.063 inch wide and 0.062 inch deep) on the under side of the flange 12b and centered around the outer circumference of the cylindrical member 12a. Given an exemplary outer diameter of 0.200 inches for the cylindrical member 12a, and the 0.500 inch diameter of the portion of the flange 12b that remains after the rest has been forcibly broken off, there will remain a 0.150 inch flange shoulder (i.e., (0.500−0.200)/2=0.150). This 0.150 inch shoulder not only prevents the barrel plug assembly A from compromising any of its design and/or safety integrity, but also prevents an unauthorized individual from forcibly removing (by pushing and/or prying) the locked barrel plug assembly A from the barrel in which it is installed. That is to say, the shoulder is significant enough to prevent the plug assembly A from being pushed through the barrel, but not significant enough for someone to grab a hold of and/or use for leverage to pull the plug assembly A from the muzzle.
The flange 12b is also used as a stop and compression point for the slide-on expansion tube 20 and one-way locking push nut 22. That is to say, the flange 12b prevents them from moving forward, away from or out of the muzzle of the firearm, when the bolt 10 is tightened.
The taper end 12c of the flanged bolt-retaining plug 12 facilitates the installation and removal of the barrel plug assembly A. The tapered end 12c is mated to and “permanently” bonded with (e.g., via chemical bonding, adhesive or the like) one of the tapered ends 14a of the expansion tube 14. The tapered end of both parts, when combined, produce a greater bonding surface area and a stronger bond therebetween. This increases the ability of the expansion tube 14 to longitudinally compress or stretch and also prevents it from twisting/turning when a torque is applied to bolt 10 and the flanged bolt-retaining plug 12 is held rotationally fix. The greater bonding area, produced by the tapered ends, is particularly advantageous when the expansion tube 14 is stretched or elongated because, it will facilitate the removal of the barrel plug assembly A from the barrel. As previously pointed out, the stretching/elongating of the expansion tube 14, and hence radially contracting the same, is useful because if an elastic tube is compressed for an extended period of time and then released, the elastic tube may not immediately relax and return to its original condition/dimension. If the tube does not return to its original condition/dimension on its own, it may cause the uncompressed elastic tube, or in this case, the expansion tube 14 to interfere/press against the inner diameter of the firearm barrel. Without longitudinally stretching/elongating the expansion tube 14, and hence radially contracting the same, it may be difficult to remove the barrel plug assembly.
Alternately, instead of using the tapered end and, e.g., chemically bonding between the flanged bolt-retaining plug 12 and the expansion tube 14, a longitudinally notched, annularly ribbed or like patterns or configurations are used in conjunction with a press fitting. The joint or connection thus formed is maintained via mechanical interference and/or the press fitting. This prevents the relative rotation of the joined parts. To keep the ends from separating, when the expansion tube 14 is stretched or elongate, a one-way locking push nut (e.g., similar to the one-way locking push nut 22) is optionally molded into the end of the expansion tube 14. The push nut is, e.g., made of spring steel with inward bent tabs. The tabs are bent in the same direction approximately 45 degrees out from the center of the push nut. In addition, the tabs are preferably equally spaced around the spring steel push nut's inner diameter. As the tabs engage/bends around the shaft/outer diameter of the flanged bolt-retaining plug 12, the spring steel push nut will grab onto the flanged bolt retaining plug and will not allow the expansion tube 14 to pull off of the flanged bolt-retaining plug 12.
It is to be noted that, optionally, in any of the same manners that the expansion tube 14 is affixed to the flanged bolt-retaining plug 12 it may also be affixed to the rear compression base 16.
In a preferred embodiment, the fit and clearance between the flanged bolt-retaining plug 12 and the specially keyed bolt 10 provides self alignment and tamper resistance. The flanged bolt-retaining plug 12 is designed so that the bolt 10 slides into its bore which is, e.g., 0.140 inches in diameter on the top or exposed side of the flange 12b. As used here the top or exposed side refers to the side or face of the flange 12b opposite of the cylindrical member 12a. To keep the bolt 10 from sliding all the way through the bolt-retaining plug 12, a fixed bushing 10c attached to or integrated with the bolt 10 abuts against the ledge or substantially normal annular surface created by the two tiered inner diameter of the cylindrical member 12a. The tolerances between the flanged bolt-retaining plug's bore diameter and the depth of the ledge, and the diameter of the bushing 10c and the distance from the bottom of the bushing 10c to the top of the stud 10b″ is all arranged and/or maintained so that the barrel plug assembly A and the removable hand ratcheting wrench assembly B will work properly and provide a secure and tamper resistant device.
Preferably, the bolt 10 and the flanged bolt-retaining plug's hole or inner bore are slip fit toleranced so that the bolt 10 is essentially only able to move up or down along and/or in a rotational direction in relationship to the flanged bolt-retaining plug's center line or the axis z. In the flanged bolt-retaining plug 12, the combination of an axially normal ledge or annular surface and a longitudinal constraint (i.e., the wall of the bore), the barrel plug assembly A is substantially self aligning. Additionally, the axially normal ledge or annular surface is used as a contact point and as a longitudinal constraint for the bushing 10c. In one preferred embodiment, the axially normal ledge or annular surface is arranged at such a depth that the bolt rests approximately 0.25 inches below the top surface of the flange 12b. Accordingly, an individual without the hand ratcheting wrench assembly B will not be able to grab or hold onto the bolt head 10b due to the combined 0.25 inch depth and 0.140 inch diameter hole clearance.
The expansion tube 14 is preferably made from a petroleum resistant polymer synthetic elastomer material that has good compressive and tension characteristics. The tapered ends 14a of the expansion tube 14 are preferably chemically bonded, permanently, to the tapered end 12c of the flanged bolt-retaining plug 12 and the tapered end 16a of the rear compression base 16. The small diameter of the parts make the tapered end advantageous. The tapered ends permit a greater bonding area which in turn translates into a stronger bond and hence the advantages attendant thereto. The length of the expansion tube 14 also provides a larger gripping area. That is to say, the expansion tube's length provides a larger contact/gripping area and when longitudinally compressed creates a greater outside diameter, as compared to, e.g., conventional “O” rings. This feature enables the barrel plug assembly A to work with a range of different firearm calibers and/or bore diameters. However, for firearms with calibers or bore diameters too large for the expansion tube 14 to wedge up against itself, the slide-on expansion tube 20 may be used.
The distal end threaded rear compression base 16 is arranged to mate either with the screw-on expansion tube adapter 18 or the plug extension 24. Such versatility allows an individual to use barrel plug assembly A with different calibers or barrel bore diameter. The screw-on expansion tube adapter 18 is designed to quickly screw on to the back of the threaded rear compression base 16. This screw-on feature allows the barrel plug assembly A to be quickly and easily converted to a larger caliber/diameter (by selecting bore adjustment components C with varying outer diameters) without having to change the entire base assembly (i.e., elements 10–16 and 24). The plug extension 24 (optionally, rigid or tension spring) can also be screwed into the threaded rear compression base 16 or otherwise attached thereto by suitable means. Again, this screw-on feature allows the barrel plug assembly A to be quickly and easily converted to accommodate varying barrel lengths (by selecting plug extension 24 with varying lengths) without having to change out the entire base assembly.
The screw-on expansion tube adapter 18 is preferably designed to quickly screw-on to the back of the threaded rear compression base 16 when selected for use and the plug extension 24 can then be screwed into the tapered side of the expansion tube adapter 18.
In one preferred embodiment, the tapered end 18a of the expansion tube adapter 18 is bonded to the tapered end 20a of the slide-on expansion tube 20. Both parts are affixed together so that the slide-on expansion tube 20 can be effectively compressed or stretched/elongated, and be prevented from twisting. Again, to produce a stronger bonded area between both of the parts, the mated ends of the expansion tube adapter 18 and the slide-on expansion tube 20 are arranged with a tapered fit. The expansion tube adapter 18 preferably also has an approximately 45 degree chamfered distal end that is used to help guide the barrel plug assembly A into the muzzle during the installation process.
The plug extension 24 prevents the firearm from being loaded, which in turn, makes the weapon inoperable. In accordance with preferred embodiments, the plug extension 24 is optionally a rigid member or a tension spring. It is arranged to be readily attached to or screwed on to the tapered end of the screw-on expansion tube adapter 18 if employed, or alternately, to the threaded rear compression base 16.
The rigid plug extension 24 is arranged so that the extension 24 will not be able to be removed from the barrel plug assembly through the rear or breech of a firearm. That is to say, the length and inflexibility of the rigid plug extension 24 prevents it from being bent and/or pulled out laterally and/or rearwardly through the breach of the firearm. In a preferred embodiment, this rigid plug extension 24 will be available in a single length which will be cut to fit each respective barrel length. The rigid plug extension 24 enables the barrel plug assembly A to be lengthened so that it will be able to block the entire barrel of a firearm. The rigid plug extension 24 may be made of any lightweight material including aluminum, brass, fiberglass, semi-hard or hard rubber or the like. The lightweight material preferably has certain material characteristics such that, e.g., the material will not compress, is light-weight, has a minimal deflection and is soft enough not to scratch the barrel's inner bore.
The tension spring version of the plug extension 24 is preferably also arranged to be irremovable from the barrel plug assembly through the rear or breech of a firearm, and will preferably come in a single size that is cut to length for a particular firearm. The tension spring is preferably made of a heavy gauge galvanized steel wire and is shaped into a tight continuous-length closed-pattern spring that is vinyl covered and semi-flexible. The vinyl cover will protect the barrel from being scratched when the barrel plug assembly A is installed or removed from the barrel. When using the plug extension tension spring 24 with the barrel plug assembly A in a gun with a very long barrel, the flexibility of the tight continuous-length closed-pattern extension spring design will aid in the installation and removal of the barrel plug assembly A. The spring can also be curled up for easy storage. Accordingly, the user will not have to struggle with a small diameter long solid rod that could get bent or broken during installation, removal or storage.
The tapered end 20a of the slide-on expansion tube 20 that mates with the face of the one-way locking push nut 22 is preferably chemically or otherwise bonded thereto. The bonded ends preferably have an approximately 45 degree chamfer radius that produces a greater chemical bonding area therebetween. This creates a stronger bond and hence the advantages attendant thereto are achieved, e.g., the bonding strength for effectively compressing or stretching/elongating the tube 20, and to prevent it from twisting/turning when a torque is applied to the bolt 10.
A selection of slide-on expansion tubes 20 with varying outer diameters allows versatile use of the barrel plug assembly A. Particular slide-on expansion tubes 20 can be installed over the original barrel plug assembly (i.e., elements 12–16) to quickly, easily and inexpensively convert the original barrel plug assembly's smaller outer diameter to a larger outer diameter. This convenient conversion gives the gun owner the ability to use the same barrel plug assembly A in any firearm regardless of bore or the barrel's inner diameter.
The size and tolerance of the slide-on expansion tube's inner diameter is noteworthy with respect to the design and versatility of the barrel plug assembly A. Preferably, the slide-on expansion tube's inner diameter is designed to have a close slip fit tolerance, when installed over the original barrel plug assembly's cylindrical body. This close slip fit tolerance is arranged so that when the bolt 10 is tightened, not only will it cause the expansion tube 14 to longitudinally compress and bulge out, but it will also cause the slide-on expansion tube 20 to simultaneously longitudinally compress and bulge out. Since the expansion tubes 14 and 20 have such a close slip fit tolerance, the bulging out of the expansion tube 14 will immediately start to push radially outward on the slide-on expansion tube's inner diameter. This radial outward force helps lock the expansion tube 14 to the slide-on expansion tube 20 in the form of an interference fit. This interference fit resists the expansion tubes 14 and 20 from being forcibly separated when the barrel plug assembly A is installed. Also, the slide-on expansion tube 20 is made to have a more uniform distribution of radial and compressive forces exerted on the inner diameter on the firearm's bore. These uniformly distributed forces provide a tighter wedging force between the barrel and the slide-on expansion tube 20.
The slide-on expansion tube's long length also provides a larger contact/gripping area which is advantageous for larger caliber firearms and when compressed creates a greater outside diameter as compared to conventional “O” rings. The slide-on expansion tube's long length and greater contact/gripping area, will preferably not increase the overall length of the barrel plug assembly A due to the fact that the slide-on expansion tube 20 slides over substantially the entire combined length of the metal threaded rear compression base 16, the rubber expansion tube 14 and the cylindrical member 12a of the metal flanged bolt-retaining plug 12. The stop that the flanged bolt-retaining plug 12 provides, and the larger contact/gripping area that the slide-on expansion tube 20 provides, enable the barrel plug assembly A to work with all ranges of gun calibers without compromising security and durability.
The one-way locking push nut 22 is preferably chemically or otherwise bonded to the end 20a of the slide-on expansion tube 20. The bonded ends preferably have a slotted 45 degree chamfer radius that produce a greater bonding area between each part. This greater bonding area gives the one-way locking push nut 22 rigidity and strength, while giving the slide-on expansion tube 20 the needed bonding strength to effectively compress or stretch/elongate and also to prevent it from twisting/turning when a torque is applied to the specially keyed bolt 10.
In a preferred embodiment, the one-way locking push nut 22 is made of spring steel and is arranged with an approximately 45 degree chamfer radius that is slotted in four equally spaced places. In one preferred embodiment, the slotted 45 degree chamfer radius forms an approximate 0.190 inch diameter hole at its center. The 0.190 inch diameter center hole is sized to form an interference fit over the flanged bolt-retaining plug's 0.200 inch diameter metal cylindrical member 12a. The locking push nut 22 is a one way nut. The nut's slotted 45 degree chamfer radius is designed to flex around and over the flanged bolt-retaining plug's 0.200 inch diameter cylindrical member 12a when the nut is pushed forwards onto the same. After the one-way locking push nut 22, which is bonded to the slide-on expansion tube 20, has been installed over the cylindrical member 12a, the nut's slotted 45 degree chamfer radius hole's inner edge will dig/grab into the outer diameter of cylindrical member 12a when the slide-on expansion tube 20 is urged in the direction opposite the one-way nature of the nut 22, e.g., by pulling on the flange 12b. The harder an individual tries to separate the slide-on expansion tube 20 from the flanged bolt-retaining plug 12, the more the one-way locking push nut's 45 degree chamfer radius will dig and/or grab into the cylindrical member 12a.
The outside diameter of the one-way locking push nut 22 is preferably sized to cover the entire outer diameter of the slide-on expansion tube 20. If an unauthorized individual attempts to obtain access to the firearm by breaking away the flange 12b and damaging the petroleum resistant polymer synthetic elastomer material that the slide-on expansion tube 20 is made out of, the one-way locking push nut's, which is pressing against the portion of the flange remaining after the break-away (see, e.g., the above description), will create a steel barrier at the muzzle of the firearm. This barrier will prevent an unauthorized individual from damaging the barrel plug assembly A to the point where it could be forcibly removed from the barrel.
One preferred embodiment of the hand ratcheting wrench assembly B is shown in
The lower handle mount 50 is used to hold the barrel plug assembly A for easy installation and removal. As indicated above, the wrench assembly B is selectively engaged with the plug assembly A via the lower handle mount 50 which has a flange receiving portion 50a that mates with the flange 12b of the plug assembly A. The flange receiving portion 50a mates with the flange 12b such that the relative rotational orientation therebetween remains fixed so long as the wrench assembly B and the plug assembly A are engaged. In a preferred embodiment, during the installation and removal process, three mating sides 52a–c (best seen in
Preferably, the flange 12b and the flange receiving portion 50a of the lower handle mount 50 have a close tolerance fit such that when the flange 12b is properly seated in the receiving portion 50a of the lower handle mount 50, an opening 56 is aligned along the longitudinal axis z with the bore of the flanged bolt-retaining plug 12 and the head 10b of the bolt 10 housed therein. In this manner, the flange receiving portion 50a of the lower handle mount 50 aligns and/or centers the wrench assembly B with the flanged bolt-retaining plug 12 so that the wrench's extraction rod 90 can easily and quickly be extended and/or retracted through the opening 56 for accurate selective engagement with the head 10b of the bolt 10 which is recessed in the flanged bolt-retaining plug 12.
The extraction rod 90 is aligned and/or guided though a hollow shaft 58 (best seen in
Elbow shaped tabs 54 form a slot into which the flange 12b is laterally slid or otherwise radially received with respect to the axis z. When the wrench and plug assemblies are engaged with one another (see, e.g.,
An upper portion 60 of the wrench assembly B is defined by three parts, namely, a inner retaining disk 62, a housing drum 64 and a housing cap 66, which collectively house or contain the wrench assembly components or parts numbered with reference numerals 80 through 110. The housing drum 64 is sandwiched between the inner retain disk 62 and the housing cap 66 which are secured to one another via a plurality of screws 68 or other like fasteners. Preferably, the lower handle mount 50, the inner retaining disk 62, the housing drum 64 and the housing cap 66 are formed or made from a suitably strong, hard, rigid and/or durable material, such as, aluminum or other metal or like material.
The upper portion 60 and the lower handle mount 50 are joined so as to be freely rotatable about the central z axis with respect to one another. Preferably, as shown, a plurality of set screws 70 extend through the housing drum 64 into a circumferential channel 59 formed in the end of the lower handle mount which is arranged inside the end of the housing drum 64 opposite the housing cap 66. In this manner, the upper portion 60 and lower handle mount 50 are joined together while being free to rotate about the z axis relative to one another.
The lower hand mount 50 is used to selectively secure the extraction rod 90 from unauthorized use and/or tampering. That is to say, to make the ratcheting wrench assembly B tamper resistant and/or to provide additional security, a user may choose to retract the extraction rod 90 upward into the lower hand mount 50. Retracting the extraction rod 90 into the lower hand mount 50 will protect the extraction rod 90 from being damaged if the hand ratcheting wrench assembly B is dropped, and will also prevent an unauthorized individual from using the hand ratcheting wrench assembly B.
The extraction rod 90 is selectively moved and locked into each of the respective positions shown in
The lock cylinder 80 is operated with a key (not shown) that fits in a key hole 80a (best seen in
In a preferred embodiment, the extraction rod 90 has a head 90a opposite the socket 90b. The head 90a of the extraction rod 90 is urged or pressed against a butt end 82a of the lock cylinder housing 82 by a compression spring 92 acting on a spring retainer 94 which is positioned between one end of the spring 92 and the head 90a of the extraction rod 90. The end of the compression spring 92 opposite the spring retainer 94 pushes off a fixed interior lateral ledge or annular lip within the housing drum 64. Accordingly, the spring 92 pushes or urges the extraction rod 90 toward the lock cylinder housing 82, and biases the push lock to the undepressed position and the extraction rod 90 to the retracted position, as shown in
With reference to
The ratchet slip clutch gear 100 has a triangular spur gear tooth pattern/profile 100b that symmetrically raps around its outer diameter. The two ratchet arms 102a and 102b are positioned opposing one another about the outer diameter of the gear 100. The arms 102a and 102b are pivotally secured at one end between the inner retaining disk 62 and a fixed interior lateral ledge or annular lip within the housing drum 64. The opposing ends of the arms 102a and 102b are biased toward the toothed outer diameter of the gear 100 by their respective compression springs 104a and 104b. The two ratchet arms 102a and 102b are positioned so that they line up/mate with the triangular spur gear's tooth root diameter and edge profile.
The ratchet arm selector 106 includes a lever 106a and a cam 106b at opposing ends of a shaft 106c. The selector 106 is arranged such that the lever 106a extends out of the housing cap 66 for manipulation by the user. By flipping the lever 106a 90 degrees to the left and/or right, a user selectively rotates the shaft 106c (which is preferably parallel with and radially offset from the z axis) and the cam 106b at the opposing end. The cam 106b is positioned between the arms 102a and 102b and the gear 100 such that in accordance with the manipulation of the lever 106a the cam 106b effects the disengagement of one of the ratchet arms from the gear 100 and effects the engagement of the other ratchet arm with the gear 100. Depending upon its rotational position, the cam 106b, acting against the biasing force of one of the springs 104a and 104b, deflects one of the arms 102a and 102b about its pivot point while the undeflected arm is urged or pressed into engagement with the gear 100 by the biasing force of it its compression spring.
In the following context, clockwise and counterclockwise refer to the direction of rotation when viewed from the housing cap 66 end of the wrench assembly B. When the lever 106a is flipped so that the arm 102a is pressed against the gear 100 by the spring 104a and the arm 102b is deflected by the cam 106b, a continuous ratcheting motion (i.e., continuous rotation in alternating directions) applied to the upper portion 60 of the wrench assembly B advances the gear 100 counterclockwise. This is because, on the counterclockwise stroke applied to the upper portion 60, the housing drum 64 and the inner retaining disk 62 rotate counterclockwise, and the arm 102a moving therewith engages the teeth 100b on the outer diameter of the gear 100 and the gear 100 is rotated counterclockwise. On the clockwise stroke applied to the upper portion 60, the housing drum 64 and the inner retaining disk 62 rotate clockwise, but the arm 102a moving therewith does not engage the teeth 100b on the outer diameter of the gear 100 and the gear 100 does not rotate. Rather, on the clockwise stroke, the arm 102a is free to deflect about its pivot point against the biasing force of the spring 104a, and so, the teeth 100b on the outer diameter of the gear 100 deflect the arm 102a (rather than engage with it) as the arm 102a is dragged across them.
Conversely, when the lever 106a is flipped so that the arm 102b is pressed against the gear 100 by the spring 104b and the arm 102a is deflected by the cam 106b, a continuous ratcheting motion applied to the upper portion 60 of the wrench assembly B advances the gear 100 clockwise. This is because, on the clockwise stroke applied to the upper portion 60, the housing drum 64 and the inner retaining disk 62 rotate clockwise, and the arm 102b moving therewith engages the teeth 100b on the outer diameter of the gear 100 and the gear 100 is rotated clockwise. On the counterclockwise stroke applied to the upper portion 60, the housing drum 64 and the inner retaining disk 62 rotate counterclockwise, but the arm 102b moving therewith does not engage the teeth 100b on the outer diameter of the gear 100 and the gear 100 does not rotate. Rather, on the counterclockwise stroke, the arm 102b is free to deflect about its pivot point against the biasing force of the spring 104b, and so, the teeth 100b on the outer diameter of the gear 100 deflect the arm 102b (rather than engage with it) as the arm 102b is dragged across them.
Please note,
As described later herein, the rotation of the gear 100 and/or a torque associated therewith is transferred and/or applied to the extension rod 90 via a slip clutch output drive gear 108. Accordingly, in this manner, the wrench's ratchet assembly allows a user to drive the extraction rod 90 in either selected direction of rotation using a continuous ratcheting motion to selectively tighten or loosen the bolt 10.
The combination of the ratchet slip clutch gear 100 and the slip clutch output drive gear 108 serves as a torque limiter to prevent an over application of torque to the bolt 10 which may potentially damage the same. The gear 100 preferably has a symmetrically oriented, beveled, angular, inner radial, gear tooth pattern 100a on its transaxial face that abuts and mates with the transaxial face of gear 108 having a corresponding gear tooth pattern 108a. The transaxial faces of the gears 100 and 108 are compressed or biased together by a slip clutch compression spring 110. Preferably, the spring 110 is a standard compression spring that is compressed between a fixed interior lateral ledge or annular lip within the housing drum 64 and the slip clutch output drive gear 108. The compressed spring 110 urges or presses the slip clutch gear 100 and the slip clutch output drive gear 108 together with a predetermined compressive force. When the compressive force is exceeded, the gears 100 and 108 will slip and rotate independently from one another.
The drive gear 108 preferably has a square or otherwise keyed center hole which receives a square or otherwise keyed portion 90c of the extraction rod 90 such that they are rotationally fixed with respect to one another. Therefore, the rotational movement and/or torque experienced by the drive gear 108 is transferred to the extraction rod 90, and in turn, the bolt 10 when it is engaged with the extraction rod 90.
When the barrel plug assembly A is being installed in a gun barrel's bore by applying a continuous ratcheting motion to the upper portion 60 of the wrench assembly B with the selector lever 106a in the bolt tightening position, both the ratchet slip clutch gear's and the slip clutch output drive gear's teeth 100a and 108a, respectively, will slip when a maximum allowable torque is exceeded. Accordingly, the torque applied to or experienced by the bolt 10 is limited. The limited torque will prevent the bolt 10 from being over tightened, which could undesirably damage the bolt's threads 10a, bushing 10c and/or head 10b. Additionally, a user installing the safety device will not have to worry if the barrel plug assembly A has been properly secured in the gun barrel's bore. This is because when the gears 100 and 108 slip between each other, they preferably make a clicking sound to indicate that the proper torque has been applied. This clicking sound is made when the mating, symmetrically oriented, beveled, and angular inner radial gear teeth 100a and 108a, slip and slide over their 90 degree vertical ledges, located along the apex of each of the gear's teeth.
When a user applying a continuous ratcheting motion to the upper portion 60 of the wrench assembly B with the selector lever 106a in the bolt loosening position to remove the barrel plug assembly A from the gun barrel's bore, the ratchet slip clutch gear 100 and the slip clutch output drive gear 108 automatically lock together. The automatic locking is achieved by using a 90 degree vertical ledge, located along the apex of each of the symmetrical oriented, beveled, and angular inner radial gear teeth. Essentially, the abutting transaxial faces of the gears 100 and 108 have mating ramped teeth 100a and 108a which form a one-way slip clutch which will not slip when the relative rotation therebetween is in a first direction, and which will slip if a predetermined torque is exceeded when the relative rotation is in a second direction opposite the first. When the gears 100 and 108 are rotated relative to one another such that their teeth 100a and 100b lock together or will not slip, the user will be able to apply as much torque/force as is needed to loosen the bolt 10 and stretch or elongate the barrel plug assembly A.
As already stated, in the center of the slip clutch output drive gear 108 is a square hole that is used as a guide and mount for the extraction rod 90. This square hole is designed to slide over the extraction rod's square body 90c. The two parts preferably have a slip fit tolerance, so that the extraction rod 90 can slide easily through the slip clutch output drive gear's square hole, with very little backlash/rotational movement. The slip clutch output drive gear 108 is used to transfer the output torque from the hand ratcheting wrench's slip clutch to the extraction rod 90, while still allowing the extraction rod 90 to be extended and retracted from the hand ratcheting wrench assembly B.
Preferably, the hand ratcheting wrench B is used to install and remove the barrel plug assembly A, and without the hand ratcheting wrench B, the barrel plug assembly A cannot be properly installed or removed. When a user wants to install the barrel plug assembly A to secure their gun, they preferably perform the following steps.
The barrel plug assembly's flanged bolt-retaining plug 12 is slid into the lower handle mount 50 located on the bottom of the hand ratcheting wrench B, as shown in
The user inserts the barrel plug assembly A, that is now connected to the hand ratcheting wrench B, into the muzzle of the gun. Preferably, the plug assembly A is inserted all the way until the flange 12 is flush with the end of the barrel, as shown in
The ratcheting rotation of the upper portion 60 of the wrench assembly B advances the ratchet slip clutch gear 100 in the clockwise direction thereby applying rotation and/or torque to the slip clutch output drive gear 108, which, in turn, is transferred to the extraction rod 90 and the bolt 10 engaged therewith. The rotation of the bolt 10 pulls the threaded rear compression base 16 (and the screw on expansion tube adapter 18, if used) and the flanged bolt-retaining plug 12 together thereby longitudinally compressing the expansion tube 14 (and the slide-on expansion tube 20, if used). Longitudinally compressing the expansion tubes 14 and 20 causes them to radially bulge and/or push against the walls in which each is contained, be it the gun barrel bore or the inner bore of the slide-on expansion tube 20. In this manner, the plug assembly A becomes wedged inside of the gun's barrel, thereby securing the barrel plug assembly A in the gun barrel. Preferably, the user continues ratcheting the wrench assembly B until the biasing force of the compression spring 110 is overcome and the gears 100 and 108 slip past one another. A “clicking” sound is heard when the two gears 100 and 108 slip and rotate between each other signifying that the barrel plug assembly A has been fully tightened. If a clicking sound is not heard from the slip clutch gears 100 and 108, the plug assembly A has not been fully tightened and ratcheting of the wrench B should continue.
Once fully tightened, the user reinserts the key in the lock cylinder 80 (if not still in the same), and unlocks the lock cylinder housing 82 by turning the lock cylinder 80 so that the locking lever 84 disengages from slot 66b of the housing cap 66. The user then allows the compression spring 92 to push the extraction rod 90 up into the retracted position and the lock cylinder housing 82 and the lock cylinder 80 into the undepressed position. Turning the lock cylinder 80 so that the locking lever 84 engages with slot 66a of the housing cap 66 and removing the key, locks the push lock in the undepressed position and the extraction rod 90 in the retracted position to prevent tampering and/or use by an unauthorized individual.
The hand ratcheting wrench assembly B may now be slid away from the flanged bolt-retaining plug 12 while the plug assembly A remains properly installed in the barrel, as shown in
When an authorized user wants to remove the barrel plug assembly A from a gun's barrel to operate the gun or otherwise, they preferably perform the following steps.
The lower handle mount 50, located on the bottom of the hand ratcheting wrench assembly B, is slid onto the flange 12b of the flanged bolt-retainer plug 12 (as shown in
If not already there, the ratchet arm selector 106 is shifted into the unlocking or loosening position using the selector lever 106a. While holding the lower handle mount 50 in one hand, the upper portion 60 of the wrench B is rotate using a continuous ratcheting motion of alternating clockwise and counterclockwise strokes. The ratchet assembly makes the removal of the barrel plug assembly A quick and easy.
The ratcheting rotation of the upper portion 60 of the wrench assembly B advances the ratchet slip clutch gear 100 in the counterclockwise direction thereby applying rotation and/or torque to the slip clutch output drive gear 108, which, in turn, is transferred to the extraction rod 90 and the bolt 10 engaged therewith. The rotation of the bolt 10 pushes the threaded rear compression base 16 (and the screw on expansion tube adapter 18, if used) and the flanged bolt-retaining plug 12 apart thereby longitudinally stretching the expansion tube 14 (and the slide-on expansion tube 20, if used). Longitudinally stretching the expansion tubes 14 and 20 causes them to radially contract. In this manner, the plug assembly A becomes unwedged from inside of the gun's barrel, thereby freeing it to be readily removed from the same. Preferably, the plug assembly A is slid or pulled from the gun barrel plug while still connected to the hand ratcheting wrench assembly B.
Preferably, to remove the hand ratcheting wrench B from the extracted gun barrel plug assembly A, the user reinserts the key in the lock cylinder 80 (if not still in the same), and unlocks the lock cylinder housing 82 by turning the lock cylinder 80 so that the locking lever 84 disengages from slot 66b of the housing cap 66. The user then allows the compression spring 92 to push the extraction rod 90 up into the retracted position and the lock cylinder housing 82 and the lock cylinder 80 into the undepressed position. Turning the lock cylinder 80 so that the locking lever 84 engages with slot 66a of the housing cap 66 and removing the key, locks the push lock in the undepressed position and the extraction rod 90 in the retracted position to prevent tampering and/or use by an unauthorized individual.
The hand ratcheting wrench assembly B may now be slid away from the flanged bolt-retaining plug 12 thereby separating it from the plug assembly A. Preferably, the entire removal or de-installation procedure can be easily completed in less than one (1) minute.
Preferably, the extraction rod 90 is formed or made from a suitably strong, hard, rigid and/or durable material, such as, hardened steel or other metal or like material. The bolt engaging end of the extraction rod's shaft and/or the socket 90b preferably have a 0.140 inch outer diameter. When the hand ratcheting wrench assembly B is used to install the barrel plug assembly A, the small diameter socket 90b is extend out past the hand ratcheting wrench assembly's lower handle mount 50. It centers itself within the very confined space of the flanged bolt-retaining plug 12 and mates up with the head 10b of the bolt 10. The extraction rod's socket 90b and 0.140 inch outer diameter shaft preferably have close slip fit tolerances. These close slip fit tolerances enable the flanged bolt-retaining plug 12 and the bolt 10 to mate/slide together with the extraction rod's socket 90b and 0.140 inch outer diameter shaft, with very little backlash or deviation from the center line or z axis.
In relationship to the socket 90b, the extraction rod 90 has a, preferably, flat 0.750 inch outer diameter, flange or head 90a that is located on the opposite end. This flange or head 90a mates with and/or abuts the bottom end 82a of the lock cylinder housing 82. The flange or head 90a permits the extraction rod 90 to rotate and move up and down within the hand ratcheting wrench assembly B, while securing the rod 90 so that it cannot be forcibly removed from the assembly B.
The lock cylinder housing 82 is used as a plunger, which when pushed into the housing cap 66 extends the extraction rod 90, as shown in
Preferably, the housing cap 66 has the two parallel 90 degree slots 66a and 66b located in an outside wall of the housing cap's lock cylinder housing's bore. These two slots are used as locking points for the lock cylinder housing 82. The lock cylinder housing 82 and the extraction rod 90 can be locked into the undepressed and the retracted positions, respectively, when the locking lever 84 is slid/rotated into the housing cap's upper slot 66a, located relatively nearer the top of the cap's curved surface. The lock cylinder housing 82 and the extraction rod 90 can be locked into the depressed and the extended positions, respectively, when the locking lever 84 is slid/rotated into the housing cap's lower slot 66b, located relatively nearer the flat bottom of the housing cap 66. The location and arrangement of the locking slots 66a and 66b ensure that when the push lock is properly lock into one of the two positions, the extraction rod 90 has been fully retracted or extended.
Preferably, the housing cap 66 and housing drum 64 are ergonomically shaped such that when the user places the hand ratcheting wrench assembly B in their hand, the palm of their hand will comfortably and easily mold around the curved top of the housing cap 66 while their fingers rest comfortably on the cylindrical surface of the housing drum 64. This ergonomic fit enables the user to quickly, comfortably, and with a minimal amount of force, selectively install or remove the barrel plug assembly A from any gun barrel.
The hand ratcheting wrench assembly's housing drum 64 isolates the upper portion 60 from the lower handle mount 50. Both of these subassemblies are isolated so that when any of the subassembly's parts are compressed, moved or rotated, these parts will not adversely affect the operation of the other parts. An example of this is when the lock cylinder housing 82 and the extraction rod 90 are locked in depressed and the extended positions, respectively, the compression spring 92 will be compressed. If the housing drum 64 is not compartmentalized, the extraction rod 90 and the compression spring 92 will push against the already compressed slip clutch compression spring 110. This increase and/or variation in the spring's 110 compression force, will adversely affect the operation of the slip clutch, by increasing the amount of torque that is required to make the slip clutch slip. The compressed slip clutch compression spring 110 should always exert the same compression force on the ratchet slip clutch gear 100 and the slip clutch output drive gear 108 so that they will be forced together and always slip at a constant preset torque.
The housing drum 64 is the main rotating body of the hand ratcheting wrench assembly B. This housing drum 64 fastens onto and rotates around the lower handle mount 50, while holding and/or housing all of the subassemblies of the wrench assembly B. The housing drum 64 enables the hand ratcheting wrench assembly B to have overall rotational movement with respect to the lower handle mount 50, and at the same time, enable its internal components/subassemblies to move in determined independent linear and rotational directions.
With reference to
The adjustable barrel plug assembly D includes a flanged bolt-retaining plug 212 that is similar to the bolt-retaining plug 12 described above. The bolt-retaining plug 212 is attached to an expansion tube 214, which is similar to the expansion tube 14 described above. The expansion tube 214 attaches to a threaded rear compression base 216, which is similar to the threaded rear compression tube 16 described above. A bolt 210 (
An extension rod assembly 224 attaches to the rear compression base 216 opposite the expansion tube 214. The extension rod assembly 224 includes a tubular plug extension 232 that receives components to allow adjustment of the length of the extension rod assembly 224. Referring to
An annular sliding bolt retaining plug 238 receives the shank 236b of the bolt 236. The sliding bolt retaining plug 238 has a flat bearing surface 238a (
The sliding expansion tube 242 is hollow to receive the shank 236b of the bolt 236. The sliding expansion tube is made from a petroleum resistant polymer synthetic elastomer material that has good compressive and/or stretching characteristics. The outer diameter of the sliding expansion tube 242 is such that it can freely move within the bore 234 and it can deform such that a friction fit between the inner surface of the bore 234 and the sliding expansion tube can be achieved when a compressive force is exerted on the sliding expansion tube. The sliding expansion tube 242 includes a first tapered end 242a that receives the tapered portion 238b of the sliding bolt retaining plug 238. Because of the small size of the components, each tapered portion advantageously increases the surface area of contact between the sliding expansion tube 242 and the sliding bolt retaining plug 238 to provide a greater area for bonding between the components. The sliding expansion tube 242 also includes a second tapered end 242b opposite the first tapered end 242a. The second tapered end 242b is received in a portion of a sliding extension rod 244.
The sliding extension rod 244 includes a tapered end 244a that is received by the second tapered end 242b of the sliding expansion tube 242. Because of the small size of the components, each tapered portion advantageously increases the surface area of contact between the sliding expansion tube 242 and the sliding extension rod 244. The sliding extension rod 244 also includes a threaded bore 244b that selectively receives the threaded shank 236b of the bolt 236. The outer diameter of the sliding extension rod 244 is such that it can freely move within the bore 234 of the tubular plug extension 232. Preferably, the sliding extension rod 244, along with the other components that are received in the bore 234, are designed with a slip fit tolerance that substantially reduces any misalignment or binding when the internal components are moved back and forth within the bore 234.
Both the attachment between the sliding bolt retaining plug 238 and the sliding expansion tube 242 and the attachment between the sliding extension rod 244 and the sliding expansion tube 242 are described as connections between tapered portions. Nevertheless, it is appreciated that the attachment between the components can be in any conventional manner. For example, the components can each include corresponding notched patterns that allow the components to connect by way of a mechanical interference.
As more clearly visible in
To adjust the length of the barrel plug assembly D, a bolt 210, which in one embodiment is a male hexagon key bolt similar to the bolt 10 described above, is removed from the assembly. The key 226 is inserted into the assembly D and is received by the appropriately shaped opening 236a of the bolt 236. When tightened, the bolt 236 contacts the bearing surface 238a of the sliding bolt retaining plug 238 pushing the bolt longitudinally toward the sliding extension rod 244. Meanwhile, the bolt 236 draws the sliding extension rod 244 towards the sliding bolt retaining plug 238. Accordingly, the sliding expansion tube 242 is compressed and deformed to engage the inner surface of the tubular plug extension 232. The sliding expansion tube 242 is advantageously tubular in configuration to provide a larger contact or gripping area when compressed, especially when compared to conventional O-rings.
With reference to
The adjustable extension rod assembly 224a includes a tubular plug extension 262 that receives components to allow the length of barrel plug assembly to adjust. The tubular plug extension 262 includes a threaded end 262a that is received by the rear compression base 216. Referring to
The central bore 264 receives a bolt 268, which in one embodiment is a female hexagon bolt. The bolt includes an opening 268a that can receive the key 226. The opening 268a in one embodiment receives a 1/16″ hex Allen wrench. The outer diameter of the bolt 268 is such that the bolt can easily slide within the bore 264 without falling into one of the notches 266. The bolt 268 also includes a shank 268b that includes threads and a tapered portion 268c at the transition from a head of the bolt 268 to the shank 268b.
The bore 264 of the tubular plug extension 262 receives a sliding extension rod 272. The sliding extension rod 272 includes a threaded bore 272a that receives the shank 268b of the bolt 268. The sliding extension rod also includes an expandable end that can selectively engage an inner surface of the tubular plug extension 262. In the embodiment depicted in
The sliding extension rod 272 also includes a guide slot 278 similar to the guide slot 252 described above. The tubular plug extension 262 also includes a guide tab 276 similar to the guide tab 248 described above. The guide slot 278 and the guide tab 276 cooperate to restrict the rotational movement of the sliding extension rod 272 when the bolt 268 is rotated.
To adjust the length of the extension rod assembly 224a, the bolt 210 is removed and the key 226 is inserted into the assembly. The key is used to tighten or loosen the bolt 268 in the threaded bore 272a. When the bolt 268 is tightened, the tapered portion 268c of the bolt forces the flanged lip 272b of the sliding extension rod 272 radially outward toward the inner surface of the tubular plug extension 262 into one of the grooves 266. When the bolt 268 is loosened, the flanged lip 272b moves radially towards the longitudinal axis and out of one of the grooves 266, to allow for adjustment.
With reference to
The bore 274a receives a sliding plunger wedge 282 and a spring 284. The spring 284 biases the sliding plunger wedge 282 towards the inner flange 274d. As seen in
With reference to
The adjustable barrel plug assembly also includes a plug extension tube 292 having a longitudinal bore 294 (
The sliding extension rod 298 includes a longitudinal bore 298a that receives a sliding bearing plunger wedge 306, a ball 308 and a biasing member 312. The sliding extension rod 298 also includes an alignment opening 298b extending through the rod that communicates with the longitudinal bore 298a.
The sliding bearing plunger wedge 306 includes a ramp 306a formed in a side. In one embodiment, the ramp 306a is a half tear-drop shape. The sliding bearing plunger wedge 306 also includes a bearing surface 306b that bears against the biasing member 312, which in the embodiment depicted is a coil spring.
The ball 308 is moves on the ramp 306a of the sliding bearing plunger wedge 306. The ball 308 is dimensioned to fit through the alignment opening 298b and partially into, preferably one-quarter of the way into a corresponding opening 296 in the plug extension tube 292. To adjust the length of the barrel plug assembly, the key 226 is inserted into the assembly to bias the sliding bearing plunger wedge 306 towards a distal end of the assembly. With the sliding bearing plunger wedge 306 biased towards the distal end of the assembly, the ball 308 can move on the ramp 306a axially toward the longitudinal axis of the sliding extension rod 298. With the ball 308 displaced toward the longitudinal axis, the sliding extension rod 298 can be moved in relation to the plug extension tube 292. Releasing the sliding bearing plunger wedge 306 results in the ball 308 traveling on the ramp 306a radially away from the longitudinal axis and towards the opening 298b. The sliding bearing plunger wedge 306 retains the ball 308 in the openings 298b and 296.
With reference to
With reference to
The invention has been described with reference to the preferred embodiments. However, certain modifications and alterations are contemplated. In one instance, it is contemplated that the wrench assembly B could be automated, for example, with a small battery operated DC reverse polarity motor. In another instance, it is contemplated that wrench assembly B and the barrel plug assembly A could be permanently joined, for example, by affixing the flange 12b to the lower handle mount 50 or by forming the flanged bolt-retaining plug 12 and the lower handle mount 50 as single piece. In either case, if the wrench assembly B was forcibly tampered with, the flange bolt retaining plugs' flange 12b (which is now joined to or part of the lower handle mount 50) would still break-away at gap 12b′ leaving the rest of the plug assembly A securely installed in the guns' barrel. Obviously, other modifications and alterations will occur to others upon reading and understanding the preceding detailed description. It is intended that the invention be construed as including all such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.
This application is a continuation-in-part of prior application Ser. No. 10/027,034; filed Dec. 20, 2001 now U.S. Pat No. 6,701,655, which is incorporated by reference herein.
Number | Name | Date | Kind |
---|---|---|---|
2836918 | Pula et al. | Jun 1958 | A |
2870794 | Thaxton | Jan 1959 | A |
2937666 | Maisch | May 1960 | A |
3154874 | Stewart | Nov 1964 | A |
3193959 | Jaycox | Jul 1965 | A |
4266814 | Gallagher | May 1981 | A |
4282982 | Nuesslein | Aug 1981 | A |
4291481 | Hillberg | Sep 1981 | A |
4299045 | Cervantes | Nov 1981 | A |
4302898 | LaRue | Dec 1981 | A |
4306487 | Beretta | Dec 1981 | A |
4310029 | Dudek | Jan 1982 | A |
4381800 | Leslie | May 1983 | A |
4384420 | Von Muller | May 1983 | A |
4385643 | Noe | May 1983 | A |
4398366 | Wernicki | Aug 1983 | A |
4412397 | Bayn | Nov 1983 | A |
4457091 | Wallerstein | Jul 1984 | A |
4461108 | Von Muller | Jul 1984 | A |
4462179 | Rogak et al. | Jul 1984 | A |
4479320 | Fix | Oct 1984 | A |
4499681 | Bako et al. | Feb 1985 | A |
4509281 | Dreiling et al. | Apr 1985 | A |
4512099 | Mathew | Apr 1985 | A |
4528765 | Johnson | Jul 1985 | A |
4532729 | Von Muller | Aug 1985 | A |
4569144 | Thurber | Feb 1986 | A |
4576021 | Holden | Mar 1986 | A |
4600036 | Noe | Jul 1986 | A |
4654992 | Lavergne | Apr 1987 | A |
4682435 | Heltzel | Jul 1987 | A |
4761906 | Guevara | Aug 1988 | A |
4763431 | Allan et al. | Aug 1988 | A |
4776123 | Ascroft | Oct 1988 | A |
4783924 | Thurber | Nov 1988 | A |
4787224 | Mesa | Nov 1988 | A |
4802298 | Baugus | Feb 1989 | A |
4827649 | Sheehan | May 1989 | A |
4908971 | Chaney | Mar 1990 | A |
4965952 | Miller et al. | Oct 1990 | A |
4969284 | Healey et al. | Nov 1990 | A |
4987693 | Brooks | Jan 1991 | A |
4999940 | Madden | Mar 1991 | A |
5001854 | Derman | Mar 1991 | A |
5014457 | Lewis et al. | May 1991 | A |
5016377 | Gunning | May 1991 | A |
5038508 | Brown | Aug 1991 | A |
5044105 | Lindley et al. | Sep 1991 | A |
5044106 | Slocum | Sep 1991 | A |
5048211 | Hepp | Sep 1991 | A |
5052142 | Mikus | Oct 1991 | A |
5054223 | Lee | Oct 1991 | A |
5062233 | Brown | Nov 1991 | A |
5070635 | Cvetanovich | Dec 1991 | A |
5115589 | Shuker | May 1992 | A |
5138785 | Paterson | Aug 1992 | A |
5140766 | Brooks | Aug 1992 | A |
5171924 | Honey et al. | Dec 1992 | A |
5229532 | Brooks | Jul 1993 | A |
5233777 | Waterman, Jr. et al. | Aug 1993 | A |
5239767 | Briley, Jr. et al. | Aug 1993 | A |
5241770 | Lambert | Sep 1993 | A |
5289653 | Szebeni et al. | Mar 1994 | A |
5315778 | Wolford | May 1994 | A |
5398438 | Williams | Mar 1995 | A |
5450685 | Peterson | Sep 1995 | A |
5457907 | Brooks | Oct 1995 | A |
5488794 | Arrequin | Feb 1996 | A |
5491918 | Elmstedt | Feb 1996 | A |
5502915 | Mendelsohn et al. | Apr 1996 | A |
5515634 | Kong | May 1996 | A |
5519956 | Howell | May 1996 | A |
5535537 | Avganim | Jul 1996 | A |
5546690 | Ciluffo | Aug 1996 | A |
5548915 | Szarmach et al. | Aug 1996 | A |
5551181 | Upton | Sep 1996 | A |
5560135 | Ciluffo | Oct 1996 | A |
5561935 | McCarthy et al. | Oct 1996 | A |
5564211 | Mossberg et al. | Oct 1996 | A |
5570528 | Teetzel | Nov 1996 | A |
5579923 | Hemmerlein | Dec 1996 | A |
5581927 | Meller | Dec 1996 | A |
5603179 | Adams | Feb 1997 | A |
5603180 | Houze | Feb 1997 | A |
5611164 | Rassias | Mar 1997 | A |
5621996 | Mowl, Jr. | Apr 1997 | A |
5636464 | Ciluffo | Jun 1997 | A |
5638627 | Klein et al. | Jun 1997 | A |
5664358 | Haber et al. | Sep 1997 | A |
5669252 | Bentley | Sep 1997 | A |
5671560 | Meller | Sep 1997 | A |
5675925 | Würger | Oct 1997 | A |
5680723 | Ruiz | Oct 1997 | A |
5680724 | Peterken | Oct 1997 | A |
5699687 | Pittman | Dec 1997 | A |
5704151 | West et al. | Jan 1998 | A |
5704153 | Kaminski et al. | Jan 1998 | A |
5713149 | Cady et al. | Feb 1998 | A |
5720193 | Dick | Feb 1998 | A |
5724760 | Langner | Mar 1998 | A |
5732497 | Brooks | Mar 1998 | A |
5732498 | Arreguin | Mar 1998 | A |
5737864 | Otto | Apr 1998 | A |
5743039 | Garrett | Apr 1998 | A |
5749166 | Brooks | May 1998 | A |
5755054 | Tuller | May 1998 | A |
5758524 | Yu | Jun 1998 | A |
5768816 | Rassias | Jun 1998 | A |
5768819 | Neal | Jun 1998 | A |
5779114 | Owens | Jul 1998 | A |
5782028 | Simon et al. | Jul 1998 | A |
5782029 | Brooks | Jul 1998 | A |
5784819 | Roper | Jul 1998 | A |
5829179 | Carter et al. | Nov 1998 | A |
5832647 | Ling et al. | Nov 1998 | A |
5860241 | Waters | Jan 1999 | A |
5867930 | Kaminski et al. | Feb 1999 | A |
5890310 | Bogstrom | Apr 1999 | A |
5896691 | Kaminski et al. | Apr 1999 | A |
5910003 | Kleinpaul | Jun 1999 | A |
5913666 | Perkins | Jun 1999 | A |
5915936 | Brentzel | Jun 1999 | A |
5918402 | Weinraub | Jul 1999 | A |
5918403 | Lurz, Jr. et al. | Jul 1999 | A |
5918492 | Klebes | Jul 1999 | A |
5924232 | Rhoden et al. | Jul 1999 | A |
5926989 | Oliver, Sr. | Jul 1999 | A |
5930929 | Bubits | Aug 1999 | A |
5930930 | Howell | Aug 1999 | A |
5934000 | Hayes, Sr. | Aug 1999 | A |
5946840 | Mickel | Sep 1999 | A |
5946841 | Roper | Sep 1999 | A |
5950344 | Ross | Sep 1999 | A |
5953844 | Harling et al. | Sep 1999 | A |
5960575 | Chiovitt et al. | Oct 1999 | A |
5966859 | Samuels | Oct 1999 | A |
5974717 | Brooks | Nov 1999 | A |
5987796 | Brooks | Nov 1999 | A |
5992076 | Magnusson | Nov 1999 | A |
6009654 | Williams et al. | Jan 2000 | A |
6032396 | Shapiro | Mar 2000 | A |
6041536 | Samuels et al. | Mar 2000 | A |
6052934 | Carpenter | Apr 2000 | A |
6098330 | Schmitt et al. | Aug 2000 | A |
6122851 | Perkins | Sep 2000 | A |
6125568 | Granaroli | Oct 2000 | A |
6128847 | Langner | Oct 2000 | A |
6134822 | Murgel | Oct 2000 | A |
6141896 | Oberst | Nov 2000 | A |
6142313 | Young | Nov 2000 | A |
6154996 | Andreassen | Dec 2000 | A |
6170186 | Reed | Jan 2001 | B1 |
6173518 | Oberst | Jan 2001 | B1 |
6185852 | Whalen et al. | Feb 2001 | B1 |
6202336 | Audino | Mar 2001 | B1 |
6205695 | Schnell | Mar 2001 | B1 |
6212813 | Luna et al. | Apr 2001 | B1 |
6219952 | Mossberg et al. | Apr 2001 | B1 |
6223461 | Mardirossian | May 2001 | B1 |
6226914 | Reed | May 2001 | B1 |
6237272 | Scott | May 2001 | B1 |
6240670 | Findlay | Jun 2001 | B1 |
6250008 | Silver | Jun 2001 | B1 |
6405472 | Dojcsak | Jun 2002 | B1 |
6418654 | Trois et al. | Jul 2002 | B1 |
Number | Date | Country | |
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20040200114 A1 | Oct 2004 | US |
Number | Date | Country | |
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Parent | 10027034 | Dec 2001 | US |
Child | 10761817 | US |