The present invention relates generally to tools for maintenance and repair of firearms, and more particularly to an improved tool for the inspection, cleaning and maintenance of a receiver assembly, breech, barrel and bore, including the upper and lower receiver components thereof, of a semiautomatic or automatic firearm or rifle.
Certain automatic and semiautomatic firearms such as the AR-15 rifle have removable and/or replaceable components, enabling repair, replacement and substitution with new or replacement parts, the receiver assembly being composed of additional subassemblies and parts that require inspection and cleaning to ensure proper maintenance and operation of the weapon, and thus needing to be disassembled and reassembled repeatedly. The disassembly and reassembly operations involve the removal of set pins, levers, springs and other components, many of which are small and easily lost, some of which are also susceptible to damage during this process owing to the force necessary to displace or insert friction fitting components associated with the receiver body of a weapon. For example, the AR-15 rifle has a receiver assembly composed of an upper receiver assembly and a lower receiver assembly connected by means of a pivot pin and a takedown pin that pass through interlocking pivot pin and takedown pin assembly blocks, respectively, located in the respective upper and lower receiver assemblies. In a typical disassembly procedure, the AR-15 rifle (and other similar weapons) is placed on one side on a flat surface and a pivot pin removal tool, such as a round pin punch is position against the pivot or takedown pin and struck with a hammer to displace and then further to dislodge the pin from the receiver assembly, which can be disassembled after both pins have been removed.
In servicing a rifle without full disassembly of the upper and lower receivers, one typically either displaces to its ball detent or fully removes only the takedown pin, so that the upper and lower receiver assemblies can be angular displaced by pivoting about the pivot pin which remains in place, allowing access to the corresponding inner surfaces of the breech, barrel and bore of the upper receiver assembly and the internal components of the lower receiver assembly. However, holding the upper and lower receiver assemblies in a fixed and stable position remains problematic as blocks and wedges typically employed can easily be displaced or jogged out of position enabling movement of the receivers, potentially damaging portions of the weapon or pinching a user's fingers or hand in the process.
Accordingly, for servicing a rifle, it would be highly desirable to have a tool that would enable easy access to the breech, barrel and bore of the rifle for inspection, cleaning and servicing, inspection and servicing of the upper and lower receiver assemblies thereof, and wherein the tool would hold the upper and lower receivers of the rifle in an open and angularly oriented position with respect to one another so as to provide such ease of access while stabilizing the receivers in a fixed, stable position.
The present invention relates to a strut tool including a hook portion for engaging an upper receiver assembly and a pivoting portion for engaging the takedown pin of a lower receiver assembly of a firearm that acts as a removable strut for holding the upper and lower receiver assemblies in a relatively aligned open angular position providing access to the inner bores and mechanisms of the firearm. The present invention also relates to a strut tool where the pivoting portion includes a bore accommodating the placement of the takedown pin in conjunction with the lower receiver assembly providing a pivotal connection permitting the angular alignment of the upper and lower receiver assemblies in an open and fixed position. The present invention also relates to a strut tool where the hook portion includes a takedown block engagement region that provides a means to accommodate the insertion and engagement of the takedown block present on the upper receiver assembly for the purpose of reversibly positioning and holding the strut tool in said relatively aligned position with respect to the lower receiver assembly. In addition, the present invention relates to a strut tool where the hook portion optionally includes a upper channel with a longitudinal and semi-circular or V-shaped cutout region providing a guide slot for the relative positioning of cleaning and inspection tools with respect to the inner bore or breach of a rifle.
Yet further, the present invention relates to a strut tool for servicing a firearm including a hook portion for engaging the upper receiver assembly of a firearm and a pivoting portion for engaging the takedown pin of the lower receiver assembly of the firearm; wherein the pivoting portion includes a bore for receiving the takedown pin of the lower receiver assembly; and wherein the hook portion optionally includes a takedown block engagement region.
The present invention also relates to a strut tool wherein the hook portion and the pivoting portion acts to reversibly hold the position of the upper receiver and the lower receiver in a relative angular orientation with respect to one another by means of engaging the takedown block of the upper receiver while simultaneously engaging the takedown pin of the lower receiver assembly.
The present invention further relates to a strut tool wherein the hook portion includes a forward, flat edge region substantially parallel to the center axis of the hook portion; a forward, beveled region extending to the flat edge region and angled with respect to the flat edge region to accommodate insertion of the flat edge region into an interior breech or bore of the upper receiver assembly; a flat, top crown region extending from the beveled region; a rear, beveled region extending from the top crown region and angled with respect to the flat edge region; a rear, angled buffer block contact region extending from the rear beveled region and extending to a transition region; wherein the transition region further extends to a flat, rear region of the pivoting portion; and a takedown block engagement region, immediately adjacent to the front, flat edge region; extending inwardly from the flat edge region and including three internal surfaces: (i) an upper contact surface; (ii) a back contact surface; and (iii) a lower contact surface; wherein each of the upper contact surface, back contact surface and lower contact surface are oriented perpendicular with respect to each other; and wherein the back contact surface is oriented parallel to the center axis of the hook portion; and wherein the lower contact surface extends to a flat, forward region of the pivoting portion; wherein the lower contact surface is oriented perpendicular to the forward region of the pivoting portion.
The present invention also relates to a strut tool wherein the pivoting portion includes a flat, forward lower surface immediately adjacent to the takedown block engagement region; wherein the forward lower surface extends from the lower contact surface of the takedown block engagement region; wherein the forward lower surface is oriented substantially parallel to the center axis, and substantially perpendicular to the lower contact surface; a curved bore region extending from the forward lower surface and extending to a flat, rear surface extending to a transition region immediately adjacent to the rear, angled region; wherein the forward lower surface and the rear surface are oriented substantially in a parallel configuration; and the forward lower surface and the rear surface extend to a front portion and rear portion of the curved bore region, respectively; a bore hole located within and extending cross-sectionally through the curved bore region at the distal end of the pivoting portion with an outer wall corresponding to the external surface of the curved transition bore region; wherein the center of the bore hole defines one point along the center axis; and wherein the bore hole is internally sized to accommodate receiving the takedown pin of the lower receiver assembly to provide a pivoting means for the pivoting portion.
The present invention further relates to a strut tool wherein the cross-dimensional first thickness of the hook portion and the second thickness of the pivoting portion are the same; wherein the first thickness is equal in size to the length of an internal chord segment of an internal bore of a barrel opening of the upper receiver assembly when the hook portion is inserted into the internal bore making contact with the bore at two points of the internal chord segment corresponding to the opposed edges of the lower contact surface of the takedown block engagement region. Generally, the second thickness of the pivoting portion is selected to approximately equal with some tolerance for a tight frictional fit in size to that corresponding to the inner spacing of the lower receiver (internal distance between the two inner opposing wall surfaces near the takedown pin block region) into which the pivoting portion of the present inventive strut tool is placed in order to engage with the takedown pin.
The present invention relates yet further to a strut tool wherein the cross-dimensional thickness of the hook portion corresponds to the first thickness and the second thickness is dimensionally smaller than the first thickness. In this particular embodiment, this enables the inventive strut tool to have a first thickness in the hook portion to accommodate a larger bore size that the standard 0.223 Military ammo employed, larger caliber bullets requiring large bore sizes to fit in modified rifles, while the second thickness of the pivoting portion can be maintained at the size providing a frictional or snug fit within the lower receiver unit where it is placed to engage the takedown pivot pin.
In use, the embodiments of the present invention as disclosed herein are typically inserted hook portion first into the breech, barrel or bore of the angular displaced upper receiver unit, engaging the takedown block thereof, and then the combined upper receiver unit with hook portion in place is lowered until the through=bore of the pivoting portion of the strut tool comes into relative alignment with the bore of or the axis of the takedown pin, which is then fully inserted through the bore of the pivoting portion and into the opposite takedown pin bore hole on the lower receiver, a detent locking the takedown pin and place and thus securing the pivoting portion of the inventive strut tool in a fixed position, holding the upper and lower receiver units or assemblies in the desired, relatively angularly positioned desired or set by the over length of the struct tool and position of the through-hole bore of the pivoting portion with respect to the upper receiver.
In yet another embodiment, the present invention relates to a strut tool wherein the top crown region includes a depressed guidance region; wherein the guidance region is configured in the form of a semi-circular cross-sectional groove having a longitudinal aspect in a perpendicular orientation with respect to the center axis of the hook portion; and wherein the guidance region accommodates the positioning of a tool selected from a boring tool, cleaning rod, cleaning tool, inspection rod, inspection tool, fiber optic cable, or combinations thereof; or optionally wherein the guidance region is configured in the form of a V-shaped cross-sectional groove having a longitudinal aspect in a perpendicular orientation with respect to the center axis of the hook portion.
The present invention also relates to a strut tool wherein either one or both of the hook portion and the pivoting portion are partially cored to form one or a plurality of depressed regions extending inward from the face of the portion; wherein the depressed regions do not extend completely to the opposite face of the portion; or alternatively to a strut tool wherein the one or plurality of depressed regions extend inward from both opposed faces of either one or both of the hook portion and the pivoting portion to form opposed depressed regions on both of the opposed faces; wherein a layer of material remains between the opposed depressed regions.
The present invention further relates to a strut tool wherein one or more of the depressed regions are fully cored from one of the opposed faces to the opposite face creating an opening without an intervening layer of material.
In yet another series of embodiments, the present invention relates to a strut tool having a first and second opposed hook portions; wherein the first and second hook portions extend to the pivoting portion; wherein the openings of the respective first and second hook portions are oriented in opposite directions; or alternatively wherein the dimensions of the first and second hook portions are different in size in order to accommodate servicing of two separate rifles.
The present invention also relates to a strut tool wherein the pivoting portion includes a first and second bore for receiving the takedown pin of the lower receiver assembly; or alternatively to a strut tool wherein the pivoting portion includes a first and second bore for receiving the takedown pin of either a first or a second lower receiver assembly; and wherein the first bore and the second bore have a first internal diameter and a second internal diameter that correspond to the diameter of a first takedown pin and a second takedown pin, respectively, of a first and second rifle.
A corresponding set of Figure Keys listing the specific component parts, regions and features of the present invention is found in the Appendix, attached hereinbelow.
Generality of Invention
This application should be read in the most general possible form. This includes, without limitation, the following:
References to specific techniques include alternative and more general techniques, especially when discussing aspects of the invention, or how the invention might be made or used.
References to “preferred” techniques generally mean that the inventor contemplates using those techniques, and thinks they are best for the intended application. This does not exclude other techniques for the invention, and does not mean that those techniques are necessarily essential or would be preferred in all circumstances.
References to contemplated causes and effects for some implementations do not preclude other causes or effects that might occur in other implementations.
References to reasons for using particular techniques do not preclude other reasons or techniques, even if completely contrary, where circumstances would indicate that the stated reasons or techniques are not as applicable.
Furthermore, the invention is in no way limited to the specifics of any particular embodiments and examples disclosed herein. Many other variations are possible which remain within the content, scope and spirit of the invention, and these variations would become clear to those skilled in the art after perusal of this application.
Specific examples of components and arrangements are described below to simplify the present disclosure. These are, of course, merely examples and are not intended to be limiting. In addition, the present disclosure may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed.
Read this application with the following terms and phrases in their most general form. The general meaning of each of these terms or phrases is illustrative, not in any way limiting.
In operation, the takedown block engagement region 111 having walls 110, 112, and 114 accommodates the insertion of the takedown block located on a lower extremity and leading edge of the upper receiver. The embodiment of the inventive strut tool 100 shown in
The width or strut thickness dimension 122 may be of any selected size, but generally is selected with respect to the inner diameter of the rifle bore or opening into which the proximate end defined by the hook entry bevel region 108 is to be inserted, so that the forward flat and beveled regions 108 and 109 and the takedown block upper contact surface 110 fit snuggly within said rifle bore or opening in the lower receiver when the strut tool 100 is engaged, the lower edge of the hook leading surface 109 immediately adjacent to the takedown block upper contact surface 110 positioned along a chord internal to the rifle barrel diameter, as shown in
The engaging surfaces of the strut tool 100 are generally disposed in either a parallel or perpendicular configuration with respect to a center axis passing through the center of the strut block takedown pin bore 118 and parallel to the distal strut body front surface 116, including the hook leading surface 109 and the takedown block back contact surface 112. The takedown block is generally a rectangular structure machined into or present on lower edge of the upper receiver having a the takedown bore passing through it, so the takedown block engagement region 111 is defined by wall 110, 112 and 114 being perpendicularly oriented (square) with respect to one another, and the depth of the opening defined by 111 being sufficient to accommodate at least a portion of the takedown block of the upper receiver, while allowing the forward hook leading surface 109 sufficient clearance to enter the bore or opening of the upper receiver immediately adjacent to the takedown block. Accordingly, the surfaces 110 and 114 and top crown region 106 are generally disposed in a perpendicular orientation with respect to the center axis of the strut tool 100 as defined above.
In contrast, the rearward facing buffer block contact surface 102 is generally disposed at an angle with respect to the strut tool center axis, the angle generally being between 0 to 45 degrees, or alternatively between 0 to 30 degrees, or alternatively between 5 to 25 degrees, the angle selected so that the flat face of 102 is parallel to the interior face or interior flat surface portion of the threaded buffer coupling block (220 as shown in
While an AR-15 rifle is illustrated herein to show the position and functioning of the inventive strut tool, additional embodiments of the inventive strut tool can be adapted by adjusting the width, length and takedown pin bore diameter, to accommodate positioning within any similar rifles and upper and lower receiver assemblies thereof, including the AR-15, AR-15A2, AR-15A3 and AR-15A4, Colt XM16 (Armalite), and Colt SMG, all products of the Colt Manufacturing Company, West Hartford, Conn., and other modern sporting rifles (MSR) having similar configurations to the Colt AR-15, including, but not limited to ArmaLite M-15, Barrett REC7, Bravo Company Manufacturing BCM Carbines and Rifles, Bushmaster XM-15, Carbon 15, Daniel Defense DDM4, DPMS Panther Arms Tactical Rifle, Haenel CR 223, Heckler & Koch MR556, Lewis Machine & Tool Company CQB16, LWRC International IC series, Midwest Industries MI series, Mossberg Tactical Semi-Automatic Rifles, Olympic Arms K series, Patriot Ordnance Factory rifles and carbines, Quality Arms Tactical series, Remington GPC, Rock River Arms LAR-15, Ruger SR-556, Savage Arms MSR-15, SIG MCX, SIG Sauer SIG516, SIG Sauer SIGM400, Smith & Wesson M&P15, Stag Arms STAG-15, Wilson Combat Tactical Rifle, Windham Weaponry R series and Yankee Hill Machine 8000 series rifles, and other rifles corresponding to Colt Model No.s. 601, 602, 603, 604, 605, 605 A & B, 606 A& B, 607 A&B, 608-609, 610, 610B, 611 and 611P, 613 K & P, 614 and 614 S, 615-616, 619-621, 629, 630, 633-636, 640; M16A1 variants 645-656 and M16A2 variants 701-746; M4 Carbines such as the Colt Automatic Rifle Model #750, 777-779, 901, 905, 920-921 and 921 HB, 925-977; M16A3 variants 941-945, and Colt SMG 991 and 922, as well as other Colt AR15, M15, M16, M4 variants without a corresponding Colt Model number designation.
In
In another embodiment, a solid strut tool 520 has a strut tool width 522 and a takedown hook width 526 with a takedown pin strut bore diameter 528 sized to accommodate an AR-10 rifle. Similar modifications in the width and spacing parameters, 506, 508, 526 and 528 as well as the overall length of the inventive strut tool, may be selected in order to enable the tool to accommodate the servicing of any selected AR-style rifle as disclosed herein. Such variations are disclosed in more detail in
To illustrate how the optional guidance slot as described herein operates,
In yet another embodiment, the instant invention includes a strut tool having two opposed hook portions with the openings of their respective takedown bock engagement regions facing in opposite directions, so that the dual hook strut tool can be used in one of two positions, with one of the selected hook portions inserted into a first rifle bore, breech or barrel for servicing a first rifle; and wherein in a second, independent servicing the second selected hook portion can be inserted into a second rifle bore, breech or barrel for servicing a second rifle. In related embodiments, the dimensions, sizes and orientations of the two hook portions and their corresponding takedown block engagement regions can differ so as to accommodate fitment to a first and second rifle bore, breech or barrel. In yet a further set of embodiments, the inventive strut tool can feature two strut block takedown pin bores located adjacent to one another and located within the pivot portion of the strut tool, enabling selection of the desired bore for use in placement and securing of the strut tool by means of insertion of the takedown pin within the selected strut block takedown pin bores, in order to increase or decrease the relative angular displacement of the upper and lower receiver assemblies with respect to one another when the strut tool is engaged accordingly. In yet another series of embodiments, the inventive strut tool can feature two or a plurality of strut block takedown pin bores having different internal diameters to accommodate different diameter takedown pin sizes.
As can be seen in
Materials of Construction
The various inventive embodiments of the strut tool as disclosed and claimed herein may be manufacture from any suitable, resilient material, including, but not limited to, plastic, polymer, metal, alloys, resins and combinations thereof. Preferred materials are those having sufficient degree of structural strength and resistance to cleaning solvents and solutions typically employed when cleaning a firearm or rifle. Suitable polymers include, but are not limited to acrylonitrile, acetal resin (DuPont™ Delrin® acetal homopolymer resin), ABS (Acrylonitrile Butadiene Styrene), polyalkylenes (such as polybutylene, polyethylenediamine, polyethylene, etc.,), polystyrene, polymethacrylate, polyethylene terephthalate (PET), polyvinyl chloride (PVC), polyoxymethylene, DuPont™ Teflon® and cross-linked polymeric carbon and silicone based resins. Suitable metals include, but are not limited to, aluminum, copper, brass, iron, steel, titanium and alloys thereof, and combinations thereof.
Methods of construction include forming the strut tool as a machined part, with the various features, chambers, core regions, edges and bores being formed after casting of the base part, as well as direct casting or molding of the strut tool in substantially finished form or configuration, with or without post machining operations to render its final form and configuration as one or more embodiments of the inventive strut tool as disclosed herein. Also suitable is 3D printing of the strut tool, using computerized tomography to print out a solid shape in the final desired form using polymer printing, metal sintering and other similar manufacturing techniques that build a part layer by layer into an integrated final solid construct, with or without any additional post machining or processing operations.
The above illustration provides many different embodiments or embodiments for implementing different features of the invention. Specific embodiments of components and processes are described to help clarify the invention. These are, of course, merely embodiments and are not intended to limit the invention from that described in the claims.
Although the invention is illustrated and described herein as embodied in one or more specific examples, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims. Accordingly, it is appropriate that the appended claims be construed broadly and in a manner consistent with the scope of the invention, as set forth in the following claims.
Number | Name | Date | Kind |
---|---|---|---|
3222808 | Smith | Dec 1965 | A |
8474171 | Simmons | Jul 2013 | B1 |
20140115937 | Harman | May 2014 | A1 |