This disclosure relates to firearm assemblies and more particularly to a recoil bracket for a handgun.
Traditionally, handguns have included a metal frame to which additional components are attached using pins or fasteners, such as the fire control group, safety levers, and grip panels. More recently, some handguns have a polymeric grip module that houses a metal receiver and components of the fire control group. The recoil assembly, which includes the slide, barrel, and a recoil spring, is mounted on rails that extend along the top of the receiver such that the slide can reciprocate during the firing cycle. When a semiautomatic handgun is fired, the slide returns rearward to cycle the action. In doing so, the slide's dust cover contacts a recoil lug in the grip module and transfers recoil forces to the receiver and on to the shooter's hand via the grip module. For recoil-operated handguns, the barrel also moves rearward and stops abruptly on the takedown lever, slide stop, or receiver. The takedown lever or slide stop and recoil lug transfer recoil force to the receiver and grip module.
One aspect of the present disclosure is directed to a handgun grip module with a metal recoil lug that is movably retained in the slide portion of the grip module. In one example, the grip module is made of aluminum, an aluminum alloy, a metal-infused polymer. For example, the polymer is infused with steel brass, and/or tungsten. The recoil lug is movably retained in contact with or closely adjacent the distal end of the receiver. The recoil lug can be made of metal, such as aluminum, an aluminum alloy, steel, titanium, brass, or tungsten. When the gun is fired, the recoil lug can move rearward against the receiver and slightly upward at the point of contact between the lug and the receiver, followed by returning to the resting position at the end of the firing cycle. In contrast to a lug that is fixedly retained to the grip module by way of fasteners, this movement in the recoil lug better transfers forces and distributes recoil forces to a greater portion of the grip module. Accordingly, the recoil lug permits a smaller contact surface and a greater working clearance, features which are particularly helpful in a compact modular handgun. In accordance with some embodiments, the recoil lug exhibits an extended life compared to those that are fixed in the grip module by fasteners or the like.
The features and advantages described herein are not all-inclusive and, in particular, many additional features and advantages will be apparent to one of ordinary skill in the art in view of the drawings, specification, and claims. Moreover, it should be noted that the language used in the specification has been selected principally for readability and instructional purposes and not to limit the scope of the disclosed subject matter.
These and other features of the present embodiments will be better understood by reading the following detailed description, taken together with the Figures herein described. For purposes of clarity, not every component may be labeled in every drawing. Furthermore, as will be appreciated, the figures are not necessarily drawn to scale or intended to limit the present disclosure to the specific configurations shown. In short, the Figures are provided merely to show example structures.
Components of a handgun assembly are disclosed. In accordance with some embodiments of the present disclosure, a handgun grip module has a recoil lug movably retained in the grip module. For example, the recoil lug is positioned closely adjacent to or in contact with a distal end of the receiver. The recoil bracket can include one or more protrusions or “teeth” that engage the distal end of the frame. In use, the recoil bracket can move in response to various forces exerted on it during the firing cycle.
Some embodiments of a handgun grip module and handgun assembly of the present disclosure advantageously better distribute recoil energy to larger regions of the grip module. Accordingly, contact surfaces on the recoil lug can be reduced and in turn increase clearance within the handgun. The ability of the recoil bracket to move can also provide an extended service life of the handgun components, in accordance with some embodiments. While the advantages of the recoil lug are particularly applicable to compact handguns, a recoil lug in accordance with the present disclosure can be configured for use in compact and full-size handguns alike. Numerous configurations and variations will be apparent in light of this disclosure.
As discussed herein, terms referencing direction, such as upward, downward, vertical, horizontal, left, right, front, back, etc., are used for convenience to describe embodiments as conventionally oriented and as shown in the figures. Embodiments according to the present disclosure are not limited by these directional references and it is contemplated that a handgun, grip module, and other components discussed herein could be used in any orientation.
As noted above, non-trivial issues arise that complicate weapons design and performance of semiautomatic handguns. During the firing cycle of a handgun, several events (firing, unlocking, slide travel, locking, etc.) transmit loads from the working parts (barrel, slide, recoil spring, etc.) to parts interfaced by the operator (receiver, grip module, grip panels, etc.). The duration and magnitude of these loads impose constraints on the materials of these parts as well as on the size of the contact surface and on clearances.
Traditionally, the recoil energy of a semiautomatic handgun is absorbed primarily through the takedown lever, slide stop, or receiver and transmitted to the grip. The shooter feels recoil force upon firing the gun when the slide and barrel move rearward, followed by the dust cover at the distal end of the slide moving rearward and stopping against the recoil lug. The barrel also transfers recoil force to the frame as it moves rearward and stops abruptly on the takedown lever, slide stop, or receiver. In the case of a polymer grip module, a recoil lug can be embedded into the grip module to reinforce the polymer material and to distribute recoil forces more evenly to the grip module.
To add mass to a polymer-framed handgun, which can reduce felt recoil forces and may improve sight acquisition on follow-up shots, some semiautomatic handguns can have a metal grip module that accepts the receiver in the same way as the polymer grip module. For example, the grip module is made of aluminum. In some existing metal grip modules, the recoil lug and grip module are a single, monolithic structure. However, a full-size aluminum frame may already be the smallest size without either having a reduced product life or an added steel recoil insert. Thus, the metal grip modules of compact handguns may employ a steel insert that is secured into the grip module using fasteners. Metal grip modules having an integral recoil lug have exhibited early failure, such as the recoil lug cracking adjacent the receiver. In other designs, the recoil lug is fixedly retained in the grip module using screws. The fixed recoil lug attempts to solve the problem of early failure seen in monolithic designs. However, such designs exhibit failure at the screws and associated threaded bores. In many cases, failure at the recoil lug or threaded bores typically requires replacing the entire grip module since repairing this failure is unlikely to be cost effective.
Thus, a need exists for an improved recoil lug for a compact modular handgun that satisfies demands for reliability and durability. The present disclosure addresses this need and others by providing a recoil lug that is movably installed in the grip module. A movable recoil lug relaxes size and clearance constraints to permit the use of smaller contact surfaces and larger working clearances. In some embodiments, the movable recoil lug, or recoil bracket, is provided with a metal grip module. For example, the grip module can be made of aluminum or an aluminum alloy. In other embodiments, the grip module can be made of a polymer infused with steel, brass, and/or tungsten, for example. In one such embodiment, the polymer includes metal particles distributed through the polymer material; in other embodiments, the grip module includes metal inserts such as rods or blocks.
As will be appreciated in light of this disclosure, a grip module with movable recoil bracket can be used in a semiautomatic handgun of any size and having either striker-fired or hammer-fired action. In accordance with some example embodiments, a grip module with a movable recoil bracket is provided as part of a semiautomatic handgun of compact size, such as one having a barrel length no greater than 4 inches, no greater than 3.5 inches, no greater than 3.25 inches, or no more than 3 inches. Other suitable host firearms and chamberings will be apparent in light of this disclosure.
While generally referred to herein as a recoil bracket for consistency and ease of understanding the present disclosure, the disclosed recoil bracket is not limited to that specific terminology and alternatively can be referred to, for example, as a recoil lug, a metallic bracket, a metal insert, a frame insert, or other terms. As will be further appreciated, the particular configuration (e.g., materials, dimensions, etc.) of a recoil bracket configured as described herein may vary, for example, depending on whether the intended use is military, tactical, or civilian in nature. Numerous configurations will be apparent in light of this disclosure.
The lug 110 includes lateral posts 116 extending upward and a bridge 118 extending between and connecting them. A distal portion of each lateral post 116 is recessed to define an impact surface 117 for the slide's dust cover. In this example, the bridge 118 has an arcuate shape that extends between and connects the lateral posts 116. The bridge 118 can have a reduced axial thickness compared to the lateral posts 116. A tooth 114 extends distally from each lateral post 116. Each tooth 114 can have a generally triangular geometry, such as a trapezoidal or a triangular shape. The teeth 114 are shaped to be received in corresponding recesses 304 in the receiver 300 (shown in
The recoil bracket 100 of
On each side of the body 104 is a shelf or wing 106 that extends laterally outward from the body 104. For example, each wing 106 extends laterally to the same extent as the lug 110 and shares an outer lateral face 110a with the lug 110. In this example, each wing 106 has a vertical thickness that is less than that of the body 104. In use, each wing 106 is received in a recess or slot in the grip module (e.g., shown in
As with the embodiment discussed above, the lug 110 includes lateral posts 116 extending upward, and a bridge 118 extending between and connecting the lateral posts 116. The bridge 118 has an arcuate top surface that defines the central opening 112, at least in part. A distal portion of each lateral post 116 is recessed to define an impact surface 117 for the slide's dust cover. The bridge 118 generally has the same axial thickness as part of the lateral posts 116. A tooth 114 extends distally from each lateral post 116. The teeth 114 are shaped to be received in corresponding recesses in the receiver. In this example, each tooth 114 is positioned along the lateral margin of the respective lateral post 116 and is flush with an outer lateral face 110a of the lug 110.
The recoil bracket 100 of
In its installed position as shown, for example, the bridge 118 of the lug 110 abuts a barrel rest 210 that is part of the grip module 200. The barrel rest 210 extends up between the lateral posts 116 and is flush along its top surface with the top of the bridge 118. In other embodiments, the barrel rest 210 is omitted and can be replaced by a bridge 118 of increased axial thickness, such as shown in the recoil bracket of
The receiver 300 includes rails 306 that extend axially along the top of the receiver 300 and are elevated above the recoil bracket 100. The receiver 300 defines a takedown lever opening 308. A barrel lug 310 extends crosswise between opposite sides of the receiver 300.
The foot 130 of the recoil bracket 100 occupies the foot recess 210 in the slide portion 204 of the grip module 200. The foot 130 makes contact with a load-bearing surface 214a during part or all of the firing cycle, in accordance with some embodiments. Note that the foot recess 210 is positioned above where the trigger guard 206 connects with the slide portion 204 of the grip module 200. The recoil lug 100 and receiver 300 transfer recoils forces to the grip module 200 by contact with one or more load bearing surfaces 214a, 214b, 214c, 214d, 214e.
In use, a recoil bracket 100 that is movably retained in the grip module 200, as variously disclosed herein, can more effectively transfer force and avoid mechanical failure compared to other designs. In accordance with some embodiments, the slide and barrel begin to unlock during the initial phase of the firing cycle. As a result, the receiver 300 is pulled upward by engagement between the barrel and barrel lug 310. Contact between the receiver 300 and the recoil bracket 100 at the teeth 114 results in an upward force on the recoil bracket 100. Wings 106 on the recoil bracket 100 engage the slot or undercut 212 in the grip module 200, pushing the grip module 200 upward. The grip module 200 then applies upward and rearward torque on the operator's wrist. The relatively greater area of contact between the recoil bracket 100 and receiver 300 in this example avoids failure at the tooth 114 and/or the failure at fastener openings in other designs of a recoil bracket.
As the end of the barrel and slide unlock, the receiver 300 is pushed downward by engagement between the barrel and barrel lug 310. As a result, the receiver 300 shifts and applies a downward force on the teeth 114 of the recoil bracket 100. In turn the recoil bracket 100 shifts and the wings 106 apply a downward force on the grip module 200. The grip module 200 then torques the operator's wrist down and forward. In contrast, other designs may fail at the tooth when the steel receiver shifts since the recoil bracket is retained in a fixed position. Also, in other designs that are screwed to the grip module, for example, the recoil bracket may fail due to forces applied at the relatively small area of the fasteners and associated bores.
When the slide impacts and stops on the impact surface 117 of the recoil bracket 100, the recoil bracket 100 is pushed rearward against the receiver 300, moving the receiver 300 rearward. The receiver 300 engages load bearing surfaces 214b-214e and transfers rearward force to the grip module 200. The grip module 200 torques the operator's wrist upward and rearward. In contrast, other designs may fail because the impact of the slide is transferred directly to the grip module by the bracket rather than being transferred to the receiver and then to the grip module at load bearing surfaces.
When the slide returns forward and stops, the receiver 300 is pushed forward by impact between the barrel and barrel lug 310. The receiver 300 then shifts so that the distal end 302 of the receiver 300 engages the recoil bracket 100, pushing the recoil bracket 100 forward. In turn, the recoil bracket 100 shifts position so that the distal end and/or foot 130 of the recoil bracket engage the grip module 200 and push the grip module 200 forward. The grip module 200 then torques the operator's wrist forward and down. In accordance with the present disclosure, moving the point of impact forward in the grip module 200 increases strain relief and allows the trigger guard 206 to share the load. In contrast, other designs may fail because the grip module is relatively thin near the distal end of the receiver.
The following examples pertain to further embodiments, from which numerous permutations and configurations will be apparent.
Example 1 is a handgun grip module assembly that includes a grip module with a handgrip portion, a slide portion, and a trigger guard extending between and connecting the handgrip portion to the slide portion. The slide portion extends longitudinally along a central axis and has opposed sidewalls and a bottom wall. The slide portion defines a bracket recess in the bottom wall and defines a receiver well between the opposed sidewalls and above the handgrip portion. A recoil bracket is movably disposed in the bracket recess.
Example 2 includes the assembly of Example 1, wherein the grip module is made primarily or entirely of metal.
Example 3 includes the assembly of Example 1, wherein the grip module is made of aluminum, an aluminum alloy, or a metal-infused polymer. In one such embodiment, the metal-infused polymer includes powder, granules, or regular or irregular blocks of metal, or combinations of such metal forms.
Example 4 includes the assembly of Example 3, wherein the recoil bracket is made of or includes steel, aluminum, an aluminum alloy, titanium, brass, or tungsten.
Example 5 includes the assembly of any one of Examples 1-4, wherein the recoil bracket has a longitudinal portion extending along the central axis, the longitudinal portion received in the bracket recess. The recoil bracket also has a lug portion extending upward from the longitudinal portion, the lug portion defining a U-shaped passageway. A portion of the bracket recess extends upward along the opposed sidewalls, and sides of the lug portion are received in the portion of the bracket recess that extends upward along the opposed sidewalls.
Example 6 includes the assembly of Example 5, wherein the recoil bracket further comprises teeth protruding rearward from the lug portion. For example, sides of the lug portion each have a tooth extending rearward.
Example 7 includes the assembly of Example 6 and further comprises a receiver disposed in the receiver well, where a distal end of the receiver abuts a proximal face of the lug portion, and where the distal end of the receiver defines recesses that receive the teeth on the recoil bracket.
Example 8 includes the assembly of Example 7, wherein the receiver includes fire control components.
Example 9 includes the assembly of any one of Examples 5-8, wherein the recoil bracket includes an eye on a bottom of the longitudinal portion, the eye defining an elongated through opening.
Example 10 includes the assembly of Example 9 and further comprises a retaining pin extending laterally through the slide portion of the grip module and the through opening of the eye.
Example 11 includes the assembly of any one of Examples 5-10, wherein a top surface of the longitudinal portion has an arcuate profile.
Example 12 includes the assembly of Example 11, wherein the top surface of the longitudinal portion is flush or substantially flush with the bottom wall of the slide portion of the grip module.
Example 13 includes the assembly of any one of Examples 5-12, wherein the bracket recess includes a foot recess portion of increased depth, and wherein the recoil bracket includes a foot extending downward from the longitudinal portion and is received in the foot recess portion.
Example 14 includes the assembly of Example 13, wherein the foot is located at a distal end of the longitudinal portion.
Example 15 includes the assembly of any one of Examples 5-14, wherein the grip module defines lateral recesses along part of the opposed sidewalls, and wherein the recoil bracket includes wings extending laterally outward from the longitudinal portion, each of the wings received in one of the lateral recesses.
Example 16 includes the assembly of any one of Examples 1-15, wherein the trigger guard connects to the slide portion of the grip module below the bracket recess.
Example 17 includes the assembly of any one of Examples 1-16, wherein the grip module defines a recoil block between the bracket recess and the receiver well, the recoil block extending up from the bottom wall and abutting or positioned to abut a proximal face of the recoil bracket in use.
Example 18 is a semiautomatic handgun comprising the handgun grip module assembly of any one of Examples 1-17.
Example 19 includes the handgun of Example 18 configured as a compact handgun having a barrel length of not more than four inches. In some embodiments, the barrel length is not more than 3.5 inches or not more than 3.25 inches.
Example 20 includes the semiautomatic handgun of Example 18 or 19, where the handgun is chambered in 9 mm Luger.
The foregoing description of example embodiments has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the present disclosure to the precise forms disclosed. Many modifications and variations are possible in light of this disclosure. It is intended that the scope of the present disclosure be limited not by this detailed description, but rather by the claims appended hereto. Future-filed applications claiming priority to this application may claim the disclosed subject matter in a different manner and generally may include any set of one or more limitations as variously disclosed or otherwise demonstrated herein.
This application claims the benefit under 35 U.S.C. § 119(e) of U.S. Provisional Patent Application No. 63/386,575, titled RECOIL BRACKET FOR A HANDGUN, and filed on Dec. 8, 2022, the contents of which are incorporated herein by reference in its entirety.
Number | Date | Country | |
---|---|---|---|
63386575 | Dec 2022 | US |