MODULAR REACTION ROD WITH INTERCHANGEABLE HEAD FOR FIREARMS

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Application No. 63/658,672, titled REACTION ROD WITH INTERCHANGEABLE HEAD FOR USE IN WORK ON FIREARMS, filed Jun. 11, 2024, which is hereby incorporated by reference in its entirety.

BACKGROUND

1) Field of the Invention

The present disclosure relates to tools for firearm maintenance and assembly, and more particularly to a reaction rod with an interchangeable head for use in holding firearms while working on the same.

2) Description of the Related Art

Reaction rods have become an integral tool in firearm maintenance and modification, particularly for AR-15 style rifles and similar platforms. These devices serve multiple purposes, including stabilizing the barrel during installation or removal of components, preventing torque transfer to the receiver, and facilitating the mounting of accessories such as muzzle brakes and gas blocks.

Traditionally, reaction rods have been constructed as single-piece units, typically machined from a solid metal such as steel or aluminum. While functional, this design approach presents several challenges. Steel rods offer excellent durability and strength but are often heavy, making them less convenient for gunsmiths and hobbyists to handle during extended use. Conversely, aluminum rods provide a lighter-weight option but may lack the necessary durability for frequent, heavy-duty applications.

The single-piece construction of conventional reaction rods also poses limitations in terms of versatility and longevity. When the working end of a rod becomes damaged or worn from repeated use, the entire tool often needs replacement. This can be costly and wasteful, especially considering that the majority of the tool may still be in good condition. Additionally, different firearms or maintenance tasks may require variations in the tool end configuration, necessitating the purchase and storage of multiple specialized reaction rods.

Another consideration in the design of reaction rods is the method of securing them in a vise or workbench. The rod itself is typically cylindrical and unsuitable for clamping in a vise. Many existing models rely on simple flat surfaces or basic geometric shapes cut from the cylindrical shape for clamping. Such Surfaces may not provide optimal grip or stability during high-torque operations or when force is applied in some directions. This can potentially lead to slippage or misalignment during critical tasks.

The firearms industry has recognized a growing need for reaction rods that address these limitations. There is demand for tools that balance strength and weight more effectively, allowing for comfortable use without sacrificing durability. Additionally, a modular design that permits the replacement of worn components or the interchange of different tool ends would enhance versatility and reduce long-term costs for users.

Furthermore, improvements in the vise attachment mechanism could enhance the overall stability and safety of the tool during use. A more secure and adaptable mounting system would benefit users working on a variety of firearm platforms or in different workshop setups.

As the popularity of firearm customization and home gunsmithing continues to grow, there is an increasing market for tools that can meet the evolving needs of both professional gunsmiths and enthusiasts. Addressing the limitations of current reaction rod designs could lead to more efficient, cost-effective, and user-friendly solutions for firearm maintenance and modification tasks.

SUMMARY

This summary is provided to introduce a selection of concepts in a simplified form that are further described below in the detailed description. This summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

A modular reaction rod for gunsmithing having a shaft with a distal end and a proximal end. Protruding from the proximal end of the shaft one or more lugs capable of engaging with an interchangeable head which can be removably mounted on the shaft. The interchangeable head features a tool end configured to engage with a firearm component and a connection end with receptacles corresponding to the lugs to accept the lugs when the interchangeable head is mounted on the shaft. The interchangeable head can be secured to the shaft by an attachment mechanism.

The foregoing general description of the illustrative embodiments and the following detailed description thereof are merely exemplary aspects of the teachings of this disclosure and are not restrictive.

BRIEF DESCRIPTION OF FIGURES

The construction designed to carry out the invention will hereinafter be described, together with other features thereof. The invention will be more readily understood from a reading of the following specification and by reference to the accompanying drawings forming a part thereof, wherein an example of the invention is shown and wherein:

FIG. 1 illustrates an isometric view of a reaction rod assembly, according to aspects of the present disclosure.

FIG. 2 shows an exploded view of components of an embodiment of the invention.

FIG. 3 depicts an exploded view of a two-part reaction rod assembly, in accordance with example embodiments.

FIG. 4 illustrates a perspective view of a partially assembled reaction rod, according to aspects of the present disclosure.

FIG. 5 shows a partially assembled view of a reaction rod assembly, according to an embodiment.

DETAILED DESCRIPTION

The following description sets forth exemplary aspects of the present disclosure. It should be recognized, however, that such description is not intended as a limitation on the scope of the present disclosure. Rather, the description also encompasses combinations and modifications to those exemplary aspects described herein.

The modular reaction rod may be used for assembly, disassembly, and maintenance of firearms, i.e. gunsmithing. In one embodiment, the modular reaction rod comprises a shaft and an interchangeable head. The interchangeable head may engage with components of a firearm, such as barrel lugs, while the shaft extends through the firearm receiver. The end of the shaft opposite the interchangeable head may provide a mounting surface for securing in a vise.

The modular design allows for interchangeability of the head. In some cases, different heads may be used with the same shaft to accommodate various firearm types or calibers. This interchangeability may also allow for replacement of worn or damaged heads without replacing the entire tool. The head of the modular reaction rod may be constructed of a strong, durable material suitable for repeated engagement with firearm components. This allows the head to withstand high torque applications without deformation. The shaft may be made of a lighter weight material, contributing to an overall lightweight design that enhances usability for gunsmiths and users.

The design of the modular reaction rod may address limitations of traditional, one-piece reaction rods. Traditional designs may require replacement of the entire tool if the engagement portion becomes worn or damaged. The modular reaction rod only requires replacement of the work component. Additionally, traditional designs may necessitate multiple tools for different firearm types. The modular design allows for adaptation to various firearms with a single base tool and interchangeable heads. The modular construction provides cost-effectiveness. First, the body of the shaft may be made from a less costly material than the interchangeable head as it is thicker and experiences less physical contact. Second, if a component becomes worn or damaged, only that specific part may need replacement rather than the entire tool. Third alternative interchangeable heads may be used allowing for a single modular reaction rod to perform the functions of multiple standard reaction rods. This may reduce both immediate and long-term costs for users. The ability to vary construction material also allows for achieving specific characteristics for one component while not compromising on another component. For instance, shaft material could be chosen for strength, or ability to resist bending, allowing for a longer elongated shaft to reach recessed components.

FIG. 1 illustrates an isometric view of a reaction rod assembly. The assembly comprises a reaction rod shaft 100 that extends longitudinally. At the distal end of the reaction rod shaft 100, a vise mount 106 is provided. The vise mount 106 may be used to secure the reaction rod assembly in a vise or other holding device during use. The vise mount 106 features mounting grooves 116 on opposing sides. These mounting grooves 116 may serve multiple purposes. In some cases, the mounting grooves 116 may provide enhanced grip when the reaction rod assembly is secured in a vise, helping to prevent rotation under load during use.

In some cases, the mounting grooves 116 may form an accessory rail. The accessory rail may be compatible with various rail systems commonly used in firearms and related equipment such as: a picatinny rail, an area rail, a dovetail rail, Warsaw Pact rail, weaver rail, SOPMOD, Magpul M-LOK, UIT rails, freeland rail and any combination. This configuration may allow for attachment of additional tools or accessories to the reaction rod assembly. Alternatively, the mounting grooves may allow for use in a specialized holding device or mounting system which can grip the grooves. The mounting grooves may also serve to mount based off of vise designed to hold components containing rails. The design of the vise mount 106 with mounting grooves 116 may provide versatility in how the reaction rod assembly can be secured and used. The mounting grooves 116 may offer improved stability and control during high-torque applications, which may be beneficial when working on firearm components. For instance, the mounting grooves provide multi-dimensional contact surface for the vise preventing the modular reaction rod from rotating within the vise.

An interchangeable head 102 is attached to the proximal end of the reaction rod shaft 100. The interchangeable head 102 includes a tool end 104 that may be configured to engage with components of a firearm, such as barrel lugs. Opposite the tool end is a connection end that contains the means to connect the interchangeable head to the reaction rod. The overall design of the reaction rod assembly presents a streamlined profile. The interchangeable head 102 transitions smoothly into the reaction rod shaft 100, which may allow for easy insertion of the assembly into a firearm receiver when in use.

FIG. 2 illustrates an exploded view of components of the reaction rod assembly. The figure shows the proximal end of the reaction rod shaft 100 and the interchangeable head 102. The proximal end of the reaction rod shaft 100 includes a connection mechanism of multiple protruding lugs 208 arranged in a pattern. This series of lugs can be arranged in a pattern that allows for rotation of the orientation of the interchangeable head in relation to the reaction rod shaft or requires that orientation be fixed. The lugs 208 may be integrally formed from the reaction rod shaft. In another embodiment, the lugs may be formed separately and received into mounting slots within the reaction rod shaft. The interchangeable head 102 features on the connection end corresponding lug receptacles 210 configured to receive the protruding lugs 208. The series of lug receptacles is formed in the same pattern as the corresponding lugs. The tool end 104 of the interchangeable head 102 contains features for engaging with firearm components.

An attachment mechanism, such as attachment bolt 212 is shown separately. The attachment bolt 212 may pass through the interchangeable head 102 and engage with the reaction rod shaft 100 to secure the assembly. When assembled, the protruding lugs 208 are received into the lug receptacles 210. This arrangement allows for the transfer of force from the interchangeable head 102 to the reaction rod shaft 100 without placing stress on the attachment bolt 212. The use of multiple protruding lugs 208 and lug receptacles 210 may distribute the load across the lugs, increasing the amount of force the assembly can withstand before failure. The attachment mechanism could be any number of means such as bolt, screw, nut, spring and detent, friction, magnet or the like. Multiple attachment mechanisms can be used in combination.

In some cases, the interchangeable head 102 may be held to the reaction rod shaft 100 by means other than the attachment bolt 212. For example, friction between the protruding lugs 208 and the lug receptacles 210 may be sufficient to secure the interchangeable head 102 to the reaction rod shaft 100. In other cases, magnets may be incorporated into the design to hold the interchangeable head 102 in place on the reaction rod shaft 100. In yet another embodiment, a spring and detent or catch could be used to hold the interchangeable head to the reaction rod shaft.

The configuration shown in FIG. 2 demonstrates how the components can be aligned and assembled. The protruding lugs 208 and lug receptacles 210 ensure proper alignment between the interchangeable head 102 and the reaction rod shaft 100, while the attachment bolt 212 provides additional securement when fully assembled.

FIG. 3 illustrates an exploded view of a two-part reaction rod assembly. The assembly includes the reaction rod shaft 100 and the interchangeable head 102 that may be coupled together. The reaction rod shaft 100 includes the protruding lugs 208 arranged in a circular pattern at the distal end. Other end patterns may be used, however it is beneficial to leave the axis open for an attachment receptacle 314. The interchangeable head 102 features the corresponding lug receptacles 210 arranged to align with and accept the protruding lugs 208 when the interchangeable head 102 is mounted onto the reaction rod shaft 100. An attachment receptacle 314 is positioned centrally within the circular pattern of the lug receptacles 210 on the interchangeable head 102. The attachment receptacle 314 may provide a means for securing the interchangeable head 102 to the reaction rod shaft 100 once the protruding lugs 208 are engaged with the lug receptacles 210.

The arrangement of the protruding lugs 208 and the lug receptacles 210 allows for proper alignment and torque transfer between the reaction rod shaft 100 and the interchangeable head 102 when assembled. This configuration may ensure that rotational forces are transmitted through the protruding lugs 208 and the lug receptacles 210, rather than through the attachment bolt 212 and the attachment receptacle 314. To assist with this, the attachment bolt 212 and attachment receptacle 314 are located along the axis of the reaction rod shaft 100. If the lugs were to break or bend, the interchangeable head could rotate around the attachment bolt without applying force to the same.

The design of the protruding lugs, lug receptacles, attachment receptacle 314 and the corresponding attachment bolt 212 may also allow for easy removal of the interchangeable head 102 from the reaction rod shaft 100, even after strenuous use. Since the attachment bolt 212 and the attachment receptacle 314 are not subjected to torque forces during operation because of the previously discussed lug and lug receptacle arrangements, these components may not become bound or damaged. This configuration may maintain the ease of disassembly and interchangeability of the head 102, which may be beneficial for maintenance, replacement, or switching between different tool end 104 configurations.

In some cases, the protruding lugs 208 and the lug receptacles 210 may be arranged symmetrically. A symmetrical arrangement may allow the interchangeable head 102 to be mounted in multiple orientations while maintaining proper alignment and function. In other cases, the protruding lugs 208 and the lug receptacles 210 may be arranged asymmetrically. An asymmetrical arrangement may ensure that the interchangeable head 102 can only be mounted in a specific orientation, which may be beneficial for certain applications or tool end 104 configurations.

FIG. 4 illustrates a perspective view of a partially assembled reaction rod. The reaction rod shaft 100 extends diagonally across the image, with the interchangeable head 102 positioned at the proximal end. The tool end 104 of the interchangeable head 102 is visible and features a specialized configuration designed to engage with firearm components. The attachment bolt 212 is shown protruding from the tool end 104 and is positioned to secure the interchangeable head 102 to the reaction rod shaft 100.

The ability to remove and interchange the interchangeable head 102 from the reaction rod shaft 100 provides several benefits. In some cases, the size of the interchangeable head 102 may be changed to accommodate different types of firearms. For example, the interchangeable head 102 may be swapped to transition from use with an AR-15 style firearm to an AR-10 style firearm. This versatility may allow a single reaction rod shaft 100 to be used with multiple firearm platforms by simply changing the interchangeable head 102.

In some cases, if the interchangeable head 102 becomes damaged during use, the interchangeable head 102 may be replaced without the need to replace the entire reaction rod assembly. This modular design may extend the useful life of the reaction rod and reduce long-term costs for users.

The modular construction of the reaction rod may allow for the reaction rod shaft 100 and the interchangeable head 102 to be made from different materials. In some cases, the reaction rod shaft 100 may be constructed from a lightweight, softer material such as aluminum, structural plastics, or the like. The use of a lighter material for the reaction rod shaft 100 may reduce the overall weight of the tool, potentially improving usability and reducing user fatigue during extended use.

The interchangeable head 102 may be constructed from a high-strength material, such as steel, titanium or the like, in some cases. High-strength material can be chosen for its capability to resist deforming force. The use of a stronger material for the interchangeable head 102 may provide increased durability and wear resistance for the component that directly engages with firearm parts. This configuration may allow for a balance between overall tool weight and durability of the working end. The two-part construction may also allow for a cheaper material to be used in non-critical locations further reducing the cost of the tool. The combination of materials, such as an aluminum reaction rod shaft 100 with a steel interchangeable head 102, may provide benefits in terms of weight, strength, and cost-effectiveness. The modular design may allow for optimization of material properties for each component based on its specific function within the reaction rod assembly.

In an alternative configuration, the interchangeable head can be made from a weaker or softer material designed to fail, i.e. deform, before other components of the reaction rod or firearm fail. In this manner the interchangeable head can be made expendable to protect the other components.

FIG. 5 illustrates a partially assembled view of the reaction rod assembly. The reaction rod shaft 100 is shown with the interchangeable head 102 positioned partially installed over the reaction rod shaft 100. The protruding lugs 208 are visible extending from the proximal end of the reaction rod shaft 100, with the interchangeable head 102 partially engaged with these protruding lugs 208. The tool end 104 of the interchangeable head 102 is configured to interface with firearm components. The attachment bolt 212 is positioned to secure the interchangeable head 102 to the reaction rod shaft 100 when fully assembled.

The figure demonstrates how the components align during the assembly process. The interchangeable head 102 may be designed to slide over and engage with the protruding lugs 208 on the reaction rod shaft 100 before being secured by the attachment bolt 212. This alignment process may ensure proper engagement between the protruding lugs 208 and the corresponding lug receptacles in the interchangeable head 102.

The ability to exchange the interchangeable heads on the reaction rod greatly enhances the functionality of the reaction rod. In some cases, the length and diameter of the interchangeable head 102 may be varied to fit different firearm types. For example, a longer interchangeable head 102 may be used for firearms with extended receivers, while a shorter interchangeable head 102 may be used for compact firearms. Similarly, the diameter of the interchangeable head 102 may be adjusted to accommodate different caliber firearms or variations in receiver dimensions. The ability to vary the dimensions of the interchangeable head 102 may allow the reaction rod assembly to be adapted for use with a wide range of firearm types and models. This versatility may be achieved without the need to replace the entire reaction rod shaft 100, potentially reducing costs and increasing the utility of the tool for users who work with multiple firearm platforms.

The modular reaction rod represents a significant advancement in firearm maintenance tools, offering a range of benefits that address limitations of traditional reaction rods while providing enhanced versatility and cost-effectiveness. An advantage of the modular reaction rod is its adaptability across different firearm types and calibers. The interchangeable head design allows users to switch between various configurations to accommodate different barrel lug patterns or other applications. This versatility eliminates the need for multiple specialized tools, as a single modular reaction rod may be adapted for use with various firearms by simply changing the head.

The modular reaction rod can be received, at least in part, into a firearm receiver. This allows the interchangeable head to reach internal components of the firearm such as the barrel lugs. The vise section of the reaction rod remains external to the receiver and capable of being mounting in a holding device such as a vise. By this manner, the receiver can be allowed to float over the reaction rod and not engaged by the reaction rod or the vise while the user works on the barrel.

The modular construction contributes to the tool's cost-effectiveness. In cases where a component becomes worn or damaged, only that specific part may need replacement rather than the entire tool. This modular approach may reduce long-term costs for users and extend the overall lifespan of the tool. Another benefit is the modular design may allow for longer length configurations. By adjusting the length of the head or shaft, the reaction rod may be adapted for use with firearms that have extended receivers or unique geometries. This flexibility in length may further expand the range of firearms that can be serviced with a single tool.

The design of the modular reaction rod allows for optimization of weight distribution and overall lightweight construction. In some cases, the shaft may be constructed from a lighter material, such as aluminum, while the head may be made from a stronger material, such as steel. This configuration may provide a balance between reduced overall weight and enhanced durability in critical areas. The lightweight design may improve usability and potentially reduce user fatigue during extended use.

The modular reaction rod may also offer enhanced strength in critical areas. By using stronger materials for the head, which directly engages with firearm components, the tool may provide increased durability and wear resistance where it is most needed. This targeted approach to material selection may result in a tool that is both lightweight and robust.

The combination of these features collectively addresses many limitations of traditional reaction rods. The modular design allows for easy replacement of worn components, adaptation to different firearm types, and optimization of materials for specific functions. This may result in a more versatile, durable, and cost-effective tool compared to traditional one-piece designs.

The modular reaction rod may find applications in various user scenarios. Gunsmiths and firearm technicians who work with multiple firearm platforms may benefit from the tool's adaptability. Military and law enforcement armories, which often maintain a diverse array of firearms, may find the modular reaction rod's versatility particularly useful. Firearm manufacturers may also utilize the tool in production and quality control processes, potentially benefiting from its ability to be configured for different models or calibers.

In one embodiment, a reaction rod for working on a firearm is provided. The reaction rod includes a shaft having a distal end and a proximal end, one or more lugs protruding from the proximal end of the shaft, and an interchangeable head removably mounted on the shaft at the proximal end. The interchangeable head has a tool end configured to engage with firearm components, a connection end, and one or more receptacles at the connection end. Each receptacle corresponds with each lug on the shaft and is configured to accept the lug when the interchangeable head is mounted to the shaft. The interchangeable head is secured to the shaft by an attachment mechanism that allows for easy removal and replacement of the interchangeable head. The attachment mechanism may be selected from a group consisting of screw, bolt, nut, friction, spring and detent, magnet, and any combination thereof.

In further refinement, the tool end of the interchangeable head is configured to engage with barrel lugs of a firearm. The distal end of the shaft may include a vise engagement section. The vise engagement section may have opposing flat portions for grip in a vise. In another embodiment, the vise engagement section may include mounting grooves configured to secure the reaction rod in a vise. The mounting grooves may form an accessory rail compatible with at least one of: a picatinny rail, an area rail, a dovetail rail, Warsaw Pact rail, weaver rail, SOPMOD, Magpul M-LOK, UIT rails, freeland rail and any combination.

The lugs on the shaft and the corresponding receptacles on the interchangeable head may be arranged in a circular pattern to distribute torque evenly when force is applied to the interchangeable head. The lugs may be formed from high strength material capable of resisting deforming force. In a refinement for light weight, the shaft may br composed of a lightweight material and the interchangeable head composed of a high-strength material.

In another embodiment, the system may include an elongated shaft having a distal end and a proximal end, a mounting portion at the distal end of the shaft configured for securing the shaft in a holding device, and an interchangeable head removably coupled to the proximal end of the shaft. The interchangeable head has a working end adapted to interface with firearm components.

The interchangeable head may be coupled to the shaft by a connection mechanism comprising a plurality of lugs protruding from the proximal end of the shaft and a plurality of corresponding receptacles on the interchangeable head configured to engage with the lugs. The shaft may sized to be received into an AR-15 style firearm or an AR-10 style firearm. The system may further comprise a set of alternative interchangeable heads, each configured to interface with different firearm types or calibers.

In another embodiment, a firearm maintenance tool is provided. The tool includes a rod portion having a distal end and a proximal end, a vise engagement section at the distal end of the rod portion, and a removable tool head attached to the proximal end of the rod portion. The removable tool head is configured to engage with firearm components. The removable tool head is interchangeable with other tool heads to adapt the firearm maintenance tool for use with different firearm types or components.

The removable head may be made of a material which will deform under force before the rod portion. The removable tool head may be secured to the rod portion via a lug pattern designed to distribute torque evenly when force is applied to the removable tool head. The removable tool head may be composed of a high-strength material and the rod portion composed of a lightweight material. The high-strength material may be steel and the lightweight material aluminum.

In summary, the modular reaction rod represents an advancement in firearm maintenance tools by offering a combination of versatility, adaptability, cost-effectiveness, and optimized design. These features collectively provide a solution that may better meet the needs of various users in the firearm maintenance and manufacturing sectors.

The dimensions and values disclosed herein are not to be understood as being strictly limited to the exact numerical values recited. Instead, unless otherwise specified, each such dimension is intended to mean both the recited value and a functionally equivalent range surrounding that value. For example, a dimension disclosed as “40 wt. %” is intended to mean “about 40 wt. %”.

A number of implementations have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the disclosure. Accordingly, other implementations are within the scope of the following claims.