Conventional firearm magazines are fabricated from metal, plastic, or a combination of the two. Plastic magazines have certain advantages over metal magazines that make them highly desirable. For example, plastic magazines are often cheaper to manufacture, lighter, quieter, and exhibit better chemical resistance characteristics. Additionally, plastics offer features not available with metals, such as allowing a see-through magazine. Further, molded plastic magazines can have more complex shapes than a stamped metal magazine.
Despite this, metal magazines typically maintain one critical advantage. Metal magazines have greater strength and rigidity compared to plastic magazines of the same wall thickness. In general, metal magazines have greater durability when dropped. The feed lips of a metal magazine are less likely to bend or fracture. Moreover, a metal magazine typically exhibits less swelling when loaded, e.g., at the taper of a double stack magazine, compared to plastics at a given wall thickness.
The basic design of a firearm magazine is constrained by the size of the magazine well of the associated firearm and the size of the rounds to be held by the magazine. The external and internal dimensions imposed by the magazine well and the rounds dictate the wall thickness. Firearms with magazines originally designed using metal may have magazine wall thickness so thin that they preclude the use of plastic magazines. In other cases, plastic magazine alternatives are available but may be significantly less reliable than the metal magazines they replace.
Not surprisingly, hybrid magazines are an attempt to merge the best features of metal and plastics and mitigate the deficiencies. Using metal to bolster the strength of the magazine at high stress points in an otherwise plastic magazine is undoubtedly desirable. Conventional hybrid magazines typically use over and/or under molding to join the plastic and metal. While such techniques may be suitable for magazines designed for certain firearms, the dimensional limitations and tolerances make hybrid magazine design a challenge and, in certain cases, impossible.
It is with respect to these and other considerations that the present invention has been made.
The following summary discusses various aspects of the invention described more fully in the detailed description and claimed herein. It is not intended to be limiting and should not be used to limit the claimed invention to only such aspects or to require the invention to include all such aspects.
The hybrid magazine includes a body having a first section and a second section. The hybrid magazine has one or more walls. The thickness of the walls in the hybrid magazine is dictated by the dimensions of the magazine well of the corresponding firearm and the dimensions of the cartridges for which the hybrid magazine is designed. The top end of the first section defines an opening bounded by the feed lips. A taper region narrows the first section and transitions the cartridges from a double stack configuration of the second section to single stack configuration for presentation at the feed lips. The first section and the second section are dissimilar materials. A conventional hybrid magazine utilizes a plastic over or under molded onto a metal component. Further, a conventional hybrid magazine may include through openings or blind openings in the metal component that are filled with the plastic for alignment, to further maintain the connection between of the plastic, or both.
For purposes of discussion, the first section is the upper part of the magazine that includes the taper region and the feed lips. The taper region and the feed lips experience the most stress. The first section is fabricated from a metal. The second section is the lower section of the magazine and is fabricated from a plastic. This hybrid approach allows the magazine to obtain the best of both materials. The first section provides the necessary strength and rigidity in the areas where it is need most while the second section offers enhancements such as weight reduction, translucency for visualization of rounds in the magazine, complex geometries for improved grip or other purposes, and ease of manufacturing.
The hybrid magazine includes retention features that securely join the first section and the second section and prevent movement along the vertical axis, the lateral (left-right) axis, and the longitudinal (front-back) axis. The retention features include the alignment joint where the second section is molded to the first section. The hybrid magazine optionally includes at least one retention coupler that prevent separation of the first section and the second section vertically and horizontally.
The retention coupler includes one or more projections (i.e., tabs) or recesses (i.e., slots) formed by the first section and complementary components formed by the second section. The tabs are molded during the formation of the second section and fill the slots of the first section. The retention coupler has two functions. First, the retention coupler increases the surface of the contact region the upper section and the lower section. Second, the geometry of the retention coupler enhances the resistance to movement of the first section relative to the second section along one or more of the vertical axis, the lateral axis, or the longitudinal axis.
The slots and tabs of the retention coupler have two main structural features the serve to maintain the connection between the first section and the second section. First, the slot has depth h relative to edge of the first section. The depth h of the slot creates an impediment to movement of the first section relative to the second section in the horizontal direction. Second, the slot has variable width w over the depth h to create some portion of the slot that is wider than the rest of the slot. This overhang creates an impediment to movement of the first section relative to the second section in the direction of the horizontal axis running parallel to the wall containing the retention coupler. Because the portion of the retention coupler formed by the second section is molded, there are no complicated manufacturing processes or fitment issues such as would be encountered if trying to join sections made from pre-formed rigid materials.
The shape of retention coupler increases the surface area connected by the alignment joint and, therefore, strengthen the bond between the first section and the second section. The face of the edge of the first section is not flat where it connects to the second section. The first section has a nonlinear edge. When the second section is molded to the first section, the plastic fills in the area of the nonlinear edge of the first section edge to form the alignment joint. The height of the alignment joint is typically only a small fraction of the overall wall thickness such that the combined thickness at the alignment joint is substantially equal to the thicknesses of the first section and the second section proximate to the alignment joint. The alignment joint prevents movement of the first section relative to the second section in the direction of the axis running perpendicular to the face of the wall.
One aspect of the present invention is that the faces of the first section and the second section are substantially planar. Thus, the there is no significant change in thickness of the wall between the first section and the second section at the alignment joint. It is contemplated that there may some situations where the design of the firearm or the magazine allows for non-critical dimensional differences at other places. Dimensional variations in the wall thickness occurring in such non-critical portions of the magazine are not considered be part of the retention features or other aspects of the present invention and are considered to fall within the scope and spirit of the present invention.
Further features, aspects, and advantages of the present disclosure will become better understood by reference to the following figures wherein like reference numbers indicate like elements throughout the several views:
Aspects of a hybrid firearm magazine are described herein and illustrated in the accompanying figures. The hybrid firearm magazine has a first section fabricated from a sheet material and a second section molded from a plastic. The first section includes a mating edge defining one or more recesses. The second section engages the mating end of the first section with the plastic filling the recesses. The mating end has nonlinear edge. The plastic fills in around the nonlinear edge of the first section to form a joint. The interface of joint prevent movement of the first section relative to the second section along the vertical and horizontal axes of the hybrid firearm magazine. The thickness of the second section at the joint is substantially equal to the thickness of the first section. Optional retention couplers improve the strength of the joint and the resistance to movement of the first section relative to the second section.
For convenience, generic references to the materials used in the construction of the hybrid magazine may be used. Such references are not intended to be limiting. Specifically, references to “plastic” are intended to encompass to any moldable material having a polymeric base including thermoset plastics, thermoplastics, and plastic composites (e.g., a glass filled nylon). Further, references to “metal” are intended to encompass any substantially rigid sheet material suitable for use in a magazine having greater strength/less ductility than plastics. By way of example, Table 1 lists some of the relevant physical properties of a representative metal and a representative plastic used in conventional magazines.
The hybrid magazine has one or more walls. The thickness of the walls in the hybrid magazine is dictated by the dimensions of the magazine well of the corresponding firearm and the dimensions of the cartridges for which the hybrid magazine 100 is designed. The top end of the first section 102 defines an opening 106 bounded by the feed lips 108. A taper region 110 narrows the first section 102 and transitions the cartridges from a double stack configuration of the second section 104 to single stack configuration for presentation at the feed lips 108. In the exemplary embodiments, the hybrid magazine 100 is depicted as a double-stack box magazine having a substantially tubular housing. However, the present invention is applicable to other types, shapes, and designs of firearm magazines.
Aspects of the present invention contemplate that the first section 102 and the second section 104 are dissimilar materials. A conventional hybrid magazine utilizes a plastic over or under molded onto a metal component. Further, a conventional hybrid magazine may include through openings or blind openings in the metal component that are filled with the plastic for alignment, to further maintain the connection between of the plastic, or both. Often a combination of these techniques in the construction of a conventional hybrid magazine. Over and under molding necessarily increases the wall thickness and can only be used in magazines where the dimensions allow for a greater wall thickness. However, there are certain magazines, e.g., magazines for the SIG P365®, where over or under molding is not an option because of tight tolerances. Aspects of the present invention allow for the fabrication of a hybrid magazine where tight tolerances preclude the use of conventional hybrid magazine construction techniques.
In the illustrated embodiment, the first section 102 is the upper part of the magazine 100 that includes the taper region 110 and the feed lips 108. As previously mentioned, the taper region 110 and the feed lips 108 experience the most stress. The first section 102 is fabricated from a metal. The second section 104 is the lower section of the magazine 100 and is fabricated from a plastic. This hybrid approach allows the magazine to obtain the best of both materials. The first section 102 provides the necessary strength and rigidity in the areas where it is need most while the second section offers enhancements such as weight reduction, translucency for visualization of rounds in the magazine, complex geometries for improved grip or other purposes, and ease of manufacturing.
The hybrid magazine 100 includes retention features that securely join the first section 102 and the second section 104 and prevent movement along the vertical axis 112, the lateral (left-right) axis 114, and the longitudinal (front-back) axis 116. Herein, the lateral axis 114 and the longitudinal axis 116 may be referred to as the horizontal axes where reference to a particular direction is not needed. The retention features include the alignment joint 118 where the second section 104 is molded to the mating end of the first section 102. The hybrid magazine 100 optionally includes at least one retention coupler 120 that prevent separation of the first section 102 and the second section 104 vertically and horizontally.
The retention coupler 120 includes one or more projections (i.e., tabs) or recesses (i.e., slots) formed by the first section 102 and complementary components formed by the second section 104. For purposes of discussion, the portion of the retention coupler 120 formed by the first section 102 will be referred to as slots and the portion of the retention coupler 120 formed by the second section 104 will be referred to as tabs. The tabs are molded during the formation of the second section 104 and fill the slots of the first section 102. Regardless of the nomenclature, the retention coupler 120 has two functions. First, the retention coupler 120 increases the surface of the contact region the upper section 102 and the lower section 104. Second, the geometry of the retention coupler 120 enhances the resistance to movement of the first section 102 relative to the second section 104 along one or more of the vertical axis 112, the lateral axis 114, or the longitudinal axis 116. In embodiment of
Because of the design of the alignment joint 118 and the optional retention coupler 120, overmolding is not required to join the second section 104 to the first section 102. Thus, the dimensions of the hybrid magazine 100 can remain consistent with a conventional all metal magazine and obtain the benefits of utilizing a plastic for portions of the hybrid magazine 100. This allows fabrication of hybrid magazines for firearms where the tight fitment tolerances imposed by the dimensions of the magazine well and the size of the rounds preclude the use of plastic magazines and the use of hybrid magazines made using conventional techniques, such as overmolding. For example, plastics cannot provide the required strength in magazine walls limited to a certain thickness while overmolding a plastic onto a metal wall causes the magazine to exceed the dimensional requirements placed on the magazine by the firearm.
The slots and tabs of the retention coupler 120 have two main structural features the serve to maintain the connection between the first section 102 and the second section 104. First, the slot has depth h relative to edge of the first section 102. The depth h of the slot creates an impediment to movement of the first section 102 relative to the second section 104 in the horizontal direction. Second, the slot has variable width w over the depth h to create some portion of the slot that is wider than the rest of the slot. This overhang creates an impediment to movement of the first section 102 relative to the second section 104 in the direction of the horizontal axis running parallel to the wall containing the retention coupler 120. In the embodiment of
The shape of retention coupler 120 increases the surface area connected by the alignment joint 118 and, therefore, strengthen the bond between the first section 102 and the second section 104. It should be noted that in embodiments of the hybrid magazine 100 utilizing multiple retention couplers 120 arranged around the perimeter, the distribution of the load over multiple retention couplers 120 further strengthens the effectiveness of the retention features.
When the second section 104 is molded to the first section 102, the plastic fills in the area of the nonlinear edge 402 of the first section edge 400 to form the alignment joint 118. The height of the alignment joint 118 is typically only a small fraction of the overall wall thickness such that the combined thickness at the alignment joint 118 is substantially equal to the thicknesses of the first section 102 and the second section 104 proximate to the alignment joint 118. Effectively, the interface is akin to intentionally controlled flashing created during the molding process; however, with a suitably strong plastic, this small interface creates a structure that is sufficient to minimize or eliminate the likelihood that the wall of the second section 104 becomes misaligned from the wall of the first section 102. In other words, the alignment joint prevents movement of the first section 102 relative to the second section 104 in the direction of the axis running perpendicular to the face of the wall.
Beyond preventing misalignment of the walls, the alignment joint 118 also contributes to preventing movement of the first section 102 relative to the second section 104. During the molding process, the plastic bonds with the metal of the first section 102 and creates resistance to separation in the direction of the vertical axis 112. As the plastic cools, it shrinks and creates an even tighter compression fitting with the first section 102 that prevents the relative movement of the first section 102 and the second section 104 relative to the horizontal axes. Because the alignment joint 118 extends around the entire perimeter of the magazine, the lateral runs provide resistance against the relative movement of the first section 102 and the second section 104 in direction of the longitudinal axis 116 and the longitudinal runs provide resistance against the relative movement of the first section 102 and the second section 104 in direction of the lateral axis 114.
One aspect of the present invention is that the faces 404 of the first section 102 and the second section 104 are substantially planar. Thus, the there is no significant change in thickness of the wall between the first section 102 and the second section 104 at the alignment joint 118. It is contemplated that there may some situations where the design of the firearm or the magazine allows for non-critical dimensional differences at other places. For example, in an extended magazine there are no dimensional limitations imposed by the firearm on the portion of the magazine that sticks out beyond the magazine well. Dimensional variations in the wall thickness occurring in such non-critical portions of the magazine are not considered be part of the retention features or other aspects of the present invention and are considered to fall within the scope and spirit of the present invention.
As before, the hybrid magazine 500 includes retention features that securely join the first section 502 and the second section 504. The retention features include an alignment joint 506 where the second section 504 is molded to the first section 502. The hybrid magazine 500 optionally includes one or more retention couplers 508 that facilitate the connection between the first section 502 and the second section 504 on at least one wall of the hybrid magazine 500 where the thickness of that magazine wall remains substantially equal in the area around the joint between the first section 502 and the second section 504. Again, dimensional variations in the wall thickness occurring in such non-critical portions of the magazine are not considered be part of the retention features or other aspects of the present invention and are considered to fall within the scope and spirit of the present invention. The embodiment of the retention coupler 508 shown in
In some magazines, at least portions of some walls of a magazine have relaxed dimensional limitations. For example, consider a magazine for a magazine well located in a pistol grip. Based on the size of the cartridges, there dimensional limitations from front to rear may be more cumbersome than from side to side. As such, there may not sufficient clearance to employ overmolding, undermolding, throughmolding, or other conventional molding techniques on either or both of the front and rear walls but plenty of room for such conventional molding techniques on the side walls. Even if sufficient clearance exists to use such conventional molding techniques on, for example, the front wall, there remains a need for a way to securely join the first section 502 to the second section 504 of the rear wall 510. The embodiment of
In
It is not sufficient to merely secure the first section 502 to the second section 504 on three sides of the hybrid magazine 500. The walls of a magazine generally present a smooth linear face along their length. Even a small offset in a wall between the first section 502 and the second section 504 can cause rounds to catch in the magazine or prevent clean insertion and removal of the magazine from the magazine well. Thus, the alignment joint facilitates maintaining a smooth linear face for the magazine wall.
In accordance with aspects of the present invention, the rear wall 510 of the first section 502 does not have any overmolding, undermolding or throughmolding. The joint 506 and the optional retention couplers 508 include the nonlinear edge treatment described herein with reference to
The above specification, examples, and data provide a complete description of the manufacture and use of the composition of the invention. Since many implementations of the invention can be made without departing from the spirit and scope of the invention, the invention resides in the claims hereinafter appended.
| Number | Date | Country | |
|---|---|---|---|
| 63446888 | Feb 2023 | US |