Muzzleloaders are a class of firearms in which the propellant charge and bullet are separately loaded into the barrel immediately prior to firing. Unlike modern breech loaded firearms where the bullet, propellant charge and primer are loaded as prepackaged cartridges, muzzleloaders are loaded by feeding a propellant charge through the muzzle of the barrel before ramming a bullet down the barrel with a ramrod until the bullet is seated against the propellant charge at the breech end of the barrel. A primer is inserted at the breech to be in communication with the propellant. The primer is then struck by an inline firing pin or an external hammer to ignite the propellant charge to create propellant gases for propelling the bullet.
A variability in muzzleloaders not present in cartridge based firearms is the quantity and type of the propellant charge. Unlike cartridge firearms where a cartridge is preloaded with a bullet and premeasured quantity of propellant is loaded into the firearm for firing, the bullet and propellant charge are combined within the firearm for firing. Accordingly, the muzzleloader operator can select the optimal bullet, propellant type and quantity combination for each shot, which is particularly advantageous given the long reloading time for muzzleloaders. While the variability of the bullet—propellant charge combination allows for an optimized shot, varying the bullet and in particular the propellant and quantity of propellant can significantly change the appropriate seating depth of the bullet. With loose or powdered propellant such as black powder, the amount of propellant is often varied between 80 and 120 volumetric grains. Similarly, propellants are often formed into cylindrical pellets that are stacked end-to-end within the barrel to form the propellant charges. The pellets are typically each about 1 cm in length and loaded in 1 to 3 pellet groups causing an even greater variation in the seating depth. Of course, variability in the powder, bullet, and seating depth causes variability in performance, including accuracy.
Another safety concern unique to muzzleloaders is an undersized or oversized propellant charge. Unlike cartridge firearms where the amount of propellant loaded for each shot is limited by the internal volume of the cartridge, theoretically, the amount of propellant loaded for each shot in muzzleloaders is only limited by the length of the barrel. While measures are often used to provide a constant quantity of propellant for each propellant charge, the measures can be difficult to use in the field or in low ambient light when hunting often occurs. Similarly, propellant can be formed into the pre-sized pellets that can be loaded one at a time until the appropriate amount of propellant is loaded. As with measuring the quantity of powder, errors can occur in loading the appropriate number of pellets. Embodiments of the disclosure address the above issues.
All conventional firearms are designed and built and chambered to fire a single size of ammunition. Incorrectly sized ammunition should not properly seat in the chamber and otherwise not allow for firing same. Breech action firearms such as single fire shotguns and double barrel shotguns conventionally have a planar breech block face with a central firing pin hole with a planar breech block face. Muzzleloading systems featuring breech loaded and sealed propellant cartridges have been developed by the owner of the instant application and have been disclosed as having a planar breech block face. See, for example, U.S. Pat. No. 10,030,956, incorporated by reference herein except for express definitions and patent claims contained therein. The applicant has developed non-conventional interface systems between the breech block face and cartridges providing a high level of certainty that only intended propellant vessels can be fired in the muzzleloader.
In some embodiments of the disclosure, a muzzleloader system has a muzzleloader rifle having a barrel with a breech chamber that opens rearwardly, a constriction portion forward of the breech chamber, and a barrel bore of reduced size forward of the constriction portion. A projectile is muzzle loaded and a pre-packaged, hermetically sealed propellant charge having a polymer vessel filled with propellant is breech loaded in the breech chamber. The polymer vessel includes a flange at a rearward end and a primer receptacle centrally positioned at the rearward end. In some embodiments, cooperating features between the rear face of the polymer vessel and the muzzleloader rifle breech block provide means for limiting engagement of the firing pin with only a specifically configured polymer vessel with primer.
In some embodiments, the muzzleloader rifle has a chamber to receive the polymer propellant vessel and a breech block face that presents a most forward extending structure within the axial rearward projection of the chamber, a primer receiving surface on the breech block face that is positioned rearwardly of the forward most extending structure, and a firing pin that does not extend forward past the forward most extending structure. In some embodiments, the forwardmost extending structure is a projection such as one or more pins, or such as an annular projection, that mate with a corresponding recess on the rear face of the propellant vessel. In some embodiments, the forward most structure is a planar breech block face that confronts the breech face around the chamber, and the primer receiving surface of the breech block face is positioned at bottom of a cylindrical recess surrounding a firing pin hole.
In some embodiments, a muzzleloader polymer propellant vessel has a primer recess with a depth that is less than an overall height of the primer so that the primer, when inserted into the primer receptacle, extends rearwardly beyond a rearward facing surface of the propellant containment vessel. The breech block face of the muzzleloader rifle may define a recess sized to receive the projecting primer. The firing pin of the rifle may be configured to not extend beyond a planar face of the breech block surface surrounding the recess. In some embodiments, the rearward face of the propellant vessel has an annular polymer projection defining the primer receptacle portion therein to receive the primer with a flange, the flange seating on the rearward face of the annular polymer projection. The breech block face may define a recess configured to receive a polymer projection and primer installed therein. In some embodiments, the components are configured such that the internal face of the recess of the breech block face is compressively engages the primer flange and polymer projection.
In some embodiments, a rimfire primer is inserted in a primer receptacle and the firing pin hole and firing pin actuation region is offset from the central axis of the chamber. The rimfire primer may extend from the rear face of the polymer vessel or may be seated in a centrally positioned annular projection. In some embodiments, one or more means for limiting engagement of the firing pin with only a specifically configured polymer vessel with primer may be combined.
An example muzzleloader system includes a propellant containment vessel for use with a primer, a projectile and a muzzleloader. In some embodiments, the system includes a propellant containment vessel separate from the primer and the projectile so that the propellant containment vessel is not in contact with the projectile and the primer does not contact the propellant containment vessel until an assembly step has been completed. In some embodiments, the propellant containment vessel is sized to be received in the breech chamber and has a head portion with a flange and a primer receptacle. A body portion may taper toward a forward end with the forward end conformed to engage a constriction portion in the muzzleloader. The propellant vessel may include means for precluding the loading of the vessel into a firearm other than an intended muzzleloader rifle. The muzzleloader rifle may include means for precluding the firing of any ammunition except for an intended and a specifically configured propellant vessel with a primer inserted therein.
In some embodiments, the system is dimensioned and adapted for use with a muzzleloader having a firing pin and a pair of positioning pins. The firing pin may be slideable between a forward-most position and a more rearward position. In some embodiments, the firing pin extends forwardly beyond a forward facing surface of a breech block by a first distance when the firing pin is in the forward-most position. In some embodiments, each positioning pin extends forwardly beyond the forward facing surface of a breech block by a second distance. The second distance may be greater than the first distance so that the firing pin does not extend through a plane defined by the forward most surfaces of the positioning pins when the firing pin is in the forward-most position.
A feature and benefit of various embodiments of the disclosure is a muzzleloader power cell capsule including a rearward portion containing a propellant charge and a forward portion covering a forward opening of the rearward portion. In some embodiments, the forward portion is expelled from the muzzle loader upon ignition of the propellant charge.
A feature and benefit of various embodiments of the disclosure is a muzzleloader system including a power cell containing a propellant charge for use with a bullet that is not attached to the power cell. In some embodiments, the lack of attachment between the power cell and the bullet may provide increased accuracy when the bullet is fired. In some embodiments, the power cell with propellant charge is loaded through the rearward breech end of the barrel and the bullet is loaded through the forward, muzzle end of the barrel.
A feature and benefit of various embodiments of the disclosure is that the breech loading or unloading of the propellant charge allows for safe separation of the propellant charge from the bullet loaded within the barrel. When it is desired to unload the muzzleloader, the propellant containment vessel is removed, unfired, from the breech and the bullet then safely pulled or pushed down the barrel and removed from the muzzleloader without risk of inadvertent or delayed ignition of the propellant charge and subsequent firing of the projectile.
A feature and benefit of various embodiments of the disclosure is a muzzleloader system power cell include a transparent or translucent body portion containing a propellant charge and a cap portion hermetically to the body portion. In some embodiments, the transparent or translucent body portion enables visual inspection of the charge without breaking the hermetic seal. In some embodiments, the cap portions are color coded in a manner representative of types and/or quantities of propellant. The cap can be on the forward or rearward end of the vessel portion.
A feature and benefit of various embodiments of the disclosure is a muzzleloader system including a power cell containing a propellant charge sized and adapted to propel a bullet having a weight greater than 200 grains so as to provide a quick and humane kill when hunting. In some embodiments, the muzzleloader system includes a power cell containing a propellant charge sized and adapted to propel a bullet having a weight greater than 250 grains. In some embodiments, the muzzleloader system includes a power cell containing a propellant charge sized and adapted to propel a bullet having a weight greater than 300 grains. Some embodiments herein are specifically addressed to muzzle-loaded projectiles from 45 caliber to 50 caliber.
A feature and benefit of various embodiments of the disclosure is a muzzleloader system including a power cell containing a propellant charge for use with primer and a bullet, the bullet being sized so that the muzzleloader system is suitable for use in hunting large game such as elk, moose and bear.
In some embodiments, there is a means for limiting engagement of a firing pin of the muzzleloader rifle with only the propellant containment vessel with the primer installed, wherein the means for limiting engagement includes features on a rearward face of the flange of the propellant containment vessel that cooperate with features on a face of a breech block of the muzzleloader rifle; wherein the propellant containment vessel has a rearward central projection with the primer seated therein and the face of the breech block defines a recess configured to receive the central projection with the primer; wherein the primer recess defines an axial depth that is less than an axial length of the primer, such that the primer projects rearwardly from the rearward face of the flange of the propellant containment vessel; wherein a firing pin of the muzzleloader rifle is precluded from extending forwardly past a plane of the face of the breech block; wherein the means for limiting engagement includes a projection from a face of a breech block of the muzzleloader rifle that extends into a recess defined at a rearward face of the flange of the propellant containment vessel.
In some embodiments, there is a means for limiting the muzzleloader rifle to firing only the propellant containment vessel, wherein the propellant containment vessel is separate from the primer and the projectile so that the propellant containment vessel is not in contact with the projectile and the primer does not contact the propellant containment vessel until an assembly step has been completed; wherein the primer receptacle defines a primer recess having an axial length that is shorter than an axial length of the primer.
In some embodiments, there is a method for manufacturing a muzzleloader power cell, the method comprising: disposing a propellant in a unitary polymer propellant containment vessel; inserting an over-powder disk into a mouth at a forward end of the unitary polymer propellant containment vessel; and forming a roll crimp at the mouth of the forward end to secure the over-powder disk at the forward end of the unitary polymer propellant containment vessel; before the step of forming a roll crimp, seating said over-powder disk on a ledge portion within the unitary polymer propellant containment vessel, the ledge portion being rearward of the mouth; forming an annular projection at a rearward face of a rearward flange of the unitary polymer propellant containment vessel, the annular projection extending axially rearward from the rearward face.
In some embodiments, there is a muzzle loader power cell comprising a rearward polymer flange portion, a polymer casing portion unitary with the polymer flange portion, the polymer casing portion extending to a forward end of the power cell and defining an interior, the flange portion having a primer aperture for receiving a primer and having a unitary polymer closure forward of the primer, the primer aperture closed with respect to the interior of the casing, propellant in the interior of the casing, the power cell having a rolled crimp closure at the forward end closing the forward end; wherein the aperture is closed by way of a polymer webbing unitary with the polymer flange.
The above summary of the various representative embodiments is not intended to describe each or every implementation of the claimed invention. Rather, the embodiments are chosen and described so that others skilled in the art can appreciate and understand the principles and practices disclosed herein. The Figures in the detailed description that follow more particularly exemplify these embodiments.
The claimed invention can be completely understood in consideration of the following detailed description of various embodiments disclosed herein in connection with the accompanying drawings, in which:
While the disclosed embodiments are amenable to various modifications and alternative forms, specifics thereof have been depicted by way of example in the drawings and will be described in detail. It should be understood, however, that the intention is not to limit the claimed invention to the particular embodiments described. On the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.
Referring to
In some embodiments, the muzzleloader 20 has a breech brake 42 that opens as shown in
Herein, “forward” and its derivatives (e.g., forwardly, forward-most) is designated by arrow 71 refers to a direction that is parallel to the z-axis of the r-O-z axis of
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The muzzleloader power cell 32f defines an overall axial length 208, extending from a rearward extremity 212 of the annular projection 146 to a forward extremity 214 of the roll crimp 206 of the propellant containment vessel 40f. The propellant containment vessel 40f defines a body axial length 216 that extends from a forward face 218 of the flange 96 to the forward extremity 214 of the roll crimp 206, and also defines a breech chamber axial insertion length 220 that extends from a rearward face of the flange 96 to the forward extremity 214 of the roll crimp 206. In operation, the muzzleloader power cell 32f is inserted into the breech chamber 60 so that the roll crimp 206 registers against the constriction portion 54 of the muzzleloader rifle 22.
Referring to
The unitary polymer structure 232 of the propellant containment vessel 40f (as well as for propellant containment vessels 40 generally) may be fabricated by techniques known to the artisan, such as injection molding, machining, or a combination thereof. For example, the unitary polymer structure 232 may be initially cast by an injection molding technique that is finished by machining techniques to provide tighter tolerances of critical surfaces and lengths (e.g., the seating face 238 of the ledge portion 204, the rearward flange face 102, the axial length L1 to the rearward extremity 136 of the annular projection 126, and/or a thickness of the distal thin wall portion 246). The over-powder disk 202 may be manufactured, for example, from a polymer or cardboard.
Functionally, the annular projection 126 provides the same safety aspects as with the muzzleloader cell 32e, described above attendant to
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The following United States patents are hereby incorporated by reference herein in their entirety except for patent claims and express definitions contained therein: U.S. Pat. Nos. 9,273,941; 9,261,335; 9,003,973; 8,875,633; 8,869,702; 8,763,535; 8,726,560; 8,590,199; 8,573,126; 8,561,543; 8,453,367; 8,443,730; 8,240,252; 8,146,505; 7,984,668; 7,621,208; 7,444,775; 7,441,504; 7,302,890; 7,278,358; 7,225,741; 7,059,234; 6,931,978; 6,845,716; 6,752,084; 6,625,916; 6,564,719; 6,439,123; 6,178,889; 5,677,505; 5,492,063; 5,359,937; 5,216,199; 4,955,157; 4,169,329; 4,098,016; 4,069,608; 4,058,922; 4,057,003; 3,776,095; 3,771,415; and 3,261,291. Components and features illustrated in the incorporated by reference references may be utilized with embodiments herein. Incorporation by reference is discussed, for example, in MPEP section 2163.07(B).
All of the features disclosed, claimed, and incorporated by reference herein, and all of the steps of any method or process so disclosed, may be combined in any combination, except combinations where at least some of such features and/or steps are mutually exclusive. Each feature disclosed in this specification may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is an example only of a generic series of equivalent or similar features. Inventive aspects of this disclosure are not restricted to the details of the foregoing embodiments, but rather extend to any novel embodiment, or any novel combination of embodiments, of the features presented in this disclosure, and to any novel embodiment, or any novel combination of embodiments, of the steps of any method or process so disclosed.
Although specific examples have been illustrated and described herein, it will be appreciated by those of ordinary skill in the art that any arrangement calculated to achieve the same purpose could be substituted for the specific examples disclosed. This application is intended to cover adaptations or variations of the present subject matter. Moreover, the embodiments herein may have applicability to other types of firearms. Therefore, it is intended that the invention be defined by the attached claims and their legal equivalents, as well as the illustrative aspects. The above described embodiments are merely descriptive of its principles and are not to be considered limiting.
This application claims the benefit of U.S. Provisional Patent Application No. 62/794,669, filed Jan. 20, 2019, the disclosure of which is hereby incorporated by reference herein in its entirety.
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