The present invention generally relates to firearms, and more particularly to systems for reducing felt recoil from discharging the firearm.
A recoil force is generated when a firearm is discharged. The bullet or slug and high pressure combustion gases generated exit the muzzle end of the barrel in a forward direction at considerable velocity. This creates a recoil force which drives the firearm in an opposite rearward direction towards the shooter (user) under the principles of momentum. The recoil force generated is substantially equal to the forward discharge force of the propellant gases. Various firearm recoil reduction approaches have been used.
When firing a long gun such as a rifle or shotgun which may use somewhat high power ammunition, the felt recoil may especially be significant and uncomfortable for the user. In addition, this may make it more difficult to reacquire a target and fire a second shot accurately. In the case of a shotgun, a user may also sometimes find it desirable to alternate between firing light load shotshells on some occasions and heavy load shotshells on other occasions depending on the type of target shooting and/or hunting activity planned. This also is applicable to switching between different cartridges in a rifle for firearms provided with this capability.
Accordingly, it is therefore desirable to at least partially abate and lessen the recoil forces acting against the user's arms and shoulder against which the buttstock of a rifle or shotgun is typically abutted. It is also further desirable to have the ability to adjust a recoil adjustment system for a shotgun or rifle to accommodate firing different type loads.
A recoil reduction system is provided for a firearm which may be mounted in the buttstock of a rifle or shotgun. The system includes a spring suppression mechanism to dampen felt recoil. In one embodiment, the recoil reduction system includes a user-tunable adjustment feature allowing the suppression or dampening capacity of the system to be changed to accommodate firing different types of loads.
According to an aspect of the invention, an adjustable recoil reduction system for a firearm includes: an axially extending buttstock having a longitudinal stock axis, a rear end, a front end, and a longitudinally extending internal cavity; a ram including a cantilevered mounting extension, the mounting extension projecting forward from the ram through the rear end of the buttstock into the internal cavity, the mounting extension slideably coupling the ram to the buttstock; a butt pad coupled to the ram; an adjustable plunger assembly comprising a rear spring guide disposed in the buttstock and a preload adjustment screw rotatably coupled to the ram and engaging the rear spring guide, the plunger assembly being movable forward and rearward in the buttstock; and a first compression spring mounted inside the buttstock and engaged by the rear spring guide, the plunger assembly operating to compress the first compression spring when the buttstock moves rearward relative to the plunger assembly; wherein rotating the adjustment screw in a first direction advances the rear spring guide and compresses the first compression spring for setting a first preload condition, and rotating the adjustment screw in an opposite second direction retracts the rear spring guide and allows the first compression spring to expand for setting a second preload condition; wherein when a rearward acting recoil force is generated by discharging the firearm, the buttstock moves rearward and compresses the first compression spring against the plunger assembly to absorb at least a portion of the recoil force.
According to another aspect of the invention, an adjustable recoil reduction system for a firearm includes: a buttstock extending rearward from a receiver, the buttstock having a longitudinal stock axis, a rear end, a front end, and an internal cavity extending between the front and rear ends; a spring assembly disposed in the buttstock, the spring assembly comprising a tubular sleeve fixedly mounted inside the buttstock, a first spring inside the sleeve, a second spring inside the sleeve concentrically arranged around the first spring, a rear spring guide engaged with the first and second springs, and a front spring guide engaged with the first and second springs; a butt pad assembly comprising a butt pad configured for placement against a shoulder of a user and a ram coupled to butt pad, the butt pad assembly movably coupled to the buttstock; an axially elongated preload adjustment screw threadably coupled to the ram and having a front end engaging the rear spring guide to fix a position of the rear spring guide relative to the sleeve, the preload adjustment screw movable forward and rearward relative to the buttstock by rotating the preload adjustment screw in opposing directions; wherein rotating the preload adjustment screw in a first direction compresses the first and second springs to set a first preload condition, and rotating the preload adjustment screw in an opposite second direction expands the first and second springs to set a second preload condition; wherein when a rearward acting recoil force is generated by discharging the firearm, the buttstock moves rearward and the rear spring guide compresses the first and second springs thereby absorbing at least a portion of the recoil force.
A method for reducing recoil in a firearm includes: providing a firearm including a buttstock, a butt pad assembly movably coupled to a rear end of the buttstock, a coiled first spring disposed inside the buttstock, and an adjustable plunger mechanism comprising a rear spring guide engaging the compression spring and a preload adjustment screw rotatably coupled to the butt pad assembly and engaging the rear spring guide, the buttstock being in a forward non-recoil position spaced apart from the butt pad assembly by a first distance; rotating the preload adjustment screw in a first direction which advances the rear spring guide forward in the buttstock; compressing the first spring by the advancement of the rear spring guide to a first preload condition; discharging the firearm; moving the buttstock in a rearward direction under recoil closer to the butt pad, the buttstock being in a rearward recoil position spaced apart from the butt pad assembly by a second distance smaller than the first distance; the buttstock compressing the first spring by movement in the rearward direction; expanding the first spring; and returning the buttstock to the forward non-recoil position.
Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter.
The features of the exemplary embodiments will be described with reference to the following drawings where like elements are labeled similarly, and in which:
All drawings are schematic and not necessarily to scale. Parts given a reference numerical designation in one figure may be considered to be the same parts where they appear in other figures without a numerical designation for brevity unless specifically labeled with a different part number and/or described herein.
The features and benefits of the invention are illustrated and described herein by reference to exemplary embodiments. This description of exemplary embodiments is intended to be read in connection with the accompanying drawings, which are to be considered part of the entire written description. Accordingly, the disclosure expressly should not be limited to such exemplary embodiments illustrating some possible non-limiting combination of features that may exist alone or in other combinations of features.
In the description of embodiments disclosed herein, any reference to direction or orientation is merely intended for convenience of description and is not intended in any way to limit the scope of the present invention. Relative terms such as “lower,” “upper,” “horizontal,” “vertical,”, “above,” “below,” “up,” “down,” “top” and “bottom” as well as derivative thereof (e.g., “horizontally,” “downwardly,” “upwardly,” etc.) should be construed to refer to the orientation as then described or as shown in the drawing under discussion. These relative terms are for convenience of description only and do not require that the apparatus be constructed or operated in a particular orientation. Terms such as “attached,” “affixed,” “connected,” “coupled,” “interconnected,” and similar refer to a relationship wherein structures are secured or attached to one another either directly or indirectly through intervening structures, as well as both movable or rigid attachments or relationships, unless expressly described otherwise.
The term “action” is used herein in its conventional sense in the firearm art as meaning the mechanism that loads and ejects shells into/from the firearm and opens and closes the breech (i.e. the area in the receiver between an openable/closeable breech face on the front of the bolt and the rear face of the barrel chamber).
Referring now to
A butt or recoil pad 40 is mounted on rear end of the buttstock. The butt pad 40 may be made of an energy absorbing resilient deformable material, such as for example without limitation foam, gel, rubber, or other material. In other embodiments the butt pad may be made of a rigid material (e.g. hard plastic, wood, etc.). A longitudinally extending cheek rest or comb 43 is mounted on the top 37 of the buttstock 30 for placement against a user's cheek when holding the firearm 20 in the ready-to-fire aiming position. In one embodiment, the comb 43 is fixedly attached to the buttstock 30 so that the comb moves rearward with the buttstock under recoil as a unit. Buttstock 30 may further include a removable bottom cover 30a which provides access for mounting the butt pad assembly to the buttstock, as further described herein.
Referring to
The stationary components generally comprise the butt pad 40, hard insert 42, spacer plate 50, ram 60, skirt 70, skirt retaining plate 110, fasteners 41, and preload adjustment mechanism comprising a preload adjustment screw 80, and transverse dowel pins 100. Collectively, these components may be considered to form a “butt pad assembly” 40a which removably mounts to the rear end of the buttstock 30. In use, these butt pad components are buttressed by a user's shoulder and remain relatively stationary with respect to the moving components recognizing that the user's body will naturally undergo some slight motion and deformation due to the recoil forces generated.
Butt pad 40 may be overmolded onto hard insert 42 which provides a rigid structure or backbone for securing the more resilient pad to ram 60 via threaded fasteners 41 that extend through corresponding holes formed in the skirt retaining plate 110 and spacer plate 50 interspersed between the butt pad and ram. The fasteners 41 each engage a corresponding threaded socket 44 disposed in the ram. In some embodiments, the sockets 44 may be formed in threaded metallic inserts disposed in upper and lower longitudinal passages 44b, 44a formed in the ram 60. In other embodiments, the longitudinal passages 44a, 44b may themselves instead be internally threaded to receive the threaded stem of the fasteners 41. Either arrangement may be used. It bears noting that in certain embodiments where the butt pad 40 is formed of a relatively rigid material, the hard insert 42 may be omitted. Butt pad 40 may include through holes 45 used to access the heads of fasteners 41 for installing and removing the butt pad from the stock 30. Accordingly, butt pad in such an embodiment is removably attached to the buttstock and readily replaceable.
Hard insert 42 may be made of a suitably rigid material, including without limitation hard plastic, metal (e.g. aluminum, titanium, steel, etc.), composites, etc. Butt pad 40 may have a vertically elongated oblong shape which is configured and contoured to abuttingly engage a user's shoulder. Hard insert 42 may have a similar complementary shape in some embodiments (see, e.g.
With continuing reference to
In one embodiment, the butt pad hard insert 42, spacer plate 50, and skirt retaining plate 110 are further mutually configured to form an interlock fit creating a nestable and stackable assembly. Referring to
In one embodiment to access preload adjustment screw 80, protrusion 113 on skirt retaining plate 110 may include an axial through hole 114. Through hole 114 communicates with corresponding vertically elongated through slot 55 in spacer plate 50, elongated through slot 48 in hard insert 42, and vertically elongated through passage 49 in butt pad 40. The combination of through holes and slots are sufficient to provide a linear path for inserting the shaft of a hex key (not shown) into a mating hex socket formed in the enlarged head of the adjustment screw 80 without disassembling the butt pad assembly 40a from the buttstock 30.
With continuing reference to
According to another aspect of the invention, the length of the buttstock 30 and butt pad assembly 40a may be lengthened by stacking two or more spacer plates 50 together. The spacer plates 50 with foregoing front and rear face interlock features described above are configured to permit such stacking interlocked arrangement and assembly.
Referring now to FIGS. 4A and 6A-D, the ram 60 includes a vertically oriented mounting flange 61 at the rear against which skirt retaining plate 110 is mounted. In one embodiment, ram 60 further includes an axially elongated cantilevered mounting extension 62 and cylindrical plunger mounting protrusion 63 which is slidably received in tubular sleeve 7. The mounting extension 62 projects in a forward direction from the flange 61 and is slideably coupled to the rear end 35 of buttstock 30. This couples the entire assembly of the butt pad 40 with hard insert 42, spacer 50, face plate 110, and ram 60 (butt pad assembly 40a) to the buttstock 30, thereby locating the assembly outboard and rearward of the rear end and main body of the buttstock (see, e.g.
In one embodiment, the ram 60 may be movably coupled to the rear end 35 of buttstock 30 via a pair of lateral dowel pins 100. The dowel pins may extend transversely to the longitudinal axis LA and centerline of the buttstock through a pair of axially/horizontally elongated spaced apart slots 101 formed in the right and left sidewalls 31b, 31a of the buttstock 30 (see, e.g.
Plunger mounting protrusion 63 includes axial through bore 64 which receives preload adjustment screw 80. The front stem end of screw 80 abuttingly engages a rear spring guide 130 which collectively forms a plunger. In one embodiment, the front end of the screw stem is not fixedly attached to the rear spring guide 130 through the open rear end 127 of the spring sleeve 120. The springs 90 and 91 bias the rear spring guide 130 into engagement with the adjustment screw.
The rear end of the adjustment screw 80 which includes the head is disposed in through bore 64 and accessible for adjusting the preload tension in the compression springs 90, 91 for firing either light or heavy ammunition shell loads which may be shotgun shells in one non-limiting example. Through bore 64 has a stepped configuration with a rear portion of the bore housing the head of the adjustment screw 80 having a larger diameter than the forward portion housing the stem of the screw. Internal threads are disposed in the smaller diameter forward portion of the through bore 64 for rotatably engaging the threaded stem of the screw 80 allowing the position of the plunger to be adjusted and varied by a user. In one non-limiting embodiment, the threads may be formed on a threaded insert 66 such as threaded nuts disposed in the through bore 64. In other embodiments, the front portion of the through bore 64 may be directly threaded instead.
To provide an audible and tactile confirmation of a full adjustment screw 80 rotation to a user, some embodiments may include a spring and ball detent 67. The detent is disposed transversely to the axial through bore 64 and positioned to engage the threaded stem of the adjustment screw 80. Rotating the screw a full 360 produces an audible “click” and tactile feedback sensation to the user when adjusting the preload mechanism.
In one embodiment, plunger mounting protrusion 63 may be connected to mounting extension 62 by an obliquely angled vertical support rib 68 extending between them. The rib 68 which mutually supports both of these cantilevered members and add rigidity to the structure. The rib 68 extends upwards from the top of mounting extension 62 to the plunger mounting protrusion 63. Rib 63 may be wedge or triangular shaped and its height diminishes moving rearward to forward.
The plunger mounting protrusion 63 is insertable into a tubular sleeve 120 disposed in the buttstock 30 which houses the spring assembly. Accordingly, protrusion 63 has a diameter which is sized slightly smaller than the inside diameter of sleeve 120 to allow forward and rearward reciprocating movement therein under recoil after discharging the firearm 20.
Ram 60 may further include an upper thrust block 61a and lower thrust block 61b formed on the front face or side of mounting flange 61. Thrust blocks 61a, 61b are raised structures projecting forward from flange 61 that define forward facing thrust surfaces arranged to engage skirt mounting plate 140 disposed on the rear end 35 of buttstock 30 under recoil (see, e.g.
Ram 60 may be made of any suitably strong material having sufficient rigidity to properly support the entire butt pad assembly 40a from the buttstock 30 in a movable manner. In one embodiment, ram 50 may be formed of a polymer for weight reduction, such as 33% glass filled nylon or other plastic. In other embodiments, ram 60 may be formed of a suitable metal such as aluminum, titanium, or other. In one embodiment, ram 60 including mounting extension 62 and plunger mounting protrusion 63 are integrally formed as a single unitary structure such as by molding or casting.
Referring to
The front end of skirt 70 includes an inwardly extending lip 73 which is trapped between the rear end 35 of buttstock 30 and the skirt mounting plate 140. The plate 140 may be secured to the rear end of the buttstock 30 via threaded fasteners. Skirt retaining plate 140 includes a vertically elongated slot 141 of sufficient dimension to receive mounting extension 62 and plunger mounting protrusion 63 of the ram 60 therethrough for slidable movement inside the buttstock. In one configuration, the slot 141 may have a keyhole shape to complement the transverse cross-sectional shape of the mounting extension 62 and plunger mounting protrusion 63. In one implementation, skirt 70 may be overmolded onto skirt mounting plate 140 forming an integral assembly.
Other suitable securement means may be used for attaching skirt 70 to the buttstock 30 and ram 60 including for example adhesives, rivets, etc. Accordingly, the invention is not limited by the method of attachment used.
Skirt 70 defines a rearwardly open internal chamber 71 into which ram 60 may be inserted through the rear end of the skirt, as best shown in
In one embodiment, the skirt 70 is made of a resiliently deformable elastomeric material having an elastic memory which may be temporarily deformed and then returns to its original shape. Skirt 70 serves as a flexible protective cover to enclose an axial gap G between the rear flange of ram 4 and rear end of the buttstock, thereby acting as a bellows or expansion joint therebetween. In one embodiment, without limitation, skirt 70 may be made of rubber. Other suitable elastomeric materials however may be used including for example various polymeric and thermoplastic elastomers suitable for the application.
Referring now to
Referring also to
In one embodiment, the sleeve 120 is held in position in the buttstock 13 by operation of the spring assembly alone which biases the front wall of the sleeve into abutting engagement with the boss 128 as shown. In other possible embodiments, fasteners or pins may be used in addition to or instead of relying on the spring assembly secure the sleeve to the buttstock. Other ways of mounting the sleeve in the buttstock are possible.
Sleeve 120 has a diameter dimensioned to slidably receive the plunger assembly of ram 60 which may have a complementary cylindrical shape. Sleeve 120 may include a vertical flange 127a on its rear end 127 disposed at an angle between 0 and 90 degrees to the cylindrical body of the sleeve. The flange 127a is configured to engage a portion of the rear end 35 of the buttstock 30 such as skirt mounting plate 140 to properly position the rear end of the sleeve for receiving the ram plunger assembly (i.e. rear spring guide 130, adjustment screw 80, and plunger mounting protrusion 63) into the sleeve. The flange 127a may include a pair of opposing lateral cutouts 127b which engage mating longitudinal protrusions 127c formed in the sidewalls 31a, 31b and cavity 38 of the buttstock 30 (see also
In one embodiment, a longitudinally extending slot 122 is formed in the bottom of the tubular spring sleeve 120 extending from the rear end 127 forward for a distance. The slot slideably receives the support rib 68 of the ram 60 thereby allowing for full movement of the plunger assembly inside the tube from the rear end.
The spring assembly includes an inner light spring 91, outer heavy spring 90, and opposing front and rear spring guides 131, 130 (see
The front spring guide 131 comprises rod 131 which is inserted into the front end of the light spring 91 and the spring mounting protrusion 123 of the spring sleeve 120 which is inserted into the front end of the heavy spring 90. The rod 131 and protrusion 123 collectively form the front spring guide 131 which together provide the same configuration and profile as the rear spring guide 130.
By utilizing the concentrically arranged pair of the lighter inner spring 91 and heavier outer spring 90 (referring to the spring force of each spring), the desired total spring force contributed by both springs is achieved in a more compact axial space of the sleeve. This allows the buttstock to be made shorter and more compact if desired. In other embodiments, a single spring may be provided if the desired spring force can be obtained with the space allocated in the buttstock for the spring assembly.
According to one aspect of the invention, a spring preload adjustment mechanism is provided which allows a user to change the spring preload to accommodate firing light or heavy shotshell loads which will each generate different magnitudes of recoil force. When firing a heavy load, the spring preload should preferably be increased to maximize the spring force produced and dampening effect of the springs 90, 91 to counteract a larger recoil force. The preload force stored in the spring will act against the recoil force applied during firing. When a light load is fired which will produce a smaller recoil force, the spring preload should preferably be decreased so that a comparatively smaller spring force is produced to effectively dampen the lesser recoil force. If the preload and spring force is at a maximum when firing a light load, the dampening effect may be too little which can transfer a disproportionately larger amount of recoil force to the shoulder of the user. In one example, without limitation, the adjustment mechanism may be designed with approximately 125 lbs. of preload. Other suitable spring preloads may be used.
With continuing reference to 12, the preload adjustment mechanism may comprise preload adjustment screw 80 which threadably engages the threaded through bore 64 disposed near the front of the cylindrical plunger mounting protrusion 63 of ram 60. The adjustment screw 80 which is linearly movable by rotating the screw in opposing direction allows the position of the rear spring guide 130 to be changed by a user with respect to the spring sleeve 120 prior to firing the firearm 20. This affects the degree to which the springs 90, 91 are either compresses or relaxed/expanded which corresponds to different spring preload conditions for matching the preload to the type of ammunition (light or heavy) being fired. The preload is infinitely adjustable to optimize and lessen the felt recoil experienced by the user.
In use, the preload may be increased for firing heavy loads by rotating the adjustment screw 80 in a first direction to advance the stem in an axially forward direction. This moves the rear spring guide 130 correspondingly forward closer to the front spring guide 131, thereby compressing the springs 90, 91. To decrease the preload for lighter loads, the adjustment screw is rotated in a second opposite direction to retract the stem in an axially rearward direction. This increases the distance between the front and rear spring guides 131, 130, thereby expanding or decompressing the springs. The adjustment screw 80 may therefore be linearly translated through and set at a plurality of possible preload adjustment positions or conditions to match the load type being fired. In one embodiment, through passage 49 in butt pad 40 allows the user to operate the preload adjustment screw with an elongated tool such as a hex key or screw driver without removing the butt pad from the buttstock 30 (see, e.g.
A method for operating the recoil reduction system will now be described with general reference to
The spring sleeve 120 and front spring guide 131 move rearward with respect to the rear spring guide 130, adjustment screw 80, and ram plunger mounting protrusion 63 (“plunger assembly”) which are stationary. The plunger assembly collectively moves farther forward and deeper into the sleeve 120 during the recoil event. The inner light and outer heavy springs 91, 90 become compressed between the axially spaced part and opposing spring guides 130, 131 to at least partially absorb and dampen the recoil force and felt recoil by the user. The resilient skirt 70 radially expands outwards as the rear end 35 of the buttstock 30 moves towards the flange 61 of the ram 60, thereby decreasing the gap formed therebetween. The upper and lower thrust blocks 61a, 61b abuttingly engage the rear end 35 (i.e. skirt mounting plate 140) of the buttstock 30 which arrests rearward movement of the buttstock assembly. This is shown in the rearward recoil position of the buttstock in
When the buttstock has moved a maximum amount to the rearward active axial recoil position, the compressed spring assembly 90, 91 expands to its original pre-firing position thereby returning the buttstock 30 back to the inactive forward non-recoil position shown in
While the foregoing description and drawings represent exemplary embodiments of the present disclosure, it will be understood that various additions, modifications and substitutions may be made therein without departing from the spirit and scope and range of equivalents of the accompanying claims. In particular, it will be clear to those skilled in the art that the present invention may be embodied in other forms, structures, arrangements, proportions, sizes, and with other elements, materials, and components, without departing from the spirit or essential characteristics thereof. In addition, numerous variations in the methods/processes described herein may be made within the scope of the present disclosure. One skilled in the art will further appreciate that the embodiments may be used with many modifications of structure, arrangement, proportions, sizes, materials, and components and otherwise, used in the practice of the disclosure, which are particularly adapted to specific environments and operative requirements without departing from the principles described herein. The presently disclosed embodiments are therefore to be considered in all respects as illustrative and not restrictive. The appended claims should be construed broadly, to include other variants and embodiments of the disclosure, which may be made by those skilled in the art without departing from the scope and range of equivalents.
The present application claims the benefit of priority to U.S. Provisional Application No. 62/022,461 filed Jul. 9, 2014, the entirety of which is incorporated herein by reference.
Number | Date | Country | |
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62022461 | Jul 2014 | US |