Firearms that shoot small caliber rimfire cartridges enjoy great popularity because the cost of the firearm and attendant ammunition cost less than center fire firearms. Rimfire cartridges are typically on the lower end of kinetic energy because the velocity of the projectile is generally about 1100 feet per second or less. The lower projectile velocities have historically prevented small caliber rimfire cartridges from being used for anything but small game and at ranges under 100 yards.
Attempts to increase the speed of small caliber projectiles has been limited by both the bullet casing metal thicknesses as well as problems associated with firing thicker bullet casings. Thicker bullet casings require a heavier main spring for discharging the cartridge. Because of the need for a heavier main spring, the uplift force required to operate the bolt can be prohibitive. In addition, the heavier main spring produces significant drag as the user rotates the bolt handle to compress the main spring. As a result, the commercial success for such firearms and ammunition has been limited.
Also, because conventional small caliber rimfire firearms are not used for distances greater than about 100 yards, there has been little interest in developing higher quality trigger mechanisms suitable for longer distance shooting. Triggers for firearms must strike a compromise between ease of use and safety. Triggers utilized in competition firearms eliminate or reduce trigger creep by reducing the amount of sear engagement. As used herein, the term “creep” generally refers to the distance that a trigger will travel, or must be pulled, before the sear is engaged and dropped, thus permitting the main spring and firing pin to discharge the firearm. In addition, the “feel” of the trigger may be improved by polishing the engaging surfaces of the sear and the trigger. However, polishing does not reduce the amount of trigger creep, just the “feel” of the trigger creep. On the other hand, a reduction in the amount of sear engagement results in a perceived better trigger pull. For example, a trigger having about 0.015 inches of engagement would be considered by most shooters to be a better trigger than a trigger having about 0.025 inches of engagement.
An engagement between the sear and the trigger of greater than about 0.020 inches generally results in a trigger that is safe from accidental firing during an impact event (e.g., jarring or dropping the firearm), but the trigger is also generally considered to be prohibitively heavy. Reducing the sear and trigger engagement to about 0.016 inches results in a more favorable trigger creep, but the firearm is more prone to accidental discharge in an impact event.
For rifles having a heavy or high-force main spring, conventional small caliber bolt action firearms can be limited by the amount of force required to actuate the bolt.
Thus, a bolt action firearm having a low creep safety trigger and capable of actuating heavier main springs while, at the same time, providing improved trigger pull and which in one embodiment may be field adjustable by the user would be welcomed.
Various embodiments of the disclosure a bolt action firearm that cocks the firing pin upon closing the bolt and includes a cam pin with dual heads. In one embodiment, actuating the main spring while closing the bolt, instead of while opening the bolt, more uniformly distributes the physical energy required by the user over the bolt actuation cycle. The dual heads of the cam pin provide symmetric reactive forces with dual cam slots, thereby preventing the cam pin from skewing or canting within the cam slots and the bolt assembly from skewing or canting within the bolt chamber. Also disclosed is a bolt action firearm with trigger mechanism and bolt particularly suited for high velocity rim fire ammunition. In one embodiment, the rifle is configured for .17 WSM ammunition.
With heavier rimfire cartridges, a substantially heavier main spring is required to reliably fire a cartridge. By way of non-limiting example, the heavier main spring can require two or three times more energy to compress than a standard rimfire spring. Because of the heavier main spring, the force required to disengage the bolt can be prohibitive using conventional designs. Standard bolts utilize a “cock-on-opening” design, wherein the firing mechanism is cocked upon disengagement of the bolt (i.e., upon the up stroke action on the bolt that initiates the extraction process). Various embodiments of the disclosure utilize a “cock-on-close” mechanism, wherein the main spring is engaged upon engagement of the bolt (i.e., upon the down stroke action on the bolt handle that readies the firearm for firing). Typically, the act of disengaging the bolt, which involves the user pulling upward and back on the bolt handle, is physically more demanding than the act of engaging the bolt, which involves the user pushing forward and down on the bolt handle. The cock-on-close aspect of the present disclosure incorporates the additional exertions required for compression of the main spring into the less demanding engagement of the bolt, making the overall sequence of physical acts more uniform.
Furthermore, a standard rimfire bolt normally utilizes a cam engaged with a single cam pin that projects to one side of the bolt. When the bolt is under an axial load, such as imposed by the main spring, the single cam pin imposes an asymmetrical reactive force between the bolt and the cam slot. There is a tendency for the asymmetrical force to cause the cam pin to skew or cant within the cam slot, which, for heavier main springs, can notably increase the drag imposed by the cam pin. Also, the asymmetric forces can also cause the bolt assembly to skew or cant within the bolt chamber.
For various embodiments of the present disclosure, the body of the bolt includes a cam pin that extends laterally (radially) therethrough, effectively creating dual pin heads that are diametrically opposed on the body of the bolt and that engage respective cam slots. Thus, when the user opens the bolt, the reactive forces of the bolt are substantially symmetrical, so that each of the dual pin heads does not skew or wind out of alignment, thereby allowing for a smoother action. As a result, the force required to operate the bolt during compression of the spring is reduced.
Structurally, the present disclosure is directed to a firearm particularly suited for high velocity rim fire ammunition, in particular .17 WSM ammunition. In one embodiment, the firearm includes: a receiver; a barrel attached to the receiver; and a dual cam bolt adapted to engage with the receiver, the dual cam bolt including a firing mechanism having a main spring and firing pin. In one embodiment, the firearm includes a trigger assembly having a stop lever, the trigger assembly including (i) a removable trigger bracket for the sear and trigger and (ii) a stop lever selectively movable between a blocking position and a non-blocking position, wherein the stop lever is finger actuated proximate to a finger portion of the trigger wherein the sear is rotatable to the non-blocking position to release the main spring and firing pin to discharge the firearm.
In one embodiment, the trigger bracket is tool-lessly attachable. The trigger bracket can be attachable without fasteners. The firearm can further include a trigger pull adjustment for the trigger, accessible by removal of the trigger bracket. In one embodiment, the trigger pull is user adjustable. The trigger pull adjustment can include a tool-less thumbwheel adjustment.
Also, in some embodiments, the thumbwheel adjustment is accessible to a user with the trigger assembly in an installed configuration within the receiver. In addition, the thumbwheel can include a detent to prevent unintentional movement of the trigger pull adjustment during use of the firearm.
In one embodiment, the bolt includes a bolt handle movable between a downward closed position and an upward open position, the bolt slidably movable within the receiver between a rearward position and a forward position. Also, in one embodiment, when the bolt is in the forward position, movement of the bolt handle to the downward closed position cocks the main spring and locks the bolt in a firing position.
In one embodiment, in the blocking position, the stop lever engages a notch in the sear.
The step can include an upper face and a lower face, separated by an engagement face. In one embodiment, the upper face and/or the lower face can be substantially planar and parallel to each other, with the engagement face being substantially perpendicular to the upper and lower faces. In various embodiments, with the stop lever in the blocking position, the sear is in primary engagement with the engagement face of the step portion. In one embodiment, the sear can contact the upper face and/or the lower face of the step. In addition, the trigger assembly can be selectively movable between an engaged configuration, wherein the trigger is in an engaged position, and a disengaged position, wherein the trigger is in a disengaged position. In one embodiment, the trigger is in the engaged position when the sear is in the blocking position with the lower horizontal surface of the trigger.
The trigger can also be in the disengaged position when the sear is in the non-blocking position. In one embodiment, the sear slides along the upper surface of the trigger between the engaged position and the disengaged position of the trigger.
In various embodiments, the firearm includes a safety bar being selectively movable between a safety-on position and a safety-off position. In one embodiment, when in the safety-on position, the safety bar engages an upper extension of the trigger.
In one embodiment, the main spring has potential energy to rotate the sear and discharge the firearm when the sear is moved to a non-blocking position.
In one embodiment, the stop lever is coaxial with the trigger. The stop lever can be nested within the trigger.
The firearm can also include a biasing element for maintaining the stop lever in a blocking position. The firearm can also include a sear return spring, and/or a trigger return spring.
These and other aspects of the present disclosure will become apparent to those skilled in the art after a reading of the following description of the preferred embodiment when considered with the drawings.
Referring to
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In one embodiment, an extractor claw 82 is coupled to the distal end 48 of the main body 42. In one embodiment, the extractor claw 82 is biased by a spring loaded pin 84 that is disposed in a second off-center bore 86 formed in the main body. The spring loaded pin 84 also captures the extractor claw 82 within a lateral recess 88.
Referring to
In one embodiment, the main body 42 also defines an elongate slot 106 that extends along a lateral face 108 of a mid portion 112 of the main body 42, the elongate slot 106 including a distal end 114. The main body can also define an open ended slot 116 on a bottom face 118 of the mid portion 112. The first off-center bore 78 of the main body 42 extends along an off-center axis 122 that is eccentric but parallel to the central axis 44, the first off-center bore 78 extending through the distal end 48 of the main body. A recess 124 can be formed in the distal end 48 of the main body 42 for engaging a cartridge therein.
Referring to
Referring to
To assemble, one of the enlarged head portions 172 of the cam pin 72 is inserted through the larger diameter portion 164 of the keyhole slot 162. Once the cam pin 72 is substantially laterally centered in the keyhole slot 162, the cam pin 72 can be set into the narrow slot portion 163 of the keyhole slot 162 that is proximal to the enlarged diameter 164. Once installed within the bolt assembly 38, the cam pin 72 can remain set in the proximal end 165 of the keyhole slot 162 because of the biasing force applied by the main spring 64. The enlarged head portions 172 limits the lateral displacement of the cam pin 72 within the narrow slot portion 163 during operation.
Referring again to
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Referring to
In one embodiment, the housing 200 includes inwardly extending retaining tab portions 222 that are disposed on a proximal end thereof 224. The inwardly extending retaining tab portions 222 are each characterized as having a distal face 226, can be of equal tangential dimension, and can be diametrically opposed, thereby defining tangential gaps 228 therebetween. The tangential gaps 228 complement and are of slightly larger tangential dimension than the outwardly extending tab portions 144 of the cam cylinder 52 of the bolt assembly 38, so that the outwardly extending tab portions 144 can be readily translated fore and aft of the inwardly extending retaining tab portions 222. Like the outwardly extending tab portions 144, the inwardly extending retaining tab portions 222 can include inclined lead-in surfaces 232.
In one embodiment, the housing 200 can further include a lateral, elongate slot 234 to which a release clip 236 (also depicted in
In assembly, for the depicted embodiments, the plunger 62 is placed within the center bore 68 of the main body 42 with the stop portion 182 oriented in the distal direction. The plunger 62 is translated within the center bore 68 of the main body 42 until the trigger pin bore 186 is aligned with a pin access aperture 244 on the main body 42. The trigger pin 70 is then inserted through the access aperture 244 and registered within the trigger pin bore 186 so that none of the trigger pin 70 extends above the plunger 62 while a portion 246 of the trigger pin 70 extends below the plunger 62. In one embodiment, a head 248 of the trigger pin 74 registers on a shoulder 252 formed in the trigger pin bore 186 (
The cam cylinder 52 is slid over the neck portion 94 of the main body 42 of the bolt assembly 38, the distal end 134 of the cam cylinder 52 being brought into contact with the shoulder portion 98 adjacent the neck portion 94. The cam cylinder 52 is rotated about the neck portion 94 so that the cam slots 136 of the cam cylinder 52 and the elongate through-slots 102 of the neck portion 94 overlap. The spring retainer 66 is inserted into the center bore 68 so that the enlarged diameter 164 of the keyhole slot 162 is distal to the narrower end 163. The spring retainer 66 is oriented within the neck portion 94 so that the enlarged diameter 164 of the keyhole slot 162 is aligned with the overlapping portions of the cam slots 136 and the elongate through-slots 102. The cam pin 72 is then inserted through the overlapping portions of the cam slots 136 and elongate through-slots 102, and through the enlarged diameter 164 of the keyhole slot 162.
In various embodiments, the main spring 64, plunger 62, and spring retainer 66 are dimensioned so that, during the alignment of the keyhole slot 162 with the cam slots 136 and the elongate through-slots 102, the main spring 64 is compressed. Accordingly, the main spring 64 exerts a force on the spring retainer 66 and the cam cylinder 52 when the bolt assembly 38 is assembled. In one embodiment, the cam cylinder 52 is retained the on the neck portion 94 against this force by the set screw 158 that passes laterally through the cam cylinder and extends into the tangential channel 104 of the neck portion 94. In one embodiment, the set screw 158 also functions to mount the handle 54 to the cam cylinder 52.
The compression of the main spring 64 biases the plunger 62 within the cylindrical chamber 210 of the housing so that the trigger pin 70 is always distal to the pin access aperture 244 once assembled, so that the trigger pin 70 will not align with the pin access aperture 244 during operation of the firearm 30. The compression of the main spring 64 also biases the cam pin 72 proximally into the narrower end 163 of the keyhole slot 162, so that the cam pin 72 does not move distally into the enlarged diameter 164 of the keyhole slot 162. In one embodiment, the biasing force generated by the main spring 64 as assembled also biases the enlarged head portions 172 of the cam pin 72 proximally into the enlargements 138 of the cam slots 136 when the cam pin is at either end of the cam slots 136. The biasing functions to provide seating of the cam pin 72 against the registration surfaces 142 of the enlargements 138, thereby causing a preference for the bolt assembly 38 to be in the fully closed or the fully open positions.
During operation, the bolt assembly 38 is translated forward within the housing chamber 200 so that the outwardly extending tab portions 144 of the bolt assembly 38 pass through the tangential gaps 228 at the proximal end 224 of the housing 200, with the handle 54 in the uncocked position. In the forward-most translated position, the bolt assembly 38 registers against the firing chamber 206. In one embodiment, the trigger pin 70 comes into contact with a sear 256 that extends through the access slot 214 of the housing 200.
The closing rotation of the handle 54 causes the cam cylinder 52 to rotate about the neck portion 94 of the main body 42 of the bolt assembly 38, so that the proximal faces 146 of the outwardly extending tab portions 144 of the cam cylinder 52 are engaged with the distal faces 226 of the inwardly extending retaining tab portions 222 of the housing 200. When present, the lead-ins 150, 232 of the outwardly extending tabs 144 and the inwardly extending retaining tabs 222 assist in the transition of the engagement.
Referring to
The rotation 262 causes each of the cam slots 136, which are inclined relative to the central axis 44 because their spiral shape, to exert an axial force FA on the respective resident enlarged head portion 172 of cam pin 72, which causes the cam pin 72 to translate forward within the elongate through-slots 102 of the neck portion 94. The forward translation of the cam pin 72 causes the spring retainer 66 to exert an axial compressive force FC on the main spring 64. The main spring 64 is captured between the plunger 62 and the spring retainer 66 as the main spring 64 is compressed. The compressive force FC generated by compression of the main spring 64 is countered proximally by the inwardly extending retaining tab portions 222 of the housing, which are now in contact with the outwardly extending tab portions 144 of the cam cylinder 52 because of the rotation 262; thus, the force exerted proximally by the compressed spring 64 transfers from the spring retainer 66 to the cam pin 72 to the cam cylinder 52 to the housing. The compressive force FC is countered distally by the sear 256, which is coupled to a trigger 340 mounted to a casing 266, the casing 266 being mounted to the housing 200. Thus, the compression of the main spring 64 is countered ultimately by the housing 200.
Accordingly, the main spring 64 is compressed between the spring retainer 66 and the plunger 62 as the cam cylinder 52 is rotated into the closed position. In this configuration, the firearm is cocked, because when the sear 256 releases the trigger pin 70, the plunger 64 thrusts forward, causing the firing pin 74 to strike the cartridge, thereby discharging the firearm 30. Thus, the rotation of the handle from the open position to the closed position causes the compression of the main spring 64 and the subsequent cocking of the firearm 30. Thus, the bolt assembly 38 is a “cock-on-close” system.
Referring to
Referring to
In various embodiments, the sear 256 includes an upper portion 256a and a lower portion 256b, the lower portion 256b including a projection 256d. The sear 256 is pivotally mounted about a pin 333 coupled to the casing 266 (
A stop lever 350, sharing a common pivot axis 351, i.e., coaxial, with the trigger 340 about pin 344, has a distally extending projection 352 (
In one embodiment, as best presented in
The trigger 340 is operatively coupled to a return spring 372 that biases the trigger 340 towards the cocked configuration (clockwise in
In one embodiment, a trigger pull adjustment 370 comprises a post 376 that is threadably engaged with a thumbwheel 374. The post 376 can extend into the inner diameter of the return spring 372. The return spring 372 compressed between the thumbwheel 374 and the pull adjustment platform portion 343 of the trigger 340. In one embodiment, the thumbwheel 374 of the trigger pull adjustment 370 is accessible from outside the casing 266.
Functionally, the return spring 372 biases the main body of the sear 256 downwardly, which rotationally biases an upper portion 256a of the sear 256 to project into the cylindrical chamber 210 of the housing 200, and in the path of the trigger pin 70. The projection 345 of the trigger 340 cooperatively engages the safety bar 360 to prevent rotation of the trigger 340 when the safety bar 360 is selectively in the blocked position. When the safety bar 360 is positioned to enable rotation of the trigger 340, the engagement between the step portion 342 and the sear 256 prevents rotational movement (counterclockwise as viewed in
When rotation of the trigger 340 is fully enabled, actuation of the trigger 340 the trigger rotates about pin 344 (clockwise in
The degree of pre-loaded compression exerted on the return spring 372 is a function of the distance between the thumbwheel 374 and the pull adjustment platform portion 343. The pre-loaded compression of the return spring 372 can thus be varied by adjusting the position of the thumbwheel 374 on the post 376. The pre-loaded compression of the return spring 372 contributes the trigger pull force.
In operation, the user accesses the trigger pull adjustment 370 by snapping the trigger guard assembly 39 away from the receiver 34. The user can adjust the trigger pull adjustment 370 by rotating the thumbwheel 374 with a thumb and/or finger of his or her hand. In this way, the force required to actuate the trigger can be adjusted to the user's preference without having to remove the assembly 32 from the receiver/stock 34, and without need for external tools or accessories.
The trigger assembly 32 can includes the safety bar 360. The safety bar 360 is movable on two rollers 62 positioned within a slot 64 (
In operation, the projection 256c engages the engagement face 342a of the step portion of the trigger 340 when the firearm is cocked. The distally extending projection 352 of the stop lever 350 extends slightly above the trigger 340 in the blocking position, poised to engage the notch 256d of the sear 256 should the sear 256 slip off the step portion 342 of the trigger 340. If the safety bar 360 is in the unblocked position (
To intentionally discharge the firearm 30, the shooter first loads and cocks firearm 30 and moves the safety bar 360 to the unblocked position. The shooter then depresses the stop lever 350 extending forward of the finger pull portion 341 of the trigger 340 with the shooter's trigger finger by a simple squeezing motion. Before the shooter's trigger finger engages the finger pull portion 341 of the trigger 340, the distally extending projection 352 of the stop lever 350 rotates away from the blocking position into the non-blocking position. As the shooter continues to squeeze the trigger 340, the resultant pivoting motion of the trigger 340 causes the projection 256c of the sear to disengage from the engagement face 342a of the step portion 342, subsequently discharging the firearm 30. Because the stop lever 350 is no longer in a blocking position, the trigger 340 is able to continue through its full firing motion, thus releasing the sear 256 for pivotal movement.
While a sear return spring 335 keeps the sear 256 biased in the same position as shown in
Referring to
In the triggered configuration 274 (
Referring to
As applied to the distal portion 404 of the housing 200, the mounting system 400 includes a front magazine mount 406, a barrel locking stud 408, a retaining clip washer 412, a flat head pillar 414, and a clamping screw 416, all mounted about a mounting axis 418 that is substantially perpendicular to the central axis 44. In one embodiment, the front magazine mount 406 comprises an inverted L-shaped bracket 420 having features 422 on a top face 424 of a distally extending leg 426 thereof The distally extending leg 426 can also include structure defining a through aperture 428 that passes therethrough about the mounting axis 418. In one embodiment, the L-shaped bracket includes a barb portion 432 formed on an end 434 of a downward extending leg 436, the barb portion 432 being opposite the distally extending leg 426. The downward extending leg 436 can also define a through-aperture 438.
Functionally, in various embodiments, the barb portion 432 engages a clip on a magazine (not depicted). The through-aperture 438 can accommodate a detent 439 on the trigger guard 39 for quick connection/disconnection.
A threaded female fastener with a male threaded portion, a barrel locking stud 408, which is depicted in isolation in
The retaining clip washer 412 can be of a beveled profile 458 (
A bushing, configured as a flat head pillar 414, which is depicted in isolation in
The clamping screw 416, which is depicted in isolation in
In assembly, the through-aperture 428 of the front magazine mount 406 is aligned with a threaded mounting hole 492 on the underside of the housing 200 (
In one embodiment, the flat head pillar 414 is mounted within a boss 496 (
The barrel assembly 36 is disposed in the receiver 34 so that the barrel locking stud 408 and the flat head pillar 414 are in alignment along the mounting axis 418. The male threaded portion 486 of the clamping screw 416 is then engaged within the female threaded portion 456 of the barrel locking stud 408 and tightened down, thereby securing the barrel assembly 36 to the receiver 36. In one embodiment, the retaining clip washer 412 is compressed between the receiver 34 and the front magazine mount 406. If the retaining clip washer 412 is of the beveled profile 458, compression causes the beveled profile 458 to flatten out, thereby providing a spring loading between the front magazine mount 406 and the receiver 34.
In one embodiment, the male threaded portion 486 of the clamping screw 416 can be dimensioned for slight interference with the reduced diameter orifice 478, thereby providing a creating high friction with the male threaded portion 486 as it is inserted through the reduced diameter orifice 478. The reduced diameter of the shaft portion 482 enables free rotation of the clamping screw 416 the male threaded portion 486 is inserted through and clears the reduced diameter orifice 478. Accordingly, the reduced diameter orifice 478 helps retain the clamping screw 416 within the receiver 34 when the barrel assembly 36 is disengaged, preventing loss of clamping screw 416, for example, during servicing in the field.
In embodiments, tightening of the screw 416 axially, due to the cooperating tapered surfaces of the screw 416 and pillar 414, exerts a force having an axial component as well as a radial component. Thus, positive reactive forces are exerted on the receiver 34, enhancing the integrity of the engagement between the pillar 414, the screw 416, and the receiver 34. Utilization of this system has been shown to provide greater stability in the connection between the connected components providing for a more robust firearm. This connection system is applicable to other firearms, particularly rifles. The connection system is suitable for polymer stocks and wood stocks. In certain embodiments, compression of the flat head pillar 414 compresses and radially expands the flat head pillar, further enhancing the integrity of the engagement between the pillar 414, the screw 416, and the receiver 34. In one embodiment, the flat head pillar 414 is fabricated from a metal. In other embodiments, the flat head pillar 414 is fabricated from a resilient polymer, which can enhance the expansion under the compressive load of the clamping screw 416 for tighter coupling to the boss 496 of the receiver.
Certain modifications and improvements will occur to those skilled in the art upon a reading of the foregoing description. By way of example, while the firearms set out in the specification are bolt action rifles, the present embodiments can be adapted to similar firearms including pump and lever actions, as well as both pistols and long guns. Also, while the present disclosure refers to “firearms,” it should be understood that the embodiments disclosed herein can also be adapted for air guns, crossbows and similar arms. It should be understood that all such modifications and improvements have been deleted herein for the sake of conciseness and readability but are properly within the scope of the claims.
Like reference characters designate like or corresponding parts throughout the several views. Also, it is to be understood that such terms as “forward,” “rearward,” “left,” “right,” “upwardly,” “downwardly,” and the like are words of convenience and are not to be construed as limiting terms.
Each of the additional figures and methods disclosed herein can be used separately, or in conjunction with other features and methods, to provide improved devices and methods for making and using the same. Therefore, combinations of features and methods disclosed herein may not be necessary to practice the disclosure in its broadest sense and are instead disclosed merely to particularly describe representative and preferred embodiments.
Various modifications to the embodiments may be apparent to one of skill in the art upon reading this disclosure. For example, persons of ordinary skill in the relevant art will recognize that the various features described for the different embodiments can be suitably combined, un-combined, and re-combined with other features, alone, or in different combinations. Likewise, the various features described above should all be regarded as example embodiments, rather than limitations to the scope or spirit of the disclosure.
Persons of ordinary skill in the relevant arts will recognize that various embodiments can comprise fewer features than illustrated in any individual embodiment described above. The embodiments described herein are not meant to be an exhaustive presentation of the ways in which the various features may be combined. Accordingly, the embodiments are not mutually exclusive combinations of features; rather, the claims can comprise a combination of different individual features selected from different individual embodiments, as understood by persons of ordinary skill in the art.
Any incorporation by reference of documents above is limited such that no subject matter is incorporated that is contrary to the explicit disclosure herein. Any incorporation by reference of documents above is further limited such that no claims included in the documents are incorporated by reference herein. Any incorporation by reference of documents above is yet further limited such that any definitions provided in the documents are not incorporated by reference herein unless expressly included herein.
References to “embodiment(s)”, “disclosure”, “present disclosure”, “embodiment(s) of the disclosure”, “disclosed embodiment(s)”, and the like contained herein refer to the specification (text, including the claims, and figures) of this patent application that are not admitted prior art.
For purposes of interpreting the claims, it is expressly intended that the provisions of 35 U.S.C. 112(f) are not to be invoked unless the specific terms “means for” or “step for” are recited in the respective claim.
This patent application claims the benefit of U.S. Provisional Patent Application No. 61/973,808, filed Apr. 1, 2014, U.S. Provisional Patent Application No. 61/973,242, filed Mar. 31, 2014, and U.S. Provisional Patent Application No. 61/839,420, filed Jun. 26, 2013, the disclosures of which are hereby incorporated by reference herein in their entirety.
Number | Date | Country | |
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61973808 | Apr 2014 | US | |
61973342 | Apr 2014 | US | |
61839420 | Jun 2013 | US |