The present invention is directed to a compact 50 caliber chain-driven machine gun system which utilizes an original Browning rear-stripping ammunition link design.
Almost 100 years ago Mr. John Browning invented a series of Machine Guns which are still in use today. They were made in multiple calibers but the functioning of the mechanism was essentially identical across the series. The original intended use for them was as a TriPod ground mounted Infantry System. Over the years however these weapons were adapted to many other uses. From airplanes and ships and on top of tanks and trucks and jeeps. One of the most successful of these weapons is the 0.50 Cal BRG MG which is sometimes called the Ma Duce or M2 50 Cal. While the other Brownings have become obsolete and have been replaced by newer mechanisms and cartridges, the Ma Duce soldiers on. The reasons are first the potency of the round of ammunition and also the fact that it is in use by so many armed forces. Literally hundreds of millions of packed and linked rounds are in the inventory of armies around the world. In spite of this huge success there is one place where the Ma Duce has never been used successfully—as an enclosed mount on tanks and armored vehicles. The Browning 0.50 Cal just does not fit in those cramped and enclosed spaces, its receiver is just too long due to the rear-stripping action of the cartridge delinker. When applied to these types of vehicles it is always mounted externally on a post mount where the gunner is mortally exposed to enemy fire. Additionally, the gun and ammunition are vulnerable to all sorts of damage, from tree branches to artillery fragments and small arms fire.
Chain-driven automatic guns include an ammunition feed and delinker system that receives an ammunition belt of linked cartridges, sequentially separates or “delinks” the cartridges from the ammunition belt, and feeds the cartridges to the gun for firing. Reliability and controllability are the advantages of chain-driven weapons over their recoil-actuated counterparts. Recoil-actuated firearms depend upon the sometimes unreliable firing of a cartridge to power the cycle of action, whereas a chain-driven gun uses an electric motor to drive a chain that moves in a rectangular circuit via four sprockets that apply tension to the chain. One link of the chain is connected to the bolt assembly, moving it back and forth to load, fire, extract, and eject cartridges. One previous example of such a gun is described in U.S. Pat. No. 4,418,607, entitled “Single Barrel Externally Powered Gun,” which is incorporated herein by reference.
The existing 0.50 caliber ammunition metallic “linked” belt is derived from the original cloth belt of the World War I era which was composed of two parallel cloth straps sewn together in which a series of pockets were formed so that rounds could be inserted along the length of the belt. The cartridges were pulled to the rear to remove them from the belt and then fed into the gun mechanism. Later the cloth was replaced by metal links but the cartridges were still removed to the rear. The function of removing the cartridge to the rear is the reason for the Browning's long receiver and its difficult vehicle mounting.
Several manufacturers have tried to fill this void with a 0.50 Cal gun designed for vehicle use but all have missed the mark for the same reason. They are all designed around a side stripping link instead of using the rear-stripping link that is already on those millions of rounds in the inventories around the world. Side stripping mechanisms separate cartridges laterally from the ammunition belt rather than pulling it rearward. Most modern ammunition links are either side stripping or forward stripping which allows for a much shorter bolt stroke and therefore a much more compact receiver and feeder assembly. The challenge is to approach that same compact shape while still using the original Browning rear-stripping link design to take advantage of the large number of 0.50 Cal ammunition belts in inventories around the world.
It is an object of the present invention to provide an improved chain driven machine gun that can first strip a linked cartridge axially to the rear from an ammunition belt link, as opposed to side stripping. A secondary object provides an improved and simplified electric anti-hangfire system.
The improved 50 caliber chain-driven gun of the present invention provides a number of advantages over prior art in that the improved design allows for rear extraction of rounds from the links, significantly shorter receiver for easier turret mounting, and simplified anti-hangfire protection. The chain-driven machine gun system features a delinker assembly configured to receive a belt of linked cartridges, separate each of the cartridge from the belt rearwardly, and feed each of the cartridges for firing. The delinking function is separated from the motion of the bolt assembly so as to reduce the overall length of the gun system. The receiver has a receiver mounting length RML from the rear base of each incoming cartridge in a belt of connected links to the rear end of the receiver that is less than 15 inches. A shuttle feed system is incorporated into the basic chain gun style mechanism which had been limited to a sprocket feed on all previous designs. An electronic anti-hangfire system uses a single proximity switch and the already existing parts and motions of the gun.
An exemplary rearward-stripping externally-powered gun disclosed herein comprises a receiver at the rear end of a longitudinal barrel, the receiver being configured to laterally receive a plurality of cartridges held within a series of connected links with a rear base of the cartridges facing to the rear. The receiver includes a motor and motor drive system, and a bolt carrier driven longitudinally forward and rearward by the motor drive system, the bolt carrier having a longitudinal tube and tower extending perpendicularly away from the tube. A bolt positioned within the longitudinal tube of the bolt carrier has a forward end with a cartridge grasper adapted to engage the rear base of a cartridge, the bolt being aligned with a breech and chamber of the barrel. A feed shuttle is adapted to translate the laterally through the receiver. A delinker shaft arranged in the receiver to translate longitudinally toward and away from the feed shuttle has a forward end adapted to engage the rear base of a cartridge and remove one cartridge at a time from the connected links. The delinker shaft passes through a bore in the bolt carrier tower, wherein the delinker shaft is coupled by a lock member to periodically translate with the bolt carrier tower. A feed rotor is arranged to rotate about a longitudinal axis and transfer a cartridge from a delinked position engaged with the delinker shaft to a load position, whereby the cartridge is engaged by the cartridge grasper of the bolt. A feed rotor drive system driven by the motor drive system periodically rotates the feed rotor to transfer a cartridge from the delinked position to the load position. Finally, the motor drive system is configured to translate the bolt carrier forward until the delinker shaft is in position to engage the rear base of a cartridge, at which point the lock member decouples further forward translation of the bolt carrier from the delinker shaft, and the bolt carrier continues forward to displace the bolt and a cartridge engaged thereby forward and deliver the cartridge to the chamber to be fired.
A method of operating a rearward-stripping externally-powered gun is disclosed. The gun has a receiver at the rear end of a longitudinal barrel, the receiver having a motor and motor drive system and being configured to laterally receive a plurality of cartridges held within a series of connected links with a rear base of the cartridges facing to the rear. A bolt carrier is driven longitudinally forward and rearward by the motor drive system, the bolt carrier having a longitudinal tube and tower extending perpendicularly away from the tube. A bolt is positioned within the longitudinal tube of the bolt carrier and has a forward end with a cartridge grasper adapted to engage the rear base of a cartridge, the bolt being aligned with a breech and chamber of the barrel. Cartridges are translated laterally through the receiver, while a delinker shaft translates longitudinally toward and away from the cartridges held within the connected links. The delinker shaft has a forward end adapted to engage the rear base of a cartridge and remove one cartridge at a time from the connected links. The delinker shaft passes through a delinker bore in the bolt carrier tower, and is coupled by a lock member to periodically translate with the bolt carrier tower. The method includes rotating a feed rotor about a longitudinal axis and transferring a cartridge from a delinked position engaged with the delinker shaft to a load position whereby the cartridge is engaged by the cartridge grasper of the bolt. The bolt carrier is translated forward until the delinker shaft is in position to engage the rear base of a cartridge, whereby the lock member decouples further forward translation of the bolt carrier from the delinker shaft, and the bolt carrier continues forward to displace the bolt and a cartridge engaged thereby forward and deliver the cartridge to the chamber to be fired.
Another method of operating the rearward-stripping externally-powered gun is provided, comprising driving a bolt carrier longitudinally forward and rearward with the motor drive system, the bolt carrier carrying a bolt having a forward end with a cartridge grasper adapted to engage the rear base of a cartridge, the bolt being aligned with a breech and chamber of the barrel. Translating the cartridges laterally through the receiver, and translating a delinker shaft longitudinally forward and rearward with the bolt carrier. The delinker shaft has a forward end adapted to engage the rear base of a cartridge and remove one cartridge at a time from the connected links when translated rearward. The delinker shaft is coupled by a movable lock member to periodically translate with the bolt carrier, wherein the bolt carrier translates the delinker shaft forward until the delinker shaft is in position to engage the rear base of a cartridge, whereby the lock member moves and decouples further forward translation of the delinker shaft from the bolt carrier, and the bolt carrier continues forward to displace the bolt and a cartridge engaged thereby forward and deliver the cartridge to the chamber to be fired. The method also includes periodically rotating a feed rotor about a longitudinal axis with the motor drive system, the feed rotor being configured to transfer a cartridge from a delinked position engaged with the delinker shaft to a load position whereby the cartridge is engaged by the cartridge grasper of the bolt.
One object of the application is a controllable delinker that allows for the delinking function to be separated from the motion of the bolt assembly so as to reduce the overall length of the gun system.
An improved chain-driven machine gun disclosed herein comprises a delinker assembly configured to receive a belt of linked cartridges, separate each of the cartridge from the belt rearwardly, and feed each of the cartridges for firing.
A further object is a delinker system that is controllably detached from the rest of the mechanism so as to reduce its required travel and permit shortening the overall size of the associated gun mechanism.
Another object is a shuttle feed system incorporated into the basic chain gun style mechanism, which previously had been limited to a sprocket feed on all previous designs
An object is also incorporation of a shuttle feed heretofore associated with self-powered guns to the mechanism of a “chain gun” style weapon
An improved chain gun anti-hangfire mechanism utilizes an electronic proximity sensor and a logic circuit, working in conjunction with the gun firing pin.
An electronic anti-hangfire system which uses a single proximity switch and the already existing parts and motions of the gun. The prior art required several parts, a solenoid and springs to accomplish the same function.
A further understanding of the nature and advantages of the invention will become apparent by reference to the remaining portions of the specification and drawings.
Features and advantages of the present invention will become appreciated as the same become better understood with reference to the specification, claims, and appended drawings.
It should be noted that some Figures that depict the operation of the chain-driven automatic gun that are denoted with “A” and “B” show identical snapshots except that the “A” version is a longitudinal section while the “B” version is a cutaway perspective. In others, the “B” version has shading indicating depth features while the “A” version does not.
The present application is directed to externally-powered automatic guns such as a chain-driven gun. Guns are broadly segregated into externally-powered or motorized guns and self-powered guns which rely on a spring recoil action or a gas spring. Externally-powered guns have a motor that drives a chain, cam or crank and connecting rod, as well as other mechanisms to engage and move the various cooperating parts (e.g., bolt and carrier) in synch. All of these will collectively be termed a “drive system” which is motor operated.
More specifically, the present application relates to an improved chain-driven automatic gun with a bolt carrier and delinker combination for rearward extraction of rounds from an ammunition belt of linked cartridges, which provides improved performance and requires less maintenance than the existing chain-driven guns. In particular, the application describes a compact 50 caliber system which utilizes an original Browning rear-stripping ammunition link design.
In most modern light machine guns the link stripping motion is performed by the bolt on its forward motion and is directly related to the total stroke of the bolt and bolt carrier. In the Chain Gun and Gatling series of machine guns, the link is stripped sideways from the link by a sprocket and then passed to the bolt by a transfer sprocket or rotor. In both of these systems the cartridge travels the stroke of the bolt. This system works well and allows mounting of the guns inside tanks or armored vehicles because of the short stroke and consequent short length of the gun. This mounting advantage, however, has not been possible for guns that rely on rearward-stripping links, like the M2 50 Cal.
According to the present invention, there is provided an improved chain driven machine gun. The gun includes five principal functional assemblies, i.e., a chain drive or bolt control assembly, a bolt assembly, a barrel assembly, a feeder assembly and a power transmission system. In its simplest form, the system is an externally powered mechanism in which the gun barrel is fixed in the sense that it does not cycle or rotate.
The output of the Geneva gear assembly operates a second bevel gear set 57, the output of which is connected to a feed rotor 60, the latter part of the feeder assembly. Cooperating with the feed rotor 60 is a feed sprocket generally designated 62, the latter driven by shaft 47. The outer drive shaft 47 has affixed to it the feed sprockets 62, each having four teeth, as illustrated in
Overview
The total length L of the gun 110 as shown in
As best seen in
Bolt Carrier
The feed rotor shaft 154 freely slides longitudinally through a bore formed in a bolt carrier 160, described in detail below. The bolt carrier 160 is seen in greater detail in
It will be understood that when assembled in the receiver 112, the left side in
As seen in
Bolt Assembly
With reference again to
The bolt 184 is a generally tubular structure having a three-pronged cartridge grasper 186 on a forward end and housing therein a firing pin 188 and firing spring 190. The bolt 184 has a forward passage 192 sized to receive a cylindrical main body portion of the firing pin 188 and leading to a narrow firing pin bore 194 which receives a forward nose 196 of the firing pin 188. The bolt 184 has a rear passage 198 with a larger diameter than the forward passage 192 and separated therefrom by a lateral channel 200. As seen in
As seen best in
With reference again to the cutaway view of
It is important to note that the firing spring 190 is constrained between a forward collar 210 fixed around a groove and circlip 212 on the firing pin 188 and a horseshoe clip 214 that extends into the rear passage 198 from outside of the bolt 184 and longitudinal tube 162 of the bolt carrier 160. The forward collar 210 initially abuts the cam pin 202. The rear of the spring 190 is constrained from rearward movement by the horseshoe clip 214 and mating collar 215, with the clip 214 also engaging a pair of vertical slots 217 in opposite sides of the bolt 184 (see
Operation
The feed cam 230 pivots about a rear pin 236 fixed in the feed cover 120, as seen in
The shape of the inner channel of the feed cam 230 is seen in
Now with reference to
All the various operating steps are driven by the chain 144, which is tensioned around four sprockets arranged in a rectangular pattern. An upwardly-projecting bolt drive pin 242 (
In the first step of
At the same time, a lower Geneva drive pin 246 (
Prior to the stage seen in
Forward movement of the bolt carrier 160 moves the delinker shaft 180 forward into position to engage a cartridge 118. The movement of the delinker shaft 180 during delinking, transferring and firing the cartridges requires an understanding of the interaction between movement of it and the bolt carrier 160. With reference first to
The delinker shaft 180 further includes a collar 252 fixed to a rear end thereof via a pin or similar expedient, which enables the tower 170 to displace the delinker shaft 180 to the rear. Just forward from the collar 252, the delinker shaft 180 has a small indent 254 on an underside thereof which receives an inter-locking pin 256 in an elevated position. When the inter-locking pin 256 is elevated, longitudinal movement of the tower 170 is coupled to that of the delinker shaft 180. The inter-locking pin 256 is positioned in a vertical space formed in the tower 170 of the bolt carrier 160 which permits the pin to drop down when the pin reaches a flat or recessed section 258 formed on the feed rotor shaft 154, as best seen in
In addition, the moment that the pin 256 drops down into the recessed section 258 is the start of the pivoting of the feed cam 230 and thus movement of the feed shuttle 234. That is, the feed cam drive roller 240 carried at the top of the tower 170 contacts a curved section of the contoured inner wall 238 of the feed cam 230 at the same time movement of the tower 170 disengages from movement of the delinker shaft 180. The delinker shaft 180 thus remains stationary while the feed cam 230 and feed shuttle 234 deliver the next cartridge 118.
The length of the delinker shaft 180 and extent of forward movement prior to disengagement from the tower 170 positions the delinker grabber 250 in line to capture the rear end of the next cartridge when it is displaced laterally by the feed shuttle 234. Again, the lateral movement of the feed shuttle 234 is enabled by the camming action of the feed cam drive roller 240 against the contoured inner wall 238 of the feed cam 230.
The reader will note that the master link 244 on the chain 144 is once again at the rear left corner on the rectangular chain path. The master link 244 has moved laterally from right-to-left in a CW direction which pauses movement of the bolt carrier 160. However, the lower Geneva drive pin 246 (
Ultimately,
The rear end of the firing pin 188 includes a laterally-extending tang 216 that slides within a slot 219 in the lower rear end of the bolt carrier 160 (
Contact between the front end of the bolt 184 and the rear of the breech 125 occurs just prior to full forward travel of the bolt carrier 160, driven by the chain 144. That is, the bolt carrier 160 continues to move forward after the bolt 184 stops. The three-pronged cartridge grasper 186 on the bolt 184 passes through the aligned cutouts 264 and contacts the rear of the barrel 124. The bolt 184 then stops moving linearly but is forced to rotate by relative sliding movement of the bolt carrier 160 and its longitudinal tube 162 thereover. Further longitudinal movement of the longitudinal tube 162 and specifically the cam slots 204 therein act on the cam pin 202.
With reference to
This does two things. First, the three-pronged cartridge grasper 186 on the bolt 184 is rotated in the cavity 262 behind the rear wall 260 of the breech 125, thus locking the bolt and breech together. Secondly, the firing pin tang 216 rotates out of engagement with the pawl 270 and into the slot 218 (
Following firing of a cartridge, the chain 146 continues to turn and eventually pulls the carrier 160 back to the rear. This rotates the bolt 184 to an unlocked position through a reverse camming sequence between the cam slots 204 and the cam pin 202, until the carrier 160 again moves linearly in synch with the bolt 184. The bolt 184 pulls the spent cartridge shell free from the breech 125 whereupon it is ejected via a mechanism that will not be described herein.
In the rear cartridge removal system described herein, the delinker is slidably attached to the bolt and carrier assembly so that its travel can be controllably timed and limited in relation to the motion of the bolt assembly. The delinker shaft is hexagonal in cross section to prevent rotation, and passes through a mating hexagonal hole in the bolt carrier. The forward and aft position of the delinker is controlled by a vertically sliding pin which engages a recess in the hex shaft and also rides against the outside of the rotor shaft which is parallel to the delinker. The rotor and rotor shaft are fixed in the fore and aft direction but rotate to deliver rounds from the delinker to the bolt during the feed process.
As the bolt and carrier assembly move forward to the firing and feeding position, the front of the delinker contacts the back of the feed tray. At the same time the vertically positioned locking pin is allowed to move out of its holding position and to move downward into a recess in the feed rotor shaft. In doing so it is decoupled from the motion of the bolt and carrier assy. That assembly is now free to continue forward and to lock and fire. At the same time as that is happening, the feed cam is moving a shuttle to feed the next round into the delinker for the next cycle.
After firing, the bolt assembly moves to the rear, free from the delinker until a collar on the aft end of the delinker shaft contacts the back of the bolt carrier and the locking pin which had been cammed into the rotor shaft is cammed back into the delinker shaft. At this point the delinking of the new round is started and the round is pulled back into a cavity in the feed rotor, ready to be rotated down into the bolt face.
Anti Hangfire System
In the past certain externally powered guns have incorporated an anti-hangfire system to protect the gunner and the gun itself from the disastrous effects of the delayed functioning or hangfire of a fired round of ammunition. Since an externally powered gun does not depend upon the gas pressure or the recoil force of the fired round to function the mechanism, it can open the breech/bolt mechanism prior to the functioning of the round. If the round fires at that time the explosive force will not be container within the gun but will blow powder and case fragments out of the gun in possibly hurt the gunner and the weapon itself. To prevent this, a system was previously disclosed in U.S. Pat. No. 4,301,709 through the use of a somewhat complex linkage system, and a solenoid was capable of preventing the possibility of a hang fire damaging the gunner or the system itself. While this system functioned well it was complex and required very close tolerances, was prone to malfunctions and was costly to build and difficult to integrate into the gun mechanism.
The anti-hang fire system presented here does away with all of the mechanical moving parts associated with the old system and replaces them with a single electronic proximity sensor and a logic circuit, working in conjunction with an already existing gun part, the firing pin.
The functioning of this system is described as follows:
Located in the receiver below the tang 216 of the firing pin 188, and at the end of its forward travel is a proximity sensor 272 which can sense the presence of the firing pin tang. The only time it can sense the tang is at the moment of primer strike. It is therefore a positive indication of the attempt to fire the round. Simultaneously, a 0.006 second timer is started in the logic circuit.
At this point one of two things occur. Either the round fires or it does not fire. If the round fires, the combination of barrel breech 125 and bolt 184 and firing pin 188 recoils towards the rear of the gun. This immediately moves the firing pin tang 216 away from the sensor 272 in the receiver 212 which remains stationary relative to the recoiling parts. This turns off the sensor 272 which tells the logic circuit that the round has fired, the timer is shut off, and the gun continues to fire.
The second thing that can happen is that the round does not fire and the barrel etc. does not recoil. The tang 216 of the firing pin 188 thus stays within the sensing distance of the proximity sensor 272. In this case the timer times out and the logic circuit shuts off the drive motor and initiates a dynamic brake to immediately stop the gun prior to the opening of the breech 125. The dwell of the bolt and carrier assembly in the locked position is sufficiently long to allow this to happen without the possibility of the bolt opening.
The use of the firing pin tang 216 as the principle indicator of the status of the firing of the gun eliminates the need for five mechanical parts, two springs, and a solenoid plus associated extra machining of the receiver and other parts, plus the space weight and power of the system, further reducing the overall gun size.
An adjunct to the above system is anticipated in the case of a gun which does not have a recoil system. In that case the firing pin 188 would not move away from the proximity sensor 272 upon firing. In that case an accelerometer would be attached to the receiver to sense the existence of a firing pulse. The firing pulse is significantly different than other accelerations experienced by the parent vehicle. In addition, only accelerations felt immediately after [within 0.006 sec] the firing pin tang is sensed by the proximity sensor 272 would be considered. All other acceleration signals will be filtered out by the logic circuit.
Those skilled in the art will appreciate that various changes and modifications may be made to the preferred embodiments, the invention in its broader aspects is not limited to the specific details, representative devices, and illustrative examples shown and described.
The present application is a continuation-in-part of U.S. application Ser. No. 16/378,264, filed Apr. 8, 2019, which is a continuation of U.S. application Ser. No. 16/101,493, filed Aug. 12, 2018, which is a continuation-in-part of U.S. application Ser. No. 15/887,111, filed Feb. 2, 2018, which claims priority under 35 USC § 119 to U.S. Provisional Application Ser. No. 62/453,682, filed Feb. 2, 2017, the entire disclosures of which are expressly incorporated herein.
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20200096270 A1 | Mar 2020 | US |
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62453692 | Feb 2017 | US |
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Parent | 16101493 | Aug 2018 | US |
Child | 16378264 | US |
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Parent | 16378264 | Apr 2019 | US |
Child | 16511875 | US | |
Parent | 15887111 | Feb 2018 | US |
Child | 16101493 | US |