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Repeating firearm

A repeating firearm is any firearm equipped with a magazine or revolving cylinder that holds multiple rounds of ammunition and features a mechanical action enabling rapid successive shots without manual reloading between each firing.^[1] This design contrasts with single-shot firearms, which require reloading after every discharge, and allows for higher rates of fire in various applications, from hunting to military use.^[1] The development of repeating firearms dates back to the early 17th century with experimental designs like the Kalthoff repeater, a flintlock mechanism using superimposed loads for multiple shots, though these early models were complex and prone to misfires.^[2] Significant advancements occurred in the 19th century during the percussion cap era, enabling more reliable multi-shot weapons; Samuel Colt patented the first mass-produced revolving-cylinder revolver in 1836, revolutionizing handgun design by allowing five or six shots before reloading.^[3] The American Civil War accelerated innovation, with the Spencer repeating rifle—featuring a seven-round magazine in the buttstock and a lever mechanism to cycle .56-56 rimfire cartridges—adopted by Union forces after President Abraham Lincoln tested it personally in 1863, providing a firepower advantage over muzzle-loading muskets. Post-war, lever-action rifles like the 1866 Winchester Model, an evolution of the Henry rifle, became iconic in the American West, capable of firing 15 rounds rapidly from a tubular magazine.^[4] Repeating firearms encompass several key types, broadly categorized by action mechanism and form factor. Revolvers, typically handguns with a rotating cylinder holding 5 to 9 chambers, operate via single-action (manual hammer cocking) or double-action (trigger performs both functions) systems and remain popular for their simplicity and reliability.^[1] Semi-automatic pistols and rifles use recoil or gas from the fired cartridge to eject spent casings and load new ones from a detachable box magazine, emerging in the late 19th century with designs like the 1893 Borchardt pistol.^[4] Shoulder-fired options include lever-action rifles, which use an under-barrel lever to cycle rounds; bolt-action rifles, manually operated via a rotating bolt for precise loading; and pump-action designs, sliding a forearm to chamber ammunition, commonly seen in shotguns.^[1] These mechanisms have profoundly influenced modern infantry tactics, law enforcement, and sporting, with ongoing evolutions toward lighter materials and higher capacities.

Definition and principles

Core concepts

A repeating firearm is a type of firearm designed to fire multiple shots without requiring manual reloading of individual cartridges between firings, typically by storing ammunition in an integrated supply and using a mechanical system to cycle cartridges through a single chamber.^[1] This capability distinguishes it from single-shot firearms, enabling sustained fire in a single loading sequence.^[5] The core operating principle of a repeating firearm revolves around a sequential action cycle that includes chambering a cartridge into the barrel, firing it, extracting the spent casing, and preparing the next round for firing, all facilitated by the firearm's mechanism. This cycle ensures efficient ammunition handling, with the action either manually operated by the user or, in self-loading variants, powered by the energy of the fired cartridge.^[6] Key components unique to repeating firearms include ammunition storage systems such as detachable or fixed magazines, rotating cylinders in revolvers, or tubular magazines integrated into the firearm's frame or stock, which hold multiple cartridges and feed them sequentially into the chamber.^[7] These elements allow for rapid succession of shots without external intervention during the loaded sequence.^[8] The transition from single-shot to repeating firearms represented a major technological leap, dramatically increasing firepower by enabling shooters to deliver multiple rounds quickly from one loading, transforming combat and sporting applications.^[5]

Distinctions from other firearms

Repeating firearms differ fundamentally from single-shot firearms in their capacity to fire multiple rounds without requiring a complete reload after each shot. Single-shot firearms, such as early muzzle-loading muskets or breechloading rifles like the Sharps, are designed to load, fire, and reload one cartridge at a time, necessitating manual intervention for each subsequent round.^[1]^[9] In contrast, repeating firearms incorporate a mechanism—such as a revolving cylinder, tubular magazine, or detachable box—to store and sequentially chamber multiple cartridges into a single barrel, enabling sustained fire until the ammunition supply is exhausted.^[1] This design advancement significantly enhanced rate of fire and tactical flexibility, particularly in 19th-century conflicts.^[9] Unlike multi-barrel volley guns, which achieve multiplicity through parallel barrels each firing a single shot either simultaneously or in rapid succession, repeating firearms rely on sequential chambering within a solitary barrel to deliver repeated shots. Historical volley guns, such as the 18th-century Nock gun with its seven barrels, were essentially clusters of single-shot mechanisms intended for a short, intense barrage but suffered from inaccuracy, heavy weight, and the need for full reloading after the volley.^[10] Repeating firearms, by contrast, avoid these limitations by cycling cartridges through one rifled barrel, promoting precision and efficiency over brute volume of initial fire.^[1] Repeating firearms encompass both manual and self-loading variants, including semi-automatic models, but are distinguished from fully automatic weapons by their controlled firing mode. Fully automatic firearms, like the Maxim gun introduced in the late 19th century, continue discharging rounds as long as the trigger is held and ammunition is available, often leading to rapid overheating and ammunition depletion.^[1] Repeaters, however, require either manual operation (e.g., lever or bolt action) or a separate trigger pull for each semi-automatic shot, emphasizing deliberate repeat fire rather than continuous automatic discharge.^[9] This boundary became more pronounced with 20th-century regulations, but pre-20th-century repeaters operated without such automatic capabilities. Terminologically, "repeating firearm" or "repeater" was a broad descriptor in the 19th century for any multi-shot arm, applied equally in civilian and military contexts without the modern regulatory distinctions seen in laws like the National Firearms Act of 1934. Military examples include the Spencer repeating rifle, adopted by Union forces during the American Civil War for its seven-shot capacity in cavalry operations.^[9]^[11] Civilian uses encompassed sporting rifles and revolvers, such as the Colt Paterson, marketed to frontiersmen and hunters for self-defense and game pursuit, reflecting the term's neutral application across non-automatic multi-shot designs prior to stricter classifications.^[9]^[12]

Historical development

Early inventions

The earliest attempts at repeating firearms emerged in the 16th century, primarily through the use of superimposed loads, where multiple charges of powder and projectiles were stacked sequentially in a single barrel to allow several shots without reloading. One notable example is a German wheellock rifle dating to around 1580, capable of firing up to 16 superimposed shots via a complex internal mechanism that advanced each charge with each firing. These designs relied on the wheellock ignition system, an early self-contained mechanism using a spring-driven wheel to generate sparks, but they remained rare prototypes due to their intricate construction by specialized gunsmiths.^[13] In the 17th century, the Kalthoff repeater represented a significant advancement in repeating firearm technology, developed by the Kalthoff brothers—Peter, Mathias, Caspar, Henrik, and William—around the 1630s and 1640s in Denmark and northern Germany. This flintlock design featured superimposed loads in the barrel, holding up to 10-20 shots (with some variants up to 30 balls stored in a magazine under the barrel and powder in the buttstock), operated by a lever that rotated 180 degrees to sequentially load powder, seat a ball, prime the pan, cock the hammer, and close the frizzen for firing.^[14] Adopted by the Danish Royal Guard, it saw combat use as early as the 1659 Siege of Copenhagen, where over 100 were purchased, marking the first documented military employment of a repeating firearm.^[14] By the late 17th century, the Cookson repeater, crafted by London gunsmith John Cookson in the 1680s, built on the Italian Lorenzoni system (invented around 1650) to create a volitional repeating flintlock carbine or pistol. This mechanism used a sliding breech block with spring-loaded magazines for powder and balls, enabling up to 8 rapid shots by rotating a lever to advance fresh charges into the chamber after each firing.^[15] Several examples were produced and signed "Fecit Londini," indicating their English origin, though they were primarily curiosities for affluent collectors rather than practical military tools.^[15] Despite these innovations, early repeating firearms faced severe limitations that hindered widespread adoption. The superimposed load systems were prone to misfires from inconsistent ignition across stacked charges, exacerbated by black powder residue causing rapid fouling and jamming after just a few shots.^[14] Their mechanical complexity demanded skilled craftsmanship, making them expensive and fragile in field conditions, often leading to disassembly for simpler single-shot designs by the early 18th century.^[15]

19th-century innovations

The 19th century marked a transformative era for repeating firearms, propelled by the Industrial Revolution's advancements in manufacturing and the invention of self-contained metallic cartridges. These cartridges, which integrated the propellant, primer, and projectile into a single unit, overcame the limitations of earlier cap-and-ball systems by enabling faster, more reliable reloading without exposing powder to the elements. The rimfire cartridge, featuring ignition via a primer in the cartridge rim struck by the firing pin, emerged as a key innovation in the 1840s, with developments like the .22 Short introduced by Smith & Wesson in 1857 paving the way for widespread adoption in repeaters.^[16] This development shifted firearm design from single-shot muzzle-loaders to multi-shot mechanisms, dramatically enhancing firepower for both military and civilian applications. A seminal advancement was the introduction of practical repeating handguns, exemplified by Samuel Colt's Paterson revolver patented in 1836. Produced by the Patent Arms Manufacturing Company in Paterson, New Jersey, this five- or six-shot .36-caliber percussion revolver used a rotating cylinder to align chambers with a single barrel, allowing rapid successive shots without reloading the entire weapon. Though reliant on loose powder and percussion caps rather than integrated cartridges, the Paterson represented the first commercially successful mass-produced repeating handgun, with approximately 2,000 units made before the company's closure in 1842 due to financial issues. Its design influenced subsequent revolvers and demonstrated the viability of interchangeable parts in firearm production, a hallmark of 19th-century industrialization.^[17]^[18] In long arms, the American Civil War (1861–1865) accelerated the deployment of cartridge-based repeating rifles, which provided Union forces with a decisive edge in several engagements. The Spencer repeating rifle, patented by Christopher M. Spencer in 1860, was the first military rifle to use metallic rimfire cartridges effectively, featuring a seven-shot tubular magazine in the buttstock loaded via a spring-follower mechanism. Chambered in .56-56 Spencer rimfire, it allowed a trained soldier to achieve a firing rate of 14 to 20 rounds per minute, far surpassing the two to three rounds per minute of standard muzzle-loading rifled muskets like the Springfield Model 1861. Over 200,000 Spencers were produced between 1860 and 1869, with significant use by Union cavalry and infantry, including at battles like Gettysburg and Chickamauga.^[19]^[20] Complementing the Spencer was the Henry rifle, patented by Benjamin Tyler Henry in 1860 and produced by the New Haven Arms Company, which served as a direct precursor to later lever-action designs. This .44-caliber rimfire lever-action rifle utilized a 15- or 16-shot under-barrel tubular magazine, enabling rapid fire through a toggle-link mechanism that ejected spent cases and chambered new rounds with each lever cycle. Approximately 14,000 Henry rifles were manufactured between 1860 and 1866, often purchased privately by Union soldiers due to initial military reluctance; its high rate of fire—up to 28 rounds per minute in skilled hands—earned it the Confederate nickname "that damned Yankee rifle you load on Sunday and shoot all week."^[21]^[22] Innovations extended to heavier weapons, including revolver-style designs for specialized roles. The Lindner repeater, patented by Edward Lindner in 1857, was an experimental self-priming, tubular-magazine, revolving-cylinder percussion carbine using .48 caliber combustible cartridges. Though prototypes were developed, it was not widely adopted due to complexity and the rise of metallic cartridges, with a few of Lindner's other breechloaders seeing limited Civil War service.^[23] These 19th-century repeaters fundamentally altered warfare by increasing effective fire rates from the two to three rounds per minute of muzzle-loaders to 10 or more for repeaters, enabling sustained volleys that overwhelmed single-shot opponents. In the Civil War, units armed with Spencers or Henrys, such as Wilder's Lightning Brigade, could deliver firepower equivalent to an entire company of musketeers, contributing to tactical shifts toward skirmishing and defensive stands while foreshadowing modern infantry doctrines. However, high ammunition consumption and cost limited their ubiquity, with most soldiers still relying on breech-loading single-shots by war's end.^[24]^[25]

20th- and 21st-century advancements

The early 20th century marked a pivotal shift toward self-loading repeating firearms, with John Moses Browning's innovations leading the way. The Browning Auto-5, patented in 1899 and entering production in 1902, became the world's first commercially successful semi-automatic shotgun, utilizing a recoil-operated mechanism to cycle shells automatically after each shot.^[26] Similarly, Browning's Colt M1911 pistol, adopted by the U.S. military in 1911, introduced a reliable semi-automatic handgun design chambered in .45 ACP, featuring a short-recoil operation that influenced handgun development for decades.^[27] These designs built on 19th-century manual repeating principles but emphasized automation for faster follow-up shots, enhancing military and sporting applications. World War II accelerated the adoption of semi-automatic rifles, transforming infantry tactics through increased firepower. The M1 Garand, designed by John C. Garand and officially adopted by the U.S. Army in 1936, was the first standard-issue semi-automatic rifle for a major military power, employing gas operation to reload after each discharge and providing U.S. troops with a significant edge in rate of fire during the conflict.^[28] Over 5 million units were produced by war's end, underscoring its role in widespread deployment across theaters. This era solidified self-loading mechanisms as essential for modern repeating firearms, prioritizing reliability under combat conditions. Post-World War II developments introduced selective-fire assault rifles, blending semi-automatic precision with full-automatic capability for versatile repeating action. The AK-47, designed by Mikhail Kalashnikov and finalized in 1947 before Soviet adoption in 1949, utilized long-stroke gas operation to enable selective fire modes, achieving legendary durability and becoming the most produced assault rifle in history with over 100 million units manufactured worldwide.^[29] In the United States, the M16 rifle, developed by Eugene Stoner in the late 1950s and adopted in the 1960s, featured direct impingement gas operation and lightweight aluminum construction, evolving from the AR-15 platform to serve as the standard U.S. service rifle through conflicts like Vietnam.^[30] These rifles emphasized intermediate cartridges for controlled full-auto fire, redefining repeating firearm standards for mass infantry use. Into the 21st century, repeating firearms evolved toward modularity, lightweight materials, and integrated technologies, enhancing customization and safety. The AR-15 platform, originating from the M16 lineage, gained prominence through its modular rail systems and interchangeable components, allowing users to adapt uppers, lowers, and accessories for diverse roles from civilian defense to competition shooting.^[31] Polymer frames, advanced since the 1980s but refined in the 2000s with corrosion-resistant composites, reduced weight by up to 40% compared to all-metal designs while maintaining structural integrity, as seen in models like the Glock 17 Gen5.^[32] Smart gun technologies emerged to prevent unauthorized use, exemplified by the Armatix iP1 pistol released in 2014, which incorporates RFID-based locking tied to a wristwatch for owner verification, though adoption has been limited by reliability concerns.^[33] The rise of 3D-printed repeating firearms introduced new manufacturing paradigms and regulatory challenges starting in 2013. Defense Distributed's release of CAD files for the Liberator pistol, a single-shot .380 ACP design printable with consumer-grade printers, sparked debates over undetectable "ghost guns," prompting U.S. State Department interventions to restrict file distribution under export controls.^[34] Subsequent adaptations extended to repeating mechanisms, such as multi-shot pistol variants, but legal implications persist, with federal laws requiring serialized metal components for manufactured firearms while allowing personal unlicensed production, leading to ongoing litigation and state-level bans on untraceable prints.^[35] Hybrid mechanisms, particularly electro-pneumatic systems, have influenced competition repeating firearms in the 2020s, drawing from airsoft and airgun technologies for precise control. These systems use electronic triggers and pneumatic valves to regulate firing sequences in semi-automatic or burst modes, as in advanced PCP air rifles like the BRK Ghost, which enable rapid, repeatable shots in precision competitions without traditional powder propulsion.^[36] While primarily seen in non-lethal training and sporting replicas, they inspire firearm innovations by improving trigger response and reducing mechanical wear, though full integration into powder-based repeaters remains experimental due to regulatory hurdles.

Manual repeating actions

Revolver mechanisms

Revolver mechanisms operate on the principle of a rotating cylinder that holds multiple chambers, each loaded with a cartridge, allowing sequential firing without reloading after each shot. The cylinder indexes—rotates to align the next chamber with the barrel—typically via manual cocking of the hammer or trigger pull, enabling repeating fire in a compact design suitable for handguns and larger artillery. This system contrasts with linear magazine feeds by relying on rotational alignment for reliability in manual operation.^[37] Single-action revolvers require the shooter to manually cock the hammer with the thumb before each shot, which rotates and locks the cylinder into position while compressing the mainspring; pulling the trigger then performs the single action of releasing the hammer to strike the firing pin or cartridge primer. This design, common in early models like Samuel Colt's 1836 Paterson revolver, emphasizes precision and lighter trigger pull for accuracy but demands more time per shot. In contrast, double-action revolvers allow the trigger pull to perform both actions: cocking the hammer (which indexes the cylinder) and releasing it to fire, providing faster follow-up shots at the cost of a heavier, longer trigger travel that can reduce precision. The double-action mechanism was first patented by Robert Adams in 1851, enabling self-cocking without separate hammer manipulation.^[38]^[39] Cylinder designs facilitate loading and unloading while maintaining structural integrity. Fixed-frame cylinders, often found in single-action revolvers, use a loading gate on the right side of the frame to access chambers individually, with an ejector rod for spent cases; this robust setup suits rugged use but slows reloading. Top-break designs hinge the barrel and cylinder forward from the frame's bottom front, allowing simultaneous ejection of all cases via a star extractor when opened, as pioneered in Smith & Wesson models from the 1850s for quicker reloads in combat. Swing-out cylinders, introduced by Colt in 1889, pivot sideways on a crane for rapid access to all chambers, combining speed with the strength of a solid frame and becoming standard in modern double-action revolvers.^[40]^[41]^[37] Revolver mechanisms extend to larger scales in revolver cannons, which employ a multi-chamber cylinder for rapid fire. The 37mm Hotchkiss revolving cannon, developed in the 1870s by Benjamin B. Hotchkiss, features five barrels arranged radially that rotate around a fixed central breechblock; a hand crank rotates the barrels to load, fire, and extract from each chamber sequentially using a single breechblock, achieving 60-80 rounds per minute with explosive or armor-piercing projectiles. This Gatling-inspired design powered naval and land defenses until the early 20th century, offering controlled bursts without full-automatic complexity.^[42]^[43] Revolver actions excel in simplicity and reliability for manual repeaters, with fewer moving parts than magazine-fed systems, reducing malfunctions from jams or failures to feed; this inherent robustness allows function even with varied ammunition types or in harsh conditions. However, limitations include the cylinder gap—the necessary space between cylinder and barrel for rotation—which permits hot gases and flash to escape forward, potentially causing burns or reducing muzzle velocity by 50-100 feet per second while posing risks if fingers intrude during firing. Reload times are also slower than detachable magazines, often requiring 10-20 seconds for full capacity versus seconds for semi-automatics.^[44]^[45]^[46]^[47]

Lever-action mechanisms

Lever-action mechanisms represent a prominent form of manual repeating action in firearms, particularly rifles and shotguns, where a pivoting lever integrated around the trigger guard manually cycles the action to chamber rounds, eject spent cases, and prepare the firearm for firing. This design traces its roots to mid-19th-century innovations, such as the Henry rifle introduced in 1860, which popularized the system for its balance of speed and reliability in combat and hunting scenarios.^[48]^[49] The core operation cycle of a lever-action firearm involves pivoting the lever downward and forward from its closed position, which unlocks the breechblock or bolt, extracts the spent cartridge case via an extractor, and ejects it through a side port. This motion simultaneously cocks the hammer or striker and advances a new round from the magazine onto the carrier block. Returning the lever to its upward position then chambers the round, locks the action, and readies the firearm for the next shot, enabling a complete cycle in approximately 2-4 seconds for proficient users.^[50]^[51] Early lever-action designs, like the toggle-link system in the 1860 Henry rifle, employed a hinged toggle joint connecting the lever to the breechblock; downward lever movement collapses the toggle to open the action, while upward motion straightens it to lock, providing sufficient strength for rimfire or low-pressure centerfire cartridges of the era. Later evolutions, such as the sliding block in the Winchester Model 1894 introduced in 1894, replaced the toggle with a robust locking block that slides vertically to engage lugs on the bolt, enhancing durability for smokeless powder loads and higher chamber pressures without the flex inherent in toggle joints.^[52]^[48]^[53] Traditional lever-actions predominantly feature tubular magazines positioned beneath the barrel, where rimmed cartridges stack end-to-end in a spring-driven tube; a follower pushes rounds rearward onto an elevating carrier during the lever cycle, ensuring sequential feeding into the chamber with minimal misalignment for pistol or rifle calibers. These magazines typically offer capacities of 8-15 rounds depending on caliber and barrel length, excelling in reliability for straight-walled or bottlenecked rimmed ammo but posing risks of primer damage from bullet tips under recoil. In comparison, box magazines—less common in classic designs but seen in modern variants like certain Henry or Marlin adaptations—use a detachable or fixed vertical stack for quicker reloading and compatibility with spitzer bullets, potentially increasing capacity to 20+ rounds while simplifying top-loading, though they can shift the firearm's center of gravity lower and complicate side-ejection compatibility.^[54]^[55] In practical applications, lever-action rifles excel as hunting tools in dense brush or close-quarters scenarios, with the Marlin 336 in .30-30 Winchester serving as a seminal example since 1948 for its lightweight 7-pound frame, 20-inch barrel, and tubular magazine holding 6-7 rounds, delivering effective medium-game performance at 100-200 yards. Trained shooters can sustain aimed fire rates of 10-15 rounds per minute, balancing speed with accuracy for dynamic pursuits like deer or boar hunting.^[56]^[57]^[58] However, lever-actions carry inherent drawbacks, including the external hammer's exposure to environmental debris, moisture, or accidental snags that may impede function or risk unintended discharge, often necessitating protective covers or internal adaptations in adverse conditions. Additionally, the pivoting lever motion demands more wrist and forearm articulation than linear alternatives, resulting in slower cycling—typically 20-30% behind pump-actions for rapid follow-ups—especially under stress or with gloved hands.^[49]^[59]

Pump-action mechanisms

The pump-action mechanism, also referred to as slide-action, is a manual repeating system predominantly employed in shotguns and certain rifles, where the shooter manually reciprocates a sliding forend to cycle the firearm. This action enables the loading, firing, and ejection of multiple rounds from a tubular magazine without needing to manually manipulate each cartridge individually. The design emphasizes simplicity and durability, making it suitable for field use in hunting, sport shooting, and defensive applications.^[60] The operating cycle begins after firing, when the shooter pulls the forend rearward; this movement retracts the bolt via connected action bars, unlocking it from the barrel extension, extracting and ejecting the spent shell through the side port, and compressing a recoil spring housed in the magazine tube or stock. As the forend is then pushed forward, the spring assists in driving the bolt forward, where the shell lifter—a pivoting component—elevates the next round from the tubular magazine into alignment; the bolt then strips the shell and chambers it, with locking lugs on the bolt engaging recesses in the barrel extension to secure the action for firing. Key internal components include the action bars, which link the forend to the bolt for synchronized movement; the shell lifter, which ensures smooth transfer of ammunition; and the locking lugs, which provide the necessary strength to contain high-pressure shotgun loads. This straightforward linear motion distinguishes pump-actions from other manual systems, relying on user input rather than mechanical leverage or rotation.^[60] Notable designs illustrate the evolution and enduring popularity of pump-actions. The Winchester Model 1897, introduced in 1897 and designed by John M. Browning as an improvement over the earlier Model 1893, was the first commercially successful pump-action shotgun capable of handling smokeless powder loads, featuring an external hammer and takedown receiver for easy field maintenance. Over a million units were produced until 1957, serving in military roles during World War I and beyond. Similarly, the Remington Model 870, launched in 1950 under the direction of Remington engineers building on prior pump designs like the Model 31, utilized a lightweight aluminum receiver and dual action bars for enhanced reliability; by 2023, more than 11 million had been manufactured, solidifying its status as one of the most prolific shotguns in history.^[61]^[62] Pump-action firearms offer versatility across applications, particularly in shotguns that accommodate a wide range of ammunition types—including birdshot for upland game, buckshot for defense, and slugs for longer-range accuracy—without requiring mechanical adjustments, unlike some semi-automatics sensitive to load variations. In rifles, such as tactical variants of the Remington Model 760 series, the mechanism supports quick follow-up shots in dynamic scenarios. Advantages include exceptional reliability in dirty or adverse conditions due to fewer moving parts and less dependence on gas or recoil energy, allowing consistent operation even with mixed ammunition. However, the manual cycling results in a slower rate of fire compared to self-loading mechanisms, potentially limiting effectiveness in rapid-engagement situations.^[63]^[64]

Bolt-action mechanisms

The bolt-action mechanism is a type of manual repeating action in firearms, primarily rifles, where a cylindrical bolt is rotated and reciprocated within the receiver to load, fire, and unload cartridges. This design relies on a rotary bolt that locks into the receiver via lugs, providing a secure breech for high-pressure rounds. Originating from innovations in the 19th century, such as those by Paul Mauser, the bolt-action became a standard for military and sporting rifles due to its simplicity and reliability.^[65] In the Mauser-style action, which influenced many subsequent designs, the bolt features two primary front locking lugs that engage extensions in the receiver through a 90-degree rotation of the bolt handle. This rotation aligns the lugs to lock securely behind the cartridge case, containing the pressure generated during firing. The cycle of operation begins with the shooter lifting the bolt handle upward approximately 90 degrees to unlock the bolt from the receiver. The bolt is then pulled rearward, where an extractor removes the spent cartridge from the chamber, and an ejector expels it from the firearm. Pushing the bolt forward strips a new cartridge from the magazine and chambers it, followed by rotating the handle downward to lock the bolt and cock the firing mechanism.^[65]^[66] Bolt-action rifles typically integrate with fixed internal box magazines or use detachable stripper clips for efficient reloading. For example, the British Lee-Enfield rifle, introduced in 1895, employed a detachable 10-round internal box magazine loaded via stripper clips, allowing rapid top-loading without removing the magazine. This configuration balanced capacity with the manual operation's pace, making it suitable for infantry use.^[67] Due to the robust locking provided by the rotary bolt, these mechanisms excel in precision applications, such as sniper rifles, where accuracy and handling of powerful cartridges are paramount. The Remington Model 700, introduced in 1962, exemplifies this with its short bolt lift and three-lug design derived from Mauser principles, serving as the basis for military sniper systems like the U.S. Army's M24. The strong locking lugs enable safe use with high-pressure cartridges, supporting long-range ballistics and durability under stress. However, the manual cycling—requiring multiple deliberate movements per shot—results in slower follow-up shots compared to other repeating actions, limiting its rate of fire in dynamic scenarios.^[68]

Self-loading mechanisms

Blowback systems

Blowback systems represent a fundamental self-loading mechanism in repeating firearms, where the bolt or breechblock remains unlocked relative to the barrel during firing. Upon ignition, the expanding propellant gases exert pressure on the base of the cartridge case, propelling it—and the attached bolt—rearward with sufficient force to extract, eject the spent case, and cock the firing mechanism. A recoil spring then drives the bolt forward to strip a new cartridge from the magazine and chamber it, completing the cycle without any mechanical lock between the bolt and barrel.^[69]^[70] This design relies on the inertia of a relatively massive bolt to contain chamber pressure long enough for the bullet to exit the barrel and pressures to drop safely, preventing premature case rupture or gas escape into the receiver. The simplicity of blowback makes it suitable for low-pressure cartridges, as higher pressures demand either heavier bolts—which increase felt recoil and slow cyclic rates—or modifications to delay bolt movement. A return spring provides the forward force, typically calibrated to match the bolt's mass and the firearm's recoil dynamics for reliable feeding.^[69]^[70] Blowback variants address the limitations of simple (or straight) blowback, which uses direct gas pressure on an unlocked bolt and is ideal for low-pressure rounds like .22 Long Rifle in pistols and rifles, where bolt mass alone suffices to manage recoil. In contrast, delayed blowback incorporates mechanisms to temporarily resist rearward bolt movement, allowing higher-pressure cartridges such as 9mm Parabellum without excessively heavy components; examples include roller-delayed systems, where rollers on the bolt head engage barrel extension recesses to create friction-based opposition until pressures subside. These delays reduce bolt velocity and recoil impulse while maintaining a lighter overall action.^[71]^[72] To ensure safe operation in simple blowback designs, engineers calculate the minimum bolt mass required to keep the breech closed until the bullet exits, preventing dangerous pressure exposure. The core relation derives from the impulse-momentum theorem: the gas pressure impulse must impart a rearward velocity to the bolt that is low enough for safe timing. Specifically, the bolt mass m must satisfy m > \frac{P \cdot A \cdot t}{v}, where P is the peak chamber pressure, A is the average cross-sectional area of the cartridge case base, t is the duration of significant pressure (approximately the bullet's travel time in the barrel), and v is the desired maximum bolt unlock velocity (typically 3–5 m/s to allow pressure drop). This formula arises as follows: The total impulse J from gas pressure is J = \int F \, dt \approx P \cdot A \cdot t, where force F = P \cdot A. By conservation of momentum, this impulse equals the change in bolt momentum m \cdot v (assuming negligible initial velocity and bullet momentum effects for approximation in low-pressure systems). Thus, m = \frac{J}{v}, and a safety margin is added to account for friction and variations, yielding the inequality. The recoil spring constant k is then selected such that k = \frac{m \cdot \omega^2}{d}, where \omega is the desired cyclic frequency and d is the bolt travel distance, ensuring prompt return without over-stressing the action. Prominent examples illustrate blowback's evolution. The Ruger 10/22 rifle, introduced in 1964, employs simple blowback for its .22 LR chambering, using a lightweight rotary-fed bolt that cycles efficiently at low pressures for target shooting and plinking. Early submachine guns like the Thompson, patented in 1918 and entering production in 1919, utilized a form of delayed blowback (initially with the ineffective Blish lock, later simplified to near-straight operation) in .45 ACP to deliver high-volume fire in close quarters. The Heckler & Koch MP5, developed in the 1960s, exemplifies advanced roller-delayed blowback in 9mm, enabling compact design and controlled full-auto rates for military and law enforcement use.^[73]^[74]^[71]

Recoil-operated systems

Recoil-operated systems harness the rearward force generated by the firing of a cartridge to cycle the action of a self-loading firearm, utilizing a locked breech to contain the high pressures of modern ammunition. This contrasts with simpler blowback designs suitable only for lower-pressure cartridges, as the locked mechanism delays unlocking until chamber pressure has sufficiently dropped. The recoil impulse, defined as I = m \Delta v, where m is the mass of the projectile and propellant gases and \Delta v is the change in velocity, transfers kinetic energy to the barrel and bolt assembly to initiate the cycle.^[75] In short recoil operation, the barrel and slide (or bolt carrier) remain locked together for a brief distance—typically a few millimeters—after firing, allowing the bullet to exit the muzzle before unlocking occurs. This short locked travel, often around 6-13 mm in pistols, ensures safe extraction while minimizing overall action mass and recoil felt by the shooter. Unlocking is achieved through mechanisms such as a swinging link or cam that tilts or pivots the barrel, disengaging locking lugs from the slide. The 1911 pistol, designed by John Browning and patented in 1911 (US Patent No. 1,009,102), exemplifies this with its tilting barrel and swinging link system, where the barrel moves rearward approximately 1/4 inch (6.35 mm) locked before the link pulls the barrel downward to unlock.^[76]^[77] Long recoil systems extend the locked travel further, with the barrel and bolt recoiling together for the full cycle distance—often 1-1.5 inches (25-38 mm)—before separating on the forward stroke, providing additional time for pressure dissipation in higher-energy loads like shotgun shells. This design requires heavier components to manage the extended motion but offers robust operation for powerful cartridges. The Browning Auto-5 shotgun, patented in 1900 (US Patent No. 659,786), employs this principle, where the barrel and bolt recoil rearward fully, compressing a main spring, then the bolt is held back by a locking shoulder while the barrel returns forward under spring tension.^[78]^[79] Variations in locking include tilt-barrel designs, where the barrel pivots downward at the rear to engage or disengage lugs with the slide, and linkless configurations using cams or ramps for direct mechanical interaction without a pivoting link. These enhance reliability by reducing wear points and simplifying manufacturing. The Beretta 92 pistol (introduced 1976) uses a short recoil tilt-barrel with a falling locking block, while earlier FN Browning pistols like the Model 1900 (patented 1899, US Patent No. 580,925) featured short recoil with tilting barrels and lugs for secure high-pressure containment.^[80]^[81]

Gas-operated systems

Gas-operated systems in repeating firearms harness propellant gases vented from the barrel to cycle the action, providing a reliable method for self-loading mechanisms in rifles and machine guns. Unlike recoil-operated systems commonly used in handguns, which rely on the rearward movement of the barrel or frame to unlock and extract the cartridge, gas-operated designs tap high-pressure gases to drive a piston or directly impinge on the bolt carrier, enabling semi-automatic or automatic fire with reduced perceived recoil in longer-barreled weapons.^[82] This approach was pioneered in the early 20th century and became dominant in military rifles by World War II, offering advantages in controllability and sustained fire rates around 600-900 rounds per minute.^[82] Piston-driven variants dominate gas-operated designs, categorized by stroke length. In long-stroke systems, the piston is rigidly attached to the bolt carrier and travels the full distance required to cycle the action, imparting direct momentum while simplifying the mechanism but potentially increasing bolt velocity and recoil impulse. The AK-47, introduced in 1949, exemplifies this with its long-stroke piston, where gases from a mid-barrel port at approximately 16.5 inches drive the carrier rearward at an initial pressure of about 9000 psi, ensuring robust operation in adverse conditions.^[82]^[83] Conversely, short-stroke systems feature a piston that moves only a brief distance to impart initial momentum to the bolt carrier, which then continues via inertia and springs, resulting in a cleaner operation with less fouling transferred to the receiver. The Soviet SKS rifle, adopted in 1945, uses a short-stroke tappet piston with a gas port at 14.5 inches, providing reliable semi-automatic function at a cyclic rate of around 600 rounds per minute.^[82] The FN SCAR series, developed in the 2000s, employs a modular short-stroke piston for enhanced reliability across calibers like 5.56mm and 7.62mm NATO, with adjustable gas settings to optimize for suppressors or varying ammunition.^[84]^[82] Direct impingement represents a pistonless alternative, where gases are routed via a tube directly to the bolt carrier group, expanding against it to initiate cycling without intermediate components. This design, lighter and with fewer moving parts, was innovated for the ArmaLite AR-10 and refined in the M16 rifle adopted by the U.S. military in 1964, featuring a gas port near the muzzle at about 20 inches to capture gases at a lower initial pressure of roughly 3000 psi, promoting accuracy but requiring meticulous maintenance to mitigate carbon buildup in the receiver.^[82]^[85] The placement of the gas port along the barrel critically influences system performance, balancing dwell time, pressure, and reliability. Mid-barrel ports, as in the AK-47, allow the bullet to pass farther before gas diversion, reducing peak pressure for smoother cycling and less wear, while ports closer to the chamber or "over-gassed" configurations ensure function in fouled or suppressed conditions by capturing higher-volume, higher-pressure gases.^[82] This trade-off prioritizes reliability in combat environments over refined recoil, with port diameters typically 0.07-0.08 inches to regulate flow.^[82] Pressure dynamics in these systems govern gas volume and flow, modeled by the tapped gas volume V = \pi r^2 L, where r is the port radius and L the effective length of gas travel or expansion chamber, determining the energy available for piston acceleration. Detailed flow equations account for quasisteady mass conservation and energy transfer, such as the mass flow rate \dot{m} = \rho_e a_e A_e (with \rho_e as exit density, a_e sound speed, and A_e port area) and continuity \frac{\partial (\rho V_c)}{\partial t} + \rho_c v_B A_c + \dot{m} = 0 in the cylinder, where subscripts denote cylinder (c) and piston base velocity (v_B). These predict pressure histories peaking at 1000-9000 psi shortly after ignition, dropping rapidly as the bullet travels, ensuring safe extraction timing at 50-70% of bore length. Experimental validations on systems like the M16 confirm these models, with friction and backflow adjustments yielding accurate piston motion predictions.^[86]

Blow-forward and other variants

In blow-forward mechanisms, the barrel moves forward upon firing while the breech remains stationary, driven by the friction and gas pressure acting on the bullet as it travels down the bore, which unlocks the action, ejects the spent cartridge, and allows chambering of a new round.^[87] This design contrasts with more common recoil-operated systems where components move rearward, but it proved challenging due to sharp recoil and safety concerns during handling.^[88] Notable examples include the Schwarzlose Model 1908 pistol in 7.65mm Browning, which used this action for semiautomatic operation, and the similar Hino-Komuro Model 1908 in 8×22mm Nambu, both of which saw limited commercial production in the early 20th century.^[88] Inertia-operated systems, employed primarily in shotguns, rely on the recoil of the firearm itself to cycle the action while the bolt remains stationary relative to the barrel during firing; the inertia spring absorbs the recoil energy to drive the bolt rearward for extraction and then forward for reloading.^[89] Patented in 1967 by Italian designer Bruno Civolani and first commercialized by Benelli in models like the Montefeltro series starting in the 1980s, this system gained prominence in the 2000s for its simplicity, reliability in harsh conditions, and reduced fouling compared to gas-operated alternatives.^[90] Benelli's implementation, as seen in the M2 and Super Black Eagle lines, uses just three main parts—the rotating bolt head, bolt body, and inertia spring—enabling consistent performance across various loads without adjustments.^[90] Hybrid electro-mechanical trigger systems integrate electronic sensing with mechanical firing components to provide precise, adjustable control, particularly in competition firearms.^[91] For instance, the Matchguns MGH1 Hybrid air pistol, designed for ISSF 10-meter events, combines an electronic trigger for consistent pull weights as low as 20 grams with a mechanical safety and firing pin, allowing shooters to maintain sight alignment during the break.^[91] Introduced in the 1990s, these hybrids became common in Olympic-level air pistols from manufacturers like Matchguns and Pardini, offering advantages in trigger consistency but requiring batteries and maintenance to prevent failures.^[91] Rare designs include the hesitation lock, a delayed blowback variant where a secondary locking element briefly hesitates the bolt's rearward movement to allow pressure to drop before full extraction, reducing slide mass and recoil.^[92] Developed by John Pedersen and used in the Remington Model 51 pistol of 1918, it enabled lighter construction but saw limited adoption due to reliability issues in later revivals like the 2014 R51.^[92] Another uncommon approach is the accelerating block mechanism, which uses a spring-loaded accelerator to impart additional velocity to the bolt during closing and opening cycles, improving chambering speed in semiautomatic rifles.^[93] Patented in 1994 for specialized applications, it remains niche, appearing in prototypes rather than widespread production arms.^[93] These variants find niche applications in competition shooting, such as electro-mechanical triggers in Olympic air pistols for precision timing, and specialty firearms like inertia-operated shotguns for hunting in adverse weather where gas systems might foul.^[90] Blow-forward and hesitation locks, largely historical curiosities, illustrate experimental paths in early 20th-century pistol design, influencing modern hybrids but rarely entering mainstream use due to ergonomic and safety trade-offs.^[92]

Automatic repeating mechanisms

Rotary-barrel designs

Rotary-barrel designs represent an early innovation in repeating firearms, enabling sustained high-volume fire through the rotation of multiple barrels around a central axis, which allows each barrel to cool while others are in use. The seminal example is the Gatling gun, invented by Richard J. Gatling and patented in the United States on November 4, 1862, under Patent No. 36,836. This hand-cranked weapon featured six barrels arranged in a cylindrical cluster that rotated via a manual crank mechanism connected to a central shaft. As the cluster turned, each barrel advanced through a sequence of operations: loading a cartridge from a hopper or gravity feed, locking the breech, firing upon alignment with a fixed striker, unlocking, extracting the spent case, and ejecting it before returning to the loading position.^[94]^[95] The Gatling gun's design emphasized reliability through independent operation per barrel, with each featuring its own breech block that locked radially to secure the cartridge during firing, preventing premature opening under pressure. This independent locking system, combined with the rotational motion, distributed heat across the barrels, as the firing position was fixed while the non-firing barrels were exposed to airflow for natural cooling during their cycle. Early models achieved rates of up to 200 rounds per minute, though practical sustained fire was limited by the operator's cranking speed and ammunition supply. The weapon saw limited use in the American Civil War and later conflicts, proving effective for defensive positions due to its ability to deliver concentrated fire without rapid overheating.^[95] Electric-powered evolutions of the rotary-barrel concept emerged in the mid-20th century, building on Gatling's principles but replacing manual cranking with motors for dramatically higher rates of fire. The M134 Minigun, developed by General Electric in the early 1960s under the U.S. military's Project Vulcan, adapted the design for modern use with six externally powered, rotating barrels chambered in 7.62×51mm NATO. An electric motor drives the rotation at speeds yielding 2,000 to 6,000 rounds per minute, depending on configuration, with delinking feeders stripping rounds from belts for sequential chambering in each barrel's independent breech. Like its predecessor, the Minigun employs per-barrel locking via rotating bolts or blocks that engage during the firing phase, ensuring safe operation at extreme velocities.^[96] The rotary motion in these designs inherently aids cooling by allowing air circulation around idle barrels, enabling prolonged bursts without thermal degradation—a key advantage over single-barrel automatics. In the M134, the multi-barrel array dissipates heat effectively, supporting sustained fire rates that would overheat conventional machine guns. Applications have centered on anti-aircraft roles and vehicle-mounted systems, where high-volume suppression is critical; the Gatling gun was deployed on horse-drawn carriages for infantry support and early anti-aircraft batteries, while the M134 equips helicopter door mounts, such as on UH-1 Huey and AH-1 Cobra aircraft, and ground vehicles like Humvees for perimeter defense and low-altitude threat engagement.^[95]^[96]^[97]

Selective-fire systems

Selective-fire systems in repeating firearms enable operators to switch between different firing modes, typically including safe, semi-automatic, and either fully automatic or limited-burst options, via a selector switch integrated into the fire control group. This mechanism, often a rotating lever or button on the receiver, engages different sears and disconnectors to control the trigger's interaction with the hammer or striker, allowing precise mode selection for tactical versatility. For instance, in the M16A2 rifle, the selector provides safe, semi-automatic, and three-round burst modes, where the burst function uses a rotating cam on the hammer to limit firing to three rounds per trigger pull by sequentially engaging the disconnector after each shot until the count is reached.^[98] Open-bolt and closed-bolt configurations play key roles in selective-fire operation, influencing safety, accuracy, and rate control. In open-bolt designs, common in full-automatic modes, the bolt remains locked rearward when ready to fire, reducing cook-off risk from residual heat and allowing simpler, higher-rate cyclic fire as the bolt strips and chambers a round upon trigger pull. Closed-bolt systems, preferred for semi-automatic modes in selective-fire weapons, hold the bolt forward with a round chambered, enhancing first-shot accuracy by minimizing barrel movement but requiring additional safety features to prevent accidental discharge. The transition between modes often leverages these configurations for reliability, with sear timing adjustments controlling the rate of fire, typically ranging from 600 to 900 rounds per minute in modern selective-fire rifles to balance controllability and ammunition conservation.^[99]^[100] Modern examples illustrate these principles in gas-operated selective-fire platforms. The HK416, introduced in 2004, features a piston-driven system with a selector for safe, semi-automatic, and full-automatic modes, achieving a cyclic rate of approximately 700-900 rounds per minute while prioritizing reliability in adverse conditions through its closed-bolt semi-auto operation. Similarly, the Steyr AUG bullpup rifle, adopted in 1977 by the Austrian military, employs a three-position selector—safe, semi-automatic (half-pull trigger), and full-automatic (full-pull)—firing from a closed bolt at around 650-700 rounds per minute, with its ambidextrous controls enhancing usability in selective-fire scenarios. In the United States, civilian access to such systems is severely restricted by the 1986 Hughes Amendment to the Firearm Owners' Protection Act, which prohibits the registration and transfer of newly manufactured machine guns, limiting legal ownership to pre-1986 examples or military/law enforcement use only.^[101]^[102]

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Operating Systems 101: Short-Recoil | thefirearmblog.com
Jun 13, 2016 · Short-recoil is a capable operating mechanism well-suited to almost all ammunition types, that can also be made to be inexpensive and very durable and reliable.Missing: explanation | Show results with:explanation
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Working systems: recoil-operated firearms - All4Shooters.com
May 23, 2016 · In long-recoil systems, the barrel and breechblock recoil and stay locked together for the entire length of the cycle; once the breechblock ...
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U.S. Patents - House of Browning
United States patents granted to John Moses Browning. 127 patents were ... Short-recoil Pistol. 58, 31/10/1896, 580925, 20/04/1897, Short-recoil Pistol. 59 ...
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Operating Systems 201: Tilting Barrel Locking | thefirearmblog.com
Jun 17, 2016 · The principle is simple: Create surfaces on the barrel that when it is straight prevent the breechblock from separating from it and moving to ...
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How Guns Work: Short Recoil Operation | The Arms Guide
With this style of short recoil operated pistols, the barrel features either a swinging link or a linkless cam located on the underside of the barrel, on the ...
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[PDF] Engineering Design Handbook: Guns Series. Automatic Weapons
Feb 5, 1970 · ... system of operation, namely: blowback, gas-operated, and recoil- operated'** a. Blowback is the system of operating the gun mechanism that ...
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AKM Russian 7.62mm Automatic Assault Rifle - ODIN
Mar 2, 2025 · The gas operated action has a massive bolt carrier with a permanently attached long stroke gas piston. The gas chamber is located above the ...
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WHY THE FN SCAR® | FN® Firearms
The advantage over the direct gas impingement system is that heat, soot and carbon from propellant combustion are not routed into the bolt or chamber, keeping ...
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[PDF] M16/M4 Accuracy Error - Army Reserve
Eliminating metal external pistons and operating rods common in other gas operated de- signs helped shave ounces and pounds. Combining the functions of a bolt ...Missing: firearms | Show results with:firearms
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[PDF] THE GAS FLOW IN GAS-OPERATED WEAPONS - DTIC
The pressure variation with time at the port is determined by the gas flow in the barrel. The mass flow through the port is small cumpared to the mass flow in ...
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Blow Forward - AFTE
An action design found in some semiautomatic pistols in which the breech is stationary and the barrel moves forward when fired to open the action and eject ...
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US5123329A - Self-actuating blow forward firearm - Google Patents
The piston device causes added momentum to be delivered to the moving barrel to assist the barrel in its forward movement. This added momentum can be further ...
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Inertia Driven System - Benelli technology
Rigorous design, simple construction, easy maintenance and mechanical accuracy guarantee maximum durability and extreme reliability.
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Gun Technology: inertia operated systems for shotguns | all4shooters
May 9, 2017 · How and when Benelli introduced the modern “inertia driven” shotgun · Patent applied for by Bruno Civolani. One of the earliest patents, applied ...
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MGH1 HYBRID - MatchGuns
The MGH1 HYBRID is a single shot air pistol designed for serious ISSF competition at the highest level and incorporates both electronic and mechanical triggers.Missing: Olympic | Show results with:Olympic
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Rifleman Review: Remington R51 | An Official Journal Of The NRA
Sep 30, 2020 · The Pedersen hesitation-lock allowed less material to be used in the slide of the Model 51, reducing weight and felt recoil. The design also ...Missing: mechanism | Show results with:mechanism
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US5359921A - Gun bolt accelerator mechanism - Google Patents
A novel mechanism for accelerating a gun bolt toward and away from the firing chamber formed in a gun barrel, to respectively load and remove a cartridge into ...
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US36836A - Improvement in revolving battery-guns - Google Patents
The object of this invention is to obtain a simple, compact, durable, and edicient tirearm for war purposes, to be used either in attack or defence.
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[PDF] The Development of The Gatling Gun
He was awarded U.S. Patent #36,836 on. November 4, 1862, for "An Improvement in Revolving. Battery-Guns." The patentable features claimed by Gatling included a ...
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GAU-2B/A - Air Force M134 - Army - GlobalSecurity.org
Jul 7, 2011 · The Air Force GAU-2B/A (Army M134) 7.62mm "minigun" was designed to provide a light weight high rate of fire armament package for use on helicopters and light ...
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It wasn't just napalm: A tale of the Huey and Cobra in Vietnam | Article
Nov 14, 2024 · The front of the AH-1 could be modified with the M28A1 weapon system that married the M134 machine gun and the M129 40-mm grenade launcher.<|separator|>
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How the M-16 3-Round Burst Works - The Firearm Blog
May 11, 2015 · A fantastic video showing how the 3-round burst works. He builds up from semi-auto, to full-auto, and finally to the burst function.
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How Does it Work: Open Bolt vs Closed Bolt Firearms
Jan 3, 2019 · Open bolt offers better cooling and prevents any possibility of cookoff, while closed bolt offers better practical accuracy.<|separator|>
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Open-Bolt vs Closed-Bolt: What's the Difference? - The Mag Life
May 10, 2024 · Open-bolt fires when the bolt springs forward, while closed-bolt fires when the bolt is completely closed, with the cartridge in the chamber ...
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AUG A3 | STEYR ARMS
Fires semi automatic when pulled halfway to a clearly felt point, fires fully automatic when pulled fully back. Safety. 3 position safety, Lateral push-through ...
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The Hughes Amendment & Machine Guns: What's the Deal?
Apr 5, 2021 · With these restrictions, only a limited number of machine guns legally owned by civilians in the US exist. No new machine guns made after the ...