fbpx
Wikipedia

Armour-piercing fin-stabilized discarding sabot

January 09, 2023

Armour-piercing fin-stabilized discarding sabot (APFSDS), long dart penetrator, or simply dart ammunition, is a type of kinetic energy penetrator ammunition used to attack modern vehicle armour. As an armament for main battle tanks, it succeeds Armour-Piercing Discarding Sabot (APDS) ammunition, which is still used in small or medium caliber weapon systems.

APFSDS at point of separation of sabot

Improvements in powerful automotive propulsion and suspension systems following World War II allowed modern main battle tanks to incorporate progressively thicker and heavier armour, while maintaining considerable maneuverability and speed on the battlefield. As a result, achieving deep armour penetration with gun-fired ammunition required even longer anti-armour projectiles fired at even higher muzzle velocity than could be achieved with stubbier APDS projectiles.

History

Armour-piercing discarding sabot (APDS) was initially the main design of the kinetic energy (KE) penetrator. The logical progression was to make the shot longer and thinner to concentrate the kinetic energy in a smaller area. However, a long, thin rod is aerodynamically unstable; it tends to tumble in flight and is less accurate. Traditionally, rounds were given stability in flight from the rifling of the gun barrel, which imparts a spin to the round. Up to a certain limit, this is effective, but once the projectile's length is more than six or seven times its diameter rifling becomes less effective.[1] Adding fins like the fletching of an arrow to the base gives the round stability.[2]

The spin from standard rifling decreases the performance of these rounds (rifling diverts some of the linear kinetic energy to rotational kinetic energy, thus decreasing the round's velocity and impact energy), and very high rotation on a fin-stabilized projectile can dramatically increase aerodynamic drag, further reducing impact velocity. For these reasons APFSDS projectiles are generally fired from smoothbore guns, a practice that has been taken up for tank guns by China, India, Israel, Italy, Japan, France, Germany, Pakistan, Turkey, Russia, and the United States. Nevertheless, in the early development of APFSDS ammunition, existing rifled barrel cannons were used, (and are still in use), such as the 105 mm M68/M68E1 cannon mounted on the M60/A1/A3 main battle tank or the British 120 mm Royal Ordnance L30 of the Challenger 2 tank. To reduce the spin rate when using a rifled barrel, a "slip obturator", (slip obturation ring), is incorporated that allows the high pressure propellant gasses to seal, yet not transfer the total spin rate of the rifling into the projectile. The projectile still exits the barrel with some residual spinning, but at an acceptably low rate. In addition, some spin rate is beneficial to a fin-stabilized projectile, averaging out aerodynamic imbalances and improving accuracy. Even smooth-bore fired APFSDS projectiles incorporate fins that are slightly canted to provide some spin rate during flight; and very low twist rifled barrels have also been developed for the express purpose of firing APFSDS ammunition.

Design

 
Modern 120 mm tank gun shells

KE penetrators for modern tanks are commonly 2–3 cm (0.787–1.18 in) in diameter, and can approach 80 cm (31.5 in) long. As more structurally-efficient penetrator-sabot designs are developed their length tends to increase, in order to defeat even greater line-of-sight armour depth. The concept of armour defeat using a long rod penetrator is a practical application of the phenomenon of hydro-dynamic penetration (see hydrodynamics).[3]

Fluid penetration

Despite practical penetrator and target materials not being fluids before impact, at sufficiently high impact velocity even crystalline materials begin to behave in a highly plastic fluid-like manner, so many aspects of hydro-dynamic penetration do apply.[4][5]

Long rod projectiles penetrate a fluid in the literal sense, based simply on the density of the target armour and the density and length of the penetrator. The penetrator will continue to displace the target to a depth of the penetrator length times the square root of the penetrator to target densities. One observes immediately that longer, denser penetrators will penetrate to deeper depths, and this forms the basis for the development of long-rod anti-armour projectiles.[4]

The important parameters for an effective long-rod penetrator, therefore, are very high density with respect to the target, high hardness to penetrate hard target surfaces, very high toughness (ductility) so the rod does not shatter on impact, and very high strength to survive gun launch accelerations, as well as the variabilities of target impact, such as hitting at an oblique angle and surviving counter-measures such as explosive-reactive armor.[4]

Tungsten and uranium

While penetrator geometry has adapted to reactive armour counter-measures, tungsten heavy alloy (WHA) and depleted uranium (DU) alloy continue to be preferred materials. Both are dense, hard, tough, ductile, and strong; all exceptional qualities suitable to deep armor penetration. Each material exhibits unique penetration qualities that may make it the best choice for a particular anti-armor application.

Depleted uranium alloy, for example, is pyrophoric; the heated fragments of the penetrator ignite after impact in contact with air, setting fire to fuel and / or ammunition in the target vehicle, contributing significantly to behind-armour lethality. Additionally, DU penetrators exhibit significant adiabatic shear band formation. A common misconception is that, during impact, fractures along these bands cause the tip of the penetrator to continuously shed material, maintaining the tip's conical shape, whereas other materials such as unjacketed tungsten tend to deform into a less effective rounded profile, an effect called "mushrooming". The formation of adiabatic shear bands actually means that the sides of the "mushroom" tend to break away earlier, leading to a smaller head on impact, though it will still be significantly "mushroomed".

Tests have shown that the hole bored by a DU projectile is of a narrower diameter than for a similar tungsten projectile. Although both materials have nearly the same density, hardness, toughness, and strength, due to these differences in their deformation, depleted uranium tends to out-penetrate an equivalent length of tungsten alloy against steel targets.[6] The use of depleted uranium, in spite of some superior performance characteristics, provokes political and humanitarian controversy, but remains the preferred material for some countries due to lower cost and greater availability than tungsten.

Sabot design

Typical velocities of APFSDS rounds vary between manufacturers and muzzle length/types. As a typical example, the American General Dynamics KEW-A1 has a muzzle velocity of 1,740 m/s (5,700 ft/s).[7] This compares to 914 m/s (3,000 ft/s) for a typical rifle (small arms) round. APFSDS rounds generally operate in the range of 1,400 to 1,800 m/s (4,593 to 5,906 ft/s). Above a certain minimum impact velocity necessary to overcome target material strength parameters significantly, penetrator length is more important than impact velocity; as exemplified by the fact that the base model M829 flies nearly 200 m/s (656 ft/s) faster than the newer model M829A3, but is only about one half the length, wholly inadequate for defeating state-of-the-art armor arrays.[citation needed]

Complicating matters, when foreign deployment of military forces or export sales markets are considered, a sabot designed specifically to launch a DU penetrator cannot simply be used to launch a substitute WHA penetrator, even of exactly the same manufactured geometry. The two materials behave differently under high pressure, high launch acceleration forces, such that entirely different sabot material geometries, (thicker or thinner in some places, if even possible), are required to maintain in-bore structural integrity.[citation needed]

Often the greater engineering challenge is designing an efficient sabot to successfully launch extremely long penetrators, now approaching 80 cm (31 in) in length. The sabot, necessary to fill the bore of the cannon when firing a long, slender flight projectile, is parasitic weight that subtracts from the potential muzzle velocity of the entire projectile. Maintaining the in-bore structural integrity of such a long flight projectile under accelerations of tens of thousands of g's is not a trivial undertaking, and has brought the design of sabots from employing in the early 1980s readily available low cost, high strength aerospace-grade aluminums, such as 6061 and 6066-T6, to high strength and more expensive 7075-T6 aluminum, maraging steel, and experimental ultra-high strength 7090-T6 aluminum, to the current state-of-the-art and incredibly expensive graphite fiber reinforced plastics, in order to further reduce the parasitic sabot mass, that could be nearly half the launch mass of the entire projectile.[7]

The discarding sabot petals travel at such a high muzzle velocity that, on separation, they may continue for many hundreds of feet at speeds that can be lethal to troops and damaging to light vehicles. For this reason, tank gunners have to be aware of danger to nearby troops.

The saboted flechette was the counterpart of APFSDS in rifle ammunition. A rifle for firing flechettes, the Special Purpose Individual Weapon, was under development for the US Army, but the project was abandoned.

See also

References

  1. ^ (PDF). Archived from the original (PDF) on 2017-02-24. Retrieved 2017-03-22.
  2. ^ "MIL-HDBK-762, Design of Aerodynamically Stabilized Free Rockets, 1990". from the original on 2017-03-23. Retrieved 2017-03-22.
  3. ^ Anderson, Orphal, Franzen, Walker (1998). On the Hydrodynamic Approximation for Long-Rod Penetration (Report). Southwest Research Institute. from the original on 2021-02-01. Retrieved 2017-03-23.{{cite report}}: CS1 maint: uses authors parameter (link)
  4. ^ a b c Anderson, Charles E. Jr. (2016). (PDF). Archived from the original (PDF) on March 23, 2017.
  5. ^ Winter, D. F. (1969). The Penetration of Targets by Long Rod Projectiles (PDF). AD0595793. Fort Halstead: Royal Armament Research and Development Establishment. p. 1.
  6. ^ J.B. Stevens and R.C. Batra. . Archived from the original on 7 October 2008.{{cite web}}: CS1 maint: uses authors parameter (link)
  7. ^ a b . Defense Update. 22 November 2006. Archived from the original on 5 August 2007. Retrieved 3 September 2007.

Further reading

  • Cai W. D.; Li Y.; Dowding R. J.; Mohamed F. A.; Lavernia E. J. (1995). "A review of tungsten-based alloys as kinetic energy penetrator materials". Reviews in Particulate Materials. 3: 71–131.

January 09, 2023
armour, piercing, stabilized, discarding, sabot, apfsds, long, dart, penetrator, simply, dart, ammunition, type, kinetic, energy, penetrator, ammunition, used, attack, modern, vehicle, armour, armament, main, battle, tanks, succeeds, armour, piercing, discardi. Armour piercing fin stabilized discarding sabot APFSDS long dart penetrator or simply dart ammunition is a type of kinetic energy penetrator ammunition used to attack modern vehicle armour As an armament for main battle tanks it succeeds Armour Piercing Discarding Sabot APDS ammunition which is still used in small or medium caliber weapon systems APFSDS at point of separation of sabot Improvements in powerful automotive propulsion and suspension systems following World War II allowed modern main battle tanks to incorporate progressively thicker and heavier armour while maintaining considerable maneuverability and speed on the battlefield As a result achieving deep armour penetration with gun fired ammunition required even longer anti armour projectiles fired at even higher muzzle velocity than could be achieved with stubbier APDS projectiles Contents 1 History 2 Design 2 1 Fluid penetration 2 2 Tungsten and uranium 2 3 Sabot design 3 See also 4 References 5 Further readingHistory EditArmour piercing discarding sabot APDS was initially the main design of the kinetic energy KE penetrator The logical progression was to make the shot longer and thinner to concentrate the kinetic energy in a smaller area However a long thin rod is aerodynamically unstable it tends to tumble in flight and is less accurate Traditionally rounds were given stability in flight from the rifling of the gun barrel which imparts a spin to the round Up to a certain limit this is effective but once the projectile s length is more than six or seven times its diameter rifling becomes less effective 1 Adding fins like the fletching of an arrow to the base gives the round stability 2 The spin from standard rifling decreases the performance of these rounds rifling diverts some of the linear kinetic energy to rotational kinetic energy thus decreasing the round s velocity and impact energy and very high rotation on a fin stabilized projectile can dramatically increase aerodynamic drag further reducing impact velocity For these reasons APFSDS projectiles are generally fired from smoothbore guns a practice that has been taken up for tank guns by China India Israel Italy Japan France Germany Pakistan Turkey Russia and the United States Nevertheless in the early development of APFSDS ammunition existing rifled barrel cannons were used and are still in use such as the 105 mm M68 M68E1 cannon mounted on the M60 A1 A3 main battle tank or the British 120 mm Royal Ordnance L30 of the Challenger 2 tank To reduce the spin rate when using a rifled barrel a slip obturator slip obturation ring is incorporated that allows the high pressure propellant gasses to seal yet not transfer the total spin rate of the rifling into the projectile The projectile still exits the barrel with some residual spinning but at an acceptably low rate In addition some spin rate is beneficial to a fin stabilized projectile averaging out aerodynamic imbalances and improving accuracy Even smooth bore fired APFSDS projectiles incorporate fins that are slightly canted to provide some spin rate during flight and very low twist rifled barrels have also been developed for the express purpose of firing APFSDS ammunition Design Edit Modern 120 mm tank gun shells KE penetrators for modern tanks are commonly 2 3 cm 0 787 1 18 in in diameter and can approach 80 cm 31 5 in long As more structurally efficient penetrator sabot designs are developed their length tends to increase in order to defeat even greater line of sight armour depth The concept of armour defeat using a long rod penetrator is a practical application of the phenomenon of hydro dynamic penetration see hydrodynamics 3 Fluid penetration Edit Despite practical penetrator and target materials not being fluids before impact at sufficiently high impact velocity even crystalline materials begin to behave in a highly plastic fluid like manner so many aspects of hydro dynamic penetration do apply 4 5 Long rod projectiles penetrate a fluid in the literal sense based simply on the density of the target armour and the density and length of the penetrator The penetrator will continue to displace the target to a depth of the penetrator length times the square root of the penetrator to target densities One observes immediately that longer denser penetrators will penetrate to deeper depths and this forms the basis for the development of long rod anti armour projectiles 4 The important parameters for an effective long rod penetrator therefore are very high density with respect to the target high hardness to penetrate hard target surfaces very high toughness ductility so the rod does not shatter on impact and very high strength to survive gun launch accelerations as well as the variabilities of target impact such as hitting at an oblique angle and surviving counter measures such as explosive reactive armor 4 Tungsten and uranium Edit While penetrator geometry has adapted to reactive armour counter measures tungsten heavy alloy WHA and depleted uranium DU alloy continue to be preferred materials Both are dense hard tough ductile and strong all exceptional qualities suitable to deep armor penetration Each material exhibits unique penetration qualities that may make it the best choice for a particular anti armor application Depleted uranium alloy for example is pyrophoric the heated fragments of the penetrator ignite after impact in contact with air setting fire to fuel and or ammunition in the target vehicle contributing significantly to behind armour lethality Additionally DU penetrators exhibit significant adiabatic shear band formation A common misconception is that during impact fractures along these bands cause the tip of the penetrator to continuously shed material maintaining the tip s conical shape whereas other materials such as unjacketed tungsten tend to deform into a less effective rounded profile an effect called mushrooming The formation of adiabatic shear bands actually means that the sides of the mushroom tend to break away earlier leading to a smaller head on impact though it will still be significantly mushroomed Tests have shown that the hole bored by a DU projectile is of a narrower diameter than for a similar tungsten projectile Although both materials have nearly the same density hardness toughness and strength due to these differences in their deformation depleted uranium tends to out penetrate an equivalent length of tungsten alloy against steel targets 6 The use of depleted uranium in spite of some superior performance characteristics provokes political and humanitarian controversy but remains the preferred material for some countries due to lower cost and greater availability than tungsten Sabot design Edit Typical velocities of APFSDS rounds vary between manufacturers and muzzle length types As a typical example the American General Dynamics KEW A1 has a muzzle velocity of 1 740 m s 5 700 ft s 7 This compares to 914 m s 3 000 ft s for a typical rifle small arms round APFSDS rounds generally operate in the range of 1 400 to 1 800 m s 4 593 to 5 906 ft s Above a certain minimum impact velocity necessary to overcome target material strength parameters significantly penetrator length is more important than impact velocity as exemplified by the fact that the base model M829 flies nearly 200 m s 656 ft s faster than the newer model M829A3 but is only about one half the length wholly inadequate for defeating state of the art armor arrays citation needed Complicating matters when foreign deployment of military forces or export sales markets are considered a sabot designed specifically to launch a DU penetrator cannot simply be used to launch a substitute WHA penetrator even of exactly the same manufactured geometry The two materials behave differently under high pressure high launch acceleration forces such that entirely different sabot material geometries thicker or thinner in some places if even possible are required to maintain in bore structural integrity citation needed Often the greater engineering challenge is designing an efficient sabot to successfully launch extremely long penetrators now approaching 80 cm 31 in in length The sabot necessary to fill the bore of the cannon when firing a long slender flight projectile is parasitic weight that subtracts from the potential muzzle velocity of the entire projectile Maintaining the in bore structural integrity of such a long flight projectile under accelerations of tens of thousands of g s is not a trivial undertaking and has brought the design of sabots from employing in the early 1980s readily available low cost high strength aerospace grade aluminums such as 6061 and 6066 T6 to high strength and more expensive 7075 T6 aluminum maraging steel and experimental ultra high strength 7090 T6 aluminum to the current state of the art and incredibly expensive graphite fiber reinforced plastics in order to further reduce the parasitic sabot mass that could be nearly half the launch mass of the entire projectile 7 The discarding sabot petals travel at such a high muzzle velocity that on separation they may continue for many hundreds of feet at speeds that can be lethal to troops and damaging to light vehicles For this reason tank gunners have to be aware of danger to nearby troops The saboted flechette was the counterpart of APFSDS in rifle ammunition A rifle for firing flechettes the Special Purpose Individual Weapon was under development for the US Army but the project was abandoned See also EditCompact Kinetic Energy Missile Impact depth Kinetic bombardment MGM 166 LOSATReferences Edit Design for Control of Projectile Flight Characteristics AMCP 706 242 US Army Materiel Command 1966 PDF Archived from the original PDF on 2017 02 24 Retrieved 2017 03 22 MIL HDBK 762 Design of Aerodynamically Stabilized Free Rockets 1990 Archived from the original on 2017 03 23 Retrieved 2017 03 22 Anderson Orphal Franzen Walker 1998 On the Hydrodynamic Approximation for Long Rod Penetration Report Southwest Research Institute Archived from the original on 2021 02 01 Retrieved 2017 03 23 a href Template Cite report html title Template Cite report cite report a CS1 maint uses authors parameter link a b c Anderson Charles E Jr 2016 Penetration Mechanics Analytical Modeling PDF Archived from the original PDF on March 23 2017 Winter D F 1969 The Penetration of Targets by Long Rod Projectiles PDF AD0595793 Fort Halstead Royal Armament Research and Development Establishment p 1 J B Stevens and R C Batra Adiabatic Shear Banding in Axisymmetric Impact and Penetration Problems Archived from the original on 7 October 2008 a href Template Cite web html title Template Cite web cite web a CS1 maint uses authors parameter link a b 120mm Tank Gun KE Ammunition Defense Update 22 November 2006 Archived from the original on 5 August 2007 Retrieved 3 September 2007 Further reading EditCai W D Li Y Dowding R J Mohamed F A Lavernia E J 1995 A review of tungsten based alloys as kinetic energy penetrator materials Reviews in Particulate Materials 3 71 131 Retrieved from https en wikipedia org w index php title Armour piercing fin stabilized discarding sabot amp oldid 1132062865, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.