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 to defeat greater line-of-sight armour depth.
Fluid penetration The concept of armour defeat using a long rod penetrator is a practical application of the phenomenon of
hydro-dynamic penetration. Practical penetrator and target materials are not fluids before impact, but at sufficiently high impact velocity even crystalline materials begin to behave in a highly plastic fluid-like manner. 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. 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. 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. Tungsten itself has been found to be
biologically hazardous and creates exposure hazards only somewhat milder than depleted uranium.
Microparticle tungsten In some countries, such as
South Korea, specific
heat treatment processes such as multi-stage cyclic heat treatment and
microstructure control are applied to tungsten penetrators to finely separate metallic grain structures, significantly improving the mushrooming deformation, which was a chronic problem for conventional tungsten alloys, increasing penetration by 8–16% and
impact toughness by 300%. This results in the
microparticle tungsten penetrator causing self-sharpening behavior equivalent to that of the DU penetrator.
Sabot design Typical
velocities of the 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). This compares to ~914 m/s (3,000 ft/s) for a 5.56mm round fired from an M16 rifle. APFSDS rounds generally operate in the range of 1,400 to 1,800 m/s (4,593 to 5,906 ft/s). Above a 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. 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. Often the greater engineering challenge is designing an efficient sabot to successfully launch extremely long penetrators, now approaching 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 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. 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 ==