Landships II

philthydirtyanimal wrote:

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And they test some armour plate of the same thickness that a Mark IV would have had ... reversing an ordinary rifle bullet in its casing would give it the capability to penetrate a tank's armour.

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You mean 'blunt' end first? What sort of range would that have? I'd have thought that the drag would make that a pretty close-range option, and also that it would be quite unstable (rifling notwithstanding). Intuitively, it would be no more than a 'barn door at ten paces' option...

The adopted solution of the trusty fifty-cal has proven more enduring - the 'original' M2 and later M3 (higher cyclic rate aviation variant; now used on trucks in Afghanistan etc. - only problem is it shakes apart every couple of thousand rounds and has to be rebuilt).

 

I didn't get to see the documentary. How were they able to identify it as F6 Feu d'Artifice? They just seem from the clip to be picking tiny bits of metal up. Even if they had the location right, wasn't F6 the Mark IV Male destroyed with Grasshopper II? How could they tell one bit of metal from another?

Gwyn

Hi James Ive have also read numerous times of such bullets being used, as I recall though it was not specifically for armour piercing but to inflict maximum damage on the enemy by digruntled soldiers and was a widespread practice by all nationalitys...... 

What interested me most though was the mention of "Case Hardened Mild Steel Armour" I would think that this would hardly be effective against a normal bullet, battled damage to tanks suggests to me that something rather harder and more brittle was used, if any one can enlighten me it would be most appreciated


Cheers

I was most interested in the reversed projectile demonstration of the Codename Tank episode. Some thoughts and observations, for what they're worth, from someone who has actually perforated steel plate with rifle fire (but not with reversed projectiles, I hasten to add).

It is part of Australian shooting lore that one can penetrate the quarter inch side armour of a Ferret scout car all day long with a .243 Winchester at 50 yards (whereas a 7.62 NATO or .308 Winchester, having essentially the same powder capacity - and considerably greater kinetic energy - will merely 'dent' it). One of the shooting magazines published photos, many years ago. In a word, the answer seems to be velocity, the projectile is conjectured to 'melt' its way through steel and it probably doesn't much matter whether it is armour plate or mild steel, the result will be much the same.

Having neither a .243 nor a handy Ferret to deface I cannot absolutely vouch for that but I have punched holes with the greatest of ease through the discarded steel 'tyre' of an ancient Minneapolis-Moline tractor using a .22-250 (even higher velocity), firing standard lead cored hollow-point projectiles. The thickness of steel was at least 6 mm (I had in mind the assertions about the Ferret).

The entrance and exit sides of the penetrating holes both showed a raised crater rim - in the case of the entrance site that would seem to be a 'splash' effect, attesting to the fluid state of the steel on impact. If I recall correctly, the demonstration at the British army establishment in Codename Tank showed exactly the same sort of penetrating hole. Perhaps a contrary indication of the 'burn through' theory is that the holes are of more or less constant diameter all the way through (with burn-through one would intuitively expect some 'coning' of the hole). Consistent diameter seems more in keeping with the 'wad punch' model of penetration - but my .22-250 projectiles were the right way around, pointy end first. I just don't have an explanation for that.

How can reversing the projectile increase velocity? The powder/propellant charge was unaltered in the army demonstration if I recall correctly. To my mind, the main suspect would be the forcing of the blunt end of the projectile into the rifling on loading the round. This will increase chamber pressure significantly. Usually there will be a short 'lead' in front of the projectile (the throat of the chamber) before it contacts the lands of the rifling on firing and that reduces the pressure pulse from standard propellants, as is well known to ammunition 'handloaders'. The American experiments (referenced by another poster) avoided that (seating the reversed projectile well down in the case, knowing full well the effect on chamber pressure otherwise) but they seemed to be more concerned with accuracy and deformation questions, not with steel plate penetration.

The lack of 'streamlining' of the reversed projectile will have little measurable effect in the first 50 metres or so of a high velocity small arms projectile's travel in my estimation. If I recall correctly, Colonel Mayevski showed well over a hundred years ago that drag is non-linear and it is 'critical' at around the speed of sound - it is always going to be a huge factor and it is always going to increase as velocity increases - but the 'shape' of a projectile with a muzzle velocity of two to three times the speed of sound is not going to increase drag sufficiently for relative retardation to be easily measurable in the first 50 milliseconds or so of flight. If it starts out faster it is still going to be faster for some appreciable distance.

Much of the conjecture could have been set aside if only the army had used a basic (and cheap) chronograph in their demonstration. I am (reasonably) sure it would show a substantially increased muzzle velocity with the reversed round - though examination of the primer would be another indication (of increased pressure, implying increased velocity), not to mention noticeably stiffer extraction of the spent cartridge.

{sigh} there was a time when I had all the materials necessary to resolve all of this, including a 7.92x57JS ex-military rifle (the chamber tolerances are significant, I think, sporting rifles may be different) and a case of ex-Israeli 'pointed spitzer' ball ammunition. Well, I didn't have the chronograph - they used to be expensive back then. But, for what it's worth, my conjecture is all I can now offer.