n7axw wrote:This whole subject is one I wish RFC would weigh in on. As has been pointed out Dilandu's argument doesn't come from textev, but by extrapolating from experience in our own time line, which, although useful, isn't decisive for Safehold.
Without calling Dilandu's research into question, I have difficulty imagining cannon shot fired at forty yards simply boucing off its target without penetrating. That is pistol range, suicide range.
i did read that section in AMF referred to up thread, but there was no textev about how thick a Safehold galleon'S hull is.
So, unless we are talking about handwavium which is an author's privelige, I don't see a way of answering the question posed in the heading of this thread.
don
I don't have time, for a lot of reasons, to engage in another epic debate with Dilandu on this topic, so after this post you will not draw me back out of hiding to argue the case with him. I composed this off-line because my intranet connection is really bad just now, and I haven't gone back and re-validated everything in the post after reading back over the entire thread. Nonetheless, I think the following should explain the situation on Charis.
I will note that there is a great deal of confusion about the difference between black powder and high explosives. The truth is that black powder's natural burning rate is actually
lower than that of nitrocellulose. Because of the difference in the two propellants' characteristics, however, black powder does produce a bigger pressure spike than nitrocellulose. The advantage of granular black powder over meal powder is less that the powder burns faster (in fact, the individual grains burn
slower) but that it burns
more completely because the air spaces between the individual grains are larger. Note that what we are talking about here happens so quickly that terms like "slower" don't really have much meaning as far as human senses' ability to detect the difference. That is, the entire combustion process is completed so rapidly and the propulsive/energy liberation effect is so enhanced by the greater efficiency of the granular powder's combustion that granular powder produces a bigger spike — for all intents and purposes, an
apparently "faster" explosion — than meal powder does.
The primary difference between black powder and nitrocellulose is that nitrocellulose
contains no noncombustible components. That means that nitrocellulose burns much more completely, producing about three times the gas volume (energy) of an equal weight of black powder because of how much of the black powder is wasted in smoke and powder residue — the "ash" left behind by those noncombustible elements, if you will. In addition, it's much more difficult to regulate the combustion rate of black powder. It burns at the speed at which it burns, although you can slow it down somewhat by using slower burning charcoal. This is what the Charisians have done in formulating "brown powder," similar to our own late nineteenth century "cocoa powder." There are distinct limits, however, and it is actually easier to introduce moderators into nitrocellulose to slow down the gas velocity produced.
Among other things, this is the reason you can use a longer barrel with nitrocellulose. Gunpowder – whether black or brown — can't be adjusted or "tuned" the way nitrocellulose can. In theory, a longer barrel means that the projectile will spend more time with the expanding volume of gas behind it accelerating it down the bore. In fact, because gunpowder "spikes" and is so much less inherently efficient than nitrocellulose, after a certain point, friction offsets the advantage. Since nitrocellulose produces three times the volume of gas and since its burn rate can be adjusted to generate that volume more gradually (note that "more gradually" in this case is a purely relative term; that gas is being generated
damned quickly whether it comes from black powder or cordite
) the longer barrel does equate to a longer — and greater — acceleration.
And now to the discussion of 30-pounder shells.
With all due respect, Dilandu has this one wrong.
It’s been stated a time or two in the books that the Charisian 30-pounder is actually much closer to a
32-pounder. The solid shot for the gun actually weighs 31.81 pounds, if you’re interested, and the explosive shell weighs 17.9 pounds with explosive charge. In other words, it’s an 18-pounder for all intents and purposes. Now, it is true that an approximately 6-inch diameter round shot which weighs 18 pounds will lose velocity faster than a shot of the same diameter which weighs 32 pounds, but at the ranges at which naval engagements are fought on Safehold (or, at least, the ranges at which they have been fought so far), the differential in velocity-bleed is not going to have a significant impact on the ability to penetrate the sides of what are essentially big frigates, not true ships-of-the-line.
An explosive shell from a 30-pounder will not have the same penetration as a solid shot from the same weapon. Dilandu is perfectly correct about that. And the lack of penetration of a 30-pounder shell when bombarding targets ashore has been commented upon in the books many times. They are, however, fully capable of penetrating the 12-18”-thick sides of a typical Safeholdian galleon from ranges of several hundred yards, and that’s the range at which naval actions are fought using sail-powered vessels and muzzle-loading smoothbores. In theory, battles could be fought at significantly longer ranges, and that may well happen in the case of maneuvering duels between single ships on each side, but it is
not the range at which any of the major engagements so far described in the books have occurred.
I can’t really speak to French practice, because I’m not as familiar with the original sources as I am where American and British practice is concerned. I’m most familiar of all with the development of big-bore, black powder shell guns during the Dahlgren-Rodman period here in the US. Dahlgren favored 9” and larger shell guns in no small part because he was also looking at the smashing effect they would have firing
solid shot against targets for which shells were not the preferred ammunition. He also determined, on the basis of extensive testing, that the ideal muzzle velocity was one which permitted the shell to penetrate the target’s side but not to pass clear through it, and he achieved that by reducing the powder charge when firing shells. With solid shot he wanted to pack in the most kinetic energy he could get; with shells he wanted to slow the projectile down — the “big and slow” Dilandu mentioned in an earlier post.
Now, there are other reasons besides the smashing effect of a bigger solid shot to prefer a 9” shell to a 6” shell. A 9” shell will sustain its velocity longer, all other factors being equal, and carries a larger bursting charge, which makes it more destructive. Unfortunately, the Charisians had a whole bunch of existing 30-pounders and no 9” long guns available, so they had to design shells they could fire out of their existing weapons. They never thought (and I never said they did) that this was the ideal weapon; it was the one they had available in quantity and it was enormously superior to anyone else’s weapons capability even with the smaller than ideal shell. If you will recall, there have been multiple references to the fact that the 57-pounder (the Charisian navy’s standard heavy carronade) is considerably more destructive over its shorter range than the 30-pounder is, and the disparity increases when both weapons are firing explosive shell. The 57-pounder has a 7.3” bore, fires a 57.35-pound solid shot, and a 31.55-pound explosive shell. This means the shell from a 30-pounder weighs only about 56% as much as one from a 57-pounder, although the longer 30-pounder can deliver its round to a greater range.
If Charis were not converting to rifled guns, then Howsmyn would probably develop something closer to the 9” (and bigger) Dahlgrens and Rodmans developed in the U S during the nineteenth century. Charis
is going to rifled artillery, however, and even the broadside 30-pounders have been fitted with rifled liners. Using the studded rifling system which was adopted several books ago, a “30-pounder” fires a 100.6-pound cylindrical solid shot and a 67.19-pound explosive shell. There is also a 90.79-pound “armor piercing” or “battering” shell which has better penetration than the standard explosive shell but a considerably smaller bursting charge which, coupled with the thicker shell walls greatly reduces the explosive effect of a hit.
As for premature detonations in the barrel, which I believe Dilandu also predicted (I’m working off-line right now and can’t really consult his earlier posts), that’s also a non-factor. Black powder-filled shells have an unpleasant tendency to explode almost instantly on impact and — on occasion — to explode prematurely inside the gun barrel. There are several reasons for this, but the primary one is the friction between the grains of powder when the shell is suddenly accelerated or decelerated. The US Army’s Parrot Rifles had a particularly bad record for bursting barrels and shells that prematured on their way down the bore, although the Army’s ordnance manuals indicate that when the gun was properly maintained and the shells were lubricated such problems were enormously reduced.
In the case of the shells manufactured for the Imperial Charisian Navy (and Army), the shells are filled before they are shipped to the units which are going to actually use. Note that this is contrary to the practice of most navies in our own history at least until into the last half of the nineteenth century. One of the reasons they are shipped already filled is that after they are filled, the powder charge is stabilized by a pour of liquid sulfur. This doesn’t close up the gaps between the individual grains of powder, so friction-induced premature explosions are still possible, but it binds the entire mass of the powder charge sufficiently to hugely reduce that possibility.
Again, don’t think that I am saying — or that I’ve ever said — that a 6-inch smoothbore firing an 18-pound explosive shell is as effective as a 12-inch smoothbore firing an explosive shell that weighs
140-pounds. All I’ve said is that it can be done, that the explosive shell is a great deal more destructive to a wooden-hulled ship than a solid shot of the same size, and that Charis had several thousand thirty-pounders capable of firing the lighter shell and
didn’t have the time to design and field and entirely new broadside weapon when the ICN needed an explosive equalizer for the numbers of ships about to be thrown at the Empire.
For
field gun employment, a 30-pounder is about the biggest muzzle-loading smoothbore anyone wants to drag around a battlefield. In fact, it’s really too big to be as mobile as the field artillerists would prefer, which is why the 12-pounder is the standard field gun size. Nonetheless, a 30-pounder shrapnel shell speaks with a great deal of authority, and the straight HE bombardment round from a 30-pounder is far more destructive than one from a 12-pounder. Again, this should not be taken to suggest that I am equating the effectiveness of a 6” smoothbore’s spherical shell with the effectiveness of the cylindrical (and much heavier) shell fired by a rifled angle-gun.
