I used the internal arrangement from the West Virginia to help me determine the proportions of the machinery spaces, giving preference for available length in sketching out the bulkheads. The WV was 600 feet at the waterline, just 35 feet longer and 27 feet wider with greater distance between the outer skin and the machinery spaces than this ship.
OK, now we're getting somewhere. You did the right thing, using a TE powerplant as a guide, but it also caused a big problem. The WV's powerplant is designed to provide 28,900-shp (it actually provided something over 30,000-shp on trials). This is only one-third to one-quarter the amount of power a cruiser will, unless you're designing a
very slow cruiser.
According to Springsharp, the powerplant is rated for almost 68,000hp with a machinery weight of almost 4300 tons, so yes it's heavy. The plant may or may not fit, as you state. But Springsharp only tells you what's in the realm of the possible. The program says machinery, storage, and compartmentation space is excellent consuming only 66.7% of the underwater volume
Springsharp only gives data for turbine plants in general. Neither Rick (writer of the original program) nor Ian (who writes the current versions) have programmed weight or volume data for turbo-electric plants. That's why I put up the US CV preliminary designs - you have to figure the volume, and possibly the weight, yourself.
Take the preliminary designs that I posted earlier (I think that designs #1 or #2 will work best), reduce it to SB scale - waterline length and beam are given. Then remove boilers until you have a plant that generates the amount of power you require (approximately 10k shp per boiler). Rearrange boilers as necessary and determine powerplant length. My gut tells me that this ship will have to be the length of a Japanese CA (about 650 ft or more) in order to fit a turbo-electric plant of 80,000 to 120,000-shp.
I don't have the armor belt depicted yet, but it is 10 feet high and runs the entire vital length of 367 feet. And I don't have all the bulkheads laid out yet since I'm depicting the process I use step by step. She's just not finished yet.
Actually, you've already done that, you just haven't realized it yet
. Friedman noted in British Cruisers that all cruiser machinery spaces are 3 decks in height - approximately 24 feet - The overhead for the machinery spaces is the armor deck. The double bottom is generally 3 feet in depth. This 27 foot depth from the armor deck to the keel is a feature of both USN and RN cruiser designs. That's not in his exact words, but that's the gist of it.
All post-WW I armored ship designs placed the top of the armor belt at the armor deck. In your design, the deck illustrated by the yellow line will be the armor deck - it is approximately 27 feet above the keel. What you need to do is get that deck several feet above the waterline (and by extension get the top of the armor belt several feet above the waterline) so that you have some armored freeboard that is vital to a ship's survival. Note: you will need at least 5 feet of the belt below the normal waterline to protect the hull against shells that fall just short of the ship and to protect areas of the ship that are exposed by wave formation (more accurately, wave troughs) at high speed.
Normally, you would get the increased armored freeboard through one of three ways: increased hull depth, decreased draft or reduction in the heights of the two upper decks. However, you can't increase hull depth in this design, it's already spot on if I estimate it correctly - I'm guessing about 42 to 43 feet. All USN flush-deck cruiser designs from the
Brooklyn to the
Des Moines classes had hull depths from 41 to 43 feet - raised forecastle types have hull depths between 34 and 36.5 feet. Reducing upper deck heights (and thereby reducing the sheer of the AD) will only raise the armor deck a small amount, perhaps a foot or so. That leaves reduced draft - I'd recommend 20 to 21 feet - with increases in length, beam and block coefficient to keep your desired displacment.
In case you haven't noticed, once you decided on a cruiser, the depth from armor deck to keel is largely fixed. The decision of hull type, flush-deck or raised forecastle, then determines hull depth amidships. Hull sheer then determines freeboard fore and aft. It all falls into place relatively easily - and I didn't even have to draw it. Then its just a matter of finding ideal length, beam and BC.
The reason that I've taken this time to point out what I consider to be errors in this design (and the earlier CL by extension) is because I've enjoyed following your AU. One of the things that you've done better than many others is to keep things real. That said, a TE powered cruiser doesn't seem particularly realistic. The USN never consider one, and I think that this is because they knew that a cruiser, with less reserve bouyancy than a battleship or carrier, would never survive the flooding of a generator room. But cruisers, with their narrow beam, could never be fitted with a torpedo defense system to prevent that from happening. Hence my attempt to keep your AU from jumping the shark, as it were.
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I have to ask this - have you tested this using actual turbo-electric plants? I've attached several US CV preliminary designs that used TE drive so that you can reduce them to SB scale and determine the length and beam requirements for the plant.
