The Dutch Government has a Walrus Replacement Program
calling for at least 4 medium-large conventional diesel-electric submarines for
launch in the mid-late 2020s.
On October 9, 2018 Anonymous examined
technical issues for a Saab A26 concept meeting the Walrus Replacement requirement.
Now Anonymous, in comments
from October 21-23 2018, is looking at technical details involved with Germany’s
TKMS meeting the Walrus Replacement requirement.
Drawing from those comments Walrus replacement concept could
be a very large version of the TKMS 212A/CD, 214 or non-AIP 209. Assuming the South
Korean 3,000 ton KSS3 is based on a TKMS design (lets call it a TKMS Type 3000). A 2,900 ton (submerged) Walrus replacement could also be a Type 3000.
Within the 2,650 ton (submerged)
current Walrus class’s double hull
structure (light & pressure hulls) there are 3 x MAN Diesel & Turbo
owned SEMT Pielstick 12 PA4 V 200 SM [1]
diesels (width ca.1470mm, not 12 PA4 200 SMDS) could be installed in parallel.
Distances (ca.400mm) between diesel-diesel and diesel-pressure hull are small
(ca.400mm).
In the Walrus replacement concept, 3 x 12 PA4 V 200 SMSD diesels
could be installed in parallel, but the separation distances could be somewhat greater
(ca.600mm). These latter diesels could be more powerful to propel a larger 2,900
tons submerged Walrus replacement [and/or charge Lithium-ion Batteries (LIBs) more quickly]. As result of these exchange of diesels,
Walrus-concept becomes more powerful. See Appendices [1],
[2], [3] and [4] below.
MAN Diesel & Turbo or SEMT Pielstick (now operate as a
brand by MAN Diesel & Turbo) has the following three generators which are
sometimes confused. Correct data are as follows:
- 8 PA4 V 200 SM, cylinder bore 200mm, V8, single
supercharger (mechanical output 700kW). A26; (2 starboard + 1 port) x 8 PA4 V
200 SM (2,100kW)
- 12 PA4 V 200 SM, cylinder bore 200mm, V12, single
supercharger (1,060kW). Walrus-class; 3
parallel x 12 PA V 200 SM (3,180kW)
- 12 PA4 V 200 SMDS, cylinder bore 200mm, V12, single
supercharger + single turbocharger (1330kW), Walrus -concept; 3 parallel x 12
PA V200 SMDS (3,990kW)
The next Dutch submarine will need much space to accommodate
some female crew, for additional quieting measures and additional weapons
spaces (possibly for anti-ship missiles, land attack missiles and UUVs, etc).
A double hull structure may be required for the stern drive sections (see red/blue in the 212A diagram above). This is if the Walrus replacement is an enlarged Type 212A/CD, 214 or 3000 equipped with LOx cylinders (diameter ca.1.7m) outside the pressure hull. To fit these cylinders the outer diameter of pressure hull in the drive sections would be considerably smaller (diameter ca.5.6m) than the 212s beam (of 6.8m) and would be an inefficient use of space. Also, the strength of pressure hull material for the 212A/CD is not high.
A double hull structure may be required for the stern drive sections (see red/blue in the 212A diagram above). This is if the Walrus replacement is an enlarged Type 212A/CD, 214 or 3000 equipped with LOx cylinders (diameter ca.1.7m) outside the pressure hull. To fit these cylinders the outer diameter of pressure hull in the drive sections would be considerably smaller (diameter ca.5.6m) than the 212s beam (of 6.8m) and would be an inefficient use of space. Also, the strength of pressure hull material for the 212A/CD is not high.
The Walrus replacement would need floating decks to insulate/isolate
vibrations thereby reducing noise effectively, but, are not in 212A/CD or 214s.
Floating decks also mitigate shock from outside thereby protecting equipment
and crew. Floating deck are used in US nuclear submarines and already in
the Stirling generator section of (LABs + AIP) Soryus. Floating decks will also feature in the future
Japanese Soryu with LIBs 29SS (to be launched in 2 to 4 years).
TKMS fuel cell AIP is more efficient than combustion type
Stirling AIP. But fuel cell AIP, owing to its use of hydrogen is less safe than
Stirling. For fuel cell hydrogen containers are placed out side the pressure
hull (see red O2 Tanks and H2 Storage in diagram above). Meanwhile the Kawasaki Stirling AIP, licensed by Kockum’s Stirling, for use in LABs + AIP Stirlings, are very expensive.
3 diesels, diesel-electric, 5,430 shp (4 MW): They confuse
12 PA4 V 200 SM (right) with 12 PA4 V 200 SMDS (wrong)
[2] Electrical output = 0.8 x mechanical output
[4] Some discussion of a TKMS option
Pete Comment
The Netherlands may not use any AIP (fuel cell or Stirling)
due to the Walrus' replacement need to travel long distance missions (maybe 8,000nm) from the
Netherlands to the Dutch
Caribbean and back. This is similar to Australia’s and Japan’s long transit missions making AIP inefficient (especially with high weight and imbalances of LOX
tanks). Thus Australia in the 1970s and Japan now have decided against future
placing of AIP in their submarines.
But Japan is obviously attracted to the submerged range and
speed advantages of LIBs. TKMS and Naval Group are also
marketing the advantages of their LIB solutions. See discussion of this tomorrow.
TKMS corporate ownership changes/problems may be of concern to the Dutch government. Hence this
may favour the A26 solution raised by a SAAB-Damen consortium or Naval Group.
Anonymous and Pete
3 comments:
HI Pete,
What about SMX Ocean. It could be one option for them as well. https://www.youtube.com/watch?v=ug6RakSBuzQ
Hi Pete
Considering deep dive under ice at the Arctic Ocean, HY-100 as pressure hull material was used for Warlus at 1979. Then, pressure hull material equal to or stronger than HY-100 is implicit precondition of post-Warlus, steels used for A26(Strenx700E [1]), TKMS214 (HY-100) and scorpene (80HLES [2]) satisfy this precondition, but, steel used for 212CD does not.
[1] Strenx900E is stronger than Strenx700E, but its welding is difficult.
[2] https://image02.seesaawiki.jp/d/e/doramarine/bb9306865d3af821.pdf
80HLES is equivalent to HY-100, and its yield strength is 770MPa. Its proof strength (strength at 0.02% strain) is lower than yield strength (presumably 690MPa).
TKMS finished basic study on methanol reforming fuel cell for submarine years ago, is developing its prototype in collaboration with SENER and had developed key techonogy (dissolver of carbon dioxide) nearly three years ago [3,4]. TKMS very recently developed lithium ion battery for submarine [5] and R&D of new 212CD by collaboration with Norway works seems to be going well [6].
In contract to successful R&D of TKMS, its production division is in a terrible situation such as delivery delay caused by lack of investment [7]. The poor performance of production division and unstability of TKMS obviously become a matter of high concern for Dutch and Polsih governments.
[3] https://www.maritime-executive.com/article/new-system-means-methanol-suitable-for-submarines
(New System Means Methanol Suitable for Submarines)
[4] http://www.revistanoticias.sener/en/news/aip-system-for-submarines/50/
(AIP system for submarines)
[5] https://www.aogdigital.com/component/k2/item/7668-thyssenkrupp-develops-new-lithiumion-batteries-for-submarines
(ThyssenKrupp Develops New Lithium-Ion Batteries for Submarines)
[6] https://www.nyteknik.se/fordon/nya-ubaten-kan-bli-forst-med-litiumbatterier-6898850
(The new submarine can be the first with lithium batteries 14/02/2018)
[7] https://global.handelsblatt.com/companies/thyssenkrupp-shipbuilding-rapidly-sinking-856111
(German shipbuilder rapidly sinking) “No submarine is delivered on time,” said one source at the company.
Regards
Hi Nicky K.D Chaleunphone
The SMX Ocean was a paper DCNS concept that DCNS, in 2014, saw as a conventional version of the nuclear Barracuda SSN.
see http://gentleseas.blogspot.com/2014/10/revised-frances-dcns-announces-smx.html
For Australia's SEA 1000 competition SMX Ocean morphed into the winning Shortfin sales pitch.
In terms of technical and financial risk for Australia and engineering completeness the Shortfin still remains behind Japan's Soryu offering.
Regards
Pete
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