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PRR Duplexes and Experimental Engines ( S1, S2, T1, Q1, V1 etc.)

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Posted by djlivus on Monday, August 2, 2021 9:20 AM

I just received the book on prr locomotives. I will scan it and send it to mail in one, two weeks. Using a lens to zoom in I have suceeded to see exactly the small numbers of D-C-C-D turbine. So: height is 16 feet, 0 inches (4,87 m), lenght between couplers is 112 feet (34,13 m), 105 feet wheelbase, 147 feet total wheelbase, 155 feet total lenght; weight without tender is 810.000 pounds (367,4 tonnes). Axle load is 45.000 pounds and 60.000 pounds (2X45.000 + 12X60.000). Tender axle load is 51.666 pounds

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Posted by djlivus on Monday, August 2, 2021 11:19 AM
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Posted by Overmod on Monday, August 2, 2021 1:26 PM

djlivus
At page 293 there are some interesting info about an 1982 steam turbine electric giant locomotive on 6 wheel trucks, 1,200,000 pounds weight

This is getting into nostalgia country.  That is Perry Shoemaker's turbine version; he also has one with a converted diesel engine block as a reciprocating prime mover, which has better performance at high turndown characteristic of non-continuous high-horsepower operation.

Note that some of the problems he encountered with the fluidized-bed combustion were and are addressable.

This was the era of 614T, when engineers had to 'rediscover' much of the art involved in practical locomotive boiler design.

Incidentally, note the bibliography a few pages earlier which contains an article by Steins in Railway Age on the proposed coal gas-turbine (Nov 27 1948, p.1029)

The history of coal turbines when I researched them in the '80s was fascinating.  Note the version in the hearings testimony, built inside an Alco DL600 with fluidized pulverized coal blown into a vibrating reservoir in the short hood.  With no sign of, say, cooled FGR passivating the pre-dried and pre-pulverized stuff, which was to be blown in from covered hoppers.  I suspect this would have rediscovered the joys of high-carbon critical-mixture facilitated rapid unanticipated disassembly.

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Posted by djlivus on Monday, August 2, 2021 5:27 PM

https://books.google.ro/books?id=qndCAQAAIAAJ&pg=RA2-PA129&dq=santa+fe+3750hp+turbine+locomotive&hl=ro&sa=X&ved=2ahUKEwiSjY7zrJPyAhXz_7sIHZvNCxEQ6AEwBXoECAYQAw#v=onepage&q=santa%20fe%203750hp%20turbine%20locomotive&f=false

http://cs.trains.com/mrr/f/13/t/40358.aspx

From these I understand that Santa Fe gas turbine was basically the same with J Yellot coal gas turbine intended to be built by Baldwin for PRR. But, the last was to be 3750 HP and have cabs at the both ends. Instead, Santa Fe,s would have been 3000 hp and would have used an oil gas turbine in a Centipede style body locomotive. There was also a project from Lima rejected.

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Posted by djlivus on Monday, August 2, 2021 5:30 PM
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Posted by Overmod on Monday, August 2, 2021 6:19 PM

http://cs.trains.com/mrr/f/13/t/40358.aspx

Note that they've got two turbine locomotives for ATSF mixed up.  The one you're discussing is the one on the Centipede frame, which I think has more affinity to the stillborn BLH free-piston locomotive than to anything out of BCR at that point (I think they were still testing the Hilsch tubes and final separation along with the turbine 'on the ground' in Dunkirk)

The missing B-B-B-B was the Allis-Chalmers turbine built for ATSF, which seems to have come and gone largely unremarked in railfan history, despite the fact that Allis-Chalmers had early competence in industrial gas turbines.

Much of the problem, including with the prospective 2-D-D-2 for ATSF, was the implicit concern that Really Cheap Garbage Fuel was the only thing making the gas turbine practical as a diesel competitor (read Charles Kerr, Jr's analysis for a better laying out of the real-eorkd economic argument).  As noted the 'big' ATSF tender was cheap for the adoption at that point, and had the ginormous oil capacity (whether #5 locomotive fuel, or 'Bunker B', or that awful cheap-as-possible dirty residual) as well as large nonstop water for the steam-ejector air on the Long Trains that big locomotive would be running.

How you get around the noise and crap in the exhaust when pulling the luxury postwar successor to the Super Chief is less certain.  I'd have liked to see at least one built... although by the time of actual construction it would have likely been span-bolstered trucks rather than colossal cast underframes...

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Posted by djlivus on Tuesday, August 3, 2021 7:24 AM

Overmod

http://cs.trains.com/mrr/f/13/t/40358.aspx

Note that they've got two turbine locomotives for ATSF mixed up.  The one you're discussing is the one on the Centipede frame, which I think has more affinity to the stillborn BLH free-piston locomotive than to anything out of BCR at that point (I think they were still testing the Hilsch tubes and final separation along with the turbine 'on the ground' in Dunkirk)

The missing B-B-B-B was the Allis-Chalmers turbine built for ATSF, which seems to have come and gone largely unremarked in railfan history, despite the fact that Allis-Chalmers had early competence in industrial gas turbines.

Much of the problem, including with the prospective 2-D-D-2 for ATSF, was the implicit concern that Really Cheap Garbage Fuel was the only thing making the gas turbine practical as a diesel competitor (read Charles Kerr, Jr's analysis for a better laying out of the real-eorkd economic argument).  As noted the 'big' ATSF tender was cheap for the adoption at that point, and had the ginormous oil capacity (whether #5 locomotive fuel, or 'Bunker B', or that awful cheap-as-possible dirty residual) as well as large nonstop water for the steam-ejector air on the Long Trains that big locomotive would be running.

How you get around the noise and crap in the exhaust when pulling the luxury postwar successor to the Super Chief is less certain.  I'd have liked to see at least one built... although by the time of actual construction it would have likely been span-bolstered trucks rather than colossal cast underframes...

 

Very interesting considerations!

Any info about wheels configurations of Lima proposal for gas turbine locomotive? Hirsimaki says it would have been single unit with 2 cabs. I think I have read somevhere it was a C-C locomotive, but  could that be large enough for a turbine locomotive? 

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Posted by Overmod on Tuesday, August 3, 2021 2:31 PM

Thank you for finding this!

As a bit of history: the first major use of this approach to free-piston power was as a 'diesel' air compressor for submarines, developed to some success in the 1930s.  I find it suggestive that Hamilton licensed the technology, was then acquired by Lima which staked its 'real locomotive' future on this idea while concentrating regular diesel development on glorified switchers, and then Lima-Hamilton was snapped up by Baldwin -- the official story being that 'parent' Westinghouse wanted the Lima heavy-construction business, but going to the free-piston construction for passenger engines may explain Baldwin's adherence to heavy slow-speed engines with little horsepower improvement upside during that era... only to embrace high-speed diesrls with Mekydro hydrokinetic transmission when it no longer mattered...

Note that the weight is still 30 tons per axle, only 'light' by comparison with relatively large steam locomotives.  That seems heavy for 'only' 3200hp, which translates in both powered axles and rough hp to one-and-a-half E units.

Think of this a bit like a FM OP cylinder turned on its side, with the rack arrangement replacing the crankshafts for timing, the bounce pistons replacing the crankshafts for piston return against compression, the large pistons providing the scavenge air compression, and the 'horsepower' taken out in the exhaust pressure.

This as previously noted greatly relieved the practical issue of TIT in a practical railroad gas turbine while offering a way to run the turbine reasonably close to its critical speed range over a range of loads by using or idling some of the independent gas generator sections -- compare this to the Essl locomotive, which proposed similar savings by a very different method.

We now know well (from subsequent GM experience with free-piston engines in ships and cars, and the stillborn FG-9) what the Achilles heel of Pescara-style free-piston turbine power is -- and to me this came as something of a surprise, similar to the reason full-active suspensions were not more popular for automobiles or trucks.  You will note the absence of a synchronizing method for the gas generators, and the need for a smoothing receiver in the drawing.  Oddly enough the practical difficulty was not exhaust impulse noise (which to me would be like the grandmother of all unsynchronized multi-engine aircraft propeller noise!) but the inlet tract noise from relatively light wall construction for the prodigious amount of air required.  (I am told that the technical results of the 'big' SNCF test of this approach exist, but I have not found them yet; that the idea was so well promoted, and disappeared so without a trace, indicates similar 'drawbacks' were encountered...

Technically the free-piston engine suffered somewhat from the use of a 'variable-speed transmission' involving a turbogenerator and traction motors (and remember that Westinghouse just at this time patented a drive with three-phase alternator and compatible motors, which could as easily be used with a gas turbine as a steam turbine).  To me this would have been a good 'fit' for a couple of Bowes drives as in the stillborn Ingalls 2000hp lightweight passenger locomotive... although coordinating three axles per truck might have been costlier and not as effective as separate hexapole motors.

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Posted by Overmod on Friday, August 6, 2021 3:01 PM

djlivus
https://pbs.twimg.com/media/Ee6XD0eXoAI1uJV?format=jpg&name=4096x4096

I'm real sure that I can run 15,200hp through four axles.  On the other hand it will pull any train it can start up to 200km/h...

Someone with the Complete Collection needs to provide the link to 'The Case for the Double-Track Train', an American answer to the Breitspurbahn with a few additional possibilities.

We have an expert on the RRollway, in its 19' wide splendor... that's now within the year range for Classic Trains...

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Posted by djlivus on Friday, August 6, 2021 6:18 PM

 

 
djlivus
https://pbs.twimg.com/media/Ee6XD0eXoAI1uJV?format=jpg&name=4096x4096

 

I'm real sure that I can run 15,200hp through four axles.  On the other hand it will pull any train it can start up to 200km/h...

 

Someone with the Complete Collection needs to provide the link to 'The Case for the Double-Track Train', an American answer to the Breitspurbahn with a few additional possibilities.

We have an expert on the RRollway, in its 19' wide splendor... that's now within the year range for Classic Trains...

 

[/quote] 

 I understand that in Classic Trains magazine is an article about american version of this rail system? If so I have acces to Classic Trains archive, so I can check.

There were any projects for american locomotives with 19' gauge or it was only an ideea?

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Posted by Overmod on Friday, August 6, 2021 8:32 PM

djlivus
I understand that in Classic Trains magazine is an article about American version of this rail system? If so I have acces to Classic Trains archive, so I can check.

The article was in Trains Magazine, during the happy period in the early Seventies when so many interesting articles were published.  The editors came in for considerable flak for publishing it at the time, as it was illustrated with HO gauge sectional track and there were many technical details that were, so to speak, handwaved in the discussion.  

The basic idea, though, was to treat a double-track mainline as if it were a 'Breitspurbahn' with four separate running rails and cross-span-bolstered bogies each at standard gauge if desired.  This would be fleeted to get directionality, and a four-track main of interesting characteristics would be needed even for the analogue of CTC, but the possibilities were interesting... and a given line still perfectly capable of being operated as two standard-gauge tracks for standard-gauge interchange traffic.

As I recall, Professor Milenkovic has considerable knowledge of RRollway in its various developments, and retains interest in the idea.  My exposure to this was as a kind of transverse high-density rapid-throughput Iron Highway for automobiles: these would be staged in rows facing the track, driven on the platform transversely, then simply driven off the other side easily or en masse at any stop -- no circus loading, no skilled backing over ramps and between cars.

The version I remember had 19' gauge over the outside rails but one rail in the middle for support.  We have had previous threads, I think findable across the Kalmbach forums with the 'community search' term, that had quite a bit of interesting information I hadn't known.

 

The thing about 'broad gauge' is that scaling laws apply to engineering just as they do to, say, entomology.  You can't just scale proportions up, like in modeling -- some parts have to be reproportioned, and there may be size limits that make further increase pointless, much as with multistage rockets.  Necessary axle strength and contact-patch size are two such for Bribdingnagian gauge inflation.

I have not read the book, but I understand that 3m was chosen as about the largest gauge that would make a cost-effective system -- some of the passenger interiors were designed around the width possible with overhang relative to the 'quarter points' over the wheels or the effective lateral points of suspension bearing.

Incidentally it turns out that for coned-tread wheelsets, it is NOT beneficial to run the wheels separately on stub axles a la Talgo. That imposes a limit on axle deflection and bending strength.

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Posted by djlivus on Monday, August 9, 2021 11:00 AM

https://i.redd.it/rxaib6wqao361.jpg

One  rendering of 5000 tons soviet atomic locomotive. Maybe just a kind of soviet propaganda.  

I just have aquired a digital edition of Robin Barnes Broader than broad (I ve sent it via dropbox on mails ) Here says it could attain a speed of 300 km hour

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Posted by djlivus on Monday, August 9, 2021 11:22 AM

https://pbs.twimg.com/media/D8oDSKgUYAA_tJz?format=jpg&name=large

 

Another soviet proposal  rendering  here

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Posted by Overmod on Monday, August 9, 2021 8:28 PM

There was no insurmountable issue with the 'double-track train' going around curves or cross-equalizing... and the test was done with HO snap track...  Note that the 'four rails in 18' gauge -- I'd suspect 5m -- would give an interesting centerline distance if considered as double track, say of 5' gauge.

Did the Russian system note that the two 'subsidiary tracks' were each lined and surfaced separately for use?  Or that the spacing of the four rails was not 'equal' spanwise?

An issue that came up with the 'double-track train' was the way superelevation and crossovers were to be handled.  Note that the Breitspurbahn freight and these Russian systems do not emphasize high speeds (and presumably would be built with limited superelevation as with contemporary "PSR" optimization (?) to 40-45mph with minimized wear and deflection to the rails.  That would simplify how crossovers,  etc. are provided for the individual tracks.

I continue to presume that carbody-mounted motors remain a good solution for these enormous things, although I see very little mention of the idea explicitly either in the German planning or these Russian versions.  You could easily have whatever final drive you wanted with transverse balance on either the upper or lower 'deck', with final drive to the individual span-bolstered 'bogies' running on their pairs of gauged rails.

I have learned more about this stuff in three months than in a whole lifetime of pottering research on some of this stuff.

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Posted by djlivus on Tuesday, August 10, 2021 6:07 AM

Very interesting considerations!

 

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Posted by Overmod on Tuesday, August 10, 2021 6:56 AM

The Lyle Borst tale is amusing.  He assigned the design problem as a hypothetical exercise.  Afterwards there was enough interest that he patented some of the design features... the AEC apparently being willing at the time to find alternative markets for uranium enrichment other than as constituents of explosives.  It does not appear that security of what is basically weapons-grade U235 for use on the general system of railroad transportation was a cost concern.

There was a brief frenzy of transportation applications when submarine reactors became known. If FM engines worked in subs and were more or less successfully ported to locomotives... why not PWRs?

The Alco A-100, which I only know from a single drawing, may use a comparable cycle, although it is tough to dispense with ocean cooling (as some Erie-Built customers reputedly recognized!).  While some improvements over the PRR S2 were needed, they were not critically incapable of solution.  And there was the promised long running time between (subsidized) reprocessings...

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Posted by djlivus on Tuesday, August 10, 2021 11:25 AM

German breitspurbahn project considered more than 40 locomotives - some designed for high speed passenger trains,some for freight. My question would be if a freight locomotive can be regeared for passenger trafic or, conversely a passenger one for freight use. If so, what such an operation would imply? I ask that questioon having in mind some examples like New Heaven Ef3 (adapted for pasenger use) or Baldwin Centipedes "rebuilt" for freight

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Posted by Overmod on Tuesday, August 10, 2021 1:58 PM

djlivus
My question would be if a freight locomotive can be regeared for passenger traffic or, conversely a passenger one for freight use. If so, what such an operation would imply? I ask that questioon having in mind some examples like New Haven EF3(adapted for pasenger use) or Baldwin Centipedes "rebuilt" for freight

The answer for diesel-electrics is simplified because some of the most ubiquitous types were inherently designed suitable for dual service, with relatively small changes.  Up to the inherent limits of nose-suspended motors the 'change' is one of gearing, with the numerical ratios chosen for an integer number of teeth on pinion and bull gears that fit into the gearcase.  (PRR typically lists this the other way round from most everybody else; EMD liked expressing it in mph (presumably representing the highest safe speed to spin the motors).

As you might suspect, suspension and guiding are key characteristics of true dual-service locomotives.  The Centipede chassis was good for over 120mph by Baldwin's perhaps over enthusiastic figuring (they had touted the ATSF 3460 class as "120 mph locomotives" and Seaboard happily bought them for 85mph freight service (replacing rather good 2-6-6-4s).  Most of the 1930s articulated-underframe high speed design -- originally serving a somewhat different purpose on the maid-of-all-work Essl locomotive) was not "as good" as evolved truck designs, like those attributed to Blomberg at EMD.  Indeed, Westinghouse seemed to be proposing nothing but AAR type B trucks on all their locomotives -- advantages as you'd expect for B instead of C trucks in high-speed work, and plenty of easily-cooled span-bolstered motor power if you want to pull freight...

The poster child for dual-service electrics is the GG1, which evolved from the New Haven design.  This was easily changed from high-speed passenger engine to capable freight locomotive with little more than a simple gearing change, as all the rest of the suspension and underframe remained substantially 100mph capable.

The Rc-4, on which the AEM-7 'toasters' were patterned, is a successful freight locomotive in Europe, albeit one that may require additional time in starting heavy trains.  If I'm not mistaken, many features of the ACS-64 'Sprinters' are shared with Vectron electrics, although I do not know how detail-design differences for high-speed service might impair its suitability.

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Posted by daveklepper on Tuesday, August 10, 2021 8:55 PM

Informative and accurate reply/

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Posted by djlivus on Wednesday, August 11, 2021 6:28 AM

Thank you for this very comprehensive answer!

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Posted by djlivus on Wednesday, August 11, 2021 11:16 AM

https://mi3ch.livejournal.com/2637409.html?page=2 :

"After the materials on the Hitler super train were declassified, similar projects appeared in the USSR.

Deputy Director of the Institute of Complex Transport Problems of the Academy of Sciences of the USSR, Soviet scientist Vasily Zvonkov, in particular, wrote: “The existing generally accepted railroad gauge in our country - 1524 millimeters - was proposed by one of the builders of the St. Petersburg-Moscow road, engineer Melnikov. Already today it cannot satisfy us. A track gauge of 3 - 5 meters will allow us to build significantly more lifting wagons and use locomotives with a capacity of 40 - 50 thousand horsepower to ensure a speed of 250 - 350 kilometers per hour. The question of using nuclear reactors on such locomotives will be greatly facilitated. After all, as you know, only a significant weight of biological protection prevents nuclear locomotives from entering our roads today,

The throughput capacity of BAM has been exhausted for today. The main problem of the inhabitants of the Far East is isolation from the center of Russia.

Nuclear reactors on trains are too dangerous. Today the train from Moscow to Vladivostok takes 7 days. At a speed of 250 km / h, this time will be reduced to one and a half days"

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Posted by djlivus on Wednesday, August 11, 2021 12:39 PM

https://e-news.su/history/256660-zheleznodorozhnyy-futurizm-sverhshirokaya-koleya-i-bezumnye-proekty-voennyh.html

"At the same time, there was an active discussion of the construction of the Pan American Intercontinental Highway to connect the Americas, and with it the idea of ​​an intercontinental broad-gauge railway was considered. It was supposed to go from Alaska to Argentina and turn both continents into a single economic zone. Nuclear locomotives were the best fit for this project. Soon, negotiations began with the creators of the X-12 on the development of a similar locomotive for an ultra-wide gauge."

 

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Posted by Overmod on Wednesday, August 11, 2021 6:16 PM

djlivus
Soon, negotiations began with the creators of the X-12 on the development of a similar locomotive for an ultra-wide gauge."

Not content with deploying liquidized weapons-grade uranium across the general system of transportation, they want to send it through a variety of Central and South American nation-states, including one then largely influenced by Juan and Evita...Surprise

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Posted by djlivus on Thursday, August 12, 2021 10:11 AM
"Will it be so far in a few decades that railway giants, super trains of dimensions still unimaginable today, 'ships on rails', pulled by nuclear locomotives, speed through the Russian steppes? Many technicians in the Soviet Union think it is possible, yes they have already worked out the plans for it. Because the solution of the traffic problem, especially the transport of huge amounts of goods through the endless expanse of the Russian, but above all the Siberian area, has become one of the most urgent tasks in the Soviet Union. The railway network of the Soviet Union currently has a route length of about 160,000 kilometers (USA 380480). Since the railroad is still the most important means of transport in the Soviet Union, work is ongoing to expand it. However, while in most other countries in the world one only deals with increasing the speed of travel (by strengthening the substructure and using stronger locomotives), increasing the comfort of passengers and improving the loading and unloading systems, new types are to be found in the Soviet Union Railways are built that would be able to cope with all traffic requirements in the foreseeable future. These plans - as fantastic as they may sound to traffic experts - undoubtedly have a real basis in the Soviet Union, in fact they are becoming a necessity there, considering that this country has only a relatively weak network of well-developed roads and motorization despite all efforts, will not have reached the level of the western world by a long way.
The planned super railway - it definitely deserves this name - should have a track width of 4500 mm. That is about three times the width of today's standard gauge, which is 1435 mm and is used on 74 percent of all railway lines in the world. (This dimension can probably only be traced back to the fact that at the time of the first railways the axis length of the stagecoach was precisely that dimension (see also 'From readers to readers', p. 9). All other important railways use a larger track width. In in the Soviet Union, Finland, Turkey and Panama it is 1524 mm each. In Ireland, Brazil and parts of Australia the 1,600 mm gauge is found, while the largest to date of 1,676 mm is found in Spain, Portugal, India, Ceylon, Argentina and Chile is in use. Narrow-gauge railways are available down to a track width of 600 mm. The oversized gauge of the Russian project would of course require the construction of wagons with a capacity that is still unimaginable today. Large goods wagons - apart from individual special wagons - nowadays have an average load weight of 50 to 60 tons on standard-gauge railways. Freight wagons with a loading capacity of 100 tons were used on the long, flat stretches of the USA and the Soviet Union. But this in turn comes at the expense of the train length, since a freight locomotive is only able to move a certain weight. A wagon for the planned Russian super broad-gauge railway would hold around 27 times as much as a conventional freight wagon, i.e. around 1,600 tonnes of payload instead of 60 tonnes.
The Soviet Union seems to be well aware of the difficulties that stand in the way of creating such a super-railroad. Today there is no railway line that has the width required for this gauge. When they were built, completely new dams would have to be built and bridges with a corresponding load-bearing capacity would have to be built. The stability of the substructure and the rails would have to be considerably greater than with today's routes. But none of this should present any insurmountable difficulties when building this super-railway through the endless expanses of the Russian area, through the plains of the Ukraine and the steppes. According to the plans, unevenness in the terrain should be compensated for by extensive excavations or embankments. Incidentally, the costs of building the route are hardly likely to be higher than the cost of a motorway that can cope with all weather conditions. As far as has been reported, the first sections of this super-railway are to connect the cities of Moscow-Leningrad-Kiev with each other, while the further expansion would primarily extend to a ring connection between the new industrial centers in Siberia.
Nuclear power is supposed to solve the fuel problem of these giant trains. Nuclear locomotives, the construction of which is being considered in all technically advanced countries, could not be realized to this day because the dimensions and weight of the nuclear reactor, but especially the inevitable radiation protection, take up too much space and make the machines too heavy for the substructure of current railways would. The nuclear locomotive the size of the Russian super broad-gauge railroad certainly does not have these space concerns. These giants of the rail line are supposed to be three times the width of a standard-gauge locomotive and at least as great a height and, since the routes are to be kept extremely curvy, also have an almost arbitrary length dictated only by the weight.
The achievable speed at which there is no longer any 'fluttering' or swinging of the trains is assumed to be 200 km / h. A higher speed would lead to excessive wear on the rails. The trains should consist of around ten cars. The amount of payload carried by a single train would correspond to that of ten normal current freight trains. Since the block spacing of the trains running one after the other did not need to be greater than today, but the speed is considerably higher, a fifteen to twenty-fold increase in performance in transport was calculated.
The super railways, which are primarily intended for freight transport, are also intended to be used for passenger transport. Given the spaciousness of the wagons, it would be possible to completely deviate from the type of railway wagon with its narrow seats, which was customary up to now, and to give the wagons an arrangement that is only possible on ships today: that is, numerous individual compartments, spacious, housed in a multi-storey structure Lounges, cinemas, baths, etc. Fresh air should only be supplied through an air conditioning system in order to keep dust levels to a minimum and to always create a pleasant temperature - in summer and winter.
Apart from the Soviet Union with its endless plains, there is hardly a country - the routes in the USA and Canada are too short and lead through frequently changing terrain - that has the conditions that make the construction and operation of such a super-railway appear profitable to let."
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Posted by djlivus on Thursday, August 12, 2021 10:14 AM
https://www.mosafilm.de/CF/heftbesprechung/hobby/5706/superzug.html
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Posted by djlivus on Thursday, August 12, 2021 10:14 AM

https://www.mosafilm.de/CF/heftbesprechung/hobby/5706/superzug.html

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Posted by Overmod on Thursday, August 12, 2021 2:43 PM

See if this makes the link clickable:

https://www.mosafilm.de/CF/heftbesprechung/hobby/5706/superzug.html

Note the reference to 200km/h stability here, too.

 

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Posted by M636C on Friday, August 13, 2021 9:08 AM

Overmod

See if this makes the link clickable:

https://www.mosafilm.de/CF/heftbesprechung/hobby/5706/superzug.html

Note the reference to 200km/h stability here, too.

Is it just me or does that Russian nuclear locomotive have styling cues based on the PRR T1? Quite apart from the "duplex" arrangement of driving wheels, look at the front casing and the shape of the casing over the wheels...

Peter

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