C&O M1 info?

Check C&O Power by Philip Shuster, Eugene L. Huddleston and Alvin Staufer, Published by Alvin Staufer, copyright 1965, Lobrary of Congress No. 65-26713, pp. 298-305. Also, do a Google search. You'll find lots of info. I did. The book is out of print, but copies can be found. I just bought a used one at my favorite hobby shop. Amazon might be able to find it for you, too.

cool, thanks.

But at http://www.skyrocket.de/locomotive/turbines.htm

What is the UP turbine featured there?

Looks mighty different from any GE made UP turbines I've ever seen

One of a pair of failures built by GE. To wit:
Discussions between General Electric and the Union Pacific in 1936, due in no small part to the UP’s insatiable desire to increase horsepower and fuel efficiency, while using fewer locomotives to do the job, resulted in the start of a project to design and build a 5,000 hp, two-unit steam-turbine-electric locomotive. It should also be noted that this pair of locomotives was another of General Electric’s attempt to compete with General Motors’ (EMD’s) passenger diesels.
On August 25, 1936, the UP Executive Committee formally approved a order for GE to build two units at $96 per horsepower, a total of $480,000 for the pair.
The initial plan was for the new locomotive to run at speeds up to 110 mph while having a range of 700 miles without refueling. (The range was later downgraded to 500 miles.)
The design that resulted more than doubled the thermal efficiency of a more-traditional, piston-powered steam locomotive. Each unit would be 87 ft. 10 in. long with a 2-C-C-2 wheel arrangement and 44-in. drivers. It had a 65/31 gear ratio and an 81,000 lb starting T.E.
Additional specifications included a total loaded weight of 506,000 lb. with 318,000 lb. on the drivers. The boiler generated 1,500 psi steam at 920 °F.
The steam was directed at a two-stage cross-compound turbine geared to two DC generators. These provided the needed electrical current to the six traction motors.
Delivery was set for April 12, 1937—just a tad optimistic it would seem.
• The boiler of unit no. 1 had to be rebuilt;
• A generator had to be remodeled;
• The traction motors had to be rebuilt;
• The main turbine didn’t meet steam consumption requirements;
• Excessive oxygen was found in the condensate, which could lead to unreasonable corrosion;
• The superheater failed;
• The high-pressure steam-reducing valve failed;
• The capacity of the evaporator was inadequate; and,
• The feedwater supply malfunctioned.
Yet, hopes remained high. GE’s/UP’s personnel were optimistic that these and other problems could be overcome.
At 1:20 P.M. on Saturday, April 1, 1939, the two-unit team-turbine-electric locomotive Union Pacific Road Numbers 1 and 2 (builders numbers 12136 and 12137) and nicknamed the “streamlined camels,” was considered finally ready for service and left Erie for delivery to UP. They were the only condensing steam locomotives built and operated in the U.S.
Behind the two units were UP baggage car No. 4450 and ten NYC coaches. The crew stopped in Toledo, Ohio for the night. Sunday morning, the locomotive and ten cars left behind a section of the 20th Century Limited, arriving at Porter, Indiana, two hours and forty minutes later at 9:00 A.M. The ten coaches were left behind on a siding while the twin locomotives and the UP baggage car transferred to the EJ&E for the run to Chicago.
Progress halted in South Bend, Ind. when a coupler’s knuckle broke on the rear of unit 2 releasing the baggage car. They didn’t arrive at West Chicago until 1:20 P.M.
The Union Pacific finally took delivery of the two General Electric-built units in Omaha at 4:40 P.M. on Monday, April 3.
A cryptic note, cited by Thomas Lee , purportedly from GE to UP stated “…the railroad understands that while locomotive units may be coupled and operated in multiple in forward position, and forward end to forward end, as may be necessary, units cannot be operated back end to back end.” This meant the locomotive units had to be turned at the end of every run, just like a traditional, piston-powered steam locomotive!
What ensued was a frenetic two-month frenzy of testing.
In late April, a special train made up of 4-4-0 (nee Virginia & Truckee No. 18 ) repainted as UP No. 58 in the lead, with turbines Nos. 1 and 2 following, and baggage car 4450, tourist car 4202 from The Challenger, six conventional heavyweight passenger cars and five old wooden cars. Known as The Paramount Special, the effort was a combined PR promotion of UP and Paramount to publicize Cecil B. DeMille’s film, “Union Pacific,” which was scheduled for its world premier in Omaha on Friday, April 28, 1939 [three years, to the day before I was born—HM].
The following two weeks saw The Paramount Special traveling the eastern half of the country, promoting the film. After a run from Omaha to Chicago, No. 2 was cut out and returned to Erie for repairs, rejoining No. 1 when its journey finally reached Erie. They continued on to Buffalo, Rochester, Albany, and finally Boston. In Boston, it was No. 1’s turn to fail. After No. 2 took over and wyed the consist oil was found flowing down from its roof. No. 2 had to be left in Boston for replacement of the heat exchanger. It was cannibalized to repair No. 1’s feed water heater. No. 1 then took the train to New York City.
Failures and repairs continued throughout May. By early June, the units were dead at the East Los Angeles Shops and the head of UP’s motive power office, Otto Jabelmann’s, patience had run out. From Chicago, he wired GE, “…We will not operate locomotive until we are definitely assured of reliable and trouble-free operation..”
On June 8, the locomotive left East LA Shops for Omaha with only 4450, the baggage/maintenance car, a coach, and a UP business car at 7:42 P.M. Problems with No. 2 while coming up Cajon Pass delayed their arrival at Salt Lake City until 5:15 P.M. on June 9.
The unsatisfactory locomotives were returned to General Electric on June 17, 1939 , following only two months of use. When returned, the No. 1 unit had operated 720 hours while No. 2 had only 573 hours. No.1 had run 17,780 miles while, due to repairs, No. 2 logged an estimated 3,000 miles less.
Renumbered GE-1 and GE-2 and repainted a dull gray-black, In contrast to their performance for the UP, after GE had accumulated another 40,000 miles of operation on its test track, (with the resulting modifications) they saw extensive, virtually trouble-free service on the Great Northern Railway during a motive power shortage.
GN was able to run the enhanced units back-to-back, rather than front-to-back as the UP was forced to do. By late 1943, after almost a year’s service, the wheel treads were quite worn and in need of replacement. And after one of the units’ boilers became defective, GE-1 and GE-2 were returned by GN to General Electric and retired.

In 1942, Robert R. Young was chairman of the board of directors for the C&O. This was the same fellow who wondered why a freight car of pigs could ride from coast to coast in the same car on the railroad, but human passengers had to change trains at Chicago on the same route. He wanted to modernize the C&O after World War II with a luxury passenger train running between Washington and Cincinnati in the daytime.
In keeping with this idea, in 1944, a group of engineers designed a steam locomotive with a steam powered turbine connected to electric generators to power electric motors connected to the driving wheel axles. This locomotive was pretty radical, all right, but not original.
Baldwin Locomotive Works and Westinghouse Electric produced three steam turbine-electric engines for the C&O in 1947-1948 . They were coal fired and less complicated than the GE/UP locomotives. These locomotives were numbered 500-502, and were the world’s largest passenger locomotives, 154 ft. long (106 ft. locomotive and 48 ft. tender). These behemoths stood 16 ft. 4 in. high, and from front coupler to rear coupler, they measured almost 30 ft. longer than C&O’s massive H-8 Alleghenies and 23 ft. longer than Union Pacific’s Big Boy. The engine weighed 428 tons exceeding that of an H-8 by 43 tons (loco and tender weighed a whopping 594 tons) . Another notable feature was the only 4-8-0+4-8-4 (2-C1+2-C1-B ) wheel arrangement in the world. Only the first three axles on the eight wheel trucks were powered. The trailing truck was powered, but the leading truck and the one in between the big powered trucks were not powered. That four wheel truck supported the firebox.
Each locomotive was powered by a 6,000 hp impulse type steam turbine with a 6:1 ratio gear reduction at 6,000 rpm. This was connected to two 2,000 KW electric generators to power eight axle-hung traction motors. The exhaust from the turbine was the boiler’s source of draft. The engines were nicknamed the Sacred Cows.
These monsters were impressively painted in brilliant red-orange, aluminum, light gray and blue. They were classed as M-1. The first, No. 500, went on an extensive publicity tour in 1947, and the next year, it went to the Chicago Railroad Fair.
In 1945, plans for the new streamlined train were progressing. It would complement the radically new locomotive. Forty-six stainless steel cars were ordered from the Budd Company. This train would be loaded with special features, such as a lounge in every car, a playroom for children, lockers for luggage, glass domes for better viewing, and movies for entertainment. The train would honor the trademark of the C&O—the Cheshire Cat. It was named the Chessie , of course. The whole train was far too opulent both inside and out to be called simply a streamliner, and hence, was dubbed a dreamliner.
There were strikes at Baldwin, Pullman and Budd in 1947 that delayed the equipment, and testing the 500 was not going well. In February 1948 the B&O launched their own streamliner between Cinncinatti and Washington DC. That train stole the Chessie’s thunder, and also showed the C&O how miniscule the daytime Cinncinatti Washington passenger train market really was.
In 1947, during test runs, the 500 had many service failures. Yet the main problem was the 500. With the streamlining removed. It looked like a pipefitters nightmare. There were many bugs in this long and complicated machine.
The situation changed suddenly. Economic problems beset Robert Young and the C&O, the train was terminated and never turned a wheel in revenue service. About half of the Chessie cars were purchased by Amtrak, and the diners went to Auto-Train Corporation for its runs to Florida.
The three Sacred Cows were used intermittently in mainline service, but the drive wheels under the tender had a tendency to slip as the coal was used and the weight decreased. They also were troubled by a poor draft, requiring excessive firing. No. 500 spent as much time in the shop as on the road. The engines could not meet the economy of the diesels. The patrons of coal had to surrender to fuel oil.
According to C&O Power , by Alvin Staufer, all three C&O M-1s were sold for scrap in 1950. However, to put a rumor to rest, according to Mr. Jeff Trueman, director of marketing & public relations at the B&O Museum in Baltimore, No. 500 is NOT stored at the B&O Museum in Baltimore, Md. Some people have mistakenly thought the preserved C&O No. 490 is the M-1 Turbine. In fact, No. 490 is a 4-6-4 Hudson that was streamlined and painted in the same colors as the Sacred Cows. The 490 was used to pull the Newport News section of the Chessie. Like sister ships Nos. 501 and 502, No. 500’s long gone, but not forgotten.

So then, I guess that the underlying message to are intending to convey is that while all manufacturers of post piston drive steam locomotives ended up finding that "competing with GM" was not going to be an option that they had any choice in determining,...that it was just a hard fact of life?

And that of all who attempted to beat them by strength, every single one failed, of their own inability to deliver on the assumption?

And only GE, managed to out fox them all, by choosing NOT to play to their strong suit, but instead matching GM's product quality, almost in a mirror image?

That's fascinating!, And a clever ploy, I must say. Even Rockefeller, and now Bill Gates were of the same philosophy, success results from making the customer think THERE is no competition from which to shop....


Crafty the way the house that built jack even devised a means of stealth in the execution of the struggle to survive in the face of impossible odds, I tip my hat!


(OF course I'm teasing!! Infact, I'm a big GM fan, considering theirs is the only auto I'd ever buy for myself.

But even my GMsnobbery stands in pale comparison to what I've seen this bunch to do....

Ya'll are HARD SEEDED!, ya know? =)

Now *THAT* was a good reply!! TONS of factual insight,...thanks!

(Makes you wonder if "fuel cell" technology in long haul freight service could be THAT far off?

Interesting thought,..but with the typical Fuel Cell
"standard operation" your power output is like 35% electric, and the remainder is heat, that can be designed to be just about any temperature you choose, in the range 200-1800 degrees Farenheit.

You could produce A LOT of steam that way, and do a "combo" power transfer that was both electric motor, and mechanical Steam...drive.

perhaps using the electric to "lug" around yards, aND TO break momentum from standing starts, up to a speed where steam driven vanes could take over.....driving similar to those hydraulic transmissions in the German Loco's Southern Pacific once had?



Fire the boiler on day one, and NOT need to add more fuel for 8-10 years? Needs only water... And the only combustion byproducts are Water and Oxygen? A truly GREEN train, that produces valued natural resources as it's exhaust waste?

Dream come true, it would seem,

Not to mention very few moving parts,...and clean enough to run in NYC, while permittng the costly to maintain caternary to simply be scrapped as "un needed"?

Course, those "core" rejuevinations after 8-10 years of service, would be costly, but the savings in not buying petro fuel diring that time, would be enormous as well...

H'mmm?

FUEL-CELL LOCOMOTIVES
Although electric-based power transmission (catenary and/or third rail) is a well proven technology going back decades, it’s not viable for application to all railroads. Catenary and/or third rail systems incur very-high installation costs as well as accompanying infrastructure maintenance requirements and the associated costs. Electricity can be used along high-density traffic lines and would be cost-effective in such applications.
As oil prices surge, as a result of oil supply reductions, electric prices could also spiral as more transportation technologies adopt electricity as their primary source of energy. In municipal transportation, the trolleybus and the streetcar are well proven. Yet these technologies would have to compete for electric power with a host of battery and flywheel-based vehicles requiring a recharge, within the next decade or two.
The energy cost of electric railroads could be expected to increase within the next decade and beyond, as the number of electric vehicles entering the market begins to increase. This possibility requires that viable alternatives to electric railway using catenary or third rail, be explored. Fuel cell locomotives may be an option. Fuels such as hydrogen and natural gas may be used as fuels.
The fuel cell is a way of taking hydrogen and oxygen and getting electricity. The hydrogen can be stored in a tank and the fuel cell will keep producing electricity as long as the fuel is supplied. The emissions from a hydrogen fuel cell running on pure hydrogen is zero. Actually, they emit water vapor but that’s all. So, not only is a fuel cell a viable option for keeping an electric vehicle going, it is quiet and as clean as you can get.

The leading research reports on fuel cell locomotives clearly identifies the fact that fuel cell technology will only be applied to the locomotive marketplace when the fuel cost and operating efficiency of fuel cell locomotives meets or exceeds the existing diesel-electric technology. Railways in North America, are bottom line driven and will not invest in technology that increases operating costs. Fuel cell locomotives are several decades away from matching the efficiencies of the diesel-electric locomotive.
Nonetheless, a fuel-cell locomotive prototype was developed by the Fuelcell Propulsion Institute (FPI) of Denver, Colorado, in a joint venture with Vehicle Projects LLC. FPI is the overall project leader, while Vehicle Projects LLC is prime contractor for the fuel-cell locomotive project, responsible for fundraising, recruiting of project partners and overall project management.
The result of this joint venture of the Fuelcell Propulsion Institute and Vehicle Projects was the development of the world’s first fuel cell-powered locomotive, an underground mining locomotive.
Natural Resources Canada (NRCan) is a partner in FPI, and contributed C$300,000 to the project over two years. NRCan, through its experimental mine in Val-d’Or, Quebec, also contributed technical and scientific expertise by integrating the fuel-cell power plant with the locomotive, which is an off-the-shelf Canadian product manufactured by R.A. Warren Equipment Ltd. of North Bay, Ontario. NRCan followed up with surface testing of the unit, which was then sent to a mine in Red Lake, Ontario, for underground testing and evaluation. The fuel-cell locomotive prototype is the only one of its kind and was developed at a total cost of C$2.1 million.
Fuel cells are like batteries in that they produce electricity that can be used to power electric motors, among other things. They work by combining hydrogen gas with oxygen, causing an electrochemical reaction that produces the electricity. The hydrogen comes from a supply carried on board a vehicle or extracted from a fuel such as propane or methanol, while oxygen is taken from the atmosphere. The only emissions and byproducts from the process are water and heat.
The power plant used in the project was constructed by Sandia National Laboratories of Livermore, Calfifornia. Sandia is an agency owned by the United States government that engages primarily in defense-related research and development, along with energy and environmental projects in conjunction with industry, academia and other government agencies. It is managed by Lockheed Martin Corp., an aeronautics and technology systems company based in Bethesda, Maryland, for the U.S. Department of Energy’s National Nuclear Security Administration.
The final test took place at the Val-d'Or mine from September 9 to 13, 2002, where the locomotive continued to meet expectations and pulled five loaded cars without any difficulties (20 tons) .
Powered by proton exchange membrane fuel cells (PEMFC), coupled with reversible metal-hydride storage, the four-ton vehicle is now working on a regular basis at the Placer Dome’s Campbell mine in Red Lake Ontario, Canada since 6 October 2002. The total project development costs of the locomotive were approximately US$1.2 million.
Underground mining is probably the most promising application in which fuel cell vehicles can compete strictly on economic merit. This is partly due to the high purchasing price of the locomotive itself, the additional costs of putting a fuel cell in are less important.
Currently (2002), two other locomotive projects are under construction. The joint venture wants to develop a larger underground mine locomotive of about 10-25 ton size for haulage in metal mining or moving roof support shield and a full size surface engine for military applications.

Thanks!!

We were looking at Installing a fuel cell "farm" in california during the height of the electricity "crunch", to provide power to our shopping mall, in lieu of blackouts.

Which was where I first became aquainted with the reality that the fuel cell is a high power, rather than a low power, generating means. And is extremely efficient in operation

The "key" is in being able to utilize All of the energy produced, and reviewing the info, the entire "cycle" is 89% efficient for Proton Exchange type, of which roughly half the power output is electric, the other half heat.

As it turned out, we had no conveiniant use for the heat, which soured the overall economics, beyond reason.

But, it got me to thinking...."which industry makes great use of heat"? h'mmmm "steam"?

It would certainly be interesting

Why not use the excess steam to drive a turbine connected to another generator? More "bang for the buck" I would think.

Why not? I have no problem with the idea either way. I'm not an engineer (either a horn tootin' nor a slide rule).

My only thought was that since both N&W's Jawn Henry and C&O's M1 that did do the steam-electric conversion are listed as collosal failures, so I was just speculating that piston driven drivers combined with electric might offer some unique "power curve" possibilities.

In our Application, during the california elect crises, The State of California was offering big incentives to large users who would "get offline" and make their own power.

My boss came in one day and said "Go findout something about fuel cells, we might wanna do this"

So I did.

And there is a lot of heat there my friend, a whole lot.

So I concluded that unless we could use the heat efficiently, on top of the electricity, we were sunk. And said so in my report, making special referance to the possibility of steam generated electricity.

My boss took that perspective to the meeting he had with engineers, and came back and gave me a pat on the back, for knowing about as much as the engineers seemed to, we were all in agreement.

Except, Since we have a sprawling campus, with 18 distinct points of entry for power from the utility, there was going to have to be 18 separate
"Fuel cell farms" on the property, OR we would have to install our own grid to a local central farm, big $$$.

And it seems, the economy of scale of 18 individual small steam-electric generators falls off pretty quickly.

I officially got credit for a "dumb idea" on that one...=)

Excess heat could be used to drive heat pumps for air conditioning.

It's a thought...