U.P.'s Blows had an ancillary diesel engine for yard moves, enabling it to move under its own power with the turbine shut down. When I worked for the U.P. at Cheyenne 40 years ago, I was told of how a daydreaming hostler and inattentive ground man took a Blow into the roundhouse once under full power. It was "like World War III," with broken glass and dead pigeons everyplace.
blue streak 1 Sawtooth500: that I read somewhere that diesels were used to shunt the UP turbines around the yard. Also, it was the rising cost of bunker C that made the turbines retire. If bunker C costs as much as regular diesel, well it's just cheaper to operate the diesels rather than the turbines. What I'm wondering is how those turbines fared in tunnels... turbines suck an incredible amount of air. A GE-90 turbine, the kind on a B777, could suck all the air out of Madison Square Garden in 2 minutes, if you want to make a comparison. I had thought about the GE-90 also. I do not believe a turbo-shaft version (for RRs) would fit in the present Class Is plate H clearances?. I know the fan version does not fit!
Sawtooth500: that I read somewhere that diesels were used to shunt the UP turbines around the yard. Also, it was the rising cost of bunker C that made the turbines retire. If bunker C costs as much as regular diesel, well it's just cheaper to operate the diesels rather than the turbines. What I'm wondering is how those turbines fared in tunnels... turbines suck an incredible amount of air. A GE-90 turbine, the kind on a B777, could suck all the air out of Madison Square Garden in 2 minutes, if you want to make a comparison.
that I read somewhere that diesels were used to shunt the UP turbines around the yard. Also, it was the rising cost of bunker C that made the turbines retire. If bunker C costs as much as regular diesel, well it's just cheaper to operate the diesels rather than the turbines.
What I'm wondering is how those turbines fared in tunnels... turbines suck an incredible amount of air. A GE-90 turbine, the kind on a B777, could suck all the air out of Madison Square Garden in 2 minutes, if you want to make a comparison.
I had thought about the GE-90 also. I do not believe a turbo-shaft version (for RRs) would fit in the present Class Is plate H clearances?. I know the fan version does not fit!
The GE-90 fan certainly wouldn't fit (about an 11 ft diameter), but I think the core just may - not sure. You may have to get rid of the catwalks though and where would be no way to make your way through the engine. But in any case, I can pretty much guarantee you if you put a GE-90 core in a RR locomotive you would be sending so much power to the wheels that all you'd do is spin them - you'd need the locomotive plus probably 3-4 slugs to actually bring all that power to the wheels. But hey, the slugs could be fuel tenders because that GE-90 would go through so much gas you'd need tenders for it.
Another interesting note on turbines is that turbines actually produces tens of thousands of HP, and in the case of exceptionally large ones like the GE-90 they actually produce a couple hundred thousand HP - however 80-90% of that HP is actually required to spin the compressor, and only 10-20% of it is available as power output. One thing that you would be able to get rid of is the dynamic breaking system (in its current iteration). If you hook up a turboshaft engine to an electrical tranny, and reverse the generator so that it spins based on recovered electricity from train momentum, the generator can spin as hard as it wants trying to turn that compressor and won't even come anywhere close to straining it. And you could even throw in power coming from slugs for dynamic braking and still come nowhere close to the limits of the compressor.
Sawtooth500 that I read somewhere that diesels were used to shunt the UP turbines around the yard. Also, it was the rising cost of bunker C that made the turbines retire. If bunker C costs as much as regular diesel, well it's just cheaper to operate the diesels rather than the turbines. What I'm wondering is how those turbines fared in tunnels... turbines suck an incredible amount of air. A GE-90 turbine, the kind on a B777, could suck all the air out of Madison Square Garden in 2 minutes, if you want to make a comparison.
blue streak 1 Sawtooth500: Also, turbines do like to be ran at high power, that's where they are best suited. It is a good point that since RR's would not be running them at full power a lot of the time a lot of their potential would be wasted. Some one help us here... Didn't UP when they were operating the big blow use a diesel to shunt around and only when they were cleared to the main would fire up and remain at full power? Wasn't it when the cost of bunker "C" big blow used began to approach diesel costs that UP retired the big blow? Also those "C" costs may have prematurely ended the use of UP's oil burning steam locos?
Sawtooth500: Also, turbines do like to be ran at high power, that's where they are best suited. It is a good point that since RR's would not be running them at full power a lot of the time a lot of their potential would be wasted.
Also, turbines do like to be ran at high power, that's where they are best suited. It is a good point that since RR's would not be running them at full power a lot of the time a lot of their potential would be wasted.
Some one help us here... Didn't UP when they were operating the big blow use a diesel to shunt around and only when they were cleared to the main would fire up and remain at full power?
Wasn't it when the cost of bunker "C" big blow used began to approach diesel costs that UP retired the big blow? Also those "C" costs may have prematurely ended the use of UP's oil burning steam locos?
I do think that I read somewhere that diesels were used to shunt the UP turbines around the yard. Also, it was the rising cost of bunker C that made the turbines retire. If bunker C costs as much as regular diesel, well it's just cheaper to operate the diesels rather than the turbines.
Sawtooth500 Also, turbines do like to be ran at high power, that's where they are best suited. It is a good point that since RR's would not be running them at full power a lot of the time a lot of their potential would be wasted.
blue streak 1 Sawtooth500: First off, as a former airline pilot I can say that there was one inaccuracy in this thread - earlier someone said turbines become more efficient at altitude - that is incorrect. Aircraft are more efficient at high altitude because the air is thinner so there is less resistance - in actually there is also less power coming out of the turbine. Turbines product the most power at sea level and cold temperatures. The colder the better. Really, it comes down to air density, or something called density altitude. Increase the density altitude and you will get less power out of the turbine. Sawtooth500 is absolutely correct. He did not mention that at higher altitudes the temperature is much colder increasing the power output as well. Since a turbine at idle uses about 1/3 the fuel flow of an crusing aircraft at altitude the off and on nature of Railroading would waste very much fuel. Partial power on turbines do not save much fuel over full power settings. I would suspect a diesel loco only operates from 15 - 25% of the time at full throttle. That leads to the possible useage of natural gas powered turbines with a recuperating generator after combustion system to supply CAT. These power plants are advertised by GE as being over 50% thermal efficiency. That is much better than steam's 5 - 10% efficiency and diesel's what 20% ? Using these as power plants enables them to spread out the demand over either a whole RR area or onto the national power grid. + these natural gas turbines can start up on 10 minutes notice and the recuperating system at full efficiency in 1 hour.
Sawtooth500: First off, as a former airline pilot I can say that there was one inaccuracy in this thread - earlier someone said turbines become more efficient at altitude - that is incorrect. Aircraft are more efficient at high altitude because the air is thinner so there is less resistance - in actually there is also less power coming out of the turbine. Turbines product the most power at sea level and cold temperatures. The colder the better. Really, it comes down to air density, or something called density altitude. Increase the density altitude and you will get less power out of the turbine.
First off, as a former airline pilot I can say that there was one inaccuracy in this thread - earlier someone said turbines become more efficient at altitude - that is incorrect. Aircraft are more efficient at high altitude because the air is thinner so there is less resistance - in actually there is also less power coming out of the turbine.
Turbines product the most power at sea level and cold temperatures. The colder the better. Really, it comes down to air density, or something called density altitude. Increase the density altitude and you will get less power out of the turbine.
Sawtooth500 is absolutely correct. He did not mention that at higher altitudes the temperature is much colder increasing the power output as well.
Since a turbine at idle uses about 1/3 the fuel flow of an crusing aircraft at altitude the off and on nature of Railroading would waste very much fuel. Partial power on turbines do not save much fuel over full power settings.
I would suspect a diesel loco only operates from 15 - 25% of the time at full throttle. That leads to the possible useage of natural gas powered turbines with a recuperating generator after combustion system to supply CAT. These power plants are advertised by GE as being over 50% thermal efficiency. That is much better than steam's 5 - 10% efficiency and diesel's what 20% ? Using these as power plants enables them to spread out the demand over either a whole RR area or onto the national power grid. + these natural gas turbines can start up on 10 minutes notice and the recuperating system at full efficiency in 1 hour.
True, at higher altitudes you have much colder temperatures but the pressure is significantly less, so the overall air density is much lower so turbines product less power.
Sawtooth500 First off, as a former airline pilot I can say that there was one inaccuracy in this thread - earlier someone said turbines become more efficient at altitude - that is incorrect. Aircraft are more efficient at high altitude because the air is thinner so there is less resistance - in actually there is also less power coming out of the turbine. Turbines product the most power at sea level and cold temperatures. The colder the better. Really, it comes down to air density, or something called density altitude. Increase the density altitude and you will get less power out of the turbine.
Jerry Pier Recuperation solves the part load fuel consmption problem with gas tubines. CNG or LNG also solves a fuel cost problem . Diesels won't work on pure natural gas.
Recuperation solves the part load fuel consmption problem with gas tubines. CNG or LNG also solves a fuel cost problem . Diesels won't work on pure natural gas.
The light weight of turbines would make hybrid locomotives a bit more practical, with the weight savings being used to increase battery capacity. A large battery capacity would reduce the number of starts and lengthen the time the turbine would be producing power after the start.
Thermoelectric (Seebeck effect) conversion may offer a further improvement in thermal efficiency as well as a means of cooling the exhaust. There have been some glowing reports about progress made in that field, though I haven't seen much of that research being turned into actual products.
You've got a good point with respect to the price of natural gas, especially since it will probably be cheaper than oil for a long time. OTOH, natural gas is probably "easy" to convert to di-methyl ether, which makes a great fuel for diesel engines, and would likely result in much cleaner engines.
- Erik
What hasn't been considered yet is that in order for the 1 for 2 unit reduction suggested by a 9000 hp. unit you would need to double the tractive effort. All current freight locomotives have ballast added so a lighter prime mover would have to be offset by adding more ballast. Current technology is already approaching the theoretical limits of metal on metal adhesion. Because of this any improvements to traction control will be subject to severe diminishing returns. The only reason to consider turbine technology is for emissions and for its ability to run on natural gas. Offsetting this will be the cost of setting up refueling stations, and the expense of fuel tenders.
Add to that , that on railroads, dust and metal fragments are a BIG issue, with amount of air a turbine uses, its hard to filter the intake air.
The dust and particles, do significant damage to the turbines, and severly shorten Turbine life.
So why aren't turbines used on RR's? Well, they are a LOT more expensive than diesels. And FYI there are aircraft that run on diesel engines too. However, turbines have a much higher power to weight ratio than diesel engines do.
Basically, in any internal engine you have 4 phases - intake, compression, combustion, and exhaust (such, squeeze, bang, and blow).
In a diesel, these 4 all happen sequentially. Hence a 4 stroke engine. In a turbine, the 4 happen all simultaneously and continuously. Therefore, your power to weight ratio is a lot higher.
Also, FYI for measuring power in turbine, there are a number of different factors, typically it's measured by either the TIT (turbine inlet temperature), ITT (inter-turbine temperature), EGT (exhaust gas temperature), or N1 speed (low pressure turbine speed percentage). The limiting factor in any turbine is the TIT, turbine inlet temperature. Depending on the manufacturer of the turbine, max continuous TIT's are typically 900-1000 degrees C.
TIT is also was makes a turbine efficient - the hotter the TIT, the more efficient it is. But you can only make it so hot until you get metal distortion, so really it's a materials limitation.
But, as I mentioned earlier turbines are a LOT more expensive than diesels. For aircraft, that makes sense. Weight is a big issue in aircraft, so airliners need a power source that gives them the best power to weight ratio. For railroads, weight isn't really an issue. So you can just have a diesel engine 4 times the weight or the turbine that cranks out equivalent power, and who cares about the weight because it's a RR. And you save a lot of money because you already have diesel infrastructure in place and costs less to buy and service diesels.
An interesting fact about turbines is a turbine will also burn just about any fuel that will catch on fire. You can even put leaded gas into a jet airplane and it will still go - the downside is that if you use the wrong fuel in a turbine it will dirty and ruin the turbine blades significantly decreasing the life of the engine.
So why don't RR's use turbines? In my opinion because weight is not an issue, so therefore they are just not worth the additional cost.
To Juniatha: It's interesting you mention engine-to-drive energy conversion using electricity. The French Saint-Chamond medium tank of World War One did exactly that. It was a lot easier to drive the tracks with electric motors than it was to build a complicated mechanical transmission system to do the job. It made the tank very easy to drive. Also, in the 1940's the Public Service Trolley system of New Jersey ran what they called ASV's, or All Service Vehicles. These were buses that ran on electric motors powered by gasoline engines, or from overhead trolley wires as needed. Looks like there's nothing new about hybrid vehicles! And of course the great French liner "Normandie" was a turbo-electric design. Steam turbines generated electricity to power the propeller shafts, again much easier to build than a complicated gearing system.
@ aegrotatio :
Hydraulic torque converter plus geared transmission have mainly been used to save mass . Torque converters have a profile of efficiency that declines with increased relative difference of input and output rpm (to keep torque converter working near range of best efficiency in automobile industry the trend is towards ever more speeds in automatic transmissions) . In contrast to earlier applications of electric ‘torque conversion’ and transmission , present-day synchronous motors , besides being perfectly suitable for electronic anti-slip control and providing an inherently elegant engineering solution for transmission of power from primary engine to powered axles in trucks - by electricity instead of mechanical gears and drive shafts - are much lighter , more compact and more powerful at the same time , which would ideally suit a gas turbine as primary engine because of its potentially higher output as compared with a diesel engine . As has been noted by others before , aspects of fuel and thermal efficiency generally tend to favor the diesel engine , however if it were for exceptionally high demands of power output per locomotive , the higher performance level asked the more that would favor consideration of switching to gas turbine as a primary engine ; some 9000 engine hp could well be realized in a Co-Co Unit to US specifications of profile and mass per axle or 8000 engine hp in a BoBo-BoBo Unit to European specifications . This could save maintenance costs as for same power output less units have to be combined to run a given heavy train at given schedule over level or nearly level lines (excluding line profiles asking for diesel units to be combined to reach the necessary tractive effort on ruling grade) .
Regards
Juniatha
Are turbines better at direct drive hydraulic or electro-motive transmission?
What kind of gear reduction has to be achieved for each mode, and what are the advantages of each?
I was surprised to learn that many turbine locomotives were direct drive hydraulic and not electro-motive.
an orbiting combustion nozzel turbine has one problem that is not addressed in any posts. What kind of materials are going to be used in the combustion chamber??. It will be really hot in the chamber. On present this generation turbines the turbine inlet temp is limited to about 975 degrees C. with cooling airflow around the combustion chamber. 975 is about 300 degrees hoter than the B-727, DC9 aircraft;s JT-8s . How much hotter is it in the actual combustion chamber with a rotating turbine???*
Bombardier built one on their own. They took it on a tour of the USA and Canada. They couldn't sell a single one. It now lives in a museum.
http://transportation.bombardier.com/en/1_0/1_10/1_10_3_4_5.jsp?menu=2_3
Dave
Lackawanna Route of the Phoebe Snow
re: this OCN engine. They say they need a bigger partner to develop it. If it had any promise wouldn't their respective governments be interested? If Israel and Russia aren't big enough then who is?
The only thing that is relevant about the UP's turbines is that they did what they were supposed to do. All the tales about noise even if true, are totally irrelevant. They were a spectacular case of bad timing. They first gas turbine generator was in 1939 so the technology was in it's infancy. Their existance was dependent on a fuel that was changing from a byproduct to a premium feedstock due to the introduction of new petroleum cracking technology.
The noise will always be there and it's not the exhaust alone. You could remove the exhaust noise entirely and the noise from the turbine itself is well beyond the threshold for ear protection. And J. piers i will differ with you on the startup . An aircraft engine is designed with as little mass as possible which allows the entire engine to heat up rapidly. A locomotive engine or powerplant engine does not have to fly and benefits from the rigidity and vibration damping properties of increased mass. This makes it very hard to go to operating temperature rapidly without uneven expansion of the engine which results in high maintainence and short life. In short it is best suited to constant full power operation.
The UP turbines would have been much better engines 10 years later but the fuel situation was still changing. They would best be compared running on the same fuel and in that light they don't stand a chance.
The idea sounds intriuging and the question comes to mind why haven't the gas turbine manufacturers thought of this before, or better yet, why haven't the air forces thought of this before?
From what I remember about gas turbines from graduate school is they are constant speed machines, and they are most efficient at full throttle; in fact there is very little difference in the fuel consumption from full throttle to low speed.
Considering that the Union Pacific stabled 30 gas turbine electric locomotives, and it used them in freight service for nearly 20 years I would hardly consider them as experimental, especially since they were highly reliable. The gas turbine locomotives were rated at aywhere from 8500 to 10,000 horsepower. When the gas turbine locomotives first went into service in the early 1950's their horsepower was equivalent to four or five diesel freight locomotives. But one of the resons they were phased out was higher horsepower diesel freight locomotives such as the GE U 50C (5000 horsepower) and the DD 40 (6600 horsepower) became available.
Gas turbines were also used to power passenger trains, the United Aircraft Turbotrains and the ANF-Frangeco/Rohr Turboliners which were not as relable as the Union Pacific's gas turbine electric locomotives.
The RTL's used aircraft derivitive gas turbines, one 850 kW (1139 hp) in each power car. One of these was later replaced with a 1200 kW (1609 hp) unit for improved fuel economy. The large unit could handle the whole train with the smaller unit fired up just for accelearation, at least that was the intent. The RTLII used two 1609 hp gas turbines. The RTL's were quiter than any diesel. There was a venturi in the exhaust pipe which helped ventilate the engine compartment but also added volume to the exhaust, reducing noise as well as temperature.
The MIT Press recently published a book by Vaclav Smil entitled Prime Movers of Globalization. It discusses the contributions that diesel engines and gas turbines have made toward a global economy. There is almost no discussion of railroads (because they don't span continents); however there is a tremendous amount of information about the use of those two forms of propulsion in other applications.
carnej1 cacole: Another factor that caused the demise of Union Pacific's Big Blow was the noise -- the only place they could be used was out across the desert because they were as loud as a 747 on takeoff. In one video I have the narrator says there were many cities they could not be ran into without being arrested because of the noise level they emitted. Amtrak's RTL turbos were not that much louder than diesels (the gas turbines themselves were smaller units than the UP GTELS had)..
cacole: Another factor that caused the demise of Union Pacific's Big Blow was the noise -- the only place they could be used was out across the desert because they were as loud as a 747 on takeoff. In one video I have the narrator says there were many cities they could not be ran into without being arrested because of the noise level they emitted.
Another factor that caused the demise of Union Pacific's Big Blow was the noise -- the only place they could be used was out across the desert because they were as loud as a 747 on takeoff.
In one video I have the narrator says there were many cities they could not be ran into without being arrested because of the noise level they emitted.
Amtrak's RTL turbos were not that much louder than diesels (the gas turbines themselves were smaller units than the UP GTELS had)..
-Don (Random stuff, mostly about trains - what else? http://blerfblog.blogspot.com/)
cacole Another factor that caused the demise of Union Pacific's Big Blow was the noise -- the only place they could be used was out across the desert because they were as loud as a 747 on takeoff. In one video I have the narrator says there were many cities they could not be ran into without being arrested because of the noise level they emitted.
"I Often Dream of Trains"-From the Album of the Same Name by Robyn Hitchcock
How about intermodal service on transcon routings? Put a backup motor on the unit to keep air pressure when the turbine is shut down.
Dan
Recuperation solves the part load fuel consmption problem with gas tubines. CNG or LNG also solves a fuel cost problem . Diesels won't work on pure natural gas. The best turbines for lcomotives are aircarft derivitive. They have never been recuperated because they don't need to be in airplanes. Another poinnt, gas turbines do not not need to be left idling. They will go from shutdown to full power in 90 seconds. Don'r get me srarted-
Turbines work most efficiently at full RPM, at idle or low RMP they just eat up tremendous amounts of fuel.
UPs experiment with the Big Blows didn't end because the turbine failed to do or perform as promised.
It ended because the fuel used, #6 fuel oil, ended up becoming more expensive than they wanted to pay, (other industrial uses cut into the supply, raising the cost) the infrastructure to service the turbine also became less cost effective than wanted, (ya can't run over to the gas station and fill up on #6 heating oil) and the traffic pattern in the area where they could most efficiently be used changed.
A turbine would make sense in freight service if it was used in a manner that best allowed it to perform to its full potential, that is a high speed non stop run with a huge train.
Anything else is a waste of the turbines efficiency.
23 17 46 11
Turbine engines have and will be in the near future fuel hogs unless operated at high altitudes. I highly doubt there is one in the railroad's near future.
Norm
This, says Dr Lior, eliminates the need for the two sets of static blades. That means an OCN engine can be built more cheaply with fewer components. It would also need to be only half the size of a conventional jet of similar power, says Dr Lior. The engine would use at least 25% less fuel and, he claims, its emissions of carbon dioxide and nitrogen oxide would be cut by three-quarters because of its unique ignition properties.
http://www.economist.com/node/16909889
Being largely ignorant of Physics and Mechanical Engineering, is there an expert in the house?
Given the historic hype and failure to embrace turbine locomotives, would this make any difference? High output efficiency versus fuel consumption at rest comes to mind as an issue. Would this design address the economics of universal applications?
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