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Diesel MPG

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Diesel MPG
Posted by ns3010 on Friday, May 29, 2009 3:12 PM

How far does the average diesel locomotive go between refuels, and how many MPG does it get? Are they all in the same range, or does it vary?

For example, say that a train with a 3000 gal. fuel tank travels 100 miles each day, every day. On day 1, it starts its work with a full tank. How many days later would it need a refuel?

Thanks in advance.

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Posted by mudchicken on Friday, May 29, 2009 3:58 PM

Tonnage? grade & curvature? MU'd/DPU'd with? Engineer qualification?, wind? axle count? 

I think you get the point....

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Posted by timz on Friday, May 29, 2009 4:08 PM
In Idle, a large diesel locomotive burns maybe 5? gallons per hour. At full power it burns something over 200 gallons per hour. So you need to make some guesses about how much time it's spending idling and how much at full power, and how fast it's covering the miles.
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Posted by Railway Man on Saturday, May 30, 2009 10:33 AM

As others said above, everything depends on the route, speed, and weight of train!  But I think what you're looking for is averages.

Here's an example that may help.  A particular coal train I have worked with runs 1,670 miles round-trip between the mine and the power plant.  The route is mountainous throughout, with numerous long ascending grades.  The train is 135-cars long with gross weight of  18,500 tons (including locomotives).  Each locomotive carries 5,000 gallons of fuel.  In that round trip, the train will refill twice, each time each locomotive taking on about 4,000 gallons.  So:

Total fuel consumed round trip = 20,000 gallons

Total mileage 1,670

Miles per gallon per locomotive = 0.41. 

But again, this is only a specific case.  Other cases are much much different. 

Another way of obtaining an average is to use the US Energy Information Administration's averages for the U.S. as a whole.  EIA found that in 2006, the BTUs per ton/mile average for freight transportation modes were:

  1.  337 - Rail
  2.  514 - Water
  3. 2,801 - Truck
  4. 21.976 - Air

So in rough equivalent numbers, if the average 80,000 lb. semi-trailer combination is getting 8 mpg to move 26 tons of freight, the average train is getting 66 mpg to move 26 tons of freight.

RWM

 

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Posted by BaltACD on Saturday, May 30, 2009 2:42 PM

One carrier that I am aware of, for locomotive management purposes, rates  the GE AC's for 1100 miles for a full 5000 gallon tank in unit train service.  Other, less stressed, services have longer mileage intervals.

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Posted by trainfan1221 on Saturday, May 30, 2009 3:03 PM

Of course the idea is that the train is moving a lot more tonnage than another form of transportation with the same fuel, so its more efficient.  Then again I would say that anyway since I am a train person.  I have seen varying accounts, I do know that railroads sometimes ordered larger fuel tanks to get longer distances out of their engines.  I don't know, maybe type of train would make a difference too, but the more knowlegable members here certainly can answer this better.

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Posted by da_kraut on Sunday, May 31, 2009 9:54 AM

 Hi,

great post Railwayman.  This shows very well how efficient the different modes of transportation really are.  Surprised that water uses more fuel then rail.


Frank

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Posted by HarveyK400 on Monday, June 1, 2009 10:24 AM

Here's some dated information on the SD-40 from "Fuel Efficiency Improvement in Rail Freight Transportation," J N Cetenich, FRA-ORD-76-136, Dec, 1975.

Throttle Position            Delivered Horsepower               Fuel Rate (gal/hr)

8                                  3100                                       168

7                                  2550                                       146

6                                  2000                                       108

5                                  1450                                        79

4                                   950                                         57

3                                   500                                         41

2                                   200                                         25

1                                    58                                           7.5

Idle                                 --                                            5.5

Dynamic Brake               --                                           25

 

Depending on speed limits, profile and load, mpg depends not only on the time spent in each throttle position during running, but also in idle between runs.  This is why shutting down is such a big issue.

Interestingly, an E8 burned 114 gal/hr at run 8.  There is little if any improvement with turbocharging and the 645-series engine with the SD40.

 

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Posted by Railway Man on Monday, June 1, 2009 10:46 AM

I am not sure how you have reached that conclusion, which is contrary to my experience and knowledge.  The table you cited is interesting. An SD40-2 doesn't deliver 3,100 hp.  It delivers 3,000 hp into the flywheel of the main generator, and about 2,500 hp onto the rail.  That's the only delivered power that matters.

According to EMD, the SD40-2 consumed 164.4 gph at 3,000 hp output into the flywheel, similiar to the table you cited, but the E8 consumed 188 gph at 2,250 hp into its flywheels instead of the 114 you cite.

Here's the numbers from EMD for horsepower per gallon per hour at notch 8 (which is the most fuel-efficient notch in terms of maximum horspower per gallon consumed):

  1. E7 - 10.8
  2. E8 - 12.0
  3. F7/GP7 - 16.1
  4. F9.GP9 - 16.2
  5. GP30 - 18
  6. GP38 - 16.3
  7. GP40/SD40 - 17.9
  8. GP40-2/SD40-2 - 18.2
  9. SD50 - 19.8
  10. SD60 - 20.8
  11. SD70 - 20.8

Conclusions: 

  1. Turbocharging increased fuel economy by 12-15%
  2. I don't specifically know why E units had such relatively awful fuel economy.

I am inferring from your post that the 645 engine really didn't accomplish as much as you think it should, relative to the 567.  I may be inferring incorrectly, but allow me a comment on that.  Horsepower per cubic inch of displacement in an engine family often doesn't increase when total displacement increases, because the engine designers want to live within a certain maximum pressure within the cylinder that's commensurate with the capabilities of the design to resist that pressure.  It's possible to increase that pressure but only by making the engine much heavier, and/or accepting a much higher maintenance cost and much lower engine longevity.  Weight and dimensional increase outcomes are usually not acceptable in the highly restricted weight/dimensional envelope in a rail application.  While it's true that engine technology improves over time, often designers want to use those advances to improve longevity and reduce maintenance cost, rather than hold those even and obtain higher horsepower, because that's what rail customers usually want.  There is very signficant improvement in the 645 over the 567, and 710 over 645, in terms of reduced engine maintenance cost and increased longevity.  Availability rates that are prime-mover related have more than quadrupled in improvement in my career.

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Posted by Railway Man on Monday, June 1, 2009 10:55 AM

da_kraut

 Hi,

great post Railwayman.  This shows very well how efficient the different modes of transportation really are.  Surprised that water uses more fuel then rail.


Frank

 

I know very little of naval engineering, but from what I can gather, the problem is the bluntness/width of the hull that is necessary to efficiently accommodate very large tonnages for the amount of steel and overall length of ship necessary to fit in ports, docks, locks, etc.  That creates enormous resistance to motion through the water.  In order to get high fuel efficiency, the hull shape needs to be more needle-like.

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Posted by rdgk1se3019 on Monday, June 1, 2009 12:07 PM

 What I would like to know is why does using the dynamic brake cause an increase in fuel usage?

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Posted by Deggesty on Monday, June 1, 2009 12:55 PM

Railway Man

I know very little of naval engineering, but from what I can gather, the problem is the bluntness/width of the hull that is necessary to efficiently accommodate very large tonnages for the amount of steel and overall length of ship necessary to fit in ports, docks, locks, etc.  That creates enormous resistance to motion through the water.  In order to get high fuel efficiency, the hull shape needs to be more needle-like.

I was having some thoughts on this line yesterday, but did not work them out as RWM did. Certainly, a streamlined prow and a stern that is shaped so as to reduce turbulence will increase fuel efficiency. I have never examined the floats of a catamaran, but I believe that they would be shaped so that not only do they lift the body of the craft out of the water, they also cut through the water more smoothly. Does anyone have any knowledge of relative fuel efficiency for a catamaran (such as those used by the Victoria Clipper)?

Perhaps one reason for uisng using (did my keyboard ever foul up on that!) barges is less roadway upkeep expense?

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Posted by Paul Milenkovic on Monday, June 1, 2009 2:33 PM

rdgk1se3019

 What I would like to know is why does using the dynamic brake cause an increase in fuel usage?

They have to rev the engine some to run the generator -- this is needed to produce what they call excitation voltage for the traction motors so they act as generators.  Acting as generators they act as brakes.

I suppose you could design self-exciting generators -- the power output of the generator in turn could produce voltage across the field windings to make them work as generators.  This is not perpetual motion as you are still converting shaft power to electric power, and you may need some initial excitation or magnetism in the field to get this going.

But I guess it was a lot simpler, safer, cheaper, easier to generate the traction-motor-as-generator excitation voltage with the main generator during dynamic braking and hence dynamic braking uses a little bit of fuel.  With expensive fuel one could pursue alternatives to this arrangement, but given the costs and benefits it may not be worth it.

What the AC traction motor locos do is something I don't know.

If GM "killed the electric car", what am I doing standing next to an EV-1, a half a block from the WSOR tracks?

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Posted by timz on Monday, June 1, 2009 5:29 PM

rdgk1se3019
why does using the dynamic brake cause an increase in fuel usage?

He gave figures for the SD40-2, on which the traction motor blower is connected directly to the 16-645-- in other words, the blower only runs full speed if the prime mover is at full speed. The traction motors still need cooling in dynamic brake.

So apparently it takes 25 gal/hr to run a 16-645 at full speed with next to no load.

Don't recall what produces TM excitation current in dynamic-- probably the D14 auxiliary alternator? Not the main generator, in any case.

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Posted by erikem on Monday, June 1, 2009 10:59 PM

Railway Man

Conclusions: 

  1. Turbocharging increased fuel economy by 12-15%
  2. I don't specifically know why E units had such relatively awful fuel economy.

 

My WAG on conclusion #2 is that the fuel consumption may include the steam generators, otherwise I'd also wonder what was killing the fuel economy of the E's.

I'd wager that conclusion #1 holds more for the 2 cycle engines, and would assume 4 cycle engines would have a smaller increase in fuel economy.

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Posted by Railway Man on Monday, June 1, 2009 11:34 PM

I don't think it's the steam generators.   More likely it's transmission inefficiency.

I can't think of any 4-stroke locomotive prime movers that did not have turbochargers.

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Posted by M636C on Tuesday, June 2, 2009 8:20 AM

Railway Man

I don't think it's the steam generators.   More likely it's transmission inefficiency.

I can't think of any 4-stroke locomotive prime movers that did not have turbochargers.

RWM

A number of the early Alco and Baldwin engines were naturally aspirated. The 660 HP 539 engine in the Alco S-1 had no turbocharger.

 The fuel saving  from turbochargers on EMD two stroke engines came from the turbocharger uncoupling from its gear drive from the crankshaft at notch 7 (or about). A look at the specific fuel consumption curve for a turbocharged EMD takes a sudden drop around notch 7 at the point that the considerable power being used to drive the blower becomes available at the generator.

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Posted by Railway Man on Tuesday, June 2, 2009 8:47 AM

 Now why didn't I recall the 539?  Since I worked on them now and then?  Old age I guess.

 The illustration on the turbo decoupling is a good one.

RWM

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Posted by bushhog8fan on Tuesday, June 2, 2009 10:56 AM

for one thing the E units were 2-567 engines not just the 1 that were in hood units. therefor more fuel used to make the 2250 horsepower

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Posted by kencompton on Tuesday, June 2, 2009 9:10 PM

I'm pretty sure the VO series engines from Baldwin were four stroke, and they were normally aspirated.

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Posted by kencompton on Tuesday, June 2, 2009 9:19 PM

Does anyone have this info on GE FDL's, or ALCo 251 and 244 prime movers?

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Posted by alangj on Tuesday, June 2, 2009 11:17 PM

That's exactly what I was thinking (about the 2 separate 567's in each E) as I read through this thread.  Two other things also crossed my mind.  One is that the E's had traction motors geared for the higher "passenger speeds", which probably would have required a bit more effort to make them turn against that higher gear ratio (Ever try to pedal a 10-speed bicycle when it's in too high of a gearing and without downshifting?  It takes LOTS of effort on the pedals to accelerate if you don't get it into a lower gearing.)  Granted, they would still go through the various transition points at lower speeds, but once they got up to their "highest" setting, they were still working against those higher traction-motor gear ratios.  The other point is that, if I recall my physics correctly, wind resistance increases proportional to the SQUARE of the speed, so to go 10% faster, you'll feel about 21% more wind resistance, and to go 40% faster (like about the difference between "freight" speeds and "passenger" speeds), you'll feel almost double the wind resistance (actually about 96% more.)  That can't have done much for the fuel economy, either.

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Posted by WSOR 3801 on Wednesday, June 3, 2009 1:38 AM

Paul Milenkovic

rdgk1se3019

 What I would like to know is why does using the dynamic brake cause an increase in fuel usage?

They have to rev the engine some to run the generator -- this is needed to produce what they call excitation voltage for the traction motors so they act as generators.  Acting as generators they act as brakes.

I suppose you could design self-exciting generators -- the power output of the generator in turn could produce voltage across the field windings to make them work as generators.  This is not perpetual motion as you are still converting shaft power to electric power, and you may need some initial excitation or magnetism in the field to get this going.

But I guess it was a lot simpler, safer, cheaper, easier to generate the traction-motor-as-generator excitation voltage with the main generator during dynamic braking and hence dynamic braking uses a little bit of fuel.  With expensive fuel one could pursue alternatives to this arrangement, but given the costs and benefits it may not be worth it.

What the AC traction motor locos do is something I don't know.

 

On the older engines, they rev up to roughly notch 6 in dynamics.  Looking back at the rack on the governor, though, shows about notch 2.  RPMs without much load.  

On newer SD40-2s, they don't rev up in dynamics until about position 6 or so.  Not sure of when the change was made, but it was after the test (1975) and before 1978.  Some older SD40-2s have been rebuilt/upgraded with this feature.  

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Posted by oltmannd on Wednesday, June 3, 2009 7:26 AM

Wow.  This thread has an interesting collection of truth, half-truth and mis-understood truth.  I spent a lot of time doing fuel consumption testing on locomotives - I have the #2 diesel-soaked work boots to prove it - so let me see if I can explain some things.

#2 Diesel fuel:  In order to  rate the fuel consumption and output of diesel engine in any meaningful way, you need a set of standard conditions.  The AAR standards for locomotive diesel engines are:

Air temp - 60 deg F

Fuel temp - 60 deg F

Barometer - 28.86" Hg (typical for 1000' above sea level - which makes Altoona a great place to do tests)

Fuel density - 7.043#/gal

Fuel HHV - 19350 Btu/gal

The engine manufacture typically has empirical correction curves compliled from actual test data that you can use to correct from what ever your test conditions are back to standard.

We always had a lab run a HHV test on the fuel we used for testing.  It was always very, very close to the standard - winter, spring, summer or fall - it didn't matter.

EMD blower vs turbo:  A biggie!  There is no "magic" when the turbo gets off the clutch.  It just means there's finally just enough energy in the exhaust stream to allow the turbine to power the compressor.  The difference is that the work you would have had to supply from the gear train in on a blower engine, you get almost for free on the turbo.  As engine output increases on a turbo engine, the fraction of the power from the turbine increases and the fraction from the gear train decreases.  Somewhere between notch 6 and 7 the gear train fraction finally reaches zero.

What does this mean for engine efficiency?  A fair comparison would be two otherwise identical locomotives, one with a turbo, one with a blower.  See the chart below (I hope it's legible - appologies for using Traction HP instead of Brake HP)

GP38-2 GP40-2
notch THP #/hr #/HP-hr incrmntl HP-hr/# THP #/hr #/HP-hr incrmntl HP-hr/#
idle 0 31.3 0 35.6
1 83 55 0.6627 3.50 81 60.5 0.7469 3.25
2 278 125.7 0.4522 2.76 371 162.9 0.4391 2.83
3 573 231.1 0.4033 2.80 659 268.7 0.4077 2.72
4 854 335 0.3923 2.70 1004 395.6 0.3940 2.72
5 1143 452 0.3955 2.47 1447 559.3 0.3865 2.71
6 1438 580.9 0.4040 2.29 1939 744.6 0.3840 2.66
7 1764 727.5 0.4124 2.22 2595 994.4 0.3832 2.63
8 2004 866.5 0.4324 1.73 3074 1185.2 0.3856 2.51

Notice that both locomotives are worse incremental power producers as you move the throttle out.   Also notice that both locomotives are close to identical in efficiency up through notch 4. Beyond that, the blower engine starts to "lose its breath" as the blowers have trouble keeping the airbox supplied.

Some other things to note.  The power producing capability of the turbo engine is nearly flat once you get past notch 2.  There is very little variation notch to notch.  The blower engine gets really lousy in the upper notches and notch 8 is horrendous.

Dynamic braking:  There were two right answers here.  You need to spin the engine to provide excitation for the TM windings AND you need to supply cooling air to the TMs.  The excitation comes from the main generator (or traction alternator) - all the companion alternator ever does is run the cooling fans and provide excitation for the main generator.  Under most conditions, the engine speed needed for cooling air is greater than that needed for excitation and N4 was a "one size fits all" solution. 

However, that mechanically driven TM blower is a HP hog.  On a GP38/40-2 it consumes 81 HP at 900 engine RPM and since fan HP goes up with speed squared, reducing the speed saves quite a bit of energy.  So, when fuel started to get expensive, EMD came out with two speed DB where they matched the engine speed to DB demand.

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Posted by timz on Wednesday, June 3, 2009 1:00 PM

oltmannd
The [dynamic braking] excitation comes from the main generator (or traction alternator)

Yeah, I was wrong about that, according to the GP40-2 Service Manual at http://rr-fallenflags.org/manual/manual.html .

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Posted by Deggesty on Tuesday, June 9, 2009 5:50 PM

oltmannd

Fuel HHV - 19350 Btu/gal

Don, you've thrown a new acronym in on me--HHV (everything else is old stuff). What is it?

Thanks,

Johnny

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Posted by creepycrank on Tuesday, June 9, 2009 6:31 PM
HHV is High Heating Value but shouldn't be 19350 btu per pound. I think no.2 diesel is about 7.04 pounds per gallon.
Revision 1: Adds this new piece Revision 2: Improves it Revision 3: Makes it just right Revision 4: Removes it.
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Posted by erikem on Wednesday, June 10, 2009 1:11 AM

 The difference between Low Heating Value and High Heating Value is the latent heat of condensing the water in the combustion gases. Anthracite and coke would have an HHV only marginally larger than the LHV.

For hydrogen, the LHV is about 50,000 BTU/lb and the HHV is about 60,000 BTU/lb (where lb is a pound mass). 

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Posted by BerkshireSteam on Thursday, June 11, 2009 5:35 PM

Railway Man

Conclusions: 

  1. Turbocharging increased fuel economy by 12-15%
  2. I don't specifically know why E units had such relatively awful fuel economy.

 

1. Turbo's seem more economical because they only produce usable boost when under a load. When that 645T engine is sitting there idling there is no usable boost from the turbo's and the engine therefore reacts like it's a regular, non turbocharged 8 cylinder. Just like in cars, trucks and such.

2. The 567 series engine was a 2-stroke diesel, I do believe the 645 was a 4-stroke. At any rate 4 strokes are way more fuel effiecent. A major part of the reason why the governent started saying everything from a car to 10cc weed eater should be a 4-stroke design engine.

I may not know alot about trains, but I do know alot about engines. And an engine is an engine. It doesn't matter if its a 6.0L diesel from a GM truck or a 197L diesel from turbocharged V8 train prime mover, it works the same. And just as a side note, back in the early 90's when Dodge/Plymoth came out with the Neon, it was originally planned to have a 2-stroke 4 cylinder engine, instead of the dumb junky 2.0L 4-stroke crapola it had.

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Posted by creepycrank on Thursday, June 11, 2009 6:08 PM
Re: 2 stroke vs. 4 stroke. You should read "EMD/ General Motors" and "Turbocharged/ Supercharged" below in this section for a pretty good discussion. Its somehow assumed that spark ignited- loop scavenged engine in outboard motors , chain saws and weed wackers are indicative of thermodynamic performance of 2 stroke diesel. Even outboard motors have cut fuel consumption rate by about 30% by going to direct inject. The largest diesel engine is the 109,000 hp Wartsila engine which is 2 stroke, uniflow scavenged 2 stroke diesel with the lowest bsfc of .260 lb per hp-hour. Of course engines that size don't have parasitic loads like jacket water pumps and lube oil pumps which are powered by auxilary engines. I heard that the uniflow principle was patented about 1930 by General Motors after experiments by Charles Kettering's bunch.
Revision 1: Adds this new piece Revision 2: Improves it Revision 3: Makes it just right Revision 4: Removes it.

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