Are multiple "Mued" Locos controlled as one or individually?

Not quite sure what you are asking about.  Are you asking about Distributed power sets where there are multiple sets of iengine in the train and  one engineer is controlling all of them or are you asking about multiple engines in one consist, all coupled together in one group?

DP engines are all controlled by one engineer and he only has one control stand, but he can control individual DP sets in the train.

Engines all in one consist are all handled together, but he can manually set some engine up to be off line (running but not pulling).

As with our models, I'm wondering if the engineer has problems matching individual loco speeds when in a consist..........

Short answer, "No".  Model engines are directly geared to the motor.  Real engines are diesel electric.

May be a bit off topic, but the CN runs a short haul manifest, train A415, from Stevens Point, WI., to Green Bay. WI., and back, with a loco and engineer on each end.

No other crew, just the 2 engineers.

Mike.

mbinsewi

—with a loco and engineer on each end.

The Bessemer & Lake Erie ran them like that for a while, too. Albion, Pa. to Conneaut, Ohio ore docks.

Cut the power off each end and move over one or two yard tracks and tie on to another hundred-car cut. Usually loads south, empties north but they did haul coal north, too, but I don't know how often that happened.

A crew could make two round-trips a day like this.

bessemer 089 by Todd Dillon, on Flickr

I rode along one night and noted that the lead engineer hardly touched the throttle at all. Up to run-8 once the train got rolling and the throttle stayed there until we got close to the curves and down-grade near the docks.

I imagine it was the same at the rear.

Regards, Ed

i'm curious

dehusman

DP engines are all controlled by one engineer and he only has one control stand, but he can control individual DP sets in the train.

Engines all in one consist are all handled together, but he can manually set some engine up to be off line (running but not pulling).

presumably a "consist" is 2 or more engines that are coupled together and distributed power means there can be multiple consists in a train separated by rolling stock.

presumably all engines in a consist have a physical electrical connection between them.    are distributed (?) consists controlled from by the engineer using radio?   if so, do the engines automatically shut-down if the radio link is lost?

i can understand that any engine is turned off (no longer providing traction).    but if there is a single control stand, are all consist/engines in the same "notch"?     and does this result in equal traction by each engine or do they simply provide whatever traction (i.e. power) that notch results in for that engine considering engine size (HP), age and any other performance deviations

 

dehusman

Short answer, "No".  Model engines are directly geared to the motor.  Real engines are diesel electric.

i think the OP was asking if prototypical engines ever "slip" like some consisted models do because they are not properly speed matched?

is this an example?   what caused this?

 

gregc

 presumably a "consist" is 2 or more engines that are coupled together and distributed power means there can be multiple consists in a train separated by rolling stock.

Correct, sorta.  A consist could be one engine.  Distributed power is separate groups of engines (I think there can be up to 6 or 7) controlled by one engineer.

presumably all engines in a consist have a physical electrical connection between them.    are distributed (?) consists controlled from by the engineer using radio?   

Yes and yes.

if so, do the engines automatically shut-down if the radio link is lost?

There is only a penalty if contact is lost for a certain length of time.  Momentary loss of contact happens all the time.  Cuts, overpasses, buildings in cities, power lines, and other things can cause loss of a signal.

i can understand that any engine is turned off (no longer providing traction).    but if there is a single control stand, are all consist/engines in the same "notch"?

Normally, unless the engineer changes something, yes.

    and does this result in equal traction by each engine

No.

or do they simply provide whatever traction (i.e. power) that notch results in for that engine considering engine size (HP), age and any other performance deviations

Yes, just like every engine in every consist controlled by any method. 

gregc

are distributed (?) consists controlled from by the engineer using radio?   if so, do the engines automatically shut-down if the radio link is lost?

i can understand that any engine is turned off (no longer providing traction).    but if there is a single control stand, are all consist/engines in the same "notch"?     and does this result in equal traction by each engine or do they simply provide whatever traction (i.e. power) that notch results in for that engine considering engine size (HP), age and any other performance deviations

 

DP first.  A DP consist in power mode will maintain the throttle position of the last command it received for 90 minutes during extended communication (comm) loss.  After that it will cut out it's brake valve and go to idle.  It will remain that way until comm is restored. 

If an engineer wishes to cut the power to the DP earlier, making a automatic brake application will signal the DP(s) to isle down.

A DP consist in dynamic braking will remain in dynamic brakes indefinitely until comm is restored.  This is because there may be times when, like on a long down grade section, you might not want to lose dynamics.  

If you need to get out of dynos, ther is away once stopped.  An emergency application when stopped will signal the DP(s) to go to idle and cut out the automatic brake.

 About all being in the same notch on a "hard wired" consist.  There are some energy managment systems that the onboard computer may run different engines within the consist in different throttle notches.  The engineer places the throttle in a certain notch.  The computer may decide that trailing engines will be run in the "optimal" notch.  It might be the same as the lead engine, it might not.  Unless the leader and trailing units are equipped with a conist monitor. the engineer won't know for sure what notch the trailing engines are actually in.

Jeff

An elementary video about DPU by a locomotive engineer:

https://m.youtube.com/watch?v=MuVRAg3HS-4&feature=youtu.be

And a tutorial from the train-simulator community about setting up DPU and then starting a heavy train on a grade -- note the helpful things in the comments...

https://m.youtube.com/watch?v=bjj-A36bYeA

Mark Cole, who helped write the ATSF manual for Locotrol II in the mid-'80s just before the aborted SLSF merger, noted that in the revision from the original to II, the Harris engineers incorporated "too many safety items which caused the trains to go into emergency whenever something wasn't exactly what the equipment required".  I suspect much of the way later versions handle 'indefinite LoS' was "informed" by such experience.

There can be issues with the loss of signal.  I still remember the original uncensored video of the Panhandle wreck, where the head-end radio was destroyed on impact and the DP kept pushing the train into the developing dust cloud...

thanks

fly-by-wire was developed during the space shuttle era as a means to control an aircraft electrically via computer or even remotely (!!).   initial systems only gave the computer 20% control which was presumably enough to relieve the pilots of the need to make frequent adjustments reducing fatique.   

another feature prevented pilots from exceeding limits.   this was modified since the pilot is the best person to make that decision when his life is on the line.    such intelligence often takes time to sort out.

while watching the videos i wondered how brakes were controlled and if brakes could be applied from the trailing unit, at least at first, presumably from obvious reasons?   

and similarly if brakes could be released from the head unit?    can brakes for any consist be independenly controlled, and for units in the middle of the train, can front and rear brake connections be independently controlled?

 

and with regard to power, why can't the computer independently control power on various units to at least maintain a desired speed, if not acc/deceleration, or even coupler force?

gregc

while watching the videos i wondered how brakes were controlled and if brakes could be applied from the trailing unit, at least at first, presumably from obvious reasons? 

 

Generally the brake application is applied from each of the remotely controlled engines at the same time in order to minimize the transmission time through the train line.  The brakes need to be applied to the whole train ASAP to maximize the braking effort and reduce train line forces.  If you apply brakes on the rear end first, then the chances of breaking the train in two is increased.

and similarly if brakes could be released from the head unit? 

Why?  That'ts what regular brakes do.  The goal, once again is to release the brakes ASAP across the whole train.

  can brakes for any consist be independenly controlled, and for units in the middle of the train, can front and rear brake connections be independently controlled?

The train line runs the length of the train.  Any changes in pressure will be propogated throughout the the whole train line eventually. If you set or release the brakes on just part of the train you will end up with brake in twos or runaways.

RE:  the sparky video of excessive wheelslip, that was probably caused by a defective wheelslip sensor or control module on that particular unit. 

Here's a TSB report on a runaway that happened as a result of poor train handling, but a key link in the chain was an emergency brake application that happened as a result of the safety features built into the Locotrol II system:

https://www.bst-tsb.gc.ca/eng/rapports-reports/rail/1996/r96c0086/r96c0086.html

I could be wrong here, and Mobilman44 should speak up and say so if I am.

But I took his question to simply mean MU'd diesels, not modern DP, and him wanting to understand how one engineer controls 2 or more locomotives without them fighting each other like our models sometimes do.

This question, if I am right, suggests that the OP does not fully understand how a diesel electric locomotive works, let alone how how three or four of them respond to one set of commands.

Maybe he needs to understand how the traction motors are connected to the wheels and the fact that a real locomotive will roll when pushed, while our models will not.

And how the traction motors are controlled electrically and how the diesel engine and the traction motors respond to the commands from the engineer.

Maybe he needs to first understand how the four or six traction motors are separately geared to their individual axles and how they work together to move the locomotive.

Then it will make more sense to him how one set of commands can control multiple locomotives with minimal "conflict" as all these separately powered axles apply power to move the train, differently from our models with one motor applying power thru worm gears that will not free wheel.

Again, I could be wrong, but I think the OP is asking a more simple question than most of you have been trying to answer.

And now the irony in this, I am DC modeler, and nearly every train on my layout is powered by more than one powered locomotive. And while many are relatively "matched sets", I also run double or trippled headed steam of mixed brands and wheel arrangements.

Example, a Spectrum 2-6-6-2 and a Proto 2-8-8-2 on the head end of a coal drag of 40-45 hoppers. They run fine together, no modifications, nothing done to "speed match" them.

Generally, if you really need two or more locos, and the starting voltage and gearing is close, they will run fine together.

So, maybe, the OP just needs to understand how the real diesel electric locomotive works in the first place?

Maybe his question was confusing because he was not sure what terms to use?

Or maybe I'm all wet?

Sheldon

 

gmpullman

The Bessemer & Lake Erie ran them like that for a while, too. Albion, Pa. to Conneaut, Ohio ore docks.

Cool.  The CN uses 2 B&LE tunnel motors as helpers on Byron Hill, which is just south of Fond du lac, WI.

Mike.

Railroaders who operate 1:1 equipment but do not model would probably not understand his joke about matching locomotive speeds.  Granted, you'd be unlikely to run into such a person on a forum like this.  

I've seen that line a few times over the years in various places online, and I've even heard it in person out at the museum (along with "what kinda transmission's in that thing").

dehusman

The brakes need to be applied to the whole train ASAP to maximize the braking effort and reduce train line forces.  If you apply brakes on the rear end first, then the chances of breaking the train in two is increased.

this is interesting.

i can understand that it may be ideal that brakes be applied to all cars simultaneously, but my understanding is this is impossile with current air brakes.   

that brakes are applied to cars starting with the cars closest to the source that the brakes are released from.    if there is a single consist at the front of the train, brakes get applied to the front of the train first resulting in "coupler slack (?)" being lost toward the rear of the train and the train "bunching up (?)"    (i don't know wat the proper terms are for these behaviors).

if there are engines at each end of the train, this means from each end and that braking occurs last to cars in the middle of the train.     if there are engines in the middle of the train, it further "equalizes" the application of the brakes resulting in brakes being more evenly "applied to the whole train ASAP".

as an (electrical) engineer i assume that being able to independently control power and braking at different parts of the train would improve control.   i don't assume a (locomotive) engineer  would know what to do with this control, but assume a computer could.   an engineer would tell the computer what he wanted to do and the computer would figure out how

i assume there are certain situtations where this would be most useful possibly going up/down a grade on a curve, cresting a hill or (??)

Geez Sheldon, 

    I do understand how a diesel loco works.  I feel bad that my question exposed all that guessed at ignorance you dug up.   

Others before you answered my question, and I guess I just marvel at how a consist of various different locos could pull/push together without fighting each other.

In the future, I'll be a lot more selective of what questions I ask here.  Ha, whoever said there was no such thing as a stupid question was obviously wrong.

Shame on me........

 

  

gregc

if there are engines at each end of the train, this means from each end and that braking occurs last to cars in the middle of the train.

A modern EOT or end of train device will allow controlled or simultaneous brake pipe reductions from the rear, too. This type is in development but the current EOTs will allow an emergency application from the rear. No need for a locomotive to apply brakes from the rear.

Regards, Ed

mobilman44

Geez Sheldon, 

    I do understand how a diesel loco works.  I feel bad that my question exposed all that guessed at ignorance you dug up.   

Others before you answered my question, and I guess I just marvel at how a consist of various different locos could pull/push together without fighting each other.

In the future, I'll be a lot more selective of what questions I ask here.  Ha, whoever said there was no such thing as a stupid question was obviously wrong.

Shame on me........

 

  

 

No worries, my apologies, your question seemed so basic and the answers quickly went into a lot of detail down a lot of paths.

Simple answer is because all these powered axles are not linked mechanically, the application of power balances out, mostly......

It is one of the virtues of electric traction.

Sheldon

gmpullman

A modern EOT or end of train device will allow controlled or simultaneous brake pipe reductions from the rear, too. This type is in development but the current EOTs will allow an emergency application from the rear. No need for a locomotive to apply brakes from the rear

thanks, i wondering about that too

gmpullman

A modern EOT or end of train device will allow controlled or simultaneous brake pipe reductions from the rear, too. This type is in development but the current EOTs will allow an emergency application from the rear. No need for a locomotive to apply brakes from the rear.

An EOT would be able APPLY the brakes, but it won't be able to RELEASE the brakes.  To do that you need an air compressor and there is no way an EOT could have that big of an air compressor and hang on a coupler.

gregc

gmpullman

A modern EOT or end of train device will allow controlled or simultaneous brake pipe reductions from the rear, too. This type is in development but the current EOTs will allow an emergency application from the rear. No need for a locomotive to apply brakes from the rear

thanks, i wondering about that too

On CN that feature was tried and found to be problematic, as the EOT's valve would tend to stick open.  This caused a few train separations as the tail end of the train would brake harder as the brake pipe pressure dropped. 

I can also see it causing an unintentional release if the valve stuck open for a bit too long and then shut itself, causing the rear brake pipe pressure to drop lower than intended and then rise again as the pressure-maintaining feature of the locomotive brake valve tried to compensate for it. 

We haven't used it for some years now, and there are standing instructions to disable it if we find a locomotive or EOT that has it enabled. 

It was called "Brake Assist".

SD70Dude

On CN that feature was tried and found to be problematic, as the EOT's valve would tend to stick open.

you would think such a thing should be thoroughly tested and possibly have redundant values so that even if one stuck open the other wouldn't.

on the other hand, if it's designed to be used in case of emergencies, wouldn't it be more important that it is guaranteed to open than closes afterwards?

In principle it's really simple, although people seem to love overthinking it philosophically 

Each locomotive contributes its tractive effort to the load, through whatever behind it is also pulling on the load.  That's how steam locomotives 'divide the effort' when double- or multiple-heading.  When helpers push on the rear it can be just as with DPU; the helpers can 'push' a certain number of cars, the lead consist pulls a certain number of cars, and the point of 'zero slack' between them (where the effective 'tractive' effort goes to zero; we call it the 'node') can move backward and forward, sometimes at high speed, just as most of us have experienced with DP trains.

Conventional diesel-electrics take this a little further: each independent traction motor is geared to a particular axle, and takes up its share of the load automatically.  A relatively modern AC locomotive controls the motors either in groups of 3 (using two inverters) or individually (using six inverters) carefully adjusting the power if urn wheelslip is detected, but otherwise adjusting the traction-alternator field to suit the commanded engine rpm.

Diesels are funny; they use a comparatively high percentage of their developed combustion horsepower for compression, so the faster they turn the more fuel they consume -- loaded or unloaded.  And the eight-notch (actually binary relay logic-determined!) models the action of a solenoid-controlled governor in adjusting engine speed -- via fuel admitted.  (The notch commands a 'governed speed', really a range of speed, and the mechanism of the governor then provides more or less fuel at the injectors to produce that ... but this is engine speed, not wheel rpm or train speed, just available power at a given generator rpm.  (FADEC/EFI does this more intricately, but with an eye toward electrical compatibility with locomotives with mechanical Woodward governors, so the effect is the same.)

Now, there are other considerations about when a consist starts to become a lashup.  One is different effective gear ratio (pinion and bull gear varies just as car differential "rear end ratios" can, and with the same quantization by integral numbers of teeth, with wherl diameter and state of tread wear complicating things) with freight units having higher mechanical advantage.  This mattered more with DC motors, where temperature rise governs minimum rpm and 'centrifugal force' governs maximum rpm ... but remember I said that every axle contributes its own pull?  What the limits mean is that a given consist is load-limited at low speed by the limitations of the least capable axle, and speed-limited by what may be a different least capable axle ... and of course, overall, by the traction the axles can achieve (or fail to achieve for the variety of reasons we've discussed over the years).

What is NOT automatic is the rate at which units in a consist load.  GEs in particular are notorious for avoiding pollution and visible smoke by taking their sweet time to accelerate to speed and then load the engine to needed fuel consumption at that rpm -- in the bad old days this could take 30 seconds or more.  Meanwhile other locomotives can load more quickly -- meaning they take more than their share and nuzzle against or try to run away from slower-loading units.  Theoretically you can engineer most of that behavior out -- but locomotive manufacturers have not made that a control priority...

gregc

 

 

dehusman

The brakes need to be applied to the whole train ASAP to maximize the braking effort and reduce train line forces.  If you apply brakes on the rear end first, then the chances of breaking the train in two is increased.

 

 

this is interesting.

i can understand that it may be ideal that brakes be applied to all cars simultaneously, but my understanding is this is impossile with current air brakes.   

that brakes are applied to cars starting with the cars closest to the source that the brakes are released from.    if there is a single consist at the front of the train, brakes get applied to the front of the train first resulting in "coupler slack (?)" being lost toward the rear of the train and the train "bunching up (?)"    (i don't know wat the proper terms are for these behaviors).

if there are engines at each end of the train, this means from each end and that braking occurs last to cars in the middle of the train.     if there are engines in the middle of the train, it further "equalizes" the application of the brakes resulting in brakes being more evenly "applied to the whole train ASAP".

as an (electrical) engineer i assume that being able to independently control power and braking at different parts of the train would improve control.   i don't assume a (locomotive) engineer  would know what to do with this control, but assume a computer could.   an engineer would tell the computer what he wanted to do and the computer would figure out how

i assume there are certain situtations where this would be most useful possibly going up/down a grade on a curve, cresting a hill or (??)

 

The DP consist(s) can't have their air brakes applied/released independently, but the DP consist(s) can be controlled independently when it comes to power or dynamic braking.  It's possible to place the head end into dynamics while having the DP consist(s) in power. 

The throttle/dynamic brake use and proper use of the air brake can control slack movement in the train.  (At least to a point.  On some of the land barges they like to run now there are places you can do everything right and still break apart.)  Ideally, you want the slack either bunched or stretched.  It's how fast or harsh the changeis made from one condition to the other that can lead to problems like a broken knuckle or pulled out drawbar.

Jeff

 

jeffhergert

It's possible to place the head end into dynamics while having the DP consist(s) in power. 

what do "dynamics" and "power" mean in this context?

jeffhergert

Ideally, you want the slack either bunched or stretched.

doesn't this mean you either want the head end consist pulling the entire train or the trail end consist pushing the entire train?

or is the ideal case where half the cars between two consists are pulled and half pushed,  where all the couplers are stretched in the half cars behind the lead consist and the couplers are bunched in half the cars front of a trailing consist?

do locomotive couplers have strain gauges that report the drawbar force in the cab?

 

 

one of the videos said a benefit of distributed power is to reduce the force on the first coupler between the lead consist and car, allowing much longer trains.   with ~equal power in a trailing consist, this force could be cut in ~half.

does this suggest that if a train were stopped on a slight grade (e.g. 0.1%) where presumbly all the coupler slack was stretched, the trailing consist should run (?) first to remove coupler slack in most of the train before the lead consist begins applying power?

obviously i have no understanding of this except for the physics.   would this never happen, happen often or easily handled by an experenced engineer?

gregc

what do "dynamics" and "power" mean in this context?

Dynamic brakes and power is, well power, the throttle is above idle and pulling.

gregc

doesn't this mean you either want the head end consist pulling the entire train or the trail end consist pushing the entire train?

Not if you have multiple powered consists.  The whole idea of helpers or DP is to not have the head end consist doing all the work.

gregc

do locomotive couplers have strain gauges that report the drawbar force in the cab?

No.

gregc

...what do "dynamics" and "power" mean in this context?

Dynamic braking and motoring, respectively.  He means you can have the head-end consist trying to slow down 'electrically' while a DP consist is actively pushing at the same moment.  As Jeff noted this would have the effect of getting more and more of the slack bunched, without necessarily involving any use of either the independent or automatic air brake.

And yes, you could keep the head end in dynamic and the rear in some power notch even after the slack had run in.  This would be like having the rear pushing on the whole of the train resistance plus the braking resistance of the lead locomotives -- wasteful in a sense, but safe within limits (which Jeff can describe far better than I could try to do).

doesn't this mean you either want the head end consist pulling the entire train or the trail end consist pushing the entire train?

"Technically" that's exactly what it comes to, but it does not mean carrying the entire load of the train, just enough of it to compress (or stretch) all the draft gears in the cars consistently, something that involves far less power.

In particular this gets around the issue in long trains where you have a mix of grades and resistance that has parts of the train in 'tension' and other parts in 'compression'.  I remember an engineer on either CNJ or LV explaining that there might be four or more such variations in a particular train... and part of professional train handling involved both recognizing and knowing how to manage the consequences.

[/quote]...or is the ideal case where half the cars between two consists are pulled and half pushed, where all the couplers are stretched in the half cars behind the lead consist and the couplers are bunched in half the cars front of a trailing consist?[/quote]For best theoretical economy you might run that way, and I often see (and hear) things like unit coal trains with reasonably consistent drawbar characteristics and no irregular patches of long-travel cushioned draft gear that are running with the node 'balanced' at the point corresponding to the power distribution.  (For example we had loaded trains westbound on the ex-Southern from just east of the University of Memphis campus to Collierville that ran with 2 units on the point and one DP rear, and the node could be observed to be about ⅔ back in the train as it ran over the somewhat irregular track profile.

However even slight power or speed changes could and did result in noticeable banging as the node moved, sometimes at surprisingly high speed, forward or back in the train.

do locomotive couplers have strain gauges that report the drawbar force in the cab?

My understanding was that the computer gets the information differently.  For example in a locomotive with good zero-weight-transfer truck design, the tractive effort is produced in the trucks and communicated to the frame (ideally around axle level) before it even gets to the draft gear.  So instead of complicating a sliding contact subject to draft and buff shock you could just rig your strain gage, LVDT or whatever in a controlled location in the locomotive.  You might PM Dave Goding (bogie engineer) as he has practical experience touching on this over a long range of technological development.

one of the videos said a benefit of distributed power is to reduce the force on the first coupler between the lead consist and car, allowing much longer trains.   with ~equal power in a trailing consist, this force could be cut in ~half.

does this suggest that if a train were stopped on a slight grade (e.g. 0.1%) where presumbly all the coupler slack was stretched, the trailing consist should run (?) first to remove coupler slack in most of the train before the lead consist begins applying power?

I believe to be more consistent with the physics described you'd indeed throttle the DP independently to start pushing the rear, but would start the front end in such a way as to get the node in the right place as above and then keep it roughly there as the train continues to accelerate and encounter stretches of up and down grade, curvature, changing train resistance, etc.  How the actual safe priority is done in real-world train handling I leave for the real-world engineers to explain better.