Train weight and pulling power

tree68

I've also heard that HP=speed.  This is where the HP/ton factor comes into play.  If you want to get the load over the road quickly, pile on the HP.  If you just want to get the load over the road, put on just enough power to do so.

monon99

With the train stretched on a grade it can be tough to restart a train. Sometimes sand, a little independent brake to keep the wheels from hopping, will get the job done.

If your power just doesn’t have the grunt(let’s say an emd), you can set a little air, shove back gently to bunch the train, set full service when the eot beeps and says movement.

Now take a deep breath, let everything settle down. Go to suppresion on the air brake, wait for that to settle, no hissing. You will get a “slow release” like from a minimum set. Brakes will now release one car at a time from the head end to the back(assuming no dp). Now you can throttle out and start moving a few cars at a time. You better have a good feel of your train. Gradually you can move the whole thing.

I’ve used this a lot on the hilly Monon subdivision, thankfully the skilled hoggers who worked that line taught me well.

 

Thanks. I was wondering if that sort of thing was ever done.

With the train stretched on a grade it can be tough to restart a train. Sometimes sand, a little independent brake to keep the wheels from hopping, will get the job done.

If your power just doesn’t have the grunt(let’s say an emd), you can set a little air, shove back gently to bunch the train, set full service when the eot beeps and says movement.

Now take a deep breath, let everything settle down. Go to suppresion on the air brake, wait for that to settle, no hissing. You will get a “slow release” like from a minimum set. Brakes will now release one car at a time from the head end to the back(assuming no dp). Now you can throttle out and start moving a few cars at a time. You better have a good feel of your train. Gradually you can move the whole thing.

I’ve used this a lot on the hilly Monon subdivision, thankfully the skilled hoggers who worked that line taught me well.

SD70Dude, right about the SD40-2. A yard that I watched for a long time had a SD40-2 switcher, then changed to an SD60, now have to ease starts to move the same amount of cars.

What is the HP rating of a typical car-moving winch?

No need for 5 horsepower -- a 0.1-horsepower person can move a train if his winch rope runs around a sufficient number of pulleys.

Power is force times speed -- in other words, force is power divided by speed. If you can accept the necessary low speed, you can produce any needed force from any power source. As long as power remains constant,  you can double the force by halving the speed, and you can keep doing that forever.

tree68

I've heard that a 5 HP Briggs and Stratton could move a sizeable train (on flat ground) given the traction and suitable gearing.  Not fast, but it could move it.

I've also heard that HP=speed.  This is where the HP/ton factor comes into play.  If you want to get the load over the road quickly, pile on the HP.  If you just want to get the load over the road, put on just enough power to do so.

Watched a B&O SW-1 with all of 600 HP and 30 years service move 8700 tons of cement out of Clark Ave. Yard in Cleveland to Brooklyn - of course it took 3 hours to go that 5.7 miles.

I've heard that a 5 HP Briggs and Stratton could move a sizeable train (on flat ground) given the traction and suitable gearing.  Not fast, but it could move it.

I've also heard that HP=speed.  This is where the HP/ton factor comes into play.  If you want to get the load over the road quickly, pile on the HP.  If you just want to get the load over the road, put on just enough power to do so.

i agree

my point is that the drawbar force is not proportional to horsepower.   it's inversely proportional to speed. 

so maximum force is at the lowest speed and of course limited by max tractive effort (i.e. weight on drivers)

No diesel locomotive can generate full horsepower at its wheelrims at 1 mph. At 30 mph today's 4400 hp locomotives can produce maybe 3800 hp at the wheelrims; at 1 mph, 3800 hp would be 1,400,000 pounds of TE.

gregc

my understanding is that max horsepower in a diesel locomotive is available at any speed.   Horsepower is work / time.    work is force multipled by distance

Maximum 'horsepower' in a diesel locomotive is imposed by the characteristics of the prime mover.  But the curve close to zero road speed is nowhere near as extreme as often drawn (especially in early EMD 'propaganda') as the effective instantaneous 'tractive force' (which is the only thing that matters when calculating resultant with train resistance) is both adhesion- and traction-motor limited.

Even with AC drives there are some limitations on the practical near-locked-rotor torque that can be produced from "maximum horsepower for traction" at the motors (e.g. from the combustion engine through the generator, inverter system, and cabling losses).  If you look at how AC motors generate torque off synchronous speed you will understand the electrical 'slip' involved; modern synthesis drives can maximize the effective torque at a given speed.

Of course, you're familiar with DC motor limitations, which are far more severe, and dramatically limit both applicable torque and effective duty cycle below about 11-12mph road speed.

There are ways to overcome much of the low-speed disadvantage of the reciprocating steam locomotive -- some of which are nominally wasteful of steam mass flow and 'associated considerations' but which can be made efficient with the correct forms of traction control and valve gear.

Lithonia Operator

Now the train is stopped on the ruling grade, with no slack. Can the engineer get the train going?

my understanding is that max horsepower in a diesel locomotive is available at any speed.   Horsepower is work / time.    work is force multipled by distance

at least on level grade, the force applied needs to overcome the friction of the bearings which is dependent on speed.   But consider, for a moment that the friction, hence force is constant at any speed.   Then the horsepower required depends on the work being done and is proportioinal to the distance the force is applied over

this means half the horsepower it required at half the speed, or that twice the force is available at half the speed.

when going up a grade, when force must also overcome a percentage of the weight of the train, the available horsepower will limit the distance the train can move at the higher force.

so when facing a steep grade, the distance traveled per unit time may be small, but not zero.

of course this is not true for a steam locomotive where horsepower is not constant and depends on speed. 

GARY WHITT

Tree, I was just browsing around. I am from Milford MI. also.

MHS Redskins, Class of '68.

I used to live on the south side, at the top of the hill.  

A discussion that probably belongs in the Classic forum, however, it speaks to some timeless issues, no matter the motive power being used.

https://www.youtube.com/watch?v=AkBX5JTS60A&feature=youtu.be&fbclid=IwAR3LQKl28EhsFdIAcXzy0hWHfNz_TwoCLyncAppK5AGw1GZD7qXiBPjMmys

Lithonia Operator

Let's take your average freight train, in this case one that has enough locomotive power to deal with the ruling grade on the line (according to guidelines), but not much more.

1) Let's say that on level ground, the engineer rolls forward slowly, taking up slack. Then, once all slack is stretched out, he stops without  letting any slack occur. The train is fully stretched out. (This is hypothetical.) Could he now start the train moving, all at once?

If the answer to the above is Yes, let's say this train proceeds until it is on the ruling grade and suddenly the engineer needs to bighole it. (Let's say he sees people on the track, but stops before hitting them, then the people leave.) Now the train is stopped on the ruling grade, with no slack. Can the engineer get the train going? Or will they have to double the hill?

 

Another thing to remember about slack...  There is free slack which is the just the small bit of space between the parts in the coupler and draft gear.  That actually doesn't add up to all that much in the train.

Most of the slack is from the draft gear.  In the old days, it was a spring.  Now, it is rubber pads.  It's main job is to protect the freight car from damage when coupling.  It cushions the blow so you can couple up at a few mph and not destroy anything.  So, when you take slack, you are compressing all the draft gear (actually shearing rubber pads in one direction).  When you have the train stretched, you have the draft gear extended some.  When you start to pull, you are actually extending the draft gear some more - so you never really have a "solid" train, it's always a bit of a slinky.

zugmann

BigJim

Why not? Ours were.

 

But they were for when the locomotive was fresh out of the factory floor.  Oh yeah, those 2 beater C40-8Ws are good for that train!  (maybe 20 years ago, and with sand, and with a hill that isn't covered in wet leaves).  Some of those engines were so ragged they could barely pull themselves.  

Not around here. If the units weren't having some electrical or mechanical problem, they would pull what they were rated. 
The only problems I ever remember having trouble with were a couple of foreign units from out west that wouldn't pull a greasy string out of a cat's petoot!

timz

The 1987 CSX empl TTs did show ratings. As I recall an SD50 was rated 18000 tons eastward over the Magnolia Cutoff, where the eastward climb is about 0.1% compensated.

Magnolia Cutoff - 

MILLR4  CUMBO4 BAQ  0  BAQ 12   6950   7950  10600 12600 13750 17450 18550 20100

The 1987 CSX empl TTs did show ratings. As I recall an SD50 was rated 18000 tons eastward over the Magnolia Cutoff, where the eastward climb is about 0.1% compensated.

CSX didn't put tonnage ratings in the ETT.  However, they did have tonnage ratings, both as head end power and as helper power (on territories when manned helpers were required).  Note - CSX was not using DPU before I retired so I am unfamiliar with how they are rating units use in DPU service.

WEVERN  WCUMB1 BA  79  BA 109   2800   3200   4300  5100  5550  7050  7500  8150

CUMBOY  BRUNSY BA 105  BA  76   3950   4500   6000  7150  7800  9900 10500 11400

CUMBOY  CUMBED BA 105  BA 178   4600   5250   7000  8300  9100 11550 12250 13300

MILLR1  CUMBOY BA 115  BA 105   2900   3300   4400  5200  5700  7250  7700  8350

NORBRN  MILLR1 BA 177  BA 115   9900  11250  15000 17850 19500 24750 26250 28500

MILLYL  HAGEWM BAE107  BAS111   2500   2850   3800  4500  4900  6250  6650  7200

MILLR4  CUMBO4 BAQ  0  BAQ 12   6950   7950  10600 12600 13750 17450 18550 20100

MILLMN  HAGEWM BAS 34  BAS111   2500   2850   3800  4500  4900  6250  6650  7200

HIGHWM  HAGEWM BAS 93  BAS111   2150   2450   3300  3900  4250  5400  5750  6250

HAGEWM  MILLYL BAS111  BAE107   4600   5250   7000  8300  9100 11550 12250 13300

HAGEWM  MILLMN BAS111  BAS 34   4600   5250   7000  8300  9100 11550 12250 13300

HAGEWM  PORTWM BAS111  BAS 49   1500   1700   2300  2700  2950  3750  4000  4350

HAGEWM  LURGWM BAS111  BAV 32   3300   3750   5000  5950  6500  8250  8750  9500

LURGWM  HAGEWM BAV 32  BAS111   2200   2550   3400  4050  4400  5600  5950  6450

CUMYD2  CONPAY BF 179  BF 270   1350   1550   2100  2500  2700  3450  3650  3950

ROCKWA  JOHNSA BF 227  BFC 45   1900   2150   2900  3450  3750  4750  5050  5500

CONPAY  CUMYD2 BF 270  BF 179   1900   2150   2900  3450  3750  4750  5050  5500

CONPAY  NEWCAY BF 270  BG  58   6900   7850  10500 12500 13650 17300 18350 19950

BRADDA  FAIWVY BF 320  BS 302   1950   2250   3001  3550  3900  4950  5250  5700

GLEJUN  EDGEPA BF 323  BG  53   1650   1900   2550  3000  3300  4200  4450  4800

GLEJUN  WASPAA BF 323  BO  35   1350   1550   2100  2500  2700  3450  3650  3950

JOHNSA  ROCKWA BFC 45  BF 227   1900   2150   2900  3450  3750  4750  5050  5500

CALLEN  GLEJUN BG  25  BF 323   1900   2200   2950  3500  3800  4850  5150  5600

CALLEN  NEWCAY BG  25  BG  58   5600   6400   8550 10150 11100 14100 14950 16200

EDGEPA  CALLEN BG  53  BG  25   5600   6400   8550 10150 11100 14100 14950 16200

NEWCAY  CONPAY BG  58  BF 270   5900   6750   9000 10700 11700 14850 15750 17100

NEWCAY  WILLAE BG  58  BG 204   4000   4550   6100  7250  7900 10050 10650 11550

STERLN  NEWCAY BG 155  BG  58   3150   3600   4800  5700  6200  7900  8400  9100

WASPAA  GLEJUN BO  35  BF 323   1350   1550   2100  2500  2700  3450  3650  3950

FAIWVY  BRADDA BS 302  BF 320   1950   2250   3001  3550  3900  4950  5250  5700

FEDONZ  BROWPA BTC  6  PLM 61   1950   2250   3001  3550  3900  4950  5250  5700

ASHTAB  CONNEA PLC  1  QD 115   4350   4950   6650  7900  8600 10950 11600 12600

ASHTAB  PAINSV PLC  1  QD 153   4350   4950   6650  7900  8600 10950 11600 12600

BROWPA  FEDONZ PLM 61  BTC  6   5900   6750   9000 10700 11700 14850 15750 17100

CONNEA  ASHTAB QD 115  PLC  1   4350   4950   6650  7900  8600 10950 11600 12600

PAINSV  ASHTAB QD 153  PLC  1   4350   4950   6650  7900  8600 10950 11600 12600

The above are the tonnage rating for portions of the CSX Baltimore Division and adjacent territory.  The First 2 columns are mnemonics of the origin and destination of the particular rating.  The next 2 columns are the assigned milepost designations for the origin and destination.  The succeding columns are the ratings for each class of locomotive from 4 axle GP40's to 6 axle AC60CW's.  I have lost the specific designation for each column of the ratings.  Note, the ratings can and in many cases are different for different directions.

BigJim

Do you really think that every engineer out there starts the cab before the engine?

Not sure I understand the question.  

Even though we generally run 4-5 car trains (13 for Polar), I try to get the slack out before I notch out.  But I'm not running 60+ car trains with significant slack between each car.  As I noted, even having the floor underneath you go from zero to just walking speed in a split second could cause some balance issues.

BigJim

Why not? Ours were.

But they were for when the locomotive was fresh out of the factory floor.  Oh yeah, those 2 beater C40-8Ws are good for that train!  (maybe 20 years ago, and with sand, and with a hill that isn't covered in wet leaves).  Some of those engines were so ragged they could barely pull themselves.  

BigJim

 

tree68

All  I know of that is what I've read.

That explains a lot!
Do you really think that every engineer out there starts the cab before the engine?

I have ridden in cabs a number of times - some starts were gentle, some were less than gentle - you soon learned where the welded rail was and wasn't.  Depending upon the engineer and the train - the inroute slack action could be severe.

timz

By the way: the tonnage ratings in the timetable are just for show -- don't assume they're realistic.

timz

Do they ever assign tonnage that the engine couldn't start,

tree68

All  I know of that is what I've read.

Gotta tell my Mom's story... when she was young (6 or 7) her family moved from Indiana to Kansas.  Her Father and brother drove a truck with their belongings while her and her Mother took a train; they rode as paying passengers in a caboose of a freight train.  (She said they saw her Father and brother waiting at grade crossings a couple of times on the trip.  She waived, but they didn't see her.)

At one stop, she said she was up prancing around, trying to stomp on flies, which were thick in the caboose on the hot summer afternoon.  A man in a dark blue suit came in the back door and told her, "Little girl, you'd better sit down."  She said she had been told not to talk to strangers and she was not about to pay any attention to this man.  "Who was he to tell me what to do!"  She turned around to face the other end of the caboose and continued stomp at flies.

A moment later she heard some banging coming from the front of the train and she suddenly was sitting on the floor.  She got up and sat next to her mother.  But she had a hard time sitting still because her bottom hurt.  She said that the man in the dark blue suit laughed at her, but she would not look at him.

I never thought to ask her if she was able to kill any flies stomping on them or in the act of suddenly sitting on the floor.

timz

Do they ever assign tonnage that the engine couldn't start, if it happened to get stopped on the steepest upgrade? Dunno how often they do it now, but it used to be common on UP coal trains east from Cheyenne. The climb is 2.7 miles averaging 0.65% compensated, and a pair of SD40-2s would use momentum from the preceding downgrade to take 13000 tons over the top.

Offhand, I can think of at least two locations between Edmonton and Vancouver that have short westbound stretches of 0.6% or 0.7%.  They are both on single track, so it is rare for a train to stop there, but some have stalled in the past.  

Soon after this type of operation began, the 0.4 HPT AC-powered trains 'discovered' a bunch of new places where it is a bad idea to stop them in the rain.  

I would go so far as to say that higher horsepower modern locomotives are getting back into the steam territory of being able to move a greater tonnage than they can start.  Especially when it is raining or they are out of sand.

On that note, I have never used up a full sandbox's worth on one shift, but I have seen a number of locomotives run out enroute, or simply get released from the shop with no sand at all.

When starting a train and at low speeds, horsepower really doesn't matter as much as weight-on-drivers and wheelslip control.  From experience switching with each of them, I think a SD40-2 would out-pull a SD60, Dash-8 or Dash-9, and be about equal to a SD70.

A 1800 HP GP9RM-slug pair will out pull any of the above at slow speeds, despite having less than half the HP.  Why?  It weighs more, and has two more traction motors.

timz

When UP had ratings in the Spec Instr a few years ago, they said GP60s were good for 3400 tons on 1%.

Lol ok.  

Maybe as long as the train kept moving above 30 mph, but we know how realistic that is.

Do they ever assign tonnage that the engine couldn't start, if it happened to get stopped on the steepest upgrade? Dunno how often they do it now, but it used to be common on UP coal trains east from Cheyenne. The climb is 2.7 miles averaging 0.65% compensated, and a pair of SD40-2s would use momentum from the preceding downgrade to take 13000 tons over the top.

By the way: the tonnage ratings in the timetable are just for show -- don't assume they're realistic. When UP had ratings in the Spec Instr a few years ago, they said GP60s were good for 3400 tons on 1%.

BigJim

tree68

Starting from bunched, however, is one reason cabooses are gone.  The last car in the train would suddenly go from zero to however fast the locomotive had gotten up to - often enough to knock crew members off their feet.

 What a crock of BS! Where do you guys come from???

A good engineer would gently pull out the slack until the rear notified him that the cab was moving.

If the floor under you goes from zero to even 5 MPH in an instant, you'll notice.  

And recall that back in the day, there were no radios...

All  I know of that is what I've read.   And slack action, accidental or intentional, was a problem.