independent brake response times

gregc

my understanding is there are 5 independent brake settings: quick-release, slow-release, lap, slow-application and quick-application.

It would be interesting to see how 'quick' application or release differed physically or pneumatically from ordinary independent application -- is this something specific to large MUed consists (e.g. the reason you keep the ring up a second or two 'for every unit in the consist' on a P42)?

Lap of course would hold the straight-air application 'applied' (less any leakage of course).

gregc

my understanding is ithere are 5 independent brake settings: quick-release, slow-release, lap, slow-application and quick-application.

no, that's not how that works on anything I've used or seen? 

1946 Victoria Railways Westinghouse Automatic Air Brake

description of driver's straight air brake valve

Ok, so you're talking about old stuff.  

zugmann

old stuff.

Interesting premise, though.  Zug, would there be practical advantage here to having a two-range proportional brake?

Overmod

Interesting premise, though.  Zug, would there be practical advantage here to having a two-range proportional brake?

I like having full control of my independent. 

zugmann

I like having full control of my independent.

I'd think that might suck.

Greg,

Where do you come up with this oddball stuff?

Now, to answer your question about independent brake response times...the response time is directly proportional to the number of diesel units in the consist that are mu'ed with the "A&R" hose cut in.

In other words, the response time of a single unit is immediate, that of five units cut in takes much longer. That is because the air signal between units must travel and fill a much longer air line.

trying to understand how a loco is controlled.   i'm an EE.   i ask technical quesitions and hope to get technical answers from people with experience

BigJim

In other words, the response time of a single unit is immediate,

does that really mean you have 100% braking immediately in the first unit or a single switching loco?

based on application-quick and application-slow, my impression is that brake % increases gradually the longer the brake is held in an application setting.

so it takes some time to increase brake % to some desired level (i.e. %) and it takes some time for a train to stop with the brakes set to some level (%) 

Overmod

 

 

zugmann

I like having full control of my independent.

 

 

Hey, wait a minute... is that Australian system description saying it has only two rates of application and release?  And that it's not self-maintaining?  And by implication there's no relationship between the position of the independent brake handle and the amount of brake currently applied?

 

I'd think that might suck.

 

 Yeah that would be like driving a car where your only options are a light braking force or stomp the pedal as hard as you can. Granted, my boss at my first job drove pretty much like that - time to move, stomp the gas pedal. Hold until halfway to destination, then let go and stomp brake pedal. Dunno if that is some typical style of Romanian driving (he was from Romania) or what - he was an EE, but not a digital specialist so I don't think it was just a binary thing.

 Everything I've seen with indepedents is they are proportional to the amount the valve is opened, unless you press the handle down to bail off so the incoming slack doesn't slam into the loco, which will stop a lot faster than all those cars behind you. I need to ask next time I get to the museum if the LEMTU (Locomotive Engineerr Mobile Training Unit) car is actually functional, if it can be powered up so the controls actually do something instead of move - it has control stands for two types of EMD, an Alco, and a Baldwin I think. All housed in a converted baggage car. There are also lots of contactors and even cab signals. Back when it was in use, they would take it to various places to teach new enginemen how to run the various locos. Half is a classroom, the other half has the various control stands. Can't pull any info from the web page any more - half says under construction. A bunch of years ago, I was in the running to take over maintaining the web site, but they gave it to a guy who is more of a web designer than I am. And now it sits... and I'm assistant treasurer (ok, everyone, even engineers, had to take Eco 1 in college...).

                                   --Randy

rrinker

Yeah that would be like driving a car where your only options are a light braking force or stomp the pedal as hard as you can.

not sure how you're coming to that conclusion.

there's a slow and quick application setting that would more slowly and more rapidly increase the air flow into the independent brake cylinders increasing the brake force until setting the brake handle to LAP.

similarly, slow and quick release allows braking to be decreased without dropping immediately to zero (%).

while this model has specific slow and quick settings, it seems that other units (e.g. S-40 pg B-6) have a continuous range of settings from lap to full release and lap to full-application, some self-lapping.

with a continuous self-lapping model, i'm curious how long it would take to reach the self-lapping pressure for a specific setting and what the brake % is

  If you gently press the brake pedal in a car, you get a gently increasing braking action. The car stops - eventually. If you nail it hard, you get a rapidly increasing braking force. The car stops, pretty quickly. With only two levels of air introduction into the system, you have just those two options - gently add more, or rapidly add more. With a more typical proportional valve, you have any rate of braking force you want, from the slightest amount to a "we gotta stop NOW". The NYAB document I linked below goes into the construction of the brake valve and how it actually works (also covers the train brake). It does make great use of air system schematic symbols, which I've forgotten most of, so at a quick glance I can't really decipher the whole thing. There are also cutaways of the valves, so more than a quick glance may reveal the answers.

 The brake application across multiple units is faster than might be expected, since the independent brake includes air relays. Applying the air in the lead loco doesn;t have the same delay if it were actually supplying pressure to the 4th unit back in the cosist - instead it supplies a signal to the relay which supplies the air to the brake cylinders from the loco air reservoir.

Microsoft Word - IP-74 Supp 1.doc (nyab.com)

CONTENTS (wplives.org)

                                        --Randy

BigJim

Greg,

Where do you come up with this oddball stuff?

Now, to answer your question about independent brake response times...the response time is directly proportional to the number of diesel units in the consist that are mu'ed with the "A&R" hose cut in.

In other words, the response time of a single unit is immediate, that of five units cut in takes much longer. That is because the air signal between units must travel and fill a much longer air line.

 

I suspect this is not an MU system. 

I have operated brake like this on old electric railway equipment. My guess is it was meant for running trains without an effective trainline.

rrinker

  If you gently press the brake pedal in a car, you get a gently increasing braking action. The car stops - eventually. If you nail it hard, you get a rapidly increasing braking force. The car stops, pretty quickly. With only two levels of air introduction into the system, you have just those two options - gently add more, or rapidly add more.

you seem to be suggesting that application-slow or quick are two pressures applied to the brake cylinder instead of the "rate" the brake pressure increases.   

application-slow will increase the brake % until it reaches 100%.   it takes less time with application-quick.   you can stop increasing the brake % by moving to LAP

did you look at the link to 26L Brake Equipment  in my previous post

Randy Stahl

I suspect this is not an MU system. 

Greg,
If you are speaking of a U.S. loco, forget all of that crap that you posted in your first post. It does not apply here.

"does that really mean you have 100% braking immediately in the first unit or a single switching loco?"

Yes! On a single unit, you will feel every move you make, from full release to full application and everywhere in between, with the independent brake valve as soon as you make it. It is when you add more units with their brakes cut in that you feel the response time slow down.

"The brake application across multiple units is faster than might be expected, since the independent brake includes air relays. Applying the air in the lead loco doesn;t have the same delay if it were actually supplying pressure to the 4th unit back in the cosist "

rrinker,
Well, that is a bit confusing! 
The independent brake is controlled by the lead unit (usually). The lead unit sends an air signal to the control valve of every unit in the consist. That signal has a maximum air pressure of 60 psi. That is why you can have multiple unit operation. That "signal" is then translated by the locomotive control valve, of which there are many types and each operate the brake cylinder at a different pressure. But this is not the point.

The point is, that the "signal" from the controling unit has to pass to each unit that the independent brake is cut in on. Consquently, the more units, the longer it takes to fill the "Apply & Release" trainline in order for the brakes to apply and release.

Just try switching with six units with their independent brake cut in. It takes what seems like forever (although it is really not that long) for the brakes to apply and release. A crew doing the same job with only one unit could out switch you so fast that it would make your head spin! Just because the indendent brake doesn't have to supply valuable signal air to trailing locomotives.

"my understanding is ithere are 5 independent brake settings: quick-release, slow-release, lap, slow-application and quick-application."

Maybe on steam engines, and early diesels and electric-powered switchers, but not on any engines I ever ran (starting in 1979, and some of them were switch engines dating back to the late 1940's).**

On engines from the late 40's onward, the independent brake had (from left to right)

- release (you could also remove the handle in this position)

- application zone (cylinder pressure increases as handle moved to right)

- full application (handle couldn't be moved any further)

... and that's all. No "lap" at all.

In addition, depressing the handle (at any position) was the "bail off" feature, and would either partially or fully release the engine brakes regardless of the automatic brake application.

** I was on an old New York Central S2 electric once at Croton, dating back to the original NYC electrification of around 1904 (or 06?), and I believe it had an older-style independent with a "lap" position.

Just for the record, I think the "Westinghouse" referred to here is the British Westinghouse Ltd., which was run by Metropolitan-Vickers after 1919.  It may bear little resemblance to anything the Westinghouse company here offered by 1946.  

I can see how desire for foolish consistency might want the locomotive brake to work 'the same' as locomotive-and-train brake -- and how a slow-speed position either side of 'lap' would be a fine answer to having to build a proportional setup.

I used to run an engine equipped with #6 ET brakes. The independent was as simple as simple can be. It responded as quickly as the air pressure could build up against the brake pistons (3 in this case) to about 45 pounds. Probably twenty to twenty-five seconds. Half that time in Quick Apply. I don't recall having to use quick application very often.

gregc

for example, would quick-application take 5 seconds to go from 0 to 100% braking?

100% braking will just get you flat spots in most cases and probably won't get you stopped any sooner.

6_ET by Edmund, on Flickr

The positions between running and release were spring loaded to return the handle to the running position. Likewise the position between Slow Application and Quick Application was spring loaded to return the handle to Slow Application.

I hardly ever recall using the lap position, maybe a little if you wanted to hold a light application but there was seldom a need to. The independent was primarily used when the engine was running light OR to keep the engine brakes bailed off (there was no bail-off on the automatic) while applying the train (automatic)  brakes.

Overheated driver tires were frowned upon.

6_ET_0001 by Edmund, on Flickr

Good Luck, Ed

Overmod

Just for the record, I think the "Westinghouse" referred to here is the British Westinghouse Ltd.,

I believe that the brake system that Greg is referring to is the A-6-ET, introduced in 1908, and is American as apple pie!

https://en.wikipedia.org/wiki/Railway_air_brake#/media/File:Westinghouse_Air_Brake_piping_diagram.jpg

There is a figure of  brake-valve handle positions, in my 1944 copy of the NZGR Air Brake Handbook, similar to the one Ed posted.

the Bear. 

Thank you, Bear. I'll show you MY pedestal (Yours looks like a No. 8, mine's only a No. 6)

6_ET-pedestal by Edmund, on Flickr

The one I'm familiar with wasn't pedestal mounted, though. It was a 1918, USRA locomotive.

Cheers, Ed

I can't quickly find a photo for conslusive proof Ed, but I'm 99.7% that those pedestals would be found on the Ka and Ja steam locomotives locomotives that were still in operation in the late 60s, early 70s.

Cheers, the Bear.

gmpullman

I used to run an engine equipped with #6 ET brakes. The independent was as simple as simple can be. It responded as quickly as the air pressure could build up against the brake pistons (3 in this case) to about 45 pounds. Probably twenty to twenty-five seconds. Half that time in Quick Apply. I don't recall having to use quick application very often.

yes, the green books says A-6-ET

~20 seconds, that's helpful

thanks

I have operated this system on old electric engines.

Before we go round and round too much more, here is a link containing how familiar and reasonably modern 26-L independent brakes are controlled (p.15):

http://www.tcrc320.org/MEMBERS/2006_LET_complete_Workbook.pdf

Oh joy!  I don't need to post any long complicated technical stuff that drives some posters nuts.  Here is technical information on 26-L from NYAB (don't bother reading if this stuff doesn't interest you):

http://www.nyab.com/media/nyab_1/documents_1/technical/instructionpamphletsip/ip_074.pdf

Zug or other real railroaders can tell you how long it takes for a control-valve change to be reflected in 'shoes biting' or measurable braking-effort change.

There's a rule that when you start bailing off the independent, you wait at least 1 second for each MUed unit in the consist.  (You see this mentioned in a number of contexts.)  This is not the same thing as the 'release speed' I think you want.

Overmod

Zug or other real railroaders can tell you how long it takes for a control-valve change to be reflected in 'shoes biting' or measurable braking-effort change.

Depends on the locomotives, hwo fast you are going, how good the brake shoes are, how they are adjusted, the weight you are trying to stop, grade, how slippery the rail is, and probably a few more I'm forgetting. 

zugmann

 

Overmod

Zug or other real railroaders can tell you how long it takes for a control-valve change to be reflected in 'shoes biting' or measurable braking-effort change.

Depends on the locomotives, hwo fast you are going, how good the brake shoes are, how they are adjusted, the weight you are trying to stop, grade, how slippery the rail is, and probably a few more I'm forgetting.

Most of our engines (GP-whatevers), if you slap the handle from release to full on, maybe a second to get max pressure? Then another second or two for the slack to run in and knock your coffee off the control stand.   I never timed it.  Widebodies may be a little longer? 

Didn't I say that in my first post...hmmm?