erikem Chuck,Where did you go to college/university? I got my BS-EECS from UC Bezerkeley in '76 and MSNE in '78. Had an interesting time in the lower division Materials Science class - lots of interesting stuff, though some of my EE classmates complained about having to learn the ins and outs of concrete. It was also amusing to note that one of the authors of the textbook used for the course, Craig Barret, went on to head Intel.As far as rail heating - the heating will come from the inelastic bending of the steel (the hysteresis that Paul mentioned). The upper limit for rail heating an be estimated from rolling resistance - the heat losses from rolling resistance will be distributed among rail heating, wheel heating, journal bearing heating, etc.Edit: Did some numbers off the top of my head, looks like the thermometer would have to be pretty sensitive to measure the temperature rise on stiff straight track - on the order of 0.1 degree F (or less) for a 10,000 ton train. Temperature rise for curved track would be higher due to increased wheel-rail friction losses.
Chuck,
Where did you go to college/university?
I got my BS-EECS from UC Bezerkeley in '76 and MSNE in '78. Had an interesting time in the lower division Materials Science class - lots of interesting stuff, though some of my EE classmates complained about having to learn the ins and outs of concrete. It was also amusing to note that one of the authors of the textbook used for the course, Craig Barret, went on to head Intel.
As far as rail heating - the heating will come from the inelastic bending of the steel (the hysteresis that Paul mentioned). The upper limit for rail heating an be estimated from rolling resistance - the heat losses from rolling resistance will be distributed among rail heating, wheel heating, journal bearing heating, etc.
Edit: Did some numbers off the top of my head, looks like the thermometer would have to be pretty sensitive to measure the temperature rise on stiff straight track - on the order of 0.1 degree F (or less) for a 10,000 ton train. Temperature rise for curved track would be higher due to increased wheel-rail friction losses.
After getting what I thought was a useless degree and working in the broadcasting biz for a few years, I came back down from Hollyweird to SUDS (or SDSU) and did a BSEE about 30 years ago, then moved out to UCSD for grad school, then into defense contracting because I had educated myself out of show biz, though that was still the most fun part of life.
I suspect, based only on engineering experience and such, that rail heating due to the bending process is probably insignificant, even with respect to flange action. I am not curious enough to take an IR thermometer and do before and after measurements; we don't have trains long enough or heavy enough down here to be interesting anyway.
erikemPaul_D_North_Jrerikem I recall that pennies left on the rail head were pretty darn hot after being flattened by the train. Were the pennies placed there on a sunny day ? Are you sure that they weren't warmed by the rail's basic temperature, as opposed to the train's wheels ? Once the pennies were flattened, they wouldn't deform any more = not absorbing any more energy. Plus, being copper they would release the heat pretty quickly. My recollection (this was pre-Amtrak) was that we did this at night and presumably the rail had a chance to cool down. If my less than perfect memory serves me, we were waiting for the southbound San Diegan at Anaheim and the pennies were overun by a northbound San Diegan.FWIW, I've done a fair amount of track work at OERM in Perris, CA and am all too familiar with how hot steel can get in the hot sun.
Paul_D_North_Jrerikem I recall that pennies left on the rail head were pretty darn hot after being flattened by the train. Were the pennies placed there on a sunny day ? Are you sure that they weren't warmed by the rail's basic temperature, as opposed to the train's wheels ? Once the pennies were flattened, they wouldn't deform any more = not absorbing any more energy. Plus, being copper they would release the heat pretty quickly.
erikem I recall that pennies left on the rail head were pretty darn hot after being flattened by the train.
Were the pennies placed there on a sunny day ? Are you sure that they weren't warmed by the rail's basic temperature, as opposed to the train's wheels ? Once the pennies were flattened, they wouldn't deform any more = not absorbing any more energy. Plus, being copper they would release the heat pretty quickly.
My recollection (this was pre-Amtrak) was that we did this at night and presumably the rail had a chance to cool down. If my less than perfect memory serves me, we were waiting for the southbound San Diegan at Anaheim and the pennies were overun by a northbound San Diegan.
FWIW, I've done a fair amount of track work at OERM in Perris, CA and am all too familiar with how hot steel can get in the hot sun.
Those pennies are being heated up by the flattening/deformation.
You can demonstrate the same effect by taking a paperclip and bending it back-and-forth until it breaks. The ends will be warm (even uncomfortably hot, if you did it quick-enough). The heat energy comes from the mechanical work you did in the bending; while a large fraction of said work goes into rearranging the atomic structure of the paperclip (or penny), a portion is turned into "heat" (i.e., vibrations of the atoms in-place).
Note that the pennies never really stop deforming as each subsequent car runs over them; it's just that in each case, they have already been spread out/deformed, and subsequent deformations will have less material at any instant to flatten out further (only the material at the contact point between the rail and the wheel is being flattened out). Eventually, if the coin stays in place long-enough (perhaps several trains), it will probably reach a point where it is so thin that it will crack/rip into multiple pieces.
ChuckCobleighI had the materials class (required for everyone) and the solid mechanics class (one other EE weirdo in there, for whatever reason) as an elective, then it was all EE and math for the rest of my academic career. Those were fun things to think about, like, for instance, what are the differences when the rail is in, say, compression, as opposed to tension? Actually the deflection is easy to come up with, I think, in any case, except I don't remember having to do anything with members other than in horizontal equilibrium, but then, it's been a few decades, too.
I had the materials class (required for everyone) and the solid mechanics class (one other EE weirdo in there, for whatever reason) as an elective, then it was all EE and math for the rest of my academic career. Those were fun things to think about, like, for instance, what are the differences when the rail is in, say, compression, as opposed to tension? Actually the deflection is easy to come up with, I think, in any case, except I don't remember having to do anything with members other than in horizontal equilibrium, but then, it's been a few decades, too.
Paul_D_North_JrChuckCobleigherikem I recall that pennies left on the rail head were pretty darn hot after being flattened by the train. With hat in mind, I could see the bearing surface of a rail getting warmer after a train passed, but would be surprised if there was a measurable temperature rise in the balance of the rail. I wouldn't. Between the ties, there is deflection of the rail as each wheel passes over it. That's mechanically working the entire cross-section. Hmmm. OK, probably worth a quick check. Conceptually, it's the area within the the plots of the stress-strain curve for steel as it is both loaded = stressed, and then unloaded = destressed. If I recall my "Nature and Properties of Engineering Materials class and text correctly, that's called the "hysteresis loop". Next time I see that book or a similar one for steel someplace - I seem to recall that we used to have a couple of those businesses around here in the Lehigh Valley and Eastern Pennsylvania once upon a time - I'll look it up to see what the analysis looks like and what typical values are. But I believe that the far harder task will be to calculate the actual stress level in the rail - it is so variable, mainly dependent on subgrade conditions, that the only way to even begin to approach it here is to make a rough simplifying assumption. (Those who have read some of my previous posts know that I have no hesitiation in doing that to try to get a handle on some of these questions.) So we'll see what comes of it when I have the time. Meanwhile, if anyone else wants to try, have at it. - Paul North.
ChuckCobleigherikem I recall that pennies left on the rail head were pretty darn hot after being flattened by the train. With hat in mind, I could see the bearing surface of a rail getting warmer after a train passed, but would be surprised if there was a measurable temperature rise in the balance of the rail. I wouldn't. Between the ties, there is deflection of the rail as each wheel passes over it. That's mechanically working the entire cross-section.
erikem I recall that pennies left on the rail head were pretty darn hot after being flattened by the train. With hat in mind, I could see the bearing surface of a rail getting warmer after a train passed, but would be surprised if there was a measurable temperature rise in the balance of the rail.
I wouldn't. Between the ties, there is deflection of the rail as each wheel passes over it. That's mechanically working the entire cross-section.
Hmmm. OK, probably worth a quick check. Conceptually, it's the area within the the plots of the stress-strain curve for steel as it is both loaded = stressed, and then unloaded = destressed. If I recall my "Nature and Properties of Engineering Materials class and text correctly, that's called the "hysteresis loop". Next time I see that book or a similar one for steel someplace - I seem to recall that we used to have a couple of those businesses around here in the Lehigh Valley and Eastern Pennsylvania once upon a time - I'll look it up to see what the analysis looks like and what typical values are. But I believe that the far harder task will be to calculate the actual stress level in the rail - it is so variable, mainly dependent on subgrade conditions, that the only way to even begin to approach it here is to make a rough simplifying assumption. (Those who have read some of my previous posts know that I have no hesitiation in doing that to try to get a handle on some of these questions.) So we'll see what comes of it when I have the time. Meanwhile, if anyone else wants to try, have at it.
- Paul North.
Have fun!
I definitely didn't retain a lot of that stuff on the top of my head; it kept falling off. At least it didn't knock much of the hair off on the way down.
erikemFWIW, I've done a fair amount of track work at OERM in Perris, CA and am all too familiar with how hot steel can get in the hot sun.
I seem to recall a summertime rule-of-thumb of ambient plus 30 degrees in high sun times. That makes sense.
There was an article in Desert magazine about 40-50 years ago where the author was relating stories of his boyhood in Needles CA. One of the summertime tricks he and his buddies would play was to wait until a westbound passenger train would stop at the station in the middle of the day, then quickly jump onto the tracks and crack an egg on the tracks, where it would appear to fry. He said that one time they did that, the easterner on board who was standing on the rear platform got off and went to the ice house to keep cool and caught pneumonia. I didn't really believe all of it then, but it makes for an amusing story.
erikem Chuck, Good point, though the amount of deflection depends a lot on the rest of the track structure.- Erik
Good point, though the amount of deflection depends a lot on the rest of the track structure.
- Erik
Your comment made me think of the BN in 1981 in Quincy, IL, just south of the Wisman Lane grade crossing, where they had a "soft spot" on the eastern rail just south of the crossing. I got stopped there a few times for freights and there was so much dip that it looked like some of the box cars were about to tip over. That rail got quite a workout.
I wonder how long that could have gone before the rail finally gave.
BTW, that is right where the Quincy Amtrak station is now. In 1981, the Amtrak station was in West Quincy, across the river.
Instead, I surmise that the heat came from the rail. The rail can absorb a lot of sunlight and turn it into heat, and be quite a bit warmer than the ambient air temperature - 20-30 degrees, easy. One of the first hard lessons for a newbie to learn in the real-world of track maintenance is not to touch, lean on, or grab a rail in the sun on a warm day with bare skin - the rails can easily get hot enough to produce1st degree burns ! (whatever temperature that is) Anyone with experience from the Southwest US can attest to this, although it can and does happen just about anyplace.
erikemI recall that pennies left on the rail head were pretty darn hot after being flattened by the train. With hat in mind, I could see the bearing surface of a rail getting warmer after a train passed, but would be surprised if there was a measurable temperature rise in the balance of the rail.
I recall that pennies left on the rail head were pretty darn hot after being flattened by the train. With hat in mind, I could see the bearing surface of a rail getting warmer after a train passed, but would be surprised if there was a measurable temperature rise in the balance of the rail.
We can safely assume the shackles from the white boxcars are somewhere nearby?
Thanks for the info guys. The info was hand written on an index card under the thermometer. The part about before and after a train passed got me wondering.
mudchicken.0007 x L x DeltaT Wonder if they knew what a taper gauge was, or did they manage to throw that out? The temperature before and after thing is most likely somebody's local fiction.
.0007 x L x DeltaT
Wonder if they knew what a taper gauge was, or did they manage to throw that out?
The temperature before and after thing is most likely somebody's local fiction.
Came across a 'rail temperature chart' the other night.
A 1300 foot string of rail will expand/contract 4 5/8 inches with a 45 degree F temperature change according to the chart.
Never too old to have a happy childhood!
tree68MC - The link you provided is a direct-contact device. Have hand-held infrared thermometers found a home in this application?
Yes, you're much more likely to see a gun style thermometer than the magnetic ones. You just point the thing at the rail and you immediately get the temp.
The before and after thing strikes me as something that could be a factor, if there was enough heat generated, but it doesn't appear that that's the case.
MC - The link you provided is a direct-contact device. Have hand-held infrared thermometers found a home in this application?
DISCLAIMER: The supplied link is just one I found. No product endorsement given or implied.
Larry Resident Microferroequinologist (at least at my house) Everyone goes home; Safety begins with you My Opinion. Standard Disclaimers Apply. No Expiration Date Come ride the rails with me! There's one thing about humility - the moment you think you've got it, you've lost it...
Eddystone [clip] In one of their display cases was a "rail thermometer" used to check the temperature of the rail before and after a train passed.
The "before and after a train" part is new to me - I've never heard of a rail thermomenter being used to obtain the a temperature reading before and after the passage of a train. I can't see that the train would affect the rail temp at all, other than maybe the shadowing effect of a long freight train from the sun might allow the rails to cool down a few degrees - but again, that information would be of no practical use that I'm aware of.
Alternatively, from a physics-work-energy standpoint, some of the energy expended by the locomotives to move the train over a given section of track might wind up being transferred to and absorbed by the rail as friction, wear, and elastic flexure (less the rebound). But that is pretty much a theoretical thing only, and outside of a lab with closely controlled conditions, could not be measured or quantified in a meaningful or useful way. And again, I'm not aware of any practical use for the information.
The point being (for continuously welded rail) that there is such a thing as a 'neutral' temperature. Without getting too complicated, rail expands when it gets hot and contracts when it gets cold (or tries to). Jointed rail could, and the movement in 39 feet isn't all that much -- but there does have to be a gap as mc said. Continuously welded rail mustn't move (the expansion or contraction, cold night to hot sunny day) is several inches (oh where is that formula when I need it?) per mile. The rail, however, is restrained against moving by rail anchors to the ties. The neutral temperature is that temperature at which the restrained rail has neither tension nor compression in it -- if you took all the restraints off, it would just sit there. Anything colder, and there is tension. Anything hotter, and there is compression. Objective of the exercise is to get the neutral temperature so that the tension when it gets cold isn't too great (which would give you a pull apart) and the compression when it is hot isn't too great either (compression gives you kinks -- ever push on a string?).
The rail doesn't have to be laid at the neutral temperature -- but if it is colder, it must be stretched to compensate, and there are tables for that.
The laying of welded rail....and before that, gauging the size of the gap in jointed rail to balance hot/cold pressures to avoid kinks and pull aparts.
Rail thermometers are still sold today. Any rail maintenance supervisor from foreman on up still has one. http://www.ptc1.com/thersur550.htm
Last weekend I went to Northlandz in Flemington N.J. In one of their display cases was a "rail thermometer" used to check the temperature of the rail before and after a train passed. Also said it was used by many eastern railroads PRR, B&O, ect. I've never heard of this or read about it, what would this info be used for or tell you?
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