Why Railroads Don't Need Expansion Joints

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My 14 yo son was telling me about metal expansion he'd learned about in school and we got onto the topic of railroads. I mentioned they don't really put railroad down in sections anymore and he asked how they accounted for expansion. I realized-- I had no idea! So thank you for this great video-- I now know.

As a engineer who works in railway track design, one thing I'd like to point out - especially since you mentioned a video on signaling will be coming soon - is that neutral temperature is typically high not because a broken rail is less dangerous than a sun kink. Yes, its more likely that a train could operate over a pull-apart rather than theough a sun kink, but largely because the signal system will detect a pull-apart as a discontinuity in the rails and thus the signal circuit - automatically turning the signal ahead of that track to red!

As a civil engineer, this type of content is therapy

2:38 As a Korean i'd say chikchikpokpok(칙칙폭폭) is onomatopoeia of a steam locomotive, which in English chug-chug. Korean language really don't have word for railway sound. I mean we can, but it's not devoted for that sound. Japanese word "Gatan-goton(ガタンゴトン)" describes exact same sound of clickety-clack.

As a trained metallurgist and engineer, I found this amazing.... what a way to encourage future engineers, Simply, softly spoken.

Fun fact: The problem with 'rock n' roll' (more formally, harmonic rocking) is bad enough that rulebooks disallow travelling at certain speeds on jointed rail. The rulebook I have says this danger zone is 13 to 21 mph, so if your train only has enough power to reach 20 mph (entirely possible, if normal, these days) safety says you'd have to slow to 13 mph on jointed rail. So CWR not only makes maintenance-of-way's job easier, it also makes operating the trains a bit easier and safer too.

Railway engineer here! A few points:
Not all rail is made of the same alloys, particularly high load areas such as points and crossings. These use harder metals to reduce wear, such as manganese. Adding this into the equation means welding plain line to p&c is a particularly complex job.
I am also glad you mentioned track circuit will be covered later on as that is a big downside to CWR with older signalling systems.
Aluminothermic welding is spectacular when it goes wrong, search it up!

If anyone wonders why the odd figure of 39 feet was the standard length of single sticks of traditional jointed rail, it was so that they'd fit into 40-foot gondola cars. Welded rail is now typically manufactured in long lengths (1,320 feet in the USA, which is ¼ mile) and can be welded in the field to be continuous. Such long rails are transported on special rail trains, like the one Grady shows half-loaded at 0:25. The yellow racks hold them in place, and the rails bend as the train goes through horizontal and vertical curves 😮.

I really enjoyed this video! Well done!

When I had the baize, AKA felt/cloth, replaced on my pool table the installer sprayed it with a thin mist of water to introduce the most amount of moisture to will ever experience. So, when stapled down it dried and tightened up the cloth putting it under tension l. So, no matter how humid it gets in the house, the cloth won’t get wrinkled keeping gameplay very consistent. I think this is very similar to installing railroad tracks on the hottest day possible to keep them under tension as well. It’s so cool how materials respond and react to their environments! Awesome video series!!!! 😊😊😊

I love that the primary solution for buckling is just “do it on a really hot day lol.” It’s the kind of thing that sounds way too dumb to work but is somehow the most genius solution ever.

"Stress is what breaks things" is a truth that more people should apply to their own lives

I developed a broken rail detection system at San Francisco BART that used ultrasonic waves traveling miles in the continuously welded rail. As part of characterizing the rail I measured acoustic properties as a function of rail temperature. It was amazing to see the rail temperature exceed 140 degrees F on medium hot days, like air temperature in the 90’s. The peak temperature was in the late afternoon when the rail web caught most of the sunlight. Definitely painful to touch!

BRILLIANT BRILLIANT BRILLIANT!!! Years ago I asked myself how it's done. A friend told me, expansion is controlled by rigid counterforce from the bed. But now YOU really opened my mind by detailed background - technically and by examples. Very good a teacher you are. English is not my mother tonge but I could understand anything. Thank's a lot and You have a nice life.

As a summer student in 1970, I worked for Canadian National Railways on an extra gang laying ties, track and ballast on a branch line. One task was repairing a sun kink by assisting in the cutting of a section of rail and replacing the bent piece with a straight one. CN soon after started installing continuous rail on the main line. For the last 50 years, I have wondered why this was viable given the absence of expansion joints. Thank you for the excellent presentation - my question is answered.

This is the first question I ever asked on the “internet” - a Compuserve message forum - back in 1989, and it was answered by a Canadian rail worker. That’s when I knew we were in a new era.

Awesome! I've seen thermite rail welding before and was curious behind the why's of it.

In Finland (North Europe) our temperature range from summer to winter is quite high, from -30C to +30C (-22F to 86F) is to be expected. If we did the “wait for the hottest day” trick, our tracks would snap in the winter from the enormous tensile stress. Instead we do it in the summer at night, as rail that has sunlight shining on it can easily reach 80C (176F). We haven’t used wooden railroad ties in over 50 years. Ours are always concrete, weighing 240kg (529lbs). Railroads buckling doesn’t happen because this is over-engineered enough so that compressive forces can always be overcome, but we can’t overcome the inherent weakness of steel under tensile stress after a certain point without making the rails ridiculously thick. Fighting buckling is economically much more viable if the temperature changes are high enough.

Excellent info. I started my RR career in the 1970s, I was a signalman and then conductor for almost 5 decades. I remember workin out in the desert doing cadweld bonding and at 8am and 70°, there was a half inch gap in the rail, in one hour when the sun came up and it was 90° the gap would close with in minutes. Those oblique slider joints are fantastic, they prevent sun kinks... good video

Started building track 51 years ago. Great video ! A few things left out are the use of rail anchors in tracks with standard tie plates, pandrol cliups as well as well as others do the same job. Ballast shoulders are an important consideration to prevent sun kinks.

I am a SCADA engineer, working in the electricity and water distribution fields, and the first thing I became aware of when I started work was that those things we take for granted to keep civilisation running are *much* more complicated than most people know. It seems that railway tracks are no exception! :)

When I first drove from East to West Germany in a train, I stood in the middle of a crowded wagon but the moment we crossed the border was obvious as click-clack instantly stopped and there was instead a nice continous sound. Everybody was surprised that this is possible.

Rail is fascinating. I never considered that (fundamentally) you could just hold it in place and force it to not thermal expand and the stress isn't always prohibitively high.

as a non-engineer minded person just wanted to say thank you for making this very easy to digest and understand. i truly appreciate learning from people who are able to follow the KISS rule lol

If I remember correctly, what my associates in the track department told me is that in the Northeast where we are, they had to lay the rail at a certain temperature range. This is to mitigate the expansion and contraction which happens in our area because of the swings in temperature across the seasons. When our company was bought out, the new owners decided to lay rail in freezing temperatures and they ended up paying the price. Obviously, in Florida, as you mentioned, they lay the rail at a high temperature for a reason. My knowledge of rail only encompasses running my trains over the tracks and also how the shape of the rail works. Your video was very interesting and informative.

I spent a couple of years in Buenos Aires in the mid 70s. The rail system there had been built 50 years before by the British and then nationalized in the 40s by Juan Peron. Very little maintenance had been done since then. There was one rail trip of 200 km that I took regularly. Leaving Bs As the train moved at 50-60 mph (my estimate) and the clickity-clack was spaced out, indicating long lengths of rail. But there was a point beyond a certain town where the speed decreased to a relative crawl and the wheel noise was almost constant. The ride quality deteriorated to the equivalent of driving on a rocky dirt road after exiting a paved highway. It seemed like the rail sections were only about 10 feet long.

Builder here. South Florida. I never understood why rail work here was always done in the summer heat!
Thanks for clearing that up. We never see rail work in our “winter”.

In the foundry industry, the reverse has to be dealt with - shrink. When we build patterns (tooling) for foundries, we have to account for the shrinking that occurs when the molten metal cools back down. Usually, it can be predicted quite accurately, but on occasion, it throws us a curve ball.

Being abroad and using for the first time in my life a German U ban, I was amazed there isn't an old-time train clicking... And just a day's after, your video explains to me why!
Your patent, easily understandable engineering language is exceptional! Thanks man.

I worked on the railways through my late teens and 20s. Your channel has reignited my interest in the railways again. I'm now 10 years roofing

Railway engineering is a gift that keeps on giving! Every time I feel like I've learned all the basics, there's a whole new thing. Love it! Thanks for being a great teacher

I am stunned by this. I knew rail was difficult to lay in general, but maintaining strain at the right tension for the whole length is incredible. Where I park for work is very close to a rail facility of some kind (I honestly don't know what it does) so I am frequently hearing train brakes whail and trains pass, and the clicking is almost non-existent. I just assumed they were more precise or something with the leveling of expansion joints, but this is amazing.
For the people who are going to weigh in on my ignorance of the rail facility beside the parking garage - it's about half a kilometer from the passenger rail station, but regularly has both freight and passenger vehicles that are definitely not meant for local unloading. It has a small spur that rarely gets used that crosses the road where passenger trains pull off onto and then almost immediately back off of. My assumption is that it's some kind of switching facility, but I don't really know.

My man, promoting math to the masses. We need more folks like you!

While studying mechanical engineering in college and now as an actual locomotive engineer for a commuter railroad, this is great information and very well presented. I’ve witnessed CWR being installed but your explanation of installing rail at its warmest neutral temperature makes perfect sense! Indeed, a rail pull-apart is much preferred over a heat-kink, not only from a rail perspective, but also the cab-signal code will drop to zero in a broken rail but may still function normally during a heat-kink which could be disastrous.

As a metalworker, I've asked myself this question so many times in my life, and you finally answered it. Thank you so much for that! I had no idea.

Back in the 1890's at the Salt Creek Oilfield in Wyoming, the built one of the first cross country pipelines. That pipeline was not buried, but rather it was just laid on the surface. It worked fine until the first winter. When the cold of winter came, they had over a dozen places where the pipeline parted, caused by thermal contraction. That was 4 inch threaded pipe with 8 round threads, which pulled apart in the cold. I enjoyed your presentation I always wondered how the railroads overcame the thermal expansion problem.

You might already be familiar, but rail (track) structure interaction analyses are a fascinating task that bridge engineers need to complete when designing longer spanning rail bridges that utilize direct fixation rather than ballasted track. It’s a fun nonlinear finite element analysis that considers the structure, the rails and the connections (with nonlinear springs to capture when the track slips from its hold down clips) to make sure the rail isn’t over stressed.

What a great video explaining sun kinks! It might be fun to know, in the world of Swiss narrow gauge, we actually have another way to manage the stress in our rails: "Bogenatmung" or "curve-breathing." Essentially we allow our narrower curves (below a radius of 120m) to expand and contract by a few centimeters over the course day. In other words, we minimise stress by allowing for a controlled lateral deformation in our track geometry

This video was pure joy (for me) as it was a revelation on things I really enjoy (trains). Let's hear it for engineers: softly spoken, confident but not arrogant, justifies everything with facts and data and shows a certain degree of humility as well but they also get things done. The best type of American is an engineer.

Fascinating! I've always wondered how they get away without having expansion joints.

As a train buff who's talked to some railroad engineers, another thing that's sometimes done (at least in california) is put an intentional slight wave in the rail (a few inches to each side every few hundred meters) this does allow the rail some side to side action when heated or cooled. Instead of preventing the buckling from happening, it's given a controlled outlet

I thermite welded ribbon rail for the CNR for 2 years (1981-82). We did lots of de-stressing and also eliminated many reoccurring heat kinks by installing cement ties with pretzel clips which allow for the expansion and contraction of the rail without dislodging the ties. Every time a thermite weld was done (we were doing 12 to 14 per day), the temperature of the track was recorded and the gap between rail ends was determined (calculated) prior to placing the thermite mould. Sometimes we had to cut a section out of the rail because of expansion. Sometimes we'd cut out a section and then find we'd have to cut out even more. Sometimes the blade got jammed into the rail due to the heat expansion. Other times we had to force the rails away from each other and then weld the rail joints together. We used a hydraulic clamp pusher/puller to manipulate the rails.
Subsequently, I ended up Joint Welding in my 3rd year with CN to repair old rail joints that were battered by the train/car wheels. As well I welded Magnesium Frogs which are the cross-over switch rails (Shaped like an "X"). They'd have to be built-up with weld then ground to the right camber, roll and smoothness.
It was all interesting work and paid very well.

I had always assumed that the expansion in CWR went into the curves. It never occurred to me that the track just loads up like a big axial spring.

In the early 1990's my railfan buddy and I saved northbound Amtrak Coast Starlight from a potentially disastrous derailment when on a hot day a portion of the SP mainline south of San Jose along a "race-track" paralleling Monterey highway developed a kink after a low-boy farm trailer bottomed out and tugged one of the rails at a rural road crossing. No change in the signals of course. We had pulled over to video the Starlight when it happened, and placed an emergency cell phone call to the SP dispatcher. Just as the headlight appeared the train halted just south of the kink. Got a nice letter from the SP thanking us for our action.

Just the other day I was discussing this question with my brother; how does the expansion work on welded rails.
Now I know, and I'll show my brother this video.Thanks for your clear explanation, and cheerful presentation.

Back around 1965-1968, British Rail built a test track near my school in Nottingham, England. It was the world's first pre-stressed railway line and astonishingly quiet for back then.
As I recall, the story was that the rail was treated to expand thickness-wise rather than length-wise, allowing lengths of rail to be welded together.
Maybe that was mis-direction or maybe it was a patented technique so a work-around was found by other railways.

You seriously have a knack for explaining enginering problems and their solutions in a way non engineers can understand (at east the principles) Thank you.

As a locomotive engineer who flunked out of civil engineering, this answers a lot of questions. I only deal with jointed rail but have always wondered about CWR. It being in tension makes sense. Thanks!

Thanks for bringing back to my memory what my father (chief engineer at the Sicily railways) explained me many years ago. I remember he also mentioned that they had a max operating temperature to be measured at the rail. Heat accumulates for irradiation on items resulting in temperatures well above the environment one. If I’m not wrong that was about 60 degrees Celsius (consider that a summer day in Sicily can easily be above 40). Above that max, despite of the very high neutral temperature set with jacks at the time of rail welding, railway cannot be operated exactly because of buckling risk.

You've got such a talent for explaining engineering concepts simply, and your demonstrations are fantastic. I wish my undergrad professors had possessed the same commitment to ensuring students understood things intuitively as well as mathmatically.

I am not an engineer but I use railways daily. And I have learnt something new today and I loved it. Thanks for the amazing knowledge.
❤️❤️❤️❤️❤️❤️❤️❤️❤️❤️❤️❤️❤️❤️❤️❤️

When i was doing fire sprinklers for a living, we had what we called expansion joints for out pipes when going between sepperations in building, but it was more for earthquakes, not temp.

In July 2002 I was on the Amtrak Capitol Limited when it derailed just north of Washington due to a buckled track on an extremely hot day. I could feel the train lurch to one side just before it derailed. Subsequent reports said the track had moved 18 inches out-of-line. You'd think the Northeast Corridor, of all rail lines, would have been properly engineered!

I have zero maths background but thoroughly enjoyed this video! I always wondered why certain stretches of my local subway have the clickety clack sound while other stretches are perfectly smooth. As for the bullet trains, they have a perfectly smooth hum for the entire run where passengers ride! Thank you for posting this info!

My uncle was the engineer on the train the derailed in Crofton KY which resulted in white phosphorus burning. It was caused by bucked rail, a warning sign that had been knocked over or never put up, and a missing warning on the orders.

Always love these videos, My Dad's a civil engineer and I've driven him mad with questions about every last thing I could see out the car door window.
He eventually got completely sick of me asking, I'm thinking of getting him your book for Christmas but I worry it might be a bit redundant for him-
pretty sure I'm more enthusiastic about his job than he is lol.

Tis is a good video about the construction of the tracks.
And here in The Netherlands they use Thermal welding to join the sections of track together.
The rails are each about 25 meters long when they are transported.
And we us a special machine to place the tracks on the sleepers.
And we first used wooden sleepers. There are still wooden sleepers in use.
And we use solid concrete sleepers.
Also we use sleepers in the shape of a dumbell. Meaning 2 concrete blocks under the track and these blocks are connected with a thick metal tube.
This is done to safe of material and cost. It's just as good but, more easy to install and has a lower weight so, a person like me can move it if needed.

The first time I pondered about this was riding the Shinkansen in Japan. That was the first time I notice their tracks has no expansion joint. I search the web as what is the secret behind this to no avail. I got it immediately as soon as you started to talk about modulus of elasticity. The most impressive thing about these rail system is the engineering structures go into withstraining the rails from buckling, especially the extremely high speed train in Japan and other countries. Brady's channel is one of the smartest on UA-cam.

I'm not even 30 seconds into the video and now I have the entire intro for Lots and Lots of Trains stuck in my head. Thanks!

There are low thermal expansion metals that could be used for the rail, Invar comes to mind of a low thermal expansion metal. Invar is used in surveying equipment so that it maintains accuracy over a greater temperature range. The problem with Invar is it's high nickel content rapidly increasing the price with needing at least 20% nickel to even start noticing the reduction of thermal expansion, and the ideal being 36% Nickel. The price for Invar is on $25/Kg versus the $100/ton of steel. vastly different orders of magnitude for price. The fact that Invar is weaker and softer than any steel used for rail use. The increase in price with a increase of maintenance cycles will increase the cost of the rail system by orders of magnitude.
The Solution became obvious to me as soon as you put the two equations together, but I thought of always having them in tension rather than a time where they are mostly in tension and tensioning the tracks instead of just installing the tracks on a hot day.

Fascinating how complicated something so "simple" is. Thanks!

As a blacksmith and metalworker, it's always nice seeing different uses of steel. When i was making grids and frames, heat was a major factor in achieving precision. The precise order at which you do the welds will move your steel around, and pull or push/buckle your bars. Welding tends to pull as the metal cools down, i think it would help against the buckling of rails

Very good! Sun Kinks a real phenomenon. In mountain country generally on curves. Enough to laterally displace concrete tie track structures. Cold weather rail contraction also can result in the rail pulling apart. I've seen it break in multiple places in severe and unusual cold temperatures for a given district. Old timer Engineers used the rhythmic 39' clickity clack as a subtle gauge of speed and distance.

Great explanations! Was genuinely waiting for the joints that we do still have to not be covered but you nailed it. Cheers!

I knew about the thermal welding of rail because of lots of videos UA-cam wants me to see. But installing it on hot days to avoid buckling due to compressive loading is amazingly simple and great

Grady, thanks for another great episode. This series on the rails is exceptionally timely, given all the difficulties being experienced across the country with failing components. By no means does it absolve the railways of their responsibility for solid monitoring and maintenance, but it gives us all insight as to the challenges facing them in doing so. There's nothing like "sunlight" to expose the issues and get the right people to take appropriate actions. :)

This video came at the perfect time. We just started studying column buckling in university, and I brought up sun kinking in rail lines. Very interesting video!

Great video! It would be interesting to also show this effect when the railway is placed on a long viaduct, an effect usually referred to as track-structure interaction. We don't always place a rail expansion device on bridges as they are very expensive to install and maintain. Instead, we analyse the effect of the bridge expanding and contracting under the track (yes it can get quite complex!) and then assess the additional stresses from this effect. We also analyse the additional stresses in the rail due to the braking and acceleration (and vertical) forces from the train on the bridge, which invokes the foundations of the bridge and eventually impact the rail stress. I've worked on this for more than two years and I keep learning new things!

Love your teaching style. It's been over 40 years since I took Engineering Mechanics and truly enjoyed your presentation.

Having lived near (

Another thing that's relevant in that space is that many high-speed rail lines use ballastless or slab track, which is usually a bed of concrete that holds concrete sleepers to mount the rails on. There are a number of variations, including elaborate constructions to reduce noise. They are estimated to last about twice as long as ballasted tracks but are rather more expensive to build or repair. Obviously, that way, it's easier to ensure the rail is perfectly straight and has the right amount of longitudinal stress.
As an aside, high-speed signalling systems can't use track-side indicators, as the engineer will not have enough time to be sure to notice them, and needs too much distance to stop the train then anyway. So signaling systems for these trains are all using radio or other electromagnetic systems, and instead of trackside masts with optical indicators, the relevant information is shown in the cab on a screen (and enforced by the on-board computer: too much speed, it may just stop the train; and pretty much all restrictions are about top speed: the equivalent to a stop signal is "keep it slow enough so you can stop in the distance left ... slower ... slower ... max speed is now zero"). Over here in Germany, the speed at which high-speed traffic rules start to apply is 160 km/h, around 100 mph. Level crossings are also forbidden then. We have two high-speed signaling systems: the old, locally-developed LZB (line train control, so named after a cable going through the middle of the track), and the newer European ETCS (from level 2 - level 1 is for slow tracks and uses traditional signals).

LOL hahaha as a Korean, I totally was going “칙칙폭폭! (chikchikpokpok!)” at the beginning of the video in my head. Then all of a sudden, you actually say it!! HAHAHAHA!!! I was NOT expecting that! LOL!!!
Growing up, my little brother and I would say the same thing when a train would pass!
What another amazing video! Your videos also inspire vibrant comments that’s just chock full of knowledge all over as other people working in the field start chiming in!
Grady, you’ve fostered such an amazing community here! Your channel is such a wonderful treat for my family! THANK YOU, and THANK YOU ALL other commenters here dropping these amazing supplementary information in the comments!

I can say that I, am a wanabee Engineer. I find your videos very educational as well as entertaining. I have always loved working with my hands and re-engineering things around my home and business. The world owes so much to engineers, such as you, who dedicate their lives to making things better and most importantly, safer for all of us! Thank you!

Listen to what's being said here. I retired from a High-Speed RR Amtrak, and the one thing that I learned early on, was HEAT KINKS are e a real hazard. Mostly because a rail under stress may not initially show signs it is. Many times, as the first few cars pass over the stress (TENSION) point the vibration will cause the rail to jump out of its bed. Naturally the train wheels can't navigate such a sharp bend and the train will derail. This is especially a hazard with the strings of welded rail that are now used, some as long a 1/4 mile with no joints. The way the RR overcome this, is heating the newly laid strings of rail to over 95 degrees with a propane heater, BEFORE anchoring it in place. If for some reason it becomes exceptionally cold and the rail contracts to a point where it breaks. the dispatcher can see this on the board and the signals will go into a restricted mode alerting th e engineer.

People get stressed sitting at a crossing waiting for the train to pass by because they have places to be. I get that. Me, I marvel at the engineering that isn't seen by the casual observer. The whole system from concept to application is mind blowing and has more facets that a jewelry cut diamond. Always enjoy your videos.

I can’t wait to see the videos on signaling, communications and electrification for railways. I think the cherries on top of them might be explanations of why ERTMS and 25kV 50 Hz AC are the gold standards of railways. Keep up the good work, Grady!

8:52 the left side should be marked "imperial", not SI, since neither Fahrenheit nor psi are SI units.

8:48 In the table, there two system of units names. However, SI signifies the International of Units (Système International d'Unités), i.e., metric units. The US system is named Customary Units, often but wrongly called the Imperial System, which are British units defined by Act of Parliament in and introduced from 1826. The US standards were derived from various earlier English standards.

i never stopped to think about the wear and tear all that click clacking has on the train wheels. i sure hope they never update my old rail yard, i will really miss that drumming of the trains

This show presented some great lessons that enhances the appreciation for welded rails as an excellent innovation invented for the real railroad.

I loved going on the east coast mainline from London to York a few months ago, but one of the best parts was seeing Bullhead Track(!) in York station. I’d never have guessed that I would see chairs and keys on rails in the 21st century, but there it was, in 60’ sections, leading right into the railway museum. It’s still used on heritage lines though, and with great success.

I've seen crews instaling CWR before. It's quite the interesting process. They have a rail car with the track sections on it. Then another rai car has arc welders. So, they feed the rails from one car to the other creating a CWR alongside the existing rail. Then they grind the rail down by hand. And after all that, a small train of equipment cars come along. Those pop the old spikes, move rhe old rail out of place, move the new ones in place at the propoer gauge, then drive spikes to hold them in place.
The other thing I remember is when they were weldng the new rail, every now and again it would pop or ring and due to the length it made this distinct echoing sound. If you ever had one of those "space tubes" growing up, it sounded similar to that, but much louder.

2:38 i didn't expect to listen to the sound of a train in Korean.
The sound ChickChick Pok Pok (칙칙폭폭) is indeed the sound of train, but it is equivalent to the steam engine train sound.
Although the word is from the sound of steam sound, still we all use that word for train sound.
Thank you for the wonderful video!
And i really appreciate using the metric systems

Have not watched the full video yet, am at 2:00 sharp. This is a problem I pondered myself about. The conjecture I produced on my own is as follows: Rails do expand and contract, but when they are layed down, they intentionally make put curves and turns in the tracks and never go straight for too long. So when they expand due to heat, the rails simply shift in turns a little outwards inside the rail bed to account for the additional length. That's why they need all these concrete struts or whatever they're called to keep the rails at constant distance to each other.

This guy actually explains it well. I’m a railroader and he explains it simply

As a civil engineer designer (in oil & gas field), always excited to learn about things outside of my normal work flow. Train related things are always cool.The SA sewer lift was cool too, our W/WW team is just over the wall so I hear alot of stuff.
Weird being in this line of work and not liking math, thank goodness for spreadsheet calculations lol

Grady: I'm a retired mechanical engineer and appreciated the video as I have often wondered how they made the CWR concept work. Great job, keep up the great work

The high neutral temperature thing is super cool, I would have been a long time thinking of that. Having the rail typically in tension also helps prevent it bend from other forces too. I wonder why they don't use that technique for more installations that have to deal with thermal expansion? Maybe significantly more complex to simultaneously apply heat/high tension and install say, a bridge girder.

In my youth in the early 80's I was a trackman for the Missouri Pacific later merging with the Union Pacific. I was on a district tie gang and we replaced railroad ties . Remove a 1000 or 1500 and put them back in a day. Sometime my job would be to reinstall the rail plates that go between the tie and the rail. A small machine called a rail lift we would push along . It would clamp the rail and then lift the rail to enable you to install the tie plates. In the summer when it was hot sometimes the rail would slide and move creating a sun kink. The welders would sometimes have to come in and do their thing removing a piece if it couldn't be realigned.Another thing that keeps the rail in place besides the ballast are rail anchors which are driven onto the rail on either side of the tie and tie plate. In a straight away they might be every third tie but on a curve every tie.

This is something I've always wondered about but never got around to looking it up! Thank you Grady, for explaining it so well and concisely! 😊

In Italy they paint the sides of CWR on HSR epites with white paint to reduce solar heating of the rail.

I've heard continuous welded rail (CWR) referred to as "ribbon track" or "ribbon rail" reflecting its ribbon--like smoothness. Thanks for the video. Keep up the great work!

You would have been everyone's favourite teacher. I'm sure you have inspired lots of people with your engaging style. More power to you my man

Good old "Youngs Modulus" one of my favourite lessons at college in the late 70's with the "Tensile Test-meter" thanks for the video.

I have wondered about this for years. Thank you.

As a medium carbon steel rod I find this content traumatic.

I work as a railway maintenance of way worker sence 2008 and install CWR on rail crews changed ties on tie crews and am a extremely experienced mrkIV tamper operator of over 10 years and some experience in plasser surfaceing as well, they use different measuing systems but work on the same principles. I still enjoyed this video. I hope you do surface and track structure video cause thats my gig, I'm all for answering questions too!
One thing you forgot to mention is that when the rail does break and a maintenance crew has to repair it we need to re heat the section of rail to close a specified gap we need to account for dependent on rail temperature mostly using fire snakes to complete the repair to maintain the PRLT (preferred rail lay temp) and put the joint together.
Great video

As a non-engineer human being I found this video absurdly interesting. Fantastic work mate! And thanks to the youtube algorithms that brought us together. :)

When working on British Rail on the busy Colchester Area in the 1970s (my first promotion and an "escape" from the Teesside Office , after attending the relevant training I completed 222 "rail stressing/re-stressing" shifts (mainly overnight when the relevant track was placed under Absolute Possession). Stressing rails to a stress-free temperature of 27 Celsius was achieved by noting the average rail temperature and length to be "pulled", jacking-up and placing the rails onto rollers, then tensing the rails hydraulically with pistons, heavy clamps & connecting rods to hold all together, plus accurate use of a chart. The main problems were extreme cold, insufficient supply of base and the "sidearm "rollers that went beneath the rails and arrogant young welders...