Why Have Radiators On Locomotives Gotten SO BIG!?

Merch, anyone? okieprint.com/SPR/shop/home

As an astrophysicist, I love how your video swerved from engine efficiency into the heat death of the Universe

Never thought that a SPR video would get so physicsy. I like it! Good video!

I never expected to hear about heat death and thermodynamics in a video on why radiators are so big , cool video must have taken a lot of research to present such complex topics

If I'm not mistaken, another significant component of how quickly a locomotive radiator has to shed heat (and therefore how large it is) is the use of dynamic braking. This switches the traction motors to generators, and the resulting current is sent through a load of big resistors, causing the train to slow down. Considering how much mass there is in a modern freight train (~10000 tons), this is a LOT of energy for even a small change in velocity.

I knew that the T4's needed a bigger radiator to help with emissions, but I didn't know they also had smaller Prime Movers.

Interesting
Video Idea: What happened to the 4 Axle Locomotives

This was a great video! I really enjoyed the explanation of heat transfer and it helped with my understanding on how locomotives stay cool.

Having failed thermodynamics at least once I feel I have an expert opinion on this subject. The waste heat is not expelled by the radiator but by the exhaust. The radiator simply keeps the engine from melting. The working flued that pushes the pistons down is air (mostly nitrogen) and exhaust gasses (CO2 and H2O). Removal of heat from these gasses completes the engine cycle. Since these gasses can't be reused they are simply dumped overboard. Same with steam engines. In (nuclear) power plants the steam is reused, so cooling must be done with those giant cooling towers. Imagine how big a radiator you'd need to cool the steam from a locomotive down to under boiling temperature, then multiply that by 100 (est.) to deal with the waste heat of the diesel trains in your example.

I love GE radiators, ever since I first saw them on the dash 8 40 BW

Another big reason for the massive radiators is due to Emission controls. In order to meet Tier 3 and tier 4 both EMD and GE had to put in intercoolers on their engines and with tier 4 going to EGR with coolers that requires more cooling back there. So the growth in the radiator sections of the locomotives. On a tier 3 GEVO you have a Radiator for the Engine then in front of that you have the intercooler for the turbocharger. On the Tier 4 you have the same plus the radiator for the EGR cooling system, EGR being Exhaust Gas Recirculation. Yes the EPA mandated that Diesel engines that produce soot particles suck down their exhaust to lower emissions. Which has the effect of lowering fuel economy and reducing reliability to the point where NO CLASS 1 wants to order NEW Locomotives instead just rebuilds their current fleets of Tier 3 and older. Why they have seen what EGR does on their other equipment like their heavy trucks used in MOW for over a decade and are like NOPE not touching this stuff with a 1000 Meter POLE. See what happens is the EGR cooler over time literally gets ate away by the acids produced by itself and then causes a failure in the cooling system and also the oiling system letting them mix.

This reminds me of the Indian Railways Diesel locomotives, where the older generation ALCO locomotives had flush radiator grilles as they were rated at 3100-3300 hp, making it easier for a smaller radiator to cool the charge down. However, the newer EMD GT46MAC (SD70MAC derivative) and the EMD GT50MAC (SD80MAC derivative) locos had much higher horsepower ratings (4500hp and 5000hp respectively), so they have large flared radiators, which made long hood operation inconvenient (India didn't use turntables to prevent delays).
The visibility issues compounded so much that finally the Indian Railways research organization relented and redesigned the EMD locos to have dual cabs, with air-conditioning mounted into the cab attached at the radiator end to prevent it from heat damage.

lol CSX 1714 looks to me like what a vacuum cleaner would look like as a locomotive, like it’s job is to pick up trash beside the tracks.

“Has to do with the heat transfer of the universe, but we’ll touch on that later” -the train channel. Made me chuckle sir

Very good information.

Dude! This was awesome! Thanks for getting down to the science behind a cooling system!

Southern Plains Physics/Engineering Channel 😁

I always learn something new from you. Great video!

Incredible Video Brother 😎

The Radiator is there to prevent the engine from melting .The exhaust is the path to the cold reservoir.

Thank you for your video, As a retired process control engineering person i can watch tech stuff like this all day long.

I would never expect the heat death of the universe to make an appearance in a video about trains, but I guess it makes sense

love your videos from uk granny who's passion is science/bilology thanyou

Excellent video! I learned way more than I expected to

Anyone who grew up with a train set knows the wide radiators are a convenient handle to pick-up the locomotive.

This was a very good video. Great job with the mini engineering lecture about thermo and heat transfer. Growing up I always noticed those rear upper radiator sections on the GE locomotive

Long ago I was taught by a techie at Fairbanks Morse that engines turned some of their heat into power and the rest was waisted and had to be dissipated, about half of that was exhaust and that problem took care of itself, the rest of the wasted heat went into the engine itself and that the engine would eventually self destroy if it wasn't gotten rid of. That function was taken care by the cooling system, generally engines use liquid cooling, generally water but the engines oil lubricating system is also a major player here. The water jacket around the cylinders removes the major heat from the engines while the oil flowing thorough the major moving parts of the engine cools these down. Over the years builders have added additional turbocharging systems to engines to increase the power output of the engine as well as reducing emissions, the turbocharger needs to be cooled as well, again the oil cools the bearings while many use a water jacket to keep the housing cool. Boyles law says that increasing the air pressure will increase the heat and it is more efficient to supply cooler air to the engine so intercoolers were added and these had to be cooled, most highway trucks use air to air systems for intercooling but most locomotives with five to ten times the horsepower needed to use water cooling. All of this along with a more than double horsepower output requires a larger radiator. I believe that most locomotives use only treated water in their cooling while trucks and cars that are routinely allow to cool down to ambient temperature that might be freezing, use an antifreeze mix that not only prevents freezing but allowing a much higher water temperature before reaching the boiling point, this higher temperature allows relatively small radiators to still be efficient and do their job. it is essential that the cooling system be of adequate size to meet the power potential of the engine, an engine cannot sustain operation at a given power level unless it can reject the heat generated. Some aircraft engines have two power ratings, one for takeoff and a second for continuous power (i.e. cruise speed), the first is time limited, five minutes is common, but especially on very hot days, the pilot must monitor his cylinder head and oil temps to stay out of the red line. Railroad locomotives might run at full output for hours when pulling a long freight train up a mountain range so full power is rated at only the continuous duty number. I had discounted the exhaust issue but it is also essential to have an efficient exhaust system, back pressure is the enemy. Generally one of the first things hotrodders do to an automotive engine is to modify the exhaust i.e. reduce back pressure. Again looking at hot rod and tractor pull engines, in both of these cases the engine is asked to run far above its heat rejection limit but only for a few seconds for the drag racer and less than a minute for the puller. Automotive engine designers have multiple goats to accomplish, the want the engine to heat up fast for car heating and defrosting as well as smoother running but the still want it to be able to climb long hills without overheating. They also want the engine to be small and light along with a small and light radiator but remember while a car needs power to get away from the stop light, most of the time it is cruising down the road making about 25% of rated power. This engine might not be too happy if you add a trailer and take a trip up to the mountains on a hot day. The engine reaches its heat rejection limit. You might note that the car engine when compared to even a light truck for a similar hp engine, has less water in the cooling system and less oil in the crankcase.

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Fairly good explanation, but a few things were off. In short, radiators getting bigger because engines are getting more powerful is the main reason, though I get the sense emissions compliance, requiring engines run cooler and stuff like cooling exhaust gas for recirculation are also factors.
The hot and cold reservoir isn't really a direct explanation. This would make sense in a closed-loop cycle, like a Stirling engine as mentioned, or a condensing steam locomotive. In those cases, the recirculating working fluid has to expel all its waste heat through a radiator like this, that being the "cold reservoir," before re-entering the cycle into the "hot reservoir." A condensing steam locomotive is a perfect example of this cycle, the water/steam a closed loop, the boiler being the "hot reservoir," the condensors and air that cooled them being the "cold reservoir." The greater the difference in temperature between these, the more effective the radiator and even cooler the ambient air, the more efficient they were. There were a few condensing steam locomotives built, they had massive condensers, I believe usually on the tender. They were thermodynamically more efficient than open-loop steam locomotives, and didn't need to refill water, but complexity and bulk of the condensers made them rare.
Internal combustion engines work rather differently in terms of the "hot" and "cold" reservoirs and the radiator's role. These are open-cycle engines, where the working fluid is ambient air drawn in, used, and expelled as exhaust (disregard EGR). The "cold reservoir" is the cold air being drawn in through the intake. In an "ideal" engine, as analyzed in my 300-level thermodynamics course, no heat is exchanged with the cylinder walls, all heat is added via combustion and expelled via the exhaust when the hot gases are exchanged for a new charge of fresh air. The waste heat leaves via the exhaust, not the water jacket. However in reality some heat is conducted into the cylinder walls and piston, which causes two things, both bad: For one thing, a reduction in efficiency as the heat leaving the cylinder that way is lost energy that otherwise could (partially) provide power. For another, this heat would heat up the engine block until it melted or seized if not removed by a cooling system, which adds a lot of complexity, weight, absorbs some mechanical power, and so on, but is necessary for the engine to not melt down. Heat dissipated from the radiator isn't an inherent part of the thermodynamic cycle but an unavoidable byproduct. The larger the volume to surface area, the less heat is lost this way, so fewer larger cylinders in theory would need proportionally less cooling (and be more efficient) than an engine with more smaller cylinders, hence the trend in that direction - this was something the video got wrong. It is still overall a fairly small fraction of the overall heat energy though, the majority of the leftover waste heat exits in the exhaust. The radiators, even if seemingly huge, are a lot smaller than they would need to be if expelling all the heat from a closed-loop cycle of equivalent power and efficiency. The overall heat to be dealt with is still at least roughly proportional to engine power, hence why more powerful engines need bigger radiators. I feel like that intuitively makes sense even without all this thermodynamics discussion - more power = more heat = bigger radiators.
Then, as briefly mentioned, as well as more powerful engines there's also emissions and efficiency stuff. I don't know the details of split-cooling, but overall modern diesel locomotives would need to cool not only the block, but also an intercooler and EGR. Earlier locomotives didn't have EGR, and I'm guessing didn't have intercoolers - many weren't even turbocharged in the early days. I also understand that, probably for NOx reduction, the engine has to be kept cooler than in the old days. This to my understanding is why Porsche had to eventually switch the 911 series to watercooling, the air-cooled engines worked pretty well but ran too hot to be capable of complying with modern emissions standards.

Very good with explaining the basic physics behind engine cooling systems! The concept of "Work" is very slippery - sometimes even physicists argue over what exactly "Work" is. But you explain it in a nice simple way.

I Saw a meme once that was a ge cab and the whole long hood was replaced with a radiator with the caption ges next locomotive

thanks for this topic, Ive been looking for this for so long. one of the reasons why I love modern gevos like the Tier 4 because of its massive prominite radiator block

This video is great I learned a lot in 8 minutes

Me: I like trains.
SPR: Here's thermodynamics explained in 8 minutes using trains as examples.

You get a subscribe just for bringing the heat death of the universe into this. Masterwork!

Cheech Marin, admiring radiator flare: (loudly sucks in air) Oooooh baby, you're so too much!

Great Job!

I’ve never heard the letter W said so nicely lol. That was a heart warming dubya right there.

This was great!

Excellent presentation!! Thanks!

2:20 what you are looking at is liquid hydrogen at near absolute 0. When hydrogen gets that cold it loses all friction and gains the ability to wick itself along and through all sorts of materials. It is wicking itself up the tupe in this clip where it falls back down into the pool before going back up the tube. Its like perpetual motion if it didnt require constant cooling to keep it that cold. Hydrogen can also wick straight through glass at these temps, as in between the atoms and straight out the bottom like it went through a hole (while also wicking itself up the walls and out the opening at the same time)

Great video.

Merch This was amazing, thanks keep them coming I have seen all your videos but one new one with very flared radiator wings looks like it may fall over lol

Hi everyone

Nice Video I Love It!

This is where Exhaust Gas Recirculation comes in

Saved the most important factoid for the last seconds.

Both EMD and GE were already offering *BIG* radiators on their locomotives in the 1990's in anticipation of the arrival of 6,000 bhp prime movers such as the EMD 265H or GE/Deutz HDL. But both engines suffered excessive fuel consumption and reliability issues, and they were dropped for smaller prime movers with other power efficiency improvements.

I think you forgot the Heat Rejection out the exhaust ! !!!!
There is just as much going out there as the radiators.
Q= mass. x ( T out. - T in)

I learned about the thermodynamic properties of a locomotive while dealing with existential dread pertaining to heat death. Nice

Nice job!

Great video thank you 👍

That is an excellent explanation, referring to the entropy. The increased use of dynamic braking reverts kinetic energy, switching motors into generator mode to electricity, which is sent to the radiator to disparate as heat. I read that some test models had a battery to store extra power to assist during shunting and maneuvers. Just my 2c. Cheers!

Great video!
One question, I've never seen the road railers (8:25) being used around Michigan. Are they still used much, and if so, where are they most often seen?

Im not onto trains, but i like them. So cool video!! I NEVER knew they had radiators!!!!!

I find this video cool! Keep up the good work Southern Plains Railfan! If your ever in Houston, go to the Rosenberg Railroad museum. They get alot of BNSF and UP trains and they got other cool things like a garden railroad (which runs a warbonnet dash 9), a Mo-Pac caboose, and a wig wag!

Damn, this was an unexpectedly good recap of my thermodynamics class, from a railroading channel. Nice.

I really like how it switched from a train video to physics. Great video by the way 👍

Plenty of energy actually exists the exhaust. You kept saying, the heat that is wasted goes into the engine block. However, a fair amount actually goes out the exhaust ports.

Love the video! While I know it wasn't supposed to be funny, I did love the casual-ness of the heat death of the universe and entropy. Cracks me up

I think the design engineers just want to make it next to impossible to see behind you. haha

you tech thermodynamics better than my science teacher

Never knew locomotive radiators were related to this heat death of the universe, I heard a rumor that it's on August 12th, 2036(feels too early)

Love the IAIS stripe in the background! 😉

That was interesting. I had always assumed that the huge radiators was required for heat dissipation in dynamic braking conditions.

Ive always wonderd why the radiators looked like that. Thanks for explaining Southern Plains Railfan. I learned something new.

This video was fire.

A video about something I thought I’d never knew for a long time. Well now I know the reasons for these radiators (I use to know some about it before though).

Ive also always wondered why the radiators on locomotives have gotten so big this answers my question thanks

Thank you 👍👍👍

Not all of the waste heat goes into the engine block. A significant fraction leaves via the exhaust system.

Do the excess heat dissipated by the radiator was being reused? I wonder if the radiators works as a heat exchanger too

Thanks for the physics lesson 🙂

That sd23 t4 horrified me

Great video was wondering why radiators were so many different size’s

Did you get a new intro, SPF? if so, it's very good

The heat death of the universe is my favorite topic in railroading!

Very good video our friend! (Dave).

My friend is a mechanic at the bnsf shops in Minneapolis and I think you need to work there. You would obviously love it. Plus I know he makes about 120k per year. Pretty good if you ask me.

As a Tier 4 complaint locomotive, the ET44s probably needed the larger radiators to reduce their emissions, thus better for the environment

I thought the extra large fans were for better dissipating heat generated by dynamic braking, helping to cool the truck motors when they get hot

Interesting fact about EMD SD23T4, it used a GE Inline 6 cylinder T4 engine hence the larger radiator.

Good point in that as power of the engines increase they need a larger radiator. However you incorrectly state that all the waste heat must be removed from the engine by the radiator. Only a small fraction of the engines waste heat will warm the engine and is removed by the radiator. . Most of the waste heat goes out the exhaust pipe and warms the air!

So the radiators have gotten larger because railroads want to destroy the universe faster?
Hmm, makes sense.

The ac6000's have the best radiator design imo, sucker literally overhangs the rear anti-climber😂

They do that so it’s easier for model train enthusiasts to pick up their model trains by the radiators.

The combustion temperatures have also been increasing to get the very last drop in increased efficiency. The excess nitrogen oxides are dealt with additional equipment

Liquid radiators can be made thicker for more liquid tubes, to handle larger engine heat transfer. The heat sinks for the dynamic braking need to be more exposed to dissipate the heat. When the engines pulling power increases, they also have to increase the dynamic braking capabilities of the locomotive proportionally, thus they have to increase the ability to dissipate the heat generated by the increased dynamic braking. Since there is not a water jacket around the dynamic braking load banks, the ability to move air over a larger heat sink has to has to happen.

When where you on Caddo Lake filming KCS?

Does it also make difference due to 2 stroke vs. 4 stroke engine?

I put an enormous radiator in my vehicle. Oil stays cleaner, the electic fan rarely runs, it seems to make more miles to the gallon. The benefits of a large radiator are great.

I wonder why these companies never thought to use the exhaust manifold as a steam boiler and put an extra turbine on the turbocharger as an assisting system? Steam could also be used to spin a small standalone turbine for extra electric power in a closed loop.

Thanks for putting it in better words then I did.

What is that train car at the end of the video? It looks like a low profile semi trailer carrier? I have never seen that before.

Isn't some of the radiator space used to disipate the heat generated by resistive heat coils in the dynamic braking system? There was no mention of dynamic braking in the video.

I like The Simpsons. That's the teacher strike episode. Hey, maybe you could fill in?

I always thought what are the large overhanging radiators were the resistor grids for the dynamic brakes.

Are they exempt from running after treatment?

What about the EMD F40PH locomotives???

Cool!