You should revisit this for a high compression engine and see if cooling the fuel can let you run lower octane gas without having to back off timing.

On a boosted Engine with very good intercooling and with the fuel injectors very close to the intake valve it can actually help to slightly heat the fuel to improve vaporization. Improved vaporization will help prevent detonation while increasing power. Many years ago Ferrari used special fuel for qualifying in Formula 1 versus what they would run during the race. The qualifying fuel was supplied by Shell that contained isopentene and cyclopentane. It would vaporize very fast because it was a light molecule and they could run higher boost because it had very good octane. They couldn't run the qualifying fuel during the race because there wasn't enough BTUs per specific volume and they were limited by fuel tank size.

I wasn't expecting a big difference since you're using EFI, it's a dry intake. Cool fuel works with a carb and wet intake setup and I believe that is what Steve and David found.

maybe redo the test with a throttle body injection rather then port injection, that way the fuel is in contact with the air longer so you get more actual air charge cooling?

I think you'd see a significant increase in power if you were using throttle body injection or carburetor. You'd essentially be cooling the air charge with the cold fuel, as opposed to the port fuel injection, which doesn't have enough time to cool the air.

I believe what we are seeing here is that the latent heat of vaporization has more of an impact than the temperature of the fuel itself. Good content!

My 94 s10 is running straight up E85 ! 2.2 l ! with the vortex cyl heads the cooling effect of E85 is pretty remarkable ! note : this is a 640,000 mile vehicle and no harm to any component done ! + i saved $ 18 on my last fuel up

I think the AIR needs to be cooled. Liquid is a set volume 40 degrees or 120 degrees. Air can compress, which means more oxygen in the same volume. I think if you put the injectors up high where it has time to cool the air you'll get a power gain.

The thing is,my 79 scout 2 had a dry ice can on it. I noticed a difference when the engine hit 210-230* temps the power didn’t drop off like a hot engine does. So even if your 4x4 is overheating in the mud, you still have the power of a cooler running engine to get you out of the mud hole you’re battling. So that’s where this test needs to happen. Like a hot running 671 blower to put more timing in to it.

Very cool test, Richard 🥶. I fully expected your results to show some significant gains in power with the frosty fuel. Based on this test, I doubt that chilled fuel would make much difference on a boosted application either. Oxygen rich cold intake air along with cold fuel should be the way to go for decent power gains. Thanks for sharing your results. Now we know 🤔.

I recall reading a book by Lingenfelter (maybe it was Banks) that mentioned how cooling fuel is counter-intuitive. You are expending energy within the cylinder to warm the fuel up to the vapor/burn temp which ultimately is wasted energy. Essentially, you want cooler air and warmer fuel. The caveat to this is how the fuel is injected; I would agree you would see various results depending on whether it is GDI, Port, Throttle Body, or Carb.

I would have been surprised to see any significant difference. The thermal mass of the fuel is very little compared to it's latent heat.

You got what I expected for hp gains in a port fuel injected application. In a carbureted application the pressure drop across the carb has an additional temp change caused by the pressure drop across the carb. The lower fuel temps would merely add to this temp change causing a greater charge cooling effect on the fuel/air mixture resulting in higher hp gains. On the port fuel injection systems the location of the injector negates any additional effects cooler fuel will have on the charge temperature. It would be interesting to see if changing injector location would have any effect. I suspect it won’t have much of an effect.

This was fun and informative Richard! Thanks for being willing to test out our crazy ideas. For sh*ts and giggles, you could go totally crazy with this by cooling the fuel way WAY down by using antifreeze and dry ice instead of water/ice in your cooling bucket. I don't think it would make any more power, but what do I know? That's why we test!

I'd definitely want to see it on a forced-induction engine, but you'd probably want to configure it for a full return setup. The carb version likely made power since it stayed cool from all that thermal mass. The fuel rails have much more surface area to absorb heat. Also the music was throwing me thru a loop til I realized it was "chill" music for a chilled-fuel topic. lol

Latent heat of vaporization is why Ethanol cools the intake charge, which works with the added O2 in the fuel to make more power, when you drop the intake temp by the fuel vaporizing it makes a denser charge. Cooling the fuel makes it harder to vaporize the fuel, even in a relative vacuum in the intake port/manifold. Boiling point goes up with more pressure, down with less pressure, so you are exacerbating the problem with cooling the fuel with a lower pressure in the intake. Gasoline needs between 80F and 450F to vaporize the component chemicals in it. Obviously some of it never vaporizes fully, which is why it wastes so much energy as heat that we have to get rid of with the radiator and exhaust. Cooling it means it takes longer for it to vaporize, and more heat in the intake. It should help with ping/knock and vapor lock like Dave and the Steve's found on EM, and cool the charge slightly just because its cold, but its when a liquid vaporizes that it pulls the heat out of the air around it. Already know what happens if you run E85 cold like gasoline. You use more of it. The power stays about the same, but you get worse mileage. If you run an alcohol engine, be it ethanol or methanol too cold, like with a 160F or no thermostat, you are going to milk the oil on the street due to condensation building up in the crankcase. It doesn't like to vaporize when its cold, which is why it doesn't like to start when the air and engine are around 20F. Trust me, I run into that here in Michigan, but you wont in SoCal. Below 40F I have to get creative starting one of my E85 Pontiacs with a carb. EFI starts a bit better, but it takes considerably longer than when its hot. Ethanol plays different than gasoline, it takes another thought process entirely to get the most out of it. It actually likes the heat in the intake, heads, ports, air, and fuel. Because all of that makes it vaporize more readily. Now its not going to make a big power increase running everything hot like that, but it will use less fuel. You probably won't see a difference in power going from 48F fuel to 200F fuel running E98/E100, you probably won't see a bfsc change either... but.. in a street driven vehicle, you will pick up mileage and keep the power. There is more to it than bfsc, tq, and hp. Lots of variables at play in a running vehicle that are simply not present on a dyno, but you already know that. Move the injectors farther upstream and heat the ethanol before it gets to the rails, but after the return so you're not sending heated fuel back to the tank, and it has more time to vaporize. This is what I have been working on in an effort to get better mileage on ethanol, along with building my engines with as much compression as I can put in them... which precludes running pump gas. The power ends up where it ends up, but with 13:1 compression in 455s with nearly double the CFM of a stock head, they make some power. Man do they ever drive nice too.

Definitely do a centrifugal supercharger to see if charge cooling is significant! Also, just because it popped into my head, make sure the oil cooler isn't a restriction or somehow dropping pressure! Also check AFRs, they may make the same power but one could be richer/leaner. I've learned so much from your videos, you're a huge reason I have a 6.0 and 4L80 in my '87 Silverado!

I like these tests, because it always brings up more questions than answers. But I agree that doing it with carburetors would yield more change.

Bringing us content we dint no we needed Thanks Richard!

I've used cool cans with carbs and had the Holley float bowls dripping with condensation and sometimes even what looked like frost. I've used dry ice in cool cans.

Would be cool to see if fuel temperature has bigger effect with outboard injector setup.

Might see a bigger change on an all out big boost combo. Sometimes a little heat helps atomisation though. I think the power gain from ethanol is because it carries its own oxygen molecule as well as 6 hydrogen molecules. You should do a 10% nitromethane test!

Did this test on a turbo Mitsubishi on the dyno back in 2002-2003. Made about 12-16 awhp on that particular setup.

Try it on a tunnel ram. Run the fuel through a NOS style plate (no holes in the tube) before it feeds the carb. Also, you can add salt to the ice. Add insulating tubing around the hard lines after the cool can.

Absolutely makes sense that it could improve power. But more so if wellnatomized fuel was mixed before going through the intake.

I would try it on a carb or efi carb style setup where the fuel enters at the beginning of the system

The vast majority of the charge cooling you get from fuel is from the latent heat of vaporization of the fuel, not the heat capacity in liquid form. Gasoline liquid has a heat capacity of 0.53 BTU/lb-deg F, but a latent heat of vaporization of around 150 btu-lb. That means that your 48 degrees of extra cooling only bought you 25 BTU/lb, or in other words 17% more cooling of the charge air than you'd get from the vaporization of the fuel alone. The power improvements from icing down fuel and manifolds in carbureted applications probably comes chiefly from cooling the manifold and carburetor down, minimizing the air heating from those (normally) hot surfaces, by improving volumetric efficiency. Good and interesting test, thanks Richard!

I read an article years ago about Smokey Unick where he heated up the fuel to 212° and used a turbo charger , not for boost , but to atomize the fuel and got quite a bit of increase in performance and mileage.

years ago i did a similar test on a carbureted street-strip car using a cool can. with cold gas i could discern a small improvement at the strip--a few hundreds of a second. in the interest of science--and my warped curiosity-- i lowered the fuel temp until i had frost on the float bowl. at that point the car slowed down, i believe because the fuel was not atomizing as well at those temps. the cool can works for a dedicated race car looking for every last hp. for a street-strip car the extra complication, clutter and inconvenience was not worth it. plus, unless there is ice in the can, the cool can will heat the fuel.

Awesome work. I thought exactly the same as you and expected a noticeable change. Thanks man!

Droplet size is the key to increasing efficiency in charge cooling... Since the droplets are the same size, no change... however, moving the injectors up the manifold will give the fuel more time to evaporate, and remove heat from the air... conversely, if you could make the droplets smaller, increasing the surface area, you will start to see gains, all things being equal. This is the idea behind ultra high fuel system utilizing DI injectors in a port position... significant charge cooling can be achieved.

Thanks for the video. I was wondering about this a few days ago. Please do one on carburetors.

I would like to try a cool can setup on a racing outboard. These are two cycle carborated two cylinder motors. Relatively low compression. Just an improvement of 200-300 rpm would be beneficial . Worth my while? ROGER

I agree, that it shall be done on high CR engine that is NA, and look at timing, normal, vs cold fuel and what may happen with the AFR, and yes with the fuel injectores further away from the port.

The fuel needs distance to cool the air to make the air denser as you said, I believe the cold fuel that close to the combustion will give you more detonation resistants in the car and lessen hot spots in the combustion chamber… more boost (more timing if it will take it) or try one of those throttle body injection deals.

I think the cooling has more of an effect when you have an engine that is really pushed to its max. It doesn't as much add power as it allows you to push other things farther. Timing, compression, boost, etc.

Please try this on a carb set up. Thanks for the videos!!

Richard you made a really interesting video here. I think you could look at it from a different perspective - how much power can you squeeze from low quality gas? What say I lived in a place where only low octane fuel is available? Does cooled fuel allow me to run a higher compression/higher boost/advanced timing for a given octane rating? I'd love to see you also revisit the water injection with the same perspective because your video on that showed that we lose power by adding water-only injection. What about the gains that can be made by the raised "effective" octane now that it's water injected? In that video you ran the same fuel, but didn't push the new limits of the fuel "octane" after water injection. IE, higher boost etc BUT good work I love your efforts!

Yes sir I think you should do the force induction test. very knowledge worthy thank you for helping us..

Cooling the fuel can theoretically help, but at the temp differences you're looking at the change in heat of evaporation is small. Even going from 212 F down to 50 F is only going to increase the heat of evaporation of a gasoline fuel by about 10%. The real cooling effect is from evaporation itself and much less from the process of heating the fuel till it reaches evaporation temp in the intake tract. In contrast, the heat of evaporation of a pure ethanol fuel is about twice that of a gasoline fuel, so you're going to pull out much more heat switching to E85 than you could theoretically do by chilling gasoline in the temp ranges we'd expect on the road.

Definitely do another test. If you can, test all power adders, I realize that may not be easy.

That's a huge surprise. My old drag race buddy Jim Hand had a homemade cool can made out of a Coleman cooler and about 10 feet of 3/8's copper line. He swore it increased his quarter mile times by up to on tenth of a second. That's 10hp or so. But that was in the car, at the track so like you said, his fuel temps might have been 140 degrees plus, and it was also a carb vs F.I. I personally have never tested this but I do know a plate between the carb and intake that cools makes a little difference. Try a carb and try a turbo application.

Great channel bro, a real scientist over here 👏 👍🏾 🙌 💪 👌

I ran circle track we were running a zz4 with a carb before qualifying we always packed the intake and carb with dry ice and wrapped with towels covered the fuel cell with dry ice bumped the timing up blocked off the nose put sterno camping fuel on the bottom of the air cleaner hat and it always picked up time on the track it definitely lowers intake air temps

Seems like as you super cool fuel, the molecules contract and therefore, you should be able to get a denser fuel charge in the combustion chamber. I would like to see a wintertime outdoors dyno. Cold air and fuel, vs a warm indoors dyno test

How does the engine behave when the engine is summer hot vs winter cool like at a drag strip? Figure the Cold Fuel would help keep engine cooler making the runs more consistent!

I think the reson for the the difference with a carb motor is where the fuel comes in. With carb at the beginning and with a EFI right before entering the cylinder. The carb had time to mix with the air and lower the charge temp. I think.

I believe it'd benefit the supercharged blow through carb or fuel injection the best. It'd give the fuel enough time to make a difference on cooling as well as a measurable effect on high pressured air.

I think the most important thing too takeaway is how fast fuel temperature increases in such a short amount of time. You’d have to start thinking about super cooled fluids(liquid hydrogen cooled) and their interaction with none supercooled mater.

The setup is just not Octane limited... Test it on a high compression boosted engine running on the edge of the given fuel. 48* drop of fuel temp doesn't make power, but it will reduce knock if you are on the edge of the given fuels limit.

I'm thinking dry ice + acetone (-78c ) and a wet setup (carb or tbi) should show an improvement. Not practical in a race application but would be cool to see the results.

Yes please do the test with blown app where there is no intercooler , these should show intake temp drop and then hp gain

Thinking about it we had heat soak in circuit use with low fuel and assumed fuel was too hot. But filling with cool fuel didn't restore power or reduce knock.

I live in Iowa. I dont feel any more power in the winter time than I do in the summer time. If you think that is different, I would have to argue it isn't. The fuel defenatly gets colder than 44 degrees f. It gets cold enuf to make a diesel engine gel up & stall out while it's running somtimes.

I’d like you see it on a boosted application. For sure. I’ve always wanted to make a cooling tank under the hood on a turbo car. I’d like to know if I’m wasting my time. I thought it would make a difference. I thought it would work on a NA engine too. But I guess not !?!?!

When you ride your car for 30 minutes fuel is gonna be more than 95F. When we had some fuel pressure problems with a turbo Mx5. After 30 minutes external fuel tank temperature was (more than the exterior of the final exhaust muffler) around 130-140F. Muffler was at abient temperature so heat was fuel pump induced

I've often considered running a fuel cooler on my Fox Mustang. I'd be very interested in seeing a boosted application test of this. Curious to know if you'd see any difference running this fuel cooler test on an actual car at operating temp with everything heat soaked & see if the fuel cooler makes a difference in performance?? I like your test & backed up by data, but it doesn't represent what we'd see in our cars. My thought process is, many of us are running higher volume/pressure pumps, & headers, all leading to more heat soak into the fuel, especially with the return style fuel system, at what point are we completely heat soaked in the fuel tank as well. Pumping hot fuel has got to lead to premature pump failure? Just curious to see some data on this on a moderatly modified street application.

you should take a street driven car that has the same motor your gonna use, test the fuel temps on a hot day driving around. Replicate those temps on the dyno for NA and boosted, get the dyno numbers for both setups, then do runs on both with the chilled fuel. It would be a more real world test in my opinion, you could put the cooler in a bucket of fairly hot water to raise the temps. That I would love to see the results of, I live in south florida and rock a fox body with a 5.0. It's been mid 90's every day here and I bet my fuel get stupid hot, I'm curious what kind of temps my fuel is when driving around town.

I can explain your result Richard. Basically two things happen here, you heat the fuel from the starting temperature to the boiling point, then you vaporise it (boil it). The act of vaporising most liquids will take far more heat out of the air than the heat it will absorb just coming up to the boiling point. I will give you some numbers so it makes more sense (A quick google gives me all of the info for ethanol, petrol wasn't as easy to find so I will pretend you're using ethanol, concept is the same either way, I'm also going to use metric because I'm Aussie). While the fuel is still liquid it will take about 2.5kJ to heat 1kg up by 1 degC, ethanol will vaporise at approx 80 degC. From a starting point of 32 degC thats a 48 degree difference, so it will take 94kJ to heat that fuel to boiling point. From a temperature of 80 degC it will then take an additional 850kJ to turn that fuel into a vapour. Thus, only about 10% of the heat taken from the air is used to heat the fuel to boiling point, the other 90% is used to vaporise the fuel. So by lowering the fuel temperature to 6 degC you are removing an additional 52kJ (32 degC - 6 degC = 26, 26*2.5kJ=52kJ). Before you cooled the fuel it took a total of 944kJ to vaporise 1kg of fuel, now it takes 996kJ, so you have cooled the charge air by an additional 5.5%, which is likely why you didn't see a difference. If you knew the fuel flow and air flow you could always calculate the theoretical change. (this could be done just from the power figure, but who's got time for that)

Tunnel Ram intake, with downdraft throttlebodies and the injectors at the top of the runners or even up in the plenum, also use a return type fuel system. perhaps 16 smaller injectors rather than 8 big ones, will atomize the fuel better and faster too.

Two things, think ice cream cooler. You can get the water below freezing by using a brine slurry. Second, as I understand it, there is more chance of fuel dropping out when the exhaust crossover is blocked on an intake, hence the use of downleg boosters to provide better atomization. So how does cooling the charge not also create or have the potential to create more fuel dropping out of suspension? I remember Smokey Yunick superheating fuel for his little Fiero project to make it (I suppose) super efficient.

What would happen if you had a higher pressure fuel system and tested from cold fuel to a heated fuel. The higher psi should prevent boiling of the fuel, but would the heated fuel aid in vaporization, leading to better mixing of fuel and air?

We use to do this with the trans cooler on all our derby cars as well as the oil cooler. I think you should try it with a super charger.

Excellent video. Definitely giving me plenty to think about. I think something like this would probably work out really well on like a carbureted engine with high compression and see if you can run a lower octane fuel

Cooler air makes a huge difference! Could try running a fuel line into the upper intake then to the injectors to assist to cool the air.

Bob Glidden Ran Pipe Insulation on All his Fuel Lines .Even Put Insulation Around His Intake !. Anything to Keep Heat away ! ! ! . . .

Heating a nitrous bottle keeps the valve from freezing during decompression. Really important for the dragstrip.

It would be nice to see if you moved injector to top intake the difference. I'm sure it's all about not enough distance to cool the air.

It would be interesting to see the results in a boosted application limited by knock

awesome test!!! would definitely like to see this test on a boosted setup

This is an interesting test. I added a fuel cooler like 2 years ago. i was running an external fuel pump on my return style system and my exhaust was close to the pump and tank. I was getting a condition where the car would warm up to temp and started having fueling issues that caused it to stall. I thought it was due to heat soak of the fuel returning to the tank after leaving the engine, but it had more to do with how the fuel system was wired.

It would be neat if you did a Smokey Yunick [Hot Vapor Injection] engine test.

the problem i see is, that we talk about a relative small amount of fuel over time going into them engine. so you do cool down the fuel, but by the time it gets to the injectors it heats up again. surely cooling it even more can kinda help, but even so my suggestion would be to somehow insulate the fuel rail it self and cool that as well. should make a difference, but i would not expect anything ground breaking...for that you would need to cool the fuel down to sub zero celsius values anyways.

Richard, I have a genIII COYOTE. Have heard that Ford uses direct injection togettop end power. Cool the fuel for direct injection? Orcool all fuel? Thanks, love your vids.

The EFI intake manifold has a lot of surface area, and had the engine been enclosed in sheetmetal to replicate an engine compartment, would hit over 200 degree temps. Since its a dry manifold, the fuel wouldn't cool it, but I think on these dynos you run 60 degrees on the inlet air, so in effect you're already accomplishing a cooling effect.

Hi Richard. I’d be curious to see this revisited on a blow through carb application

Turbojet aircraft engines often use a FOHE (Fuel-Oil heat exchanger) to cool the oil, and intentionally heat the fuel so it atomizes better in the combustion chambers. I understand there is not an easy and safe way to do this for car engines, but it would be a neat experiment.

I think you would need to super cool the fuel , like down to the temp right before the fuel “ freezes” . As the fuel gets colder it should become more dense and can fit more in the same size tank .

I've always been curious how much air cooling results from the venturis. The principle of accelerating the air within the venturi to create low pressure drawing fuel out of the float bowl uses energy from the air - heat.

Definitely try this on a boosted application with direct injection. Also, put the fuel in the freezer

I feel like the carb set up has a better chance to see temps drop but I oy if it's not sitting in the bowl for forever. Probably needs timing to see it's fullest potential

I ran a 12 X 12 fuel cooler on my 76 gmc sprint after I did a mild build on the 350. It could be 95+ degrees and the carb would have condensation dripping off of it. Never had a problem with vapor lock! I would love to see what happens with a boosted engine running pump gas with no ethanol.

Do all three, and relocate the injectors. Plus: Add table salt to the ice bucket (Too improve heat transfer) and run a larger color as well. I have a feeling that if you get high-content alcohol-based fuel cold enough, it'll be like "Who needs an intercooler...?!" Especially if the injector placement is stratified correctly.

Some key considerations. 1, fuel atomization v vaporization. Colder fuel is harder to vaporize, which leads to combustion anomalies because of wet flow changes. As more atomized fuel can enter the chamber and less vaporized, the wet flow now, theoretically, favours a leaner tune. This would be interesting to test on both low octane fuel and E85. 2, an engine uses air as its source to generate cylinder pressure. The fuel heats said air when its burnt. In this fuel injected example, colder fuel doesn't change the density of air to increase the cylinder pressure, only the fuel burning characteristics. Compared to a carburetor application, the colder carby lowers air temperature. Because the air is colder, it will expand more when heated, thus generating extra cylinder pressure. 3, it would be interesting to see if timing changes were made, or if a/f ratio changed.

Thanks for sharing. Please redo the test with higher delta T and boosted application.

Looking forward for this test with a single port injection and boosted engines :)

Vaporisation (liquid to gas phase change) is what takes a lot of heat input. Not so much for just heating up the liquid to vaporisation temperature. So get that fuel atomised as fine as you can and injected further away from intake valves to allow time for phase change. Then results will follow...to some extent at least!

The question is how cool is cool enough? If the fuel was hotter than normal would it lower performance or is 90 degrees fine

I had a crazy idea about this a while back- wrapping the injector rails with coiled copper line and running LN2 through them. That way the fuel is chilled right before it is injected and there’s no parasitic heat getting to it beforehand like on an inline cooler setup.

Cooled fuel does not shrink and then expand to a larger volume. Fuel needs to expand to mix into the correct ratio to burn....cooling will cause thos process to take longer. Super cooled air contracts then expands rapidly when heated creating more volume and pressure inside a confined space giving a larger volume to burn when compressed. The old police interceptor I had used a brass plate I'm the bottom of the intake to super heat the fuel quickly into gaseous form and using cooled air did give it good performance.

Ice water is OK, but you can only cool down to just above freezing. A big spiral of stainless tubing, in a bucket of just ice. With a way for the melt run off to drain. Now you have below freezing ice directly cooling the fuel. I deal with chilling liquids to as cold as possible on a daily basis. Straight ice is always colder than ice water

I didn't think it would add power, but figured it would change the afr. Did that change?

Definitely try this on a roots type supercharger on a big block chevy

I understand lil change in power but should max timing out with hot fuel and then I’d bet you’d be able to increase timing with cold fuel??

boosted either turbo or SC should be interesting...a twin screw with a carb on top & cold fuel should see some gains

Try it with a turbo and moving injector location, some BMW use water injection to cool the intake manifold (what I think that it's happening) is that the fuel has to be able to vaporize when the heat in the combustion chamber is enough, so it needs to be in very tiny droplets and a little high temperature, but before entering the combustion chamber the fuel could transfer his coldness into the intake air charge to make it densier, and therefore the fuel being hot enough and the air cold enough, so moving the injectors should help, and increasing temperature difference like in a turbo aplication should also help, becauseof it can take more advantage of it

Fuel turns into vapor before it’s fired that cooler temp fuel wont matter after it gets vaporized/mixed with warm air, now if you dropped temp of incoming air to match the temp of the fuel that will impact more as its will be a cooler charge all together. There is 12.7:1air to fuel ratio feeding a engine so the air temperature will have a larger impact.

I wonder if real-world, i.e. under-the-hood temps, would make more of a difference. If the fuel coming to the engine is 180°, vs 90° to start, and cooled by 50 degrees to 130°, will that possibly be more beneficial than a 90° to 40° drop?

I think cooling the air would show better results then cooling fuel. Give chill factor performance a call see if you can test one of those intake pipe cool wraps.

I would like to see this test on say a sniper efi of fitech. Also a bigger cubic inch that would require a bit more fuel supply.