LS TURBO INTERCOOLER TEST-ATA vs ATW 

I mean, it's not wrong.

The sound is music to our ears, so I'd say it's accurate. I find it even funnier when it says "applause" to the sound of a dyno pull

lol

That’s true but a2a intercoolers have a power rating, so putting in a larger intercooler would have brought it back down

Intercooler power rating is an airflow rating, not cooling capacity. You can install a straight piece of pipe that has the same horsepower rating.

Totally agree; was about to post the same. If the ATA setup was octane/ knock limited or tuned to the point that it was knock limited, you’d see the difference between the ATA and ATW intercooler. 14 degrees won’t be a huge difference, though. Would’ve liked to see the ATW run with ice water to show POTENTIAL difference, too.

If you’re watching this channel you probably also watch Paul. They’re definitely cut from the same cloth.

The meat target would definitely make this more interesting.

@@krtacct 20 something bikini model?

I was just telling Dustin Lee that Paul Harrell is like talking engines with guys that know what they’re talking about. Literally 10 minutes before I watched this.

Bah! I did that every morning, driving to work in my 42 HP Austin Mini back in the 70's.

Why haven't more people at least acknowledge your comment ... I believe you are correct

Yes. I agree.

Basically the Boost curve would be identical. The difference is about 3% less hp around the curve entirely under boost with no intercooler do to the inefficiency as the heat in the inlet would be +165'F

Or even vs a carbed blow thru setup.

And with ice water in the air to water system also.

Very true. He's not testing a closed loop water system. His water source is the dyno cell water. Most people only have small tanks and serious guys have actual cells full of ice.

That Cletus event will be super cool

Keeps air intake temps below 160 and all is good. Nothing to gain.

Both were already optimized

Hmmm, but it was the same timing on both setups? At 10:50 you said timing didn’t change.

ATW may have advantages in transient operations, space, minimizing charge piping, and depending on the application being able to easily cool below ambient temperature (ice in the expansion tank)

A general rule is 10deg temp with change 1% hp. In this case we should have seen a difference of only about 8hp. Nothing crazy but should have been seen in the comparison. Mystery. However, the lower charge temps should allow a touch more ignition timing when on pump gas where knock could be a limiting factor.

@@meetthecarolinas9638 That was the point I was trying to make, 1.4% (14 degrees) is nominal & is probably less than the margin of error for the dyno. Even if you gained the 8 HP by going ATW, you're not going to notice it from the driver's seat.

@@damonriddle1370 you'll absolutely feel it from the driver's seat, but it depends on your application. If you're banging off 1/8th or 1/4 miles you won't heat soak. Spend time on a road course, or pulling something up a hill and you'll quickly see the massive advantages of air to water.

Good post, most people forget this.

science alert-the difference in IAT shouldn't be expressed in Kelven. 12 degree difference compared to 108 base is 11% or 9.8% compared to the 112 degree base

@@richardholdener1727 I have to agree with Science alert, you must use absolute temperatures.

@@richardholdener1727 On that Mr. Holdener, I’m going to have to respectfully disagree 😉. But that’s what makes the world a great and diverse place. For completeness (and for everyone’s knowledge) : here is an overview of the reason that cooler intake air is more desirable. It’s because of the ideal gas equation: PV=nRT as I mentioned earlier. P = Pressure (Pa) V = Volume (m³) n = No. of moles (basically the mass of the gas in this case) R = Gas Constant (~8.315JK−1mol−1) T = Temperature (°K) All values are absolute values, not ‘gauge’ values (unless you have an absolute gauge😉, And are especially not US customary units 😉) So taking the example at hand: -P and V are fixed. P = 170kPa (10Psi gauge) and V = the volume of the intake manifold for simplicity. Its actual value is not important, since both are constant. -R is also constant by definition Which leaves ‘n’ and ‘T.’ Now in our case ‘n’ is the dependent variable, as it is dependent on ‘T’ which we have control over, via out choice of intercooling. Since both the Left and Right side of the equation must be equal: (Here’s the CRUX) as temperature rises, the mass of the gas must fall to maintain our desired pressure (170kPa) in our pre-defined volume (the intake manifold.) The inverse is also true (Colder air, requires more mass to maintain the same 170kPa in the intake manifold.) Since power output is dependent on the mass of air (Oxygen) contained within the cylinder, the cooler the intake charged at a fixed pressure, the more power you should make. Now as Richard (and others) have rightly noted, it is difficult to do back to back tests as: -turbine heat plays a roll, -Intercooler design (resistance across the core) effects results -Exhaust back pressure can be affected because of different Intercooler core resistance at the same intake manifold pressure. Turbo must work harder to push air through a crap cooler to make the same manifold pressure -> higher turbine drive pressure -> less shaft power at the crank. -Atmospheric changes (humidity and temperature) -Fuel temperature -The list can go on. Regardless, the test performed is very good and very insightful. I whole heartedly agree with Richard that it’s a matter of choosing the right tool (intercooler in this case) for the job. And that each design is best suited to differing aspects of motorsport. As a Circuit and Rally racer, Air-Air rules the roost 😉. I stand by my assertion that there is only a 2.5% relative difference in air mass entering the engine (Based on absolute values) in this test. Thus, this would fall well within normal test variance or within the dyno’s level of accuracy based on the number of uncontrollable variables (listed above.) Keep the video’s coming Richard. I’ll keep watching and learning from your wealth of test data. Regards Jordan

I think its the other way around, ive always read w2a had way less pressure drop than air to air. Im sure you could get a inefficient w2a intercooler that had more drop then a really efficient a2a but apples to apples w2a are better at maintaining pressure they are also superior at drawing heat out of air.

thnx-cooling the fuel helps-cooler air helps even more

@@richardholdener1727 At least that's what I learned from watching Engine Masters lol :) I wish I were closer to you guys because I'm building a 1.8 turbocharged ecotec engine out of my Chevy Cruze. Custom JE pistons, H-beam rods, big turbo gt3582 and shooting for 450+ whp. Uncharted territory, but a good lil foundation for a serious hp build because of the cast iron block and aluminum head with DOHC VVT. Thanks for all the great content. Your videos have helped a lot in furthering my knowledge. Thanks, Richard!

Yeah add 3 degrees and try again

No, you can’t match air speed across the core for the air to air. The air to water is using a pump with water pressure to force cool water across the core.

Exactly. So even if they were at the same boost at the intake, what was the pressure and temp before and after the intercooler? How about the backpressure? Never enough data collected/presented on these intercooler tests to answer the question. Power tracks with mass airflow (less inefficiencies) Have a higher temp but the same manifold pressure? You have less mass airflow and less cylinder pressure. Made the same power power to the flywheel though? Probably exhaust backpressure.? Whats the turbine speeds? DATA Richard!

the pressure drop across both cores was identical-they were not restrictive at this power and boost level

Correct, i would like to see a boost port on either side of the intercooler bridges to a boost gauge to see the pressure delta.

Not if the wastegate reference was coming from after the cooler... then the pressure at the throttle body will be the same either way.

W/A IC generally have lower pressure drop due to their relatively short and wide flow path.

how do you know the ATW had a larger pressure drop-you don't have that data

@@richardholdener1727 hi mate, the cross section of the ATA is absolutely huge due to the tanks mounted on the long edges of the core (its the opposite way around on a bmw n54 intercooler) As for data, you mention all engine parameters were equal as was the power - this was dispite the charge temp difference. It's seems it takes more engine effort to push airflow past the WTA intercooler which looks to be a significantly less cross section than ATA core. What are your thoughts mate? 😉

Yep and that is the problem with alot of these dyno tests. They seem to think that if they keep everything the same, the results are a direct reflection on the thing being tested. Methanol Injection test was a big one.

Short version: Road Race, air to air, anything shorter duration, air to water...

Water to air is better if you have a icebox but its dont last long before the heat melt the ice = good for drag racing

Also this test might be more consistent with a supercharger since is not dependent on engine load as much.

Seems about right

air to water isn't the best choice for road racing

more like dry ice and isopropyl rubbing alcohol!

Thanks for the sub!

we tossed around this idea after the first big bang motor to see how many pulls it could make at 1,000 hp, or how long it could stay loaded at that level

Also most will end up doing a 5.3, so how about possibly doing the forged 5.3 vs a stock 5.3 at a sustained HP level most could feasibly build for, and see when the stock 5.3 internals gives out, and how much MORE we can get out of a forged internals 5.3 WOOHOO!!

No sanction on public streets lol

we did

WOULD BE BETTER IF IT WENT ATA FIRST-THEN ATW

AIR TEMP GOING INTO THE TURBO OR BLOWER WILL DEFINITELY CHANGE THE POWER OUTPUT