Unofficial Message Board Home of Steve Wood
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Could be, I am on the north end of lake Superior but no.If you said a turbo at a certain rpm flowed, by itself, enough air to make 1000 hp I get that.What started this is a guy locally wanted to put 2 stock gn turbos on a warmed over 400 sbc and I don't think that would work properly for a low 9 but I don't know how to explain why.Maybe I'm wrong.He ended up putting on 2 -70's.
It just seems to me there is a basic ''premise'' missing.If I put said turbo on a 1 liter motor it will make 1000 hp?If i put said turbo on a 16 liter motor IT will make 1000 hp ?What does ''support'' mean in this context?
It takes a given amount of air and a matching appropriate amount of fuel to create enuf heat to generate a theoretical hp.The turbo is an air pump and the amount of air it generates could be measured or calculated. When the turbo is employed, we must move away from cfm.One formula to compute a theoretical amount of hp is: CFM x 0.069 x 10 = maximum horsepower that a turbo can theoretically support.We used to see turbos listed with a cfm number and max hp supported. The above formula usually matched up between the two. As turbos compress the air, we have to deal with lbs of air mass per minute instead of cfm to take into account the increased number of oxygen molecules per cfm. I would guess the hp potential is based upon the compressor map at the peak of the efficiency zone. I think one must have a good combination to get close to this numberTyler may have a more modern formula?
If you 'maximize' an engine for N/A and add a turbo, you're pretty much going to blow it up. Or be happy at 2psi of boost.an N/A engine with a turbo isn't right, and a turbo engine ran N/A won't be right. Camshaft overlap alone knocks it out. An engine is a total system. Not a standard that all applications start from.Also: Everytime I hear or read the term ''back pressure'' I want to murder a baby bunny.
Brad, you used too big a turbo for the combination and it did not have a chance to come into the zone where it was designed for. It was lazy.
Tyler, if we use two stock GN turbos on a 400 inch v8, each turbo will see half the engine on a bank and bank mounting system. Therefore, each turbo will be feeding 200 ci which is less than a single turbo on a 231 Buick. Therefore, it will seem to be slightly larger as it is feeding a smaller system.In this case, it will be able to produce a bit more usable air flow (more mass) than it would on a turbo buick and it will add quite a bit of power.If you add some serious heads, and a big cam, then you have just changed the rules of the game. In that case, you have limited the utility of the two turbos as the power band has been moved up and away from the capability of the two turbos to keep up.It's the same with a 231 if you put higher flowing heads and a big cam in the engine...you just ran away from the turbo by pushing the power band to a higher rpm. You have to keep a reasonable datum on the combination if you wish to demonstrate a point that is valid. We are dealing with something that is fairly simple in concept but quite complex in application.
More testing for you. I bolted Norbs' 70 P trim with a .63 Garret exhaust housing on it. The car went 12.2 at 114 with the high/low gear 02's checking in just under 800 with alky on 23 PSI. I slapped the 6262 on it with the same tune and the car instantly went 11.5 at 121 on 20 PSI with the same tune and alky. C'mon turbo experts...tell me why.
I'm likely oversimplifyin g this. A given engine can only swallow so much air? We've heard overturboing an engine. What dictates how many lbs per hour or CFM's a given engine can handle.
Tyler said: "Exactly. Your cylinder heads dictate the volume of air that can enter the cylinder, to potentially create power. The compression ratio (dynamic/etc), combustion chamber design, fuel used, spark advance, valve timing, etc...all dictate how much airflow the engine will actually use and burn. Heads provide the potential for power, the rest of the engine determines if it can use that potential."And this is why we have seen a few cars with stock cams run mid tens. Good heads with a good turbo to push the air in when the valves open in spite of a short duration, low lift opening.Two things matter and I believe they have been covered already. First you have to push all the air you can into the engine. Second, you have to trap that air long enuf to burn it well before it goes to the turbo and out the tail pipe.I disagree with Earl's comments about a turbo engine won't run well with a NA cam. Many of the cams we have used to get better performance are NA profiles. The Edelbrock 204/214 was very popular early on. Then we had/have the 206/206, 208/208, and the ever popular 212/212. All of these are NA profiles but they work. The really early cams like the 218/218 and such also made power but gave up the bottom end and have mostly gone away with the advent of better turbos.And, yes, Mike/Earl, in theory, cams designed for turbos will be much better. In theory, that is. In practice, on street cars, no one has come up with the magic required to demonstrate theoretical superiority. As most of us drive our cars on the street some portion of the time, performance walks, theory talks... Maybe with dual overhead cams, or such, things will change. Variable cam timing! yeah, baby!