Quote:
Originally Posted by RETed
Sorry, but you are dead wrong.
TTT is right.
Pressure (i.e. "psi") is only one variable when talking about turbo potential.
AIR FLOW the other big variable.
To ignore air flow is downright stupid.
15psi with a T3 is not the same as 15psi with an HKS T51R SPL...
Air temperature is tied into the whole thing (see PV=nRT), but it's a relatively minor variable.
To emphasize air temps over air flow is downright...ignorant.
-Ted
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You're in such a hurry to contradict me, you didn't pay any attention to what I actually wrote. You need to re-read what I wrote, and what I responded to, and rethink your statement. We're not talking about total turbo potential, we're talking about two turbos on the same engine, both capable of making a given pressure at a given flow rate (CFM).
Flow and pressure are directly related; unless you have enough flow to over-supply the engine, you can't make boost. Thus, increasing flow in a system increases the pressure. With a larger turbine, you can't "flow" any more air into the engine at any given boost level than with any other turbo capable of flowing the same amount (assuming, of course, identical hot-sides, and thus equal exhaust backpressure at that boost level). So where does the power come from when you swap to a larger cold side? Increased efficiency, and thus a cooler air charge.
Being capable of flowing more air doesn't mean you actually do, it just means that it takes less work for the compressor to flow the air you do need, and less work means less heat.