Benny wrote:As the compressed air/fuel mixture is ignited (increasing temperature), the pressure of the gases from this heating is used to power the turbocharger (after it pushes the piston down and is exhausted out the exhaust valve), hence a turbo is powered by the pressure of the heated gasses.
Is that correct or not?
Benny wrote:What you also forget Danny, is that a lot of the rotational force of a turbocharger is not caused just by exhaust pressure, but by exhaust heat, and it is this heat that actually causes most of the rotation of the turbocharger impellor.
The inconsistencies, they make me lol. It's ok to be wrong, although I agree that it's hard to admit it after you've been an arrogant jerk about it. You are correct about the workings of the combustion chamber though. If this is something that you're willing/wanting to discuss more, I'd gladly explain it via PM, but I'd rather not crap up this thread with any more 'I know more physics than you' pissing matches.
Back to the original topic at hand, imagine a naturally aspirated car, where the exhaust suddenly drops from the usual 2 inches to 0.5 inches in diameter, then back up to 2 inches. Would that bottleneck in the flow cause a loss to the power made? Yes, yes it would. Now imagine that when exhaust goes through that constriction, the engine magically makes more power. That loss is still there, but the new magic power overcomes it and so the total power produced is greater than before. What you've just imagined is a turbocharger. Thus, there is a parasitic load associated with a turbo, but it is proportional to the velocity of exhaust gases rather than to engine RPM.
