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GeoffBob, there's one bit I'm unsure of...
I thought the reason for bigger inlets was volumetric efficiency, due to the differing pressures the inlet/exhaust charges see when being shoved through the ports and valves. Assuming naturally aspirated for a quick theoretical example:
Inlet = 14.5psi of pressure pushes the air into the cylinder in a simplified engine, ie atmospheric pressure (which is also why engines lose power at altitude) which is fairly weedy and why a bigger valve helps fill the cylinder more quickly. If the valve remained closed it would see 14.5psi trying to get past it.
Exhaust = The air is forced out of the engine by the rising piston, with many times the force/pressure. In fact if the exhaust valve is closed on a 10:1 compression ratio engine at TDC the valve sees 145psi from the charge (minus the 14.5psi of the atmosphere in the exhaust manifold) trying to get past it, so 9x the potential pressure differential is available to overcome a small port.
So as the inlet is the weak link the best bet is a bigger inlet valve, which all engines I know or have. The fun part comes when you add boost, if you had 9bar of boost on the same 10:1 ratio engine (theoretical) you might need the same size inlet and exhaust valves?
A few notes:
- All the above ignores the heat / pressure / density changes caused by combustion, it's a cold-air engine!!!!
- In a real exhaust stroke the charge is hotter, with more pressure and less dense which makes it "runnier", which is another reason for a smaller exhaust (your original point in fact).
- In a real engine the valves of course open as soon as they get a chance, so there's far less of a pressure differential at the valve, I was only making the point about the potential pressure if the ports were flowing really badly or similar.
Slightly off topic but on a "boosted" theme!
