Mookinator,
In a gasoline engine the speed of combustion does change with engine speed. However, the relationship is in no way linear.
For a given AFR & air mass per stroke (Load) increasing the engine speed will not only change the speed of combustion (ie 0-100% mass fraction burnt) but it will also change the ratios of 0-10 (ignition phase) :10-90 (flame front phase) :90-100% (post flame phase) MFB
Consider this; with a constant AFR & Load, the propensity of the engine to knock is affected thus: -
At low speed, where combustion speed is also low, the flame front will still be progressing through the charge when the end gases reach their Auto Ignition point & detonation will, therefore, occur. In this condition the position of Maximum Advance for Best Torque (MBT) may not be achievable before knocking occurs and the engine is said to be knock limited.
However, at higher engine speeds detonation may never occur because the charge is consumed by the quickly moving flame front before the end gases ever get near their AI point. In this condition it is often quite possible to continue to wind spark in until misfire occurs (because of the reduced residency time of the charge)
The change in speed of combustion is totally to do with the mixture preparation being improved by the increase in gas speed.
As mentioned above, squish & swirl do their part to improve matters at higher speed whereas a more useful mechanism at lower engine speed is tumble. An optimised combustion system makes use of all three in different areas of the engines operating range.
Dicer,
"Ignition advance in a diesel is accomplished by advancing the fuel injection start point"
This isn’t quite true; the point of ignition in terms of crank angle is pretty well constant on a diesel, for a given rpm.
The advance of the start of injection only really controls the rate of heat release; the more advanced the injection the quicker the charge (as a whole) combusts. This is because of the increased residency time of the fuel, allowing more of it to be in a combustible state when the 'ignition point' is reached.
"all high speed diesel engines have advanced injection"
Whilst I agree with that it’s not really the whole story.
The maximum engine speed in diesels is, to a great extent, governed by the speed of combustion of the charge. In terms of increasing this combustion speed both the geometry of the chamber and the atomisation of the fuel are very important (since the charge is inherently heterogeneous).
Whilst it is possible to fire the whole injection amount into the cylinder very advanced of TDC this then causes the most horrendous noise ‘diesel knock’ and also heaps of NOx production because of the greatly increased rate of heat release. Also ignition would occur at the same point if the only a small fraction of the whole injection amount had been injected prior to this point.
Modern diesels combat this by using an advanced pilot injection even before the main charge is injected, thus causing a relatively longer combustion event and a slower rate of heat release.
However, as always, that is not the whole story either. When other factors such as variable fuel pressure are taken into account (which a modern Common Rail Direct Injection engine will have) things become even more complicated, and this is not the time or the place to discuss!
MS
