Uh, oh... scientific consensus ... has anybody seen Algore?
"If it is consensus, it is not science." -- Michael Crichton
Without attempting to address all of your misunderstandings, I will focus on three of them.
jack action said:
I'm not sure what are your definitions of rpm, angular velocity and instantaneous crank speed, as it all sound pretty much the same to me. rpm is a type of unit for angular velocity and if someone used the term crank speed, I would think he or she is referring to the angular velocity of the crankshaft.
The term "crank angle" is usually understood to refer to the angle turned by the crank from a fixed reference line. That is the way I use this term. The "crank speed" and "crank angular velocity" are used interchangeably (ignoring the vector nature of an angular velocity) to refer to the time derivative of the crank angle.
Now, while it is narrowly correct to say that rpm is simply the same thing as crank speed, it is not common industrial usage to do so. Rather, for a machine operating at constant nominal speed, rpm is usually taken to refer to the time average value of the crank speed, expressed in units of revolutions per minute, rather than the radians per second commonly used for crank speed. The words, "per minute" suggest a longer measuring interval, although this is only understood, not stated.
The term "instability" is understood in mathematics to refer to a solution that either (1) diverges continually from a fixed value, or (2) never converges to a fixed value, although it may oscillate around a fixed value. Thus, the solutions of x'' - k*x = 0 exhibit an instability (exponential growth), and the solutions of x'' + k*x also are also unstable (oscillation around a fixed point). To get a stable solution (no instability), we need to consider a system such as x'' + c*x' + k*x = 0 for c>0, k>0 that has a damped (stable) solution.
The speed fluctuations that occur in an operating IC engine are not necessarily periodic, but rather ever combustion event is unique and hence produces a different motion. Thus speed can fluctuate (assume many different values near a fixed value), without necessarily oscillating like an unstable motion.
jack action said:
Furthermore, the only fluctuation I know that is «unavoidable in a slider-crank IC engine» is the piston speed, not the crank speed.
In all kinematic studies I've seen about piston-crank assemblies, the angular velocity is assumed to be constant, hence there are no fluctuations on that point of view.
It is easy, and common, in a mathematical analysis of the kinematics of a slider-crank to assume that the crank speed is constant.
But this is an assumption; the real, operating engine knows nothing at all about that assumption, and could hardly care less. It is unfortunate that this is the only sort of analysis that you have seen. I regularly publish technical papers where this assumption is not made; I published two through ASME last month (I would give you the citations, but I don't think PF would allow that). I have been doing torsional vibration consulting work for various engine companies for 40 years now, and the assumption of constant instantaneous crank speed is never made, although constant average speed is routinely assumed.
I think I'm finished on this thread. It is getting really tedious.
