Every single post of Greg's as far as I can tell either uses the term 'steady state', or is explaining the logic of a post that used the term 'steady state'.
By definition, 'steady state' means that there is no weight transfer occurring- any and all weight transfer that ever will occur has already occurred and the system is in equilibrium.
The point (I believe) Greg is trying to make is that once the system has reached equilibrium (in which case all forces are constant, are in equilibrium, and any transfer of forces laterally, longitudinally, or diagonally have already occurred and settled to a constant) the only way to transfer weight front or rear is longitudinal acceleration, which is either not present in steady state, or is present but constant so that there is no change in weight distribution occurring through any axis.
He's talking about steady state and the rest of you are making arguments about dynamic situations.
Greg, I apologize for putting words in your mouth, that isn't really my intent here, but watching you all talk circles around each other is exhausting.
140airpower said:
The inside tire normal force begins to go to zero (diminishes) just as soon as cornering begins. The suspension is usually designed to be compliant which means that as soon as the torque described exists, the CG begins to react to it by rising.
It is true that cornering causes the normal force of the inside wheel to diminish- but that does not mean the CG is rising. Think about where the roll center is.
Until the inside rear wheel is no longer contacting the ground, it is still contributing normal force to the total for the axle it is attached to- this means two things: 1) the axle in question is still contributing to the roll resistance of the entire vehicle and 2) the spring of the outside wheel is not yet supporting 100% of the axle normal force, so as roll continues to accumulate that spring will continue to compress, and in almost all cases that means the CG is moving down, not up.
At the exact instant the inside wheel comes off of the ground, the axle ceases to contribute to the roll resistance of the vehicle as a whole, so the vehicle-level roll resistance plummets; the wheel also ceases to contribute any of the total axle normal force- this means that the outside wheel bears all of it, and will not compress further. This behavior means that the roll center of this axle ceases to be the geometric roll center of the suspension, and becomes a point somewhere in the contact patch of the outside tire. Any further added cornering force will cause this end of the car to try and rotate around this new roll center, which will cause the CG to move up away from the ground- but unless the suspension geometry (and thus roll center location) are very strange, the CG will not move up until this happens.
