JACKHOLE wrote:DaveW in What the 'Fric' is it wrote:The rear is locked initially. When it finally starts to move the apparent friction falls, suggested that once the friction is overcome, it takes time for it to reset. The characteristic is reminiscent of a pre-loaded shim valve (which requires time for the fluid boundary layer to be ejected after the valve closes, during which time it still leaks fluid).
Dave, I am Having a hard time wrapping my head around this wondering if you could explain a little more or an example. I haven't heard of this before.
I know its a little off topic.
Not here, however.
First a restatement of the the phenomenon. The
plot shown in red was taken from 13.8 seconds into a run, when the input frequency was 1.4Hz. Here the suspension was static over a load range of 600 N. The load was high for a damper (much higher than the front suspension of the same vehicle, and also much greater than the same plots for a standard vehicle at both axles. Over-plotted is a trajectory, taken at 26 seconds into the same run, when the input frequency was 4.2 Hz. Here, the damper has a digressive characteristic, but the damper keeps moving throughout. It would seem that there is a "time" element to the friction force.
I first encountered the phenomenon when using a single corner rig to characterise a range of dampers. One damper (from a Lotus Esprit, I recall) was digressive and heavily rebound biased. Sweeping up through the frequency range, the spring mass was pulled down and then, at a frequency of around 15 Hz, the sprung mass suddenly returned to a ride height that was (close to) its static position. The effect was entirely repeatable, and even did the same thing (in reverse) when the frequency was swept down. It followed, I think, that the damper was able to support a pressure drop across the piston (pulling the sprung mass down), but only up to point. In this case, the point appeared to be a frequency, but more properly, it was time. Below that time, I argued, the valves did not close properly. The feature seemed to be analogous to the
"Stribeck effect".
I struggled to find an obvious example, but
here is one that is interesting in its own right. It shows trajectories extracted from the same run of a road car application with a Koni damper fitted with an "FSD" widget in rebound only. The term "Frequency Sensitive Damping" is something of a misnomer, because it is time, rather than frequency sensitive. In the present case the rebound trajectory follows a low rate path, gradually stiffening up with time. Thus the rebound trajectory follows a counter-clockwise path in the plot. At low frequency, shown in red, the average damping is high, gradually reducing as the frequency increases, see the green and blue plots. Arguably, the "FSD" widget attempts to emulate the phenomenon under discussion (not completely successfully, because it happens rather slowly). The black trajectory is rather different. The structure of the damping has all but disappeared, leaving a slightly hysteretic liner trajectory. The min, max & mean
time histories are shown here. The dampers pulled the vehicle down by around 10 mm at 22 seconds (+ve is compression). At 36 seconds the the mean value suddenly increases (in the blue circle). The last two damper trajectories (blue & black) were taken either side of the hiatus. Arguably, the lack of structure in the black sample suggest that the valves are no longer in control of the trajectory.
The phenomenon is quite commonly found in road car dampers, but is less obvious in race car dampers.
Here is another example - all plots are again taken from the same run. The dampers are quite digressive at low frequencies (the red trajectory was taken at a frequency of 2.3 Hz), the digression reduces as the frequency is increased (the green trajectory was taken at 7.7 Hz), and finally all but disappears at higher frequencies (the blue trajectory was taken at 12.7 Hz). I would argue that development drivers spend a lot of time devising stack builds that use the phenomenon to achieve control at low frequencies, whilst washing out the digression at high frequencies in the interests of ride.
