That the "J-damper" is "curb friendly". On the face of it, inerters don't like being accelerated, and once moving, don't like stopping. What is it that makes them "curb friendly"? Not a trick question, I genuinely want to learn.Powerslide wrote: ....Care to share how I might have amplified your imaginations?
Good spot. I know that some teams have replaced corner dampers with position controlled actuators for setting front and rear ride heights in full scale tunnel tests. The idea is to run through a matrix of front & rear ride heights for each configuration. I doubt that would work for straight line tests, however.Psyclone wrote:How hard would it be to use the already developed systems in a race scenario?
Correct me if my chronology of events is inaccurate but the J-Damper came about around when teams wanted to make their own version of mass damper. It is a kinetic motor that pulls two suspension together when triggered by certain frequency in this case, an initial impact of a curb. Renault had a huge advantage going over curbs when they were running mass damper which got banned for being too aerodynamicDaveW wrote:That the "J-damper" is "curb friendly". On the face of it, inerters don't like being accelerated, and once moving, don't like stopping. What is it that makes them "curb friendly"? Not a trick question, I genuinely want to learn.Powerslide wrote: ....Care to share how I might have amplified your imaginations?
Yes, inerters do not like being accelerated, its like having really bad unsprung mass on compression but I am suspicious that after initial 'irritation' it will buckle front suspension load to ease tyre bounce over curbs while the outer tyre is still leaning on a corner.I'm unsure about the chronology, but Scarbs has views. Tuned mass dampers and inerters are very different devices, and on an F1 car work in different ways. The first is designed to dissipate disturbance energy directly, whilst the second is intended to make the existing dampers work more effectively. The first works best if the conventional suspension is "locked" out, the second requires the conventional suspension to move.Powerslide wrote:Correct me if my chronology of events is inaccurate but the J-Damper came about around when teams wanted to make their own version of mass damper.
I'm not sure I would describe an inerter as a "motor". The picture you paint is for a "centre" installation, but they still seem to work (perhaps surprisingly) when fitted to "corner" units, with no "3rd's" in sight. Unlike the mass damper, an inerter is not, by itself, frequency sensitive. So what do they do:Powerslide wrote:...It (the inerter) is a kinetic motor that pulls two suspension together when triggered by certain frequency in this case, an initial impact of a curb....
When wanting to apply to race cars they borrowed a patent from a scientist who had made a 'kinetic motor' or mechanical motor if I'm not mistaken. I am aware of the difference between mass damper and interters. Just thought it was a new way to around slow speed curbs.DaveW wrote: I'm not sure I would describe an inerter as a "motor".
There is nothing to water down if FIA makes changes for a new season. And a standard active suspension should be very cheap against the development and production of the interconnected suspensions they are using today.crazyguru94 wrote:It definitely wont be cheap, because designers only wanna use the superior high-cost hydraulic controls, not like in present road cars. but it can be implemented through a single supplier but they'd cry as they did with pirelli. but if it comes through a single supplier, it's gonna cut costs and help smaller teams for sure. but eventually bigger teams will water down through their votes in the strategy group or whatever it is. what a shame
I have only worked with TMD once and never with inerters so it just what I read and tried to understand. Everything written about this I could find basically didn't make any sense and I assumed the writers didn't understand it.Powerslide wrote:When wanting to apply to race cars they borrowed a patent from a scientist who had made a 'kinetic motor' or mechanical motor if I'm not mistaken. I am aware of the difference between mass damper and interters. Just thought it was a new way to around slow speed curbs.DaveW wrote: I'm not sure I would describe an inerter as a "motor".
It does make sense that they work the dampers, never came across that one. A thought would appear that, with suspension at those rates, unsprung mass is no more that important. Most likely concerntrated on slow speed work of the dampers as the spring are rock hard and to capture whatever movement with an interter and create more of it. Arguably maybe still curb friendly but not in the same physics as tuned mass damper. I still can't see them playing a part in entering, mid and exiting a corner on a flat plane. Care to enlighten?
Would it benefit aerodynamic effected grip more or help unassisted grip more? I would think that tuned mass damper would be beneficial for slow corners that are not aerodynamically dependent. It would seem that Formula One cars have all these toys to keep the suspension working both on and off downforce where it gets sophisticated is when there is lack of stability with a race car i.e low downforce situation. A strong downforce would certainly assist in tyre pressure contact patch and those really hard suspension, at high downforce, will provide returning motion and retain a lot of its grip on challenging surface. I think they would have damper capable to be set at variable frequencies.gixxer_drew wrote: I guessed that why this can be construed as an aerodynamic device is because of the way the car responds to the forces transmitted to the sprung mass.
I reviewed the various options for "active" suspension in an earlier post in this thread. There I stated that "the (fully active) solution, though attractive, was the least plausible of the options."I don't think traction control should be embraced because it is a true driver aid. It's helping a driver do something that he should really be doing himself. Active suspension on the other hand is something that shouldn't frighten people any more. It was done previously and outlawed because of the aerodynamic influence the suspension had over the car but, these days, with single ECU control, active suspension on the car would be much simpler.
And much cheaper, because if you put it in its simplest form you have an actuator on each corner and you can throw away all your springs, dampers and roll bars because the active suspension would do it all for you. So all these very expensive, sophisticated hydraulically linked suspensions would be a thing of the past - or could be - if we went for an active suspension system. It is something that is hovering on the radar.
The inerter gains grip because it reduces oscillation of tire load. What this means is your minimum tire load will be higher so its harder to lose grip.thisisatest wrote:my understanding of inerters:
spring rates are very high in f1. tires have tall sidewalls and tire bounce is largely undamped. suspension frequency and tire frequency get really close, so with or without damping, you get bounce off curbs, porpoising, etc.
one way to lower the natural frequency of the suspension is to soften the springs. another way is to increase weight of the unsprung mass. the inerter does that. the suspension doesnt necessarily handle the initial bump impact better with it, it handles the aftermath (tire oscillation, etc) better, and the bump event is over sooner.
