TLW wrote:I would not call it Ideology, more a mistake that people keep running into, and end up with a fatal lift against gravity. Not unlike trying to use CF wherein you end up with a fatal pull inward against CF.
Hi Trevor .. yes, it is a mistake IMO also, but when you are bereft of alternatives it's the 'go to' - Cf's are problematic
IF there is no reset method, like the hangar & batteries experiment, IMO.
TLW wrote:Like I asked you before, what RPM do you expect to rotate your system?
The reason for this question was to try and understand what forces your RBGs would encounter at the speed in which the device would spin before you could use CF to move your weights outward.
Like I said before Trevor that's difficult to answer or predict without experimentation - that's because a single mechanism like I showed would turn very slowly because it drives thru approximately a 1/4 arc only on the down-going side - after that it is in coast mode - so frictions would deplete the momentum slowly - IF however there is additional momentum & RKE given to the wheel system than the energy cost of producing that force then this is not a great problem.
The more mechanisms it has the faster it turns - if there are overlapping or butting mechanisms so that at least one mech is always driving at right angles to the axle then it will accelerate until it reaches a resonance speed - that speed will likely be dictated by lag of the rack in particular - because each cycle it must move a short distance to the right after 12 o'cl, then return to the left after 6 o'cl - it has to overcome the inertia of the low mass flail & of course the speed the flail can accelerate the wheel proper by applying force to the rim stop also dictates that transition speed of the rack in that phase.
Lastly, while Cp's = mv^2/r (force in Newtons) we are really using the inertial forces of the rack moving outwards - traditionally this is viewed as the reduction in Energy from moving to a greater radius, albeit a small radius change indeed (as per the hangar & batteries experiments).
This means you have to give the wheel system activation energy to start it rotating, then the rack energy will be determined by its speed, whatever that is - if the push is too small little force is transmitted by the flail, & if you have only one mech then frictional losses will stop it before it completes a cycle.
TLW wrote:My main concern was the increase in friction on the gearing when the weights were being pulled back inwards and outwards as the CF outward pull would be pulling the levers apart, and not in the same direction as with Gravity. This is Just a thought, when I run a sim in my mind.
I think this is the disconnect Trevor - the rack always moves outwards to a greater radius (never inwards to a closer radius), specifically because of the RBGS influence & the offset to axle track (eccentric circle oo) the beam takes - this means there is a reset each cycle where the rack moves to a greater radius, albeit a very small change indeed - so we don't ever have to supply energy to push the rack inwards to a closer radius against Cf's.
The frictional forces will be what they will be, & can be minimised by good engineering - they are not significant if multiple mechs are used as I explained before.
