Turbogrimace asked me in a PM to do the math for him, and I had some spare time, so I did. I hate being troll fodder, but I like math more, so here you go. Dilbone, please feel free to comment on my math. Even if I got some magnitudes wrong, the signs are correct as far as I can tell, and point to the forces moving beads in the direction of balance.
So consider a wheel rim rotating with a compound motion, with a linear period equal to its rotation rate: that is, for every time it moves up and down along the shocks, it is rotating once around the axle. This is the case for an unbalanced wheel, since the weighted side will "throw" the wheel up and down a bit.
For fun, let's first calculate the centrifugal acceleration of the beads: this is the "false force" imposed on the beads by their rotation with the rim. It's easy to do: v-squared-over-r. If you want to use real units, let's say we're running a 15 inch wheel (we'll simplify here and say the wheel is the same ID and OD), and we're moving at 50MPH. The acceleration toward the rim is then given by (50MPH^2)/(15/2 inches), and is 2622m/s^2. Dang, that's 267g of acceleration. Not kidding, are we? That's a lot of force!
(edit: fixed embarrassing magnitude mistake)Incidentally, that's the reason I think SiliconDoc's belief the beads will fly about inside the tube when the contact patch shifts them up is crap. Wait! Actually, this is pretty easy! Since the radius of curvature of the tire as it transitions to the contact patch will always be less than the radius of curvature of the wheel, and since there's a constant tangent rate (road speed), the acceleration due to contact patch will always be less than the acceleration due to wheel rotation. Therefore,
the beads will never lift off of the surface of the inner tube due to the contact patch.
Having the centrifugal force on the beads, we then note the eccentricity of the wheel's rotation along the shocks. This has a few effects. The one we're concerned with is the change in acceleration experienced over a single rotation of the wheel. The trick to depicting elliptical motion is that R, the radius, is constantly changing. Let's say the shocks are moving a quarter inch in each direction over the course of a rotation. This seems like a pretty serious imbalance to me. So when the heavy side of the wheel is up, the shock is most compressed. When the light side is up, the shock is most extended.
Note that "R" now depends on where the bead is located in relation to the light or heavy side of the wheel. When the bead is located at the heavy point, the change in R over the course of a rotation produces a variation in force that is completely radial: that is, there is no tangential component of force on the bead. When the bead is 90 degrees offset to the heavy point, the force changes both in radial and tangential components over the course of a rotation. It's those tangential forces that do the balancing work of the DynaBeads. I don't care much about the variation in radial force for the purposes of this analysis, both because they are insignificant compared to the static radial force of 134g, and because they don't work to change the position of the beads, which is what I'm interested in. Therefore, we focus on the tangential forces for now.
Let's make this as easy as possible, and use the rotating reference frame of the wheel as our inertial reference frame. The heavy side of the wheel will be at 0 degrees, for reference. The light side is then at 180 degrees. A good mental image right about now is to picture the rotation of the wheel as it moves up and down along the shock axis. (I'm not worrying about fork angle for this discussion, since it's the travel itself that matters, not the direction.)
The tangential force is then equal to the sine of the radial angle between the heavy point and the bead in question, times the acceleration produced by the linear shock travel. For the case of a bead located exactly at the heavy point, given that the sine of zero is zero, there is no tangential force, and the bead will not move along the rim. The same applies to a bead located exactly at the lightest point. For the case of a bead located halfway between the heavy and light points, the sine of 90 is 1, and maximal tangential force results. Let's find that force.
In the "90 degree" case, the acceleration of the shock is always tangent to the rim, producing a tangential force equal to the shock acceleration. If the shock is moving sinusoidally at 18.7Hz (15 inch rim moving at 50MPH) with a displacement of 1/2 inch (as postulated above), we can say its displacement from zero becomes D = 0.25 inch x cos(18.7*2*pi*t)
The velocity of the shock, being the derivative w.r.t. time of the displacement, becomes V = 18.7 x 0.25 inch x sin(18.7*2*pi*t).
The acceleration, which is what we're interested in, becomes the derivative w.r.t. time of the velocity, or A = 18.7 x 18.7 x 0.25 inch x -sin(18.7*2*pi*t). Of particular note is the sign of the acceleration, which is opposite our reference point (the heavy point), producing a force that accelerates beads away from the heavy point. This is true for the tangent force all the way around the wheel:
at every point that is not exactly at the heavy point or exactly at the light point, a tangent force is produced that accelerates the beads toward the light point.The change in tangent acceleration is synchronized (and in phase) with the rotation of the wheel itself, and because of this, both these accelerations can be combined into a static tangent acceleration that does not vary over the rotation of the wheel. This acceleration is A = shock displacement x (radial rate ^ 2) x -sin(angle between heavy point and point in question). Multiply this acceleration by the mass of a DynaBead to find the tangent force acting on the bead in the direction of the light side.
Of course, as the beads shift toward the light point, the shock displacement decreases due to the lessening imbalance. This decrease in travel causes a corresponding decrease in tangential force, until the system comes into balance. Then, with zero shock displacement, the beads no longer move.
It's a cute problem! I had a lot of fun figuring out the math. I'm sure SiliconDoc will have something pithy to say, but this is for Turbogrimace, not him. And in any case, I've got him ignored.
