Tumbleweed - that was the no-moving-parts cylinder thing, right? I had a scan through your paper.
yep. my first version was teh no moving parts cylinder.
Pardon me if I've missed a lot, and particularly if you dispute that they tested a significantly correct version, their results, or whatever.
The latest version of my document says that no-moving-parts cylinder doesn't work. If you read an older version, click on my username and go to my website for the latest rev. Somewhere in my latest rev I describe my first design as teh no-moving-parts cylinder and then show why I was wrong and why it doesn't work.
There's an interesting question left hanging for me, which is whether it is possible to build a DDFTTW device with no moving parts
I don't know if it's possible or not. I came up with a strange design that only has two moving parts total. but it would be a machining challenge to actually try and build it. ANd it would be extremely difficult to balance. It's hard to describe in text.
One part would consist of a "wheel" that is two pieces of metal bolted together through the axle. In between these two pieces, you'd have to machine gear teeth that go around the axle. the two pieces might look like "dualies" on a truck. Two "tires" side-by-side. On the "sidewalls" of the tires in betwen the tires, you'd have to machine some gear teeth that go around the axle.
The second moving part is a propeller on a horizontal shaft with a gear that engages the teeth between teh tires. The shaft would have the propeller in back, the gear in the middle, and part of the shaft woudl stick out front wtih a counterweight so that the second piece's center of mass is right where the gear teeth contact the tire. So that the thing doesn't want to roll over from its own weight. So you could place it on the ground and it won't roll over and push the prop into the dirt.
And the gear teeth on the tire would have to curve around the gear of teh prop shaft so that it can hold the shaft up, but the gear teeth would have to have a gap big enough for the shaft itself to stick out fore and aft.
Trying to get it to move would be hard too. You couldn't just put it on a treadmill because the prop needs to be spinning and if it isn't the prop will just spin around and gouge a hole into the rubber. ANd there isn't anything to hold onto, cause there's no stationary part of the device.
If it starts out stationary and you put a tailwind behind it, you might be able to get the prop to spin and that would cause the prop and shaft to rotate along the shaft but also "climb" up the teeth on the tires. When the prop "climbs", it moves the center of gravity of the whole object and the tires rotate forward, bringing the prop back down to horizontal.
You'd probably have to put it on the ground in a controlled windtunnel, and slowly bring up the windspeed until it started moving and then adjust the speed to make sure the propshaft doesn't climb right into a rollover. Once you get over a certain speed, the prop starts working efficiently and the power on the prop is much greater than the friction between teh gears (the only point of friction in this design), and there should be a steady state point where it is going faster than the wind.
If it would work at all. Like I said, building it would be hard. And getting it from zero to steady state wouldn't be easy either. And in the end, you don't really get anything other than a design with only two moving parts but is harder to build and operate than other designs with five or ten moving parts. So I stopped working on the idea much more than that.
Not that any of this has much practical value, but anyway.
I'll post a diagram and details later.
until I get some feedback from the aero and mech experts round here.
