I want to build a rotary table that can handle continuous milling!
Do you think my drawing would work?
The upper gear belt pulley can rotate freely on the axle, and is connected to the axle via the spring, and is preloaded.
I want to build a rotary table that can handle continuous milling!
Do you think my drawing would work?
The upper gear belt pulley can rotate freely on the axle, and is connected to the axle via the spring, and is preloaded.
As an alternative, "google" Howimat. This concept is ball driven like a ballscrew in the round.
Dick Z
DZASTR
I will check it out! I have also been thinking of using 2 servos and do the preload eletronically with a µC
Looks like it would work to me, although mixing gears, lubricant and timing belts might be a problem.
How about placing the two worm gears at an angle to each other, driving one directly and the other via a bevel gear? (if you see what I mean)
Or...
What about a buying or copying Commercial anti backlash worm drive ?
Bill
Hmm, thats an interesting idea! I'll make a drawing!
I made a drawing and realized that the worms would need to rotate in the same direction in this configuration :P
The dual servo version seems more and more appealing!
Just swap the main-shaft bevel gear to the front of the perpendicular one.
Bill
There are a lot of commercially available low backlash drives on eBay. Search for "harmonic drive" or "bayside drive". One of those sure will least trouble and expense.
Another possibility is to preload the heck out of your rotab drive with another gear and some bellvues. Not sure how much torque you plan to put on it though.
People also run 2 of the main circular gears spring loaded to spread the teeth just enough to get rid of the backlash. In this case, you'd make the spread adjustable with a threaded screw.
These last two solutions seem prone to binding and wear.
I would be tempted to also consider a big timing belt drive. properly set up, you'll get minimal backlash. People are even using these for linear motion with good success.
For really high torque situations, you might still find a brake is useful. Slew the 4th axis to the desired position, send an M-code to lock the brake, cut, and unlock. Small disk brakes from everything from mini-bikes to lawn tractors are readily available and work with an air over hydraulic and solenoid valve.
Cheers,
BW
Aaah yes...
:withstupi
Harmonic Drive is the way to go, if your willing to spend a little money.
http://www.powertransmission.com/iss...6/harmonic.htm
I want it to be able to use it for continuous milling, like gear hobbing and milling springs, not just indexing!
I think it's best to have the worms axially stiff because they can't be backdriven. So if you just can keep both worms in contact with the gear teeth with a little rotational preload it should be backlash free and much stiffer than the version with axial preload of the worms or split wormgear!
Harmonic drive seems nice! But i like to design and build stuff more than paying for complete solutions
I was thinking of a gear belt drive at first.. but it's a little impractical when you want 1:100 ratio or so..
Even 50:1 is awkward. I'm thinking about retaining the rack & pinion Z axis in my drill mill (in order to keep a manual option),and I will require about a 50:1 back-lash free worm drive for that, hence my interest in your project.I was thinking of a gear belt drive at first.. but it's a little impractical when you want 1:100 ratio or so..
Twin servo-motor would certainly work, but could be as difficult to get 'right' as your twin worm design, and would almost certainly be more expensive.
Bill
You could perhaps build something like this!?
http://www.globalspec.com/FeaturedPr...lDrive/74196/0
That's nowhere near enough for my hand re-sharpened drillsNominal tangential load up to: 30,000 Lbs.,(135,000N)
Bill
Machine your own harmonic drive
Would probably be the best solution for your application, you can get 100:1 no problem, and I'm pretty sure most of the new 4th axis equiptment are using harmonic drives? It's how I ran accross them.
Decent load handling, probably indefinate gearing available, no backlash due to design, compact and readily available.
But if your determined to make it all yourself, I like the duel servo idea. But are you going to make the servo's?:stickpoke
Just joking, I get it,
MC
Just a couple of basic engineering things to think about.
Solid worm gears need some clearance to operate or they lock. Worm gears are not very efficient which is why they don't backdrive easily.
Let's say you adjust your drive worms for .0001 clearance. Have you thought about runout on the main gear? This is why Hass hobs their gears after they are mounted. Ever priced a class 9 worm gear set? I pay over $4500 for mine and they are only 6 inch in dia.
Spring loaded worm gears use very light springs to allow the halves to move when operating. Because of this it's very easy to overcome the springs and they have very limited top speeds or they wear like crazy from the sliding friction between the worm and wheel.
The wheel gear is fairly large and grows and shrinks with temp changes. Set one up in a 68 degree room with almost no clearance and it will be locked solid when the wheel temp goes up to 80 degrees. Worm gears generate a fair amount of heat when running because the sliding friction is so high.
Harmonic drives can be purchased in zero mechanical backlash configurations but the main drive flexspline is made of spring steel and will deflect under pressure (although not as much flex as a split worm gear). Grab the end of a robot arm and move it back and forth. Older robots are almost all harmonic drives.
Dual worms driven by servos are a nice idea but how do you get around the problem that the gear teeth are not going to be exactly spaced. You have to consider manufacturing tolerances into any design work. No gearset is perfect.
There are also high resolution direct drive rotary motors. Basically linear motors wrapped in a circle. These are used in the rotary axis of very high end machine tools and high priced robots. Very expensive and they still have at least +/- 5 counts of "backlash".
IMO a harmonic drive from e-bay makes a good option (they are very expensive purchased new). Be aware that they are not all "zero backlash" units and mounting accuracy of the components is critical. They also take up more room than a worm drive.
DDR motors are great but they require very high resolution feedback devices and sophisticated controllers.
Worm gears work but you just have to live with some backlash in a fixed design or give up top speed and realize life will be shorten in a spring loaded design.
The life of any machine designer is full of tradeoffs.
Bob
You can always spot the pioneers -- They're the ones with the arrows in their backs.
I have been thinking of building a BL AC motor/servo for fun But thats another story!But if your determined to make it all yourself, I like the duel servo idea. But are you going to make the servo's?
Good points about the problems with the wormgear solution! I'm thinking of perhaps using something like in the globalspec link! Drawing will follow!
This is what i came up with, it has 60:1 gearing. I think it would cost about the same because now you can skip the angular contact bearings and just use bushings!
That's clever; I like the use of a single spring to preload two gear sets (two reduction stages)
BTW I think I've spotted another problem with the spring loaded worms:
Effectively one worm moves the gear in one direction and the other worm moves it in the opposite direction.
In one direction, when the main-shaft worm is driving, the friction on the spring loaded worm will act with the spring (in effect the spring will be dragging the worm around against the worm-gear friction).
In the other direction the spring loaded worm is driving, the friction will be acting with the spring, so as the spring is turned it is pushing the worm against the worm-gear friction increasing the load on the worm and thus the friction. If the initial friction is high enough (i.e. if the load on the main gear is high) and there is sufficient backlash to allow it to build, there is a danger that the friction will increase until it locks. The main gear will then stop until the back-lash has been taken up by the main-shaft worm.
It may be better to use a axial spring to pre-load the worms (rather than a rely on twisting the worm to generate the axial force).
Bill