Thread: What stepper motor size (torque)
Ok, been hunting around and thinking about router designs, but I'm at a bit of a loss about what sort of size / torque stepper motors are suitable for a given size router cutting different materials.
For instance if I have a 4'x2' bed router cutting MDF, what torque motors will I need to get a reasonable speed?
Hmm, thinking about this before hitting submit, there are a lot of variables:
What size cutter/how many flutes/cutter rotational speed/depth of cut...
What is a reasonable speed come to that :confused:
Also you can use lower torque motors if your drive uses some form of reduction gear, at a trade off of lower speed.
Maybe it would be better if people could post some information about what torque motors they use in their own machines, and what sort of speeds they can do non-cutting fast traverses. This could then hopefully act as a resource for others.
Any ideas anyone?
There's two approaches to this..
1/ suck it and see based on what others have done
2/ the scientific calculated approach...
I personally go for a mix of the two.
I have a spreadsheet that does the calculations. I'll post it up here shortly (its on one of the other PCs).
As I understand it, it’s also based on motor Inductance isn’t it?
The lower Inductance the faster the motor driver can talk to the motor, so what you got to do is go for the highest torque you can get with the lowest Inductance at the same time. That also being a trade off ?.Me
The formula is V = 32 * sqrt(L) where L is in mH. A 10mH coil ideally therefore needs a drive of 100v, but of course most steppers have a winding breakdown of 65 - 80v and 100v drivers are expensive anyway. What it means is that such a motor on a 48v driver (e.g. a Gecko) will not maintain torque above about 60% of max step rate. A better motor for a 48v drive would have an inductance no more than 2.25mH.
But too large a motor can be as much a problem as too small. Big motors have more rotor inertia which can reduce the ability to accelerate (e.g. change direction when cutting). You need to choose a motor thats in the 'sweet spot' else you can end up with nasty resonance issues (as well as pay more than you need to for both motors and drivers). The 'sweet spot' is an operating torque at cutting speed about 40% margin over what's needed. Thats NOT the same as stall torque which is how motors are rated. Its also important to ensure that the step rate at cutting speed is below that at the knee point (where the L/R effect starts). That may mean the steppers need to be geared to the leadscrews which also changes the inertial and torque dynamics. Hence the need to do the calculations.
After an unplanned break Thanks for the info, looks like stepper motor choice is a bit more complicated than I thought :(.
Been looking in EBay hoping for a bargain, but a bit scared now to spend around £100 on quite possibly the wrong motors.
Thanks for the info and link, time for some reading I think. Fortunately I'm not completely lost in the world of Volts, Amps, Henries, - I used to work in electronic engineering, just have to remember all the bits ;)
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