Fair play to you for having a go at it.
I'll admit: I'm not looking forward to writing the post for Fusion for the Swissmak...
Oh Yes, it's most definitely a PITA to make it work seamlessly. It will take some macros for sure. 2 separate swap axis macros. One for swapping x/z so turning code from fusion cam will work and one for swapping spindle/4th axis. At the same it needs to adjust steps per unit properly between the 2 spindles since the mill spindle and lathe spindle arent gonna have same steps per unit. I don't have the macro skills yet to make it work seamlessly so I'll probably start out with multiple machine profiles for doing turning and 4 axis milling separately just to get it going and test the actual capabilities. Switching to a different control software is definitely an option. I think even mach4 is much easier to deal with when it comes to multiple spindle.
I've looked at the swissmak and it's very interesting. I would love to eventually build something with the same capabilities, maybe a bit heavier duty, linear rail and ballscrews, servos on all axis. That would require the mill turn spindle as well as a pivoting B head. I would probably lay it out differently than the swissmak though, giving the ability to use an actual mill table rather than being limited to just work in the spindle. The other idea I had which I've been talking about in mach3 section is adding a small sub spindle permanently mounted 90 degrees to my main mill spindle instead of an actual rotating B head. This would allow doing work on the face of parts in the 4th. So many different possible approaches for laying out a machine. Space is an issue for me, so that's even more reason for wanting a multipurpose machine. If I had room, I would consider just building a cnc lathe, but it's not really an option for me at this point.
Fair play to you for having a go at it.
I'll admit: I'm not looking forward to writing the post for Fusion for the Swissmak...
Whenever Mactec is wrong, he changes the question so that he's right. Ignore him and move on.
Gerry
UCCNC 2017 Screenset
[URL]http://www.thecncwoodworker.com/2017.html[/URL]
Mach3 2010 Screenset
[URL]http://www.thecncwoodworker.com/2010.html[/URL]
JointCAM - CNC Dovetails & Box Joints
[URL]http://www.g-forcecnc.com/jointcam.html[/URL]
(Note: The opinions expressed in this post are my own and are not necessarily those of CNCzone and its management)
I was not wrong so what's your problem, changed nothing they just could not grasp that you don't loose any resolution no matter how you look at it, if you can't understand how it works go on line and see for yourself
Here is a snip for you
This series of high precision, stepper motor driven, vertical/horizontal rotary tables can be used with a milling machine to produce complex parts with great accuracy. The rotary "A" axis is supported by our Mill Master Pro and is commanded in degrees. The standard resolution using half stepping results in 100 discrete positions per degree (or 0.005 degrees/step). The stepper motor is the 34HT390 rated at 6.6 amps per phase and includes prewired, armor jacketed cables with a circular locking Amp connector.
He only have to replicate this into his drive that he wants to do, electronic gearing works just the same as mechanical gearing
Mactec54
Your answering a different question then he asked, which he pointed out several times. You can go back and read the posts, if you want.
Gerry
UCCNC 2017 Screenset
[URL]http://www.thecncwoodworker.com/2017.html[/URL]
Mach3 2010 Screenset
[URL]http://www.thecncwoodworker.com/2010.html[/URL]
JointCAM - CNC Dovetails & Box Joints
[URL]http://www.g-forcecnc.com/jointcam.html[/URL]
(Note: The opinions expressed in this post are my own and are not necessarily those of CNCzone and its management)
In your example of those rotary tables, What Is the max rpm they can run? Probably not much. As I said before, the challenge is finding a balance of resolution and speed for use as a mill turn. I'm already quite aware I can easily get 0.005 degree resolution very easily, but the drive will reach it's max capable frequency at a low rpm. Only way to get that rpm back is electronic gearing, with the trade off of... losing resolution. No way around it with a step/dir controlled servo drive with max 500khz frequency. As electronic gearing is increased, resolution at servo shaft is lost, there's no arguing it
In your mind, there are 3 different guys that are all wrong in exactly the same way and you are right. dont you think maybe a more logical explanation for this phenomenon is than you are possibly the one that is wrong? Seems a bit more likely maybe? Brings me back to this show i was watching the other day. Flat earth activist
Last edited by QuinnSjoblom; 03-17-2019 at 03:04 PM.
No Resolution is lost if it was, your servo drive would go into a fault mode
Again you are fixated on resolution, there are many ways to solve this buy buying the right servo and Encoder to start with, or a lower count encoder and use mechanical gearing, machines have had this capability for years nothing new in what you are trying to do, mill turn machines are every where
The snip I posted was to show you that you can get this step resolution quite easy, which you keep saying you can't
You have no concept at all of what you are trying to do, I have done it so know how it works
Yaskawa
Mitsubishi
Delta
And others
All have a servo system where you could use there servo and servo motor direct drive and have an even much higher accuracy for indexing than what you are looking for, plus 3000RPM for turning all capable of being run by Mach3
Mactec54
No man, you're still not getting it and I feel like you're not even reading my posts. I never once said you can't get that step resolution, you just can't get that step resolution AND high rpm. I've repeated it literally like 10 times and you just turn it into something else. Yes, you can get the resolution back with mechanic gearing. What happens then? YOU LOSE THE MAX RPM. I'm going to repeat it again. It's very easy to get as fine of resolution as you want, but not at the same time as getting high rpm along with it. Yes, many mill turns out there. They either use drives and servos worth thousands of dollars with higher frequency capability, or they use dual drive with magnetic clutches to engage one or the other. I understand what the limitations are and that i have to find a happy medium between speed and resolution, but your claim of not losing resolution when increasing electric gearing for higher rpm capability is just flat out wrong. Somehow you are going around in a circle and not realizing what the final result is. Yes you can have higher electronic gearing and get your resolution back by gearing it down mechanically, but you've just gone in a circle and brought your max rpm back down with mechanical gearing.
As for the brands you mentioned that can hit 3000 rpm with .005 degree resolution, they either have 3mhz plus frequency drives, which I doubt unless they are thousands of dollars, or you're once again flat out wrong.
Quinn,
There's a bit of useful advice buried above...
One way around the speed/resolution compromise is to find a different servo & drive combo. The DMM was suggested as it's a superb cost to feature package, but with the 500khz input limitation.
As an example of drives with higher input frequency limits, I have an older Parker Gemini I'm setting up for a spindle motor. A quick check shows it has a 2MHz step input limit - 4x the DMM. I suspect it's due to better optos, but I could be wrong.
Checking Parker's latest drives, it looks like the newer Compax series supports up to 5MHz inputs. With a drive input like that coupled with a 32bit encoder on the motor, you could have seriously fine resolution and still support high-speed spindle operation.
Trolling ebay for a gently-used creampuff servo & drive combo might get you where you want, although I think the DMM with a dual gear ratio drive would still work like a champ.
-R
EDIT - you obviously get it. Just sayin... I found my drive & motor for $hundreds, not $thousands.
Yep, another drive with higher frequency capability would be the only option for higher rpm with same resolution, but in my price range I'm sure that means buying used. Not that I'm against buying used, but the dmm is going to work fine for me and I've already come up with a happy medium configuration that will work for me. I'm just trying to clear up misinformation. The conversation was about the dmm drive to begin with and the idea that increasing electronic gearing doesn't decrease resolution, which it does.
And is that not what I have been telling you check my posts
And again the electronic Gearing does not change the Resolution at the shaft of the servo motor the Encoder you can not change it's Resolution only the way you drive it
Well if you are still talking Dmm then you need to look at there 32Bit Encoder and job is done, this was developed for Robot precise positioning, so would work perfect for what you are trying to do, which I said from the start
Mactec54
No, the encoder is not the limit in this case, the drive is. That's the part you're not getting. The dyn4 drive maxes out at 500khz. You can not get 3000rpm AND full resolution of encoder. With electronic gearing added to stay within 500khz, each step received by mach3 is going to turn the servo multiple encoder counts, therefore reducing resolution. I can get a quote directly from the manufacturer if that's what it's gonna take. If you drove the servo with full encoder resolution at 3k rpm, you would would be hitting the drive with over 3 mhz which it can't handle
Mactec54
Mactec54
You could set it up like my mill 4th axis, 3600 steps per degree. But on the other hand, my 4th axis maxes out at about 10 RPM
Jim Dawson
Sandy, Oregon, USA
And like I keep saying, yes you can get the 3000 to 5000rpm, but not at full resolution. It's a really simple concept. If steps per rev are set for 2000 for example, the rotation is split into 2000 equal steps and a single step is the smallest move. Really feel like a broken record. It's getting kind of pointless. Doesn't matter how I put it, doesn't seem to get through. Only way to get full resolution and max rpm is with higher frequency capable drive. Do you understand how the frequency limit comes into play? It can only handle so many pulses per second. Do the math, it's simple. If you were sending 16 bit worth of pulses every rev at 3k rpm, you would be over 6 times the limit of the drive. There's no way around this.
Unless you changed the digital gearing on the fly - you don't care about positioning so much when you're using it as a spindle, and you don't care about speed so much when you're doing fiddly precision. How you get Mach3 to spit that out is another question altogether...
Yep, and that's kind of how I'm gonna handle it. Don't think there's a way to do it on the fly, but basically for one group of smaller diameter parts, I need full rpm and not as much resolution. Other parts, mostly just the large gears I'll be hobbing, need higher resolution and no need for speed. I've decided a single mechanical gear ratio will work for both, but electrical gearing/ steps per rev will be changed back and forth for one vs the other. With hobbing the big gears, I need the resolution but doesn't require much torque so 2 to 1 mechanical is still fine. The hob itself actually pulls the gear along at the specific rate of 4th axis rotation, so the 4th needs hardly any torque behind it at all. I'm thinking most likely I'll get the dmm 1kw. More than enough power for what I need to do. I'll gear it down mechanically 2 to 1 for 1500rpm max and about 4000oz/in torque which is gonna be plenty for most of what I do. When geared down electrically far enough to allow full rpm, it will give me .015 degree step which will also be good enough for most work. When hobbing gears, i will take out electrical gearing which will give me .0025 degree resolution and limit rpm. All this is with leaving mechanic gearing at 2 to 1. I'll have different pulley options for turning faster at lower res or slower at higher res, but I think the 2 to 1 ratio is gonna be a good general purpose setup that allows turning and milling in same program. Keep in mind, these are aluminum parts, under 2 inches in diameter, most of them closer to 1 inch, So i think 4000oz/in torque should hold plenty well enough during index milling. On a 1 inch diameter part, it will handle 500lb of tool pressure on the outside edge. 2 inch part will handle 250lb of tool pressure. I think it's gonna work just fine. For turning operations, 1kw goes a long way in aluminum. Easily a few cubic inch per minute mrr.