Hi Mark,
Thanks. Yes, I agree I need, and would love to have, more time on my lathe 1440GT. For those of us who are really hobby types or use the shop to make things for other projects... and so do not make a living in their machine shop this lack of experience is all ways an issue. The real reason I have a decent shop is that I ran into projects that needed parts that I could not easily get. I have done a fair amount of precision optics and was building a very specialized microscope and needed to be able to do very fine threading at high TPI for some of my optical mounts and slides. My old SB just could not do everything I needed any more.
I have had my solid state VFD installation running in one form or another for over a year now, and in the current version for most of the year, and have not observed any problems or failures. It works a lot better than the operator! I am still using the original motor as it seems to work fine. At least... good enough for me. I typically run it at 20-25Hz and certainly has no problem going faster, but when I want, it seems to run fine right down to 1Hz and I have not noticed any overheating or other issues. Maybe I need to run it much much longer? It even starts from a dead stop at 1Hz. I jog at 6 Hz. I doubt that it has much horse power at these low speeds, but it at least starts. As the U-tube video showed, the fellow had problems during acceleration and I think he even mentioned interacting with you. Yes, he said on his post that he switched to the Marathon E470 motor to fix his problems, but I don't think he mentioned you're getting it for him at 1/2 price! If you find another at that price let me know. I only see the ~$600+ adds.
Due to our previous discussion, regarding the proximity sense distance that one really needs for different cutting conditions, I went ahead and added a counter to my VFD design. I was going to do this anyway for my winding projects. Using this feature was how I obtained the TPI values for the non-factory gear positions. (see the table above). However, in this counter install, at the flip of a switch, it is also set up to start counting only after the proximity sensor trips. This way I get an accurate measurement of the fractional (1/10 turn resolution) turns of the spindle during the electronic braking process to stop. Also, who is to say that the Hitachi really breaks the spindle in the spec time? As I noted I have a 10 magnet Hall sensor set up so can resolve 1/10 spindle turn. I will get around to these measurements one of these days. Anyway, when running at ~25 Hz I noted a small amount of RPM fluctuations in the spindle RPM and so it occurred to me that I could probably measure spindle speed stability for various settings, loads, gears, frequencies, etc. I also have a spectrum analyzer in my shop that I could connect to the Hall sensor signal and do a bit more detailed analysis. It is also possible that this fluctuation is either due to my 10 magnets not all being perfectly space or that the counter is just not that stable. However, I did test one like it with a decent function generator before and did not see this behavior.
Stability perspective: At 60Hz the measured RPM fluctuations appear to be a few parts in 1000, say 1000 +-5. At 25Hz it is more like 1000+-10. At less than 5 Hz it appears to be more like 1000 +-50. Around 2-3 Hz I can hear the spindle speed gears clicking slightly which will stop if you put a drag load on the part. At 1Hz there is no clicking from the speed gears. Overall, for my work I consider all of these to be suitable.
At this point I cannot see any reason to change from my original stock motor as things seem to work fine. No acceleration problems and I have never really observed any issues once the machine is up to speed. However, all of this is TBD with more time and experience.
Dave L.
Thanks. Yes, I agree I need, and would love to have, more time on my lathe 1440GT. For those of us who are really hobby types or use the shop to make things for other projects... and so do not make a living in their machine shop this lack of experience is all ways an issue. The real reason I have a decent shop is that I ran into projects that needed parts that I could not easily get. I have done a fair amount of precision optics and was building a very specialized microscope and needed to be able to do very fine threading at high TPI for some of my optical mounts and slides. My old SB just could not do everything I needed any more.
I have had my solid state VFD installation running in one form or another for over a year now, and in the current version for most of the year, and have not observed any problems or failures. It works a lot better than the operator! I am still using the original motor as it seems to work fine. At least... good enough for me. I typically run it at 20-25Hz and certainly has no problem going faster, but when I want, it seems to run fine right down to 1Hz and I have not noticed any overheating or other issues. Maybe I need to run it much much longer? It even starts from a dead stop at 1Hz. I jog at 6 Hz. I doubt that it has much horse power at these low speeds, but it at least starts. As the U-tube video showed, the fellow had problems during acceleration and I think he even mentioned interacting with you. Yes, he said on his post that he switched to the Marathon E470 motor to fix his problems, but I don't think he mentioned you're getting it for him at 1/2 price! If you find another at that price let me know. I only see the ~$600+ adds.
Due to our previous discussion, regarding the proximity sense distance that one really needs for different cutting conditions, I went ahead and added a counter to my VFD design. I was going to do this anyway for my winding projects. Using this feature was how I obtained the TPI values for the non-factory gear positions. (see the table above). However, in this counter install, at the flip of a switch, it is also set up to start counting only after the proximity sensor trips. This way I get an accurate measurement of the fractional (1/10 turn resolution) turns of the spindle during the electronic braking process to stop. Also, who is to say that the Hitachi really breaks the spindle in the spec time? As I noted I have a 10 magnet Hall sensor set up so can resolve 1/10 spindle turn. I will get around to these measurements one of these days. Anyway, when running at ~25 Hz I noted a small amount of RPM fluctuations in the spindle RPM and so it occurred to me that I could probably measure spindle speed stability for various settings, loads, gears, frequencies, etc. I also have a spectrum analyzer in my shop that I could connect to the Hall sensor signal and do a bit more detailed analysis. It is also possible that this fluctuation is either due to my 10 magnets not all being perfectly space or that the counter is just not that stable. However, I did test one like it with a decent function generator before and did not see this behavior.
Stability perspective: At 60Hz the measured RPM fluctuations appear to be a few parts in 1000, say 1000 +-5. At 25Hz it is more like 1000+-10. At less than 5 Hz it appears to be more like 1000 +-50. Around 2-3 Hz I can hear the spindle speed gears clicking slightly which will stop if you put a drag load on the part. At 1Hz there is no clicking from the speed gears. Overall, for my work I consider all of these to be suitable.
At this point I cannot see any reason to change from my original stock motor as things seem to work fine. No acceleration problems and I have never really observed any issues once the machine is up to speed. However, all of this is TBD with more time and experience.
Dave L.
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