Mechomatic
Mechanical
- Apr 23, 2013
- 50
Hello EEs-
For reasons that are somewhere between "trivial" and "pipe-dream", I am trying to learn about the viability of utilizing a centrifugal pump with a nameplate rating different than the electrical supply. I've poked around this forum and gleaned some understanding, but I'm afraid the single class/lab in EE required for my BSME did not provide me with the tools I need to decipher the mathematics at play. Just to have an example, let's take the Taco 0010-F3 centrifugal circulator pump, which has a permanent split-capacitor, impedance protected motor. Nameplate data indicates: 115/1/60, 1.1A, 3250 RPM, 1/8 HP. It also has available motors in 220/1/50, 220/1/60, 230/1/60, and 100-110/1/50-60.
My understanding is that motors are designed for a specific V/Hz ratio (proportional to magnetic flux, right?). Operating at a different frequency with the same ratio (as with VFD) produces a linear relationship between frequency and motor torque. Operating at a different V/Hz ratio can result in problems, such as drawing too much current and burning up the motor. Am I right that operating a 60Hz motor at 50Hz with constant voltage (so at a higher V/Hz) is worse than operating a 50Hz motor at 60Hz? I say this under the impression that operating at a higher-than-rated V/Hz will result in too high current for the windings. Is there a quick way to predict what the actual current through the motor will be at 60Hz? I also guess that operating the motor at 60Hz will result in less torque, higher speed, and thus a longer start up time at increased start-up current. With the motor on a dedicated breaker, my guess would be that the breaker might have to be oversized (more than normal) so it doesn't produce nuisance trips during the prolonged start-up time?
Stemming from operating at non-design condition, what effect can I expect in terms of motor/pump output? The nameplate speed indiates ~10% slip. But with the higher speed and lower torque, will there be additional slip and how can I go about calculating that (analytically)? Based on
Torque = HP * 5250 / RPM
is it a safe assumption that the torque output of the motor will be 5/6 of the rated motor torque? Or will there also be an effect on the horsepower?
I know this is a lot of (probably) basic stuff I'm asking, but I seem to be going in circles on my own and hoped that one or some of you could clear the haze and set me on the right track. Thank you for your consideration.
For reasons that are somewhere between "trivial" and "pipe-dream", I am trying to learn about the viability of utilizing a centrifugal pump with a nameplate rating different than the electrical supply. I've poked around this forum and gleaned some understanding, but I'm afraid the single class/lab in EE required for my BSME did not provide me with the tools I need to decipher the mathematics at play. Just to have an example, let's take the Taco 0010-F3 centrifugal circulator pump, which has a permanent split-capacitor, impedance protected motor. Nameplate data indicates: 115/1/60, 1.1A, 3250 RPM, 1/8 HP. It also has available motors in 220/1/50, 220/1/60, 230/1/60, and 100-110/1/50-60.
My understanding is that motors are designed for a specific V/Hz ratio (proportional to magnetic flux, right?). Operating at a different frequency with the same ratio (as with VFD) produces a linear relationship between frequency and motor torque. Operating at a different V/Hz ratio can result in problems, such as drawing too much current and burning up the motor. Am I right that operating a 60Hz motor at 50Hz with constant voltage (so at a higher V/Hz) is worse than operating a 50Hz motor at 60Hz? I say this under the impression that operating at a higher-than-rated V/Hz will result in too high current for the windings. Is there a quick way to predict what the actual current through the motor will be at 60Hz? I also guess that operating the motor at 60Hz will result in less torque, higher speed, and thus a longer start up time at increased start-up current. With the motor on a dedicated breaker, my guess would be that the breaker might have to be oversized (more than normal) so it doesn't produce nuisance trips during the prolonged start-up time?
Stemming from operating at non-design condition, what effect can I expect in terms of motor/pump output? The nameplate speed indiates ~10% slip. But with the higher speed and lower torque, will there be additional slip and how can I go about calculating that (analytically)? Based on
Torque = HP * 5250 / RPM
is it a safe assumption that the torque output of the motor will be 5/6 of the rated motor torque? Or will there also be an effect on the horsepower?
I know this is a lot of (probably) basic stuff I'm asking, but I seem to be going in circles on my own and hoped that one or some of you could clear the haze and set me on the right track. Thank you for your consideration.
![[smile]](/data/assets/smilies/smile.gif "[smile] [smile]")
. I'll admit that I probably would not be so adventurous (or cavalier, depending on your viewpoint) with potentially installing a motor with a different supply frequency if the output were a critical system parameter. But, I believe I now have (at least some of) the tools to go about doing so in the future, if such a need arises. I certainly will put in the effort and time required, though, in a critical application. I'm fortunate this first time venturing into tinkering with nameplate electrical supply is a "relaxed" opportunity to learn and experiment.