Cold Fusion
Senior Member
- Location
- way north
Laszlo -
Request you read post 9 and 10. My example is a current source drive.
[1]What would be the value of a capacitor on the output side of an ASD?
3 Wye connected banks of 7200V - 500kvar. So 1500kvar reflected to 6500V or 1500 X (6500^2)/(7200^2). Although why the actual number of kvars/farads would matter I don't know. It's what Rockwell included when they sold us the drives.
[2]What is it intend to accomplish either from the technological or the finanacial side?
Well, I didn't discuss this with Rockwell. My assumption is the motor side caps reduce the lagging power factor (lower the motor magnetizing current) seen by the inverter.
I also suspect CS drives use caps on the output to smooth the current output delivered by the inverter. The inverter delivers power in a 400hz or 800hz fairly narrow pulse. When the inverter semiconductors turn off, the motor, being inductive, continues to draw current. As you are aware, most semiconductors have trouble in this quadrant - high voltage, high current.
Designing CS drives is not my area of expertise - I'm only guessing. There are others here that are more knowledgable than I. Perhaps one of them will jump in.
Couldn't tell you anything about the financial side - probably made Rockwell some money selling us drives that worked and met spec.
[3]Since the capacitor is not variable a resonant circuit at some frequencies, especially with varying carrier frequency is practically unavoidable.
No question here - I'll assume that you wish to know my views on how the drive avoids the "unavoidable".
Maybe the engineers avoided carrier frequencies that could resonate. That would be my guess.
[4]How would one surmount the resultant problems?
What problems? The drives work fine.
[5]What about the increased discharge voltages due to the harmonics?
I don't have a definition for "increased discharge voltages due to the harmonics". I don't know what that means in this context. If you are asking on how Rockwell keeps voltage spikes developing from harmonics, from damaging the inverter semiconductors - well, I don't know there are any spikes, harmonic or otherwise. Looking at the inverter output with a 200mhz scope, I don't see anything that causes me heartburn.
There are snubbers across each semiconductor to keep the voltage even across each semiconductor in each series string while that string is turned off.
I'm not in the drive design business. Nor am I particular knowledgable about the intricacies of drive design. I don't want to be. I'm in the drive application business. The contract was for Rockwell to supply drives and motors to meet a spec. We did not tell them how to do it. Rockwell did not include the output caps without needing them to meet spec.
I answered your questions. However, let's not get side-tracked. You made statements without supporting evidence. Are you going to support your statements? I'm not going to do your homework.
cf
Request you read post 9 and 10. My example is a current source drive.
[1]What would be the value of a capacitor on the output side of an ASD?
3 Wye connected banks of 7200V - 500kvar. So 1500kvar reflected to 6500V or 1500 X (6500^2)/(7200^2). Although why the actual number of kvars/farads would matter I don't know. It's what Rockwell included when they sold us the drives.
[2]What is it intend to accomplish either from the technological or the finanacial side?
Well, I didn't discuss this with Rockwell. My assumption is the motor side caps reduce the lagging power factor (lower the motor magnetizing current) seen by the inverter.
I also suspect CS drives use caps on the output to smooth the current output delivered by the inverter. The inverter delivers power in a 400hz or 800hz fairly narrow pulse. When the inverter semiconductors turn off, the motor, being inductive, continues to draw current. As you are aware, most semiconductors have trouble in this quadrant - high voltage, high current.
Designing CS drives is not my area of expertise - I'm only guessing. There are others here that are more knowledgable than I. Perhaps one of them will jump in.
Couldn't tell you anything about the financial side - probably made Rockwell some money selling us drives that worked and met spec.
[3]Since the capacitor is not variable a resonant circuit at some frequencies, especially with varying carrier frequency is practically unavoidable.
No question here - I'll assume that you wish to know my views on how the drive avoids the "unavoidable".
Maybe the engineers avoided carrier frequencies that could resonate. That would be my guess.
[4]How would one surmount the resultant problems?
What problems? The drives work fine.
[5]What about the increased discharge voltages due to the harmonics?
I don't have a definition for "increased discharge voltages due to the harmonics". I don't know what that means in this context. If you are asking on how Rockwell keeps voltage spikes developing from harmonics, from damaging the inverter semiconductors - well, I don't know there are any spikes, harmonic or otherwise. Looking at the inverter output with a 200mhz scope, I don't see anything that causes me heartburn.
There are snubbers across each semiconductor to keep the voltage even across each semiconductor in each series string while that string is turned off.
Just for finishers .......
I'm not in the drive design business. Nor am I particular knowledgable about the intricacies of drive design. I don't want to be. I'm in the drive application business. The contract was for Rockwell to supply drives and motors to meet a spec. We did not tell them how to do it. Rockwell did not include the output caps without needing them to meet spec.
I answered your questions. However, let's not get side-tracked. You made statements without supporting evidence. Are you going to support your statements? I'm not going to do your homework.
cf
