Transformer problems?
Transformer problems?
(OP)
I was at a customers site and I was troubleshooting on the VFDs ( Variable Frequency Drives) AC of course.It was tripping out on high DC link voltage...anyway that not the issue.I measured the following on the motor.
L1-ground = 440 V AC
L2- ground = 440 V AC
L3- ground = 55 V AC
I went to the power distribution and it was the same there.
The first thought I had but not sure: They must have a open Delta Transformer where one leg is tied to ground..the L3 leg I believe...is that possible?.Or please tell me whats going on.If you can provide me a PDF with any form of drawing that would be great.Thanks so much!






RE: Transformer problems?
FWIW some VFDs do not like the corner grounded system and trying to use on on such a supply leads to problems and or damage to the drive. VFDs are usually designed to work on a grounded star (wye) supply. The input filters are the cause of the problem if I recall correctly: I think there's some discussion on here somewhere but the search facility has hidden it.
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If we learn from our mistakes I'm getting a great education!
RE: Transformer problems?
Thnaks for your reply.Yes you are right.I told the customer to not run the VFDs until they had solved this grounding problem due to damage.What do you mean by corner grounding system?.I was thinking about putting on input chokes but since there were 20 VFDs that would be expensive and not really solve the problem since the root cause to the problem is grounding.
RE: Transformer problems?
It would be interesting to know what the phase-phase voltage are.
RE: Transformer problems?
Well as far as I remember they were normal.
L1-L2= 485V
L1-L3= 486V
L2-L3 = 485V
Ya doesnt it seem like the L3 leg is grounded since it is 55 V ?.Thanks
RE: Transformer problems?
I'd check the grounding connections at the transformer(s) and at the service panel.
Corner-grounded deltas are a PITA. They are uncommon, so some "expert" may have removed the bonding jumper from the corner to ground, leaving the neutral to float.
Or you have what is supposed to be an ungrounded 480 V system that has one leg grounded somewhere, or nearly so.
If this is a utility service, they can tell what it is supposed to be - then troubleshooting can begin.
RE: Transformer problems?
Is this a single 3-phase unit or 3-single phase units bank together?
If these are single-phase units bank together are there any of the units with secondary breakers (CSPs)?
Does this 3-phase source supply any single phase loads?
I have a theory as to what may be happening but need these issues clarified first.
RE: Transformer problems?
Iam sorry I dont have this information.I just dont know,I was the technician that was troubleshooting on the VFDs and I know our equipment has to have a wye ( star) connection on the secondary side with the neutral connected to ground for the VFDs to operate safe..I guess if you measure from ground to L1,L2,L3 there should be 277V right ?. 480 / 1,73
thanks
RE: Transformer problems?
L1-Ground = 480V
L2-Ground = 480V
L3-Ground = 0V
Also between any of the phases the voltage should be 480V as well. In this case you will not have 277V at all on your system. If you can, please verify transformer nameplate supplying the VFD. The nameplate should indicate connection type. My advice is to start troubleshooting from both sides of "your" system (transformer to VFD and VFD to transformer)if possible.
"Throughout space there is energy. Is this energy static or kinetic! If static our hopes are in vain; if kinetic — and this we know it is, for certain — then it is a mere question of time when men will succeed in attaching their machinery to the very wheelwork of nature". – Nikola Tesla
RE: Transformer problems?
A properly maintained ungrounded system should show very close to the same voltage to ground from each phase, nominally 277V on a 480V system, but that won't make it suitable for use with VFDs that were designed for use only on a grounded wye system.
RE: Transformer problems?
Did you measure the L-G voltages with load (motor) on? or off?
Also how far away from the source (grounding point) did you measure them?
With load on and away from the source, you will measure the source voltage minus the voltage drop in the condutor due to the load current.
If the VD is indeed 55V, your readings seems somewhat consistent. 440+55=495V which could be the voltage at the source.
Measure the voltages with load off.
RE: Transformer problems?
RE: Transformer problems?
RE: Transformer problems?
Thanks so much for your answers.They were all helpful.I found out that the whole building is ungrounded...this building was built in the late 50's and it never got grounded.Now I am understanding why the drives were faulting on high DC link voltage,because the voltage across the capacitors is way too high.The normal DC link voltage should be about 650V DC.There are 2 capacitors in series with a ground between them and with no ground this voltage will be up to over 900V DC with no grounded system..so this explains the high DC link voltage fault.Yes they are thinking now of getting isolation transformers.I dont know of drives that will work without problems without a ground system.
RE: Transformer problems?
Bill
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"Why not the best?"
Jimmy Carter
RE: Transformer problems?
I had similar problems with a drive tripping on a DC overvoltage link when the drive was not even running a load. This drive was on a HRG system. I figured the drive was tripping due to the flucuations on the incoming voltage due to some sort of transient upstream (cap switching etc...) All voltages on this 480V drive checked out fine.
After reading this thread I became more curious about this but cannot seem to understand how being ungrounded is causing the voltage across these capacitors to be high? I'm guessing that its just due to normal capacitive coupling to ground which is high and causing the drive to therefore have a high DC voltage.
RE: Transformer problems?
Im curious about your suggestion. Could you explain your thinking? I have seen in installation manuals where some VFDs will not function on delta systems. Why is that?
bluesman,
The 55 volts on the grounded leg, could it not be the result of a High Resistance Ground system? Have you checked to see if such a device is in the system? Not that it is important at this point, I believe davidbeach is onto the solution.
RE: Transformer problems?
The power electronics of most VFDs are designed with the assumption of a grounded wye system as the supply source, allowing for the use of lower voltage ratings on components than would be necessary for an ungrounded system.
RE: Transformer problems?
I should have been a more specific on the question, I understood the reasoning for the transformer, I was not certain as to why some VFDs will only work on a WYE system.
Thank you... that was worth a star.
I asked the motor/drive manufacturers tech dept. that very question and got a long winded "not completely sure" kinda answer that left me more puzzled...
RE: Transformer problems?
The problem is not whether the system is delta or wye, it is the voltages that may be experienced and the voltage rating of the components.
A machine designed for use on 480 Volt, grounded wye must have components suitable for 277 Volts to ground.
A machine designed for a 480 Volt ungrounded delta system or a 480 Volt HRG wye system must have components suitable for 480 volts to ground.
A ground on one phase of a floating delta system or an HRG wye system will drive the voltage to ground of the other two phases to 480 Volts (line voltage).
Bill
--------------------
"Why not the best?"
Jimmy Carter
RE: Transformer problems?
In older style three phase UPS systems the input rectifier consisted of a controlled thyristor rectifier. This was then inverted using an output transformer. Using this shcheme the DC voltage didn't have to be above the peak voltage of the output AC waveform as the transformer could adjust. The input to the rectifier only required the three phases to operate and no neutral was required.
The output transformer was very expensive and so for economic reasons circuit topologies were developed to do away with this transformer. One of these was to use a standard three phase rectifier followed by two boost circuits which would develop a positive and negative DC voltage both referenced to a neutral point. The DC voltage was at a level to be above the peak voltage of the required output AC voltage.
In this topology (and other closely related topologies) the neutral is required, if the neutral is not present the DC loses control and either the positive or negative legs will go into an over-voltage mode.
Do VFDs now use a boost style input?
RE: Transformer problems?
We have several 480V VFD's that are connected to isolation transformers which have a delta corner grounded secondary. To my knowledge none of these drives have ever had a problem and I'm thinking this is due to the fact that becuase one leg is grounded a fault will cause a OCPD trip rather then cause an overvoltage condition and damage components as warros said.
I have other 480V VFD's that are connected on a HRG wye secondary. How can you tell if a VFD is rated to be on an HRG wye or ungrounded delta and weather the components are rated for 480V L-G. It this rating typically on a nameplate somewhere?