Voltage Drop Across Xfmr

[marshavillareal]

I'm using ETAP to model a new electrical system and I am seeing a large voltage drop across my incoming transformer (~5%) The transformer is not overloaded I'm using about 16 out of my 20 MVA ONAF rating. When I increase the transformer rating the voltage drop is only a couple percent. Can anyone explain what is going on here? Is there any standard that talks about transformer loading / sizing?

 

[LarryFine]

What's the unloaded voltage reading (using the same meter)?

 

[Cold Fusion]

I don't think there is a meter involved. I suspect it is a design calc program (etap)

mars (or marsha ) -

If I understand, you are wondering why the Vd with 16 megs of load on a 5%Z, 20mva xfm is more than the Vd for 16meg load on a 5%Z, 40 mva xfm - if so:

The impedance of a 5%, 40mva xfm is half that of a 5%Z, 20mva xfm. But I'm thinking that you already knew that.

For standards, I'd probably start with the IEEE color book series.

cf

 

[bob]

I'm using ETAP to model a new electrical system and I am seeing a large voltage drop across my incoming transformer (~5%) The transformer is not overloaded I'm using about 16 out of my 20 MVA ONAF rating. When I increase the transformer rating the voltage drop is only a couple percent. Can anyone explain what is going on here? Is there any standard that talks about transformer loading / sizing?

The voltage drop across the transformer is based on the transformer %Z.
If your transformer has a %Z = 6% then you will have a 6% drop at full load.
Assuming you have 6% Z, 16 mva/20mva x 6% = 4.8% drop. Are you using 16 mva
with the 40 mva sub?

 

[jghrist]

The voltage drop across the transformer is based on the transformer %Z.
If your transformer has a %Z = 6% then you will have a 6% drop at full load.
Assuming you have 6% Z, 16 mva/20mva x 6% = 4.8% drop. Are you using 16 mva
with the 40 mva sub?

This is not correct. Both the impedance and the load current are complex values. The voltage drop is only equal to the %Z for full load if the load impedance angle equals the transformer impedance angle.

 

[bob]

This is not correct. Both the impedance and the load current are complex values. The voltage drop is only equal to the %Z for full load if the load impedance angle equals the transformer impedance angle.

Since the OP did not specify any of the information regarding impedance angle, how can you say its incorrect?

 

[Cold Fusion]

Since the OP did not specify any of the information regarding impedance angle, how can you say its incorrect?

Isn't the xfm impedance mostly reactive? Generally x/r >10. And the standard industrial load is .8pf? I would think it would be a good guess that the two won't line up.

But I still would not have said you were wrong :grin::grin:

cf

 

[bob]

Isn't the xfm impedance mostly reactive? Generally x/r >10. And the standard industrial load is .8pf? I would think it would be a good guess that the two won't line up.

But I still would not have said you were wrong :grin::grin:

cf

This OP is not using actual load. He is using ETAP to model an electrical system.

 

[Cold Fusion]

This OP is not using actual load. He is using ETAP to model an electrical system.

Yes, I knew that. I think I mentioned that in post 3.

If I were modeling in etap, (which I occasionally do), I'd either show the initial loading as .8pf or resistive.

cf

 

[marshavillareal]

Thanks for the information. It was helpful.