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 | 1 | initial version |
The model is faithfully simulating the data you have given it.
You can do a sanity check using ohms law; if the impedance between the fault and the supply is about 10% of the impedance of the fault, then you have a voltage divider situation, and it will result in a 10% voltage drop.
When I say "between the fault and the supply" I also mean the impedance of the volage source itself; so check the MVA base of the machine that is the supply, and check its impedance.
One useful way to look at the impedance of your load flow case is to get an SLD diagram, and click on the "DAT" button, which "
| | 2 | No.2 Revision |
The model is faithfully simulating the data you have given it.
You can do a sanity check using ohms law; if the impedance between the fault and the supply is about 10% of the impedance of the fault, then you have a voltage divider situation, and it will result in a 10% voltage drop.
When I say "between the fault and the supply" I also mean the impedance of the volage source itself; so check the MVA base of the machine that is the supply, and check its impedance.
One useful way to look at the impedance of your load flow case is to get an SLD diagram, and click on the "DAT" button, which "
| | 3 | No.3 Revision |
The model is faithfully simulating the data you have given it.
You can do a sanity check using ohms law; if the impedance between the fault and the supply is about 10% of the impedance of the fault, then you have a voltage divider situation, and it will result in a 10% voltage drop.
When I say "between the fault and the supply" I also mean the impedance of the volage source itself; so check the MVA base of the machine that is the supply, and check its impedance.
One useful way to look at the impedance of your load flow case is to get an SLD diagram, and click on the "DAT" button, which "to "Display impedance data on the Active diagram"
