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Latest revision as of 07:31, 22 November 2020
This page describes the most common synchronous machine models used in stability studies.
Nomenclature
The standard machine parameters are defined as follows:
- is the armature resistance (pu)
- is the armature reactance (pu)
- is the d-axis synchronous reactance (pu)
- is the q-axis synchronous reactance (pu)
- is the d-axis transient reactance (pu)
- is the q-axis transient reactance (pu)
- is the d-axis subtransient reactance (pu)
- is the q-axis subtransient reactance (pu)
- is the d-axis transient open loop time constant (s)
- is the q-axis transient open loop time constant (s)
- is the d-axis subtransient open loop time constant (s)
- is the q-axis subtransient open loop time constant (s)
- is the machine inertia constant (MWs/MVA)
- is an additional damping constant (pu)
Note that per-unit values are usually expressed on the machine's MVA base.
6th Order (Sauer-Pai) Model
6th order synchronous machine model based on the book:
Sauer, P.W., Pai, M. A., "Power System Dynamics and Stability", Stipes Publishing, 2006
Stator magnetic equations:
where
Stator electrical equations (neglecting electromagnetic transients):
Equations of motion:
Initialisation:
6th Order (Anderson-Fouad) Model
6th order synchronous machine model based on the book:
Anderson, P. M., Fouad, A. A., "Power System Control and Stability", Wiley-IEEE Press, New York, 2002
Stator magnetic equations:
Stator electrical equations (neglecting electromagnetic transients):
Equations of motion:
Initialisation:
4th Order (Two-Axis) Model
Stator magnetic equations:
Stator electrical equations (neglecting electromagnetic transients):
Equations of motion:
Initialisation:
2nd Order (Classical) Model
Stator equations:
Equations of motion:
Initialisation: