The three-bus power system shown in the figure has one alternator connected to bus 2 which supplies 200 MW and 40 MVAr power. Bus 3 is an infinite bus having a voltage of magnitude \(|V_3| = 1.0 \, \text{p.u.}\) and angle of \(-15^\circ\). A variable current source, \(|I|\angle \phi\) is connected at bus 1 and controlled such that the magnitude of the bus 1 voltage is maintained at 1.05 p.u. and the phase angle of the source current, \(\phi = \theta \pm \tfrac{\pi}{2}\), where \(\theta\) is the phase angle of the bus 1 voltage. The three buses can be categorized for load flow analysis as:
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Show Hint
- Bus 1: Slack bus, Bus 2: \(P - |V|\) bus, Bus 3: \(P - Q\) bus
- Bus 1: \(P - |V|\) bus, Bus 2: \(P - |V|\) bus, Bus 3: Slack bus
- Bus 1: \(P - Q\) bus, Bus 2: \(P - Q\) bus, Bus 3: Slack bus
- Bus 1: \(P - |V|\) bus, Bus 2: \(P - Q\) bus, Bus 3: Slack bus
The Correct Option is D
Solution and Explanation
Step 1: Identify bus 3 (infinite bus).
Bus 3 is given as an infinite bus with fixed voltage magnitude (\(1.0 \, \text{p.u.}\)) and fixed angle (\(-15^\circ\)).
- An infinite bus is always treated as the slack bus.
Step 2: Identify bus 2 (alternator bus).
Bus 2 supplies active and reactive power:
\[
P_2 = 200 \, \text{MW}, Q_2 = 40 \, \text{MVAr}
\]
Thus, at bus 2 both \(P\) and \(Q\) are specified.
Hence, bus 2 is a \(P - Q\) bus (load bus).
Step 3: Identify bus 1 (controlled current source bus).
At bus 1, the magnitude of the voltage is maintained at 1.05 p.u., but the phase angle of current is controlled (\(\phi = \theta \pm \pi/2\)).
This implies:
- Voltage magnitude \(|V|\) is specified.
- Active power \(P\) is controlled by the current injection.
Thus, bus 1 is a \(P - |V|\) bus (generator bus / PV bus).
Step 4: Categorize.
\[
\text{Bus 1: } P - |V| \, \text{bus},
\text{Bus 2: } P - Q \, \text{bus},
\text{Bus 3: Slack bus}
\]
Final Answer:
\[
\boxed{\text{Bus 1: \(P - |V|\) bus, Bus 2: \(P - Q\) bus, Bus 3: Slack bus}}
\]
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