Figure shows the one-line diagram of a simple three-bus power system with generation at buses 1 and 3. The voltage at bus 1 is V1 is 1.025 at an angle of 0^◦ per unit. Voltage magnitude at bus 3 is fixed at 1.03 pu with a real power generation of 300 MW. A load consisting of 400 MW and 200 MVAr is taken from bus 2. Line impedances are marked in per unit on a 100 MVA base.

(a) Construct Ybus matrix for the system in Figure

(b) Using Gauss-Seidel method and initial estimate of V₂⁽⁰⁾ = 1.0 + j0 and V₃⁽⁰⁾ = 1.03 + j0 and keeping |V3| = 1.03 pu, determine the phasor values of V2 and V3. Perform two iterations.

Transcribed Image Text:

The image illustrates a power network diagram for electrical engineering analysis. It consists of three buses interconnected with each other. Here's a detailed description: 1. **Bus 1 (Slack Bus):** - Voltage: \( V_1 = 1.025 \angle 0^\circ \) - Connected to Bus 2 via an impedance of \( j0.025 \). - Connected to Bus 3 via an impedance of \( j0.05 \). 2. **Bus 2:** - Connected to Bus 1 with an impedance of \( j0.025 \). - Connected with a power load of 400 MW and 200 Mvar. 3. **Bus 3:** - Active Power \( P_3 = 300 \) MW. - Voltage magnitude: \( |V_3| = 1.03 \). - Connected to Bus 1 with an impedance of \( j0.05 \). - Connected to Bus 2 with an impedance of \( j0.025 \). **Overview of Diagram Layout:** - The diagram is indicative of a simple network used for load flow analysis. - The connections between buses are labeled with their respective impedances. - The loads and power values given at each bus help in calculating power flow and stability within the network. This diagram serves as a fundamental example for understanding power distribution and flow in an electrical network, typically used for educational purposes in power systems engineering courses.