The one line diagram of a three-phase power system is shown in Fig.8. Impedances are marked in per unit on a 100 MW, 400 kV base. The Load at Bus 2 is S2 = 15.93 MW - j33.4Mvar, and at Bus 3 is S3 = 77 MW + j14 Mvar. It is required to hold the voltage at Bus 3 at 400 kV, Angle 0 degs. Working in per unit, determine the voltages at Buses 2 and 1.
The one line diagram of a three-phase power system is shown in Fig.8. Impedances are marked...
Answer part D The single line diagram of a power network is shown in the figure. Bus#1 is a slack bus. The scheduled powers for bus#2 and bus#3 are given. The impedances shown in the figure are all in per-unit considering a power base of 100 MVA. 30 400 MW 320 MVAr Slack V-140 j0.0125 jo.0s 00 MW 270 MVAr A. Use the Gauss Seidel technique to determine voltages at bus#2 & bus#3. (Start with an initial guess 140 for...
Figure 3, 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 \(V_{1}=1.025 \angle 0^{\circ}\) per unit. Voltage magnitude at bus 3 is fixed at \(1.03\) pu with a real power generation of \(300 \mathrm{MW}\). A load consisting of \(400 \mathrm{MW}\) and \(200 \mathrm{Mvar}\) is taken from bus 2. Line impedances are marked in per unit on a 100-MVA base. For the purpose of hand calculations,...
Fig Qshows the one-line diagram of a three-phase power system. As shown in Fig. Q3. the two zones are connected by a 400 MVA, 240-kV/24-kV, Ý-A three phase transformer. The Y-A three phase transfonmer has an equivalent series impedance of ZTH - 1.2 + j1.6n per phase referred to the high voltage side (primary side). The three-phase power system can be studied with per unit quantities using base values of S-500 MVA and 240 kV in zone 1. By using...
Fig. Q3 shows the one-line diagram of a three-phase power system. As shown in Fig. 23, the two zones are connected by a 400 MVA, 240-kV/24-kV, Y-A three phase transformer. The Y-three phase transformer has an equivalent series impedance of 2T - 1.2 + |1.6 per phase referred to the high-voltage side (primary side). The three-phase power system can be studied with per unit quantities using base values of So=500 MVA and 240 kV in zone 1. 2 -1.61253.15" Line...
Q2. i) The one-line diagram of simple three-bus power system with generation at bus 1 is shown in figure Q2. 0.02 + 30.04 2 256.6 MW 0.0125 + 30.025 +110.2 Mvar 0.01 + 30.03 Slack Bus 3 Vi = 1.0520° 138.6 MW 45.2 Mvar Figure Q2 The magnitude of voltage at bus 1 is adjusted to 1.05 per unit. The scheduled loads at buses 2 and 3 are as marked on the diagram. Line impedances are marked in per unit...
A power system network is shown in Figure 1. All impedances, except the loads at buses 3 and 4, are expressed in per unit on 100 MVA, 154 kV bases. The loads at buses 3 and 4 are expressed in MW and MVAr. a) Assuming a voltage magnitude of 1.0 per unit at buses 3 and 4, convert the loads to per unit impedances b) Convert network impedances to admittances and obtain the bus admittance matrix
Figure 1 shows the one line diagram of a simple power system. Generators are connected at buses 1 and 3 while the loads are indicated at all five buses. Base values for transmission system are 100 MVA, 138 kV. The line data of Table 1 gives per unit series impedances and the charging MVar accounting for the distributed capacitance of the 5 lines. The bus data in Table 2 list values for P, Q and Vat each bus. The slack...
The one-line diagram of a three-bus power system is shown in Figure 4. All impedances are expressed in per unit on a common MVA base. All resistances and shunt capacitances are neglected. Information on each component in this system is given below: • Each generator is represented by an emf behind the sub-transient reactance of j0.045 and their neutrals are connected to the ground. • Line 1-2 has reactance of j0.88 • Line 2-3 has reactance of j0.65 • Line...
The Fig. P1.1 is a one-line diagram of a simple power system. There prefault system is on no-load with 1.0 pu voltage and prefault currents are zero. A BOLTED THREE-PHASE FAULT occurs at point P. (a) Draw the pre-fault single-phase equivalent circuit showing numerical values. (b) (i) Calculate the subtransient current in the fault (ii) Calculate the voltages at the busses during the fault. (iii)Calculate the e subtransient current in the lines. (c)) Determine the Zbus relating the bus currents...
The single line diagram of a power network is shown in the figure. Bus#1 is a slack bus. The scheduled powers for bus#2 and bus#3 are given. The impedances shown in the figure are all in per-unit considering a power base of 100 MVA. 30 400 MW 320 MVAr Slack V-1400.0125 jo.os 3 300 MW 270 MVAr A. Use the Gauss Seidel technique to determine voltages at bus#2 & bus#3. (Start with an initial guess 140 for both buses). [Only...