A DC Optimal Power Flow problem consists of a 3-bus network. The per-unit reactances of the lines interconnecting the buses are as follows: X₁2 = 0.35 pu, X13 = 0.25 pu and X23= 0.1 pu. Bus 2 is taken as the reference bus, and SBase = 125 MVA. The power flow limit on transmission line 2-3 is 500 MW. Which one of the below is the constraint that needs be incorporated in the DCOPF problem to account for line 2-3 transmission capacity limit? Select one: O a. 03 -0.6 rad = O b. 03 = -0.4 rad O C. 500 (0₁.03) = 500 O d. 03 -0.5 rad = O e. 4 1000 (02.03) = 500 Of. None of these

A DC Optimal Power Flow problem consists of a 3-bus network. The per-unit reactances of the lines interconnecting the buses are as follows: X₁2 = 0.35 pu, X13 = 0.25 pu and X23= 0.1 pu. Bus 2 is taken as the reference bus, and SBase = 125 MVA. The power flow limit on transmission line 2-3 is 500 MW. Which one of the below is the constraint that needs be incorporated in the DCOPF problem to account for line 2-3 transmission capacity limit? Select one: O a. 03 -0.6 rad = O b. 03 = -0.4 rad O C. 500 (0₁.03) = 500 O d. 03 -0.5 rad = O e. 4 1000 (02.03) = 500 Of. None of these

Power System Analysis and Design (MindTap Course List)

6th Edition

ISBN:9781305632134

Author:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Publisher:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Chapter3: Power Transformers

Section: Chapter Questions

Problem 3.49P: Consider the single-Line diagram of a power system shown in Figure 3.42 with equipment ratings...

See similar textbooks

Related questions

Q: Three zones of a single-phase circuit are identified in Figure. The zones are connected by…

A: per unit system The ratio of actual value to the base or reference value in the same unit is called…

Q: Figure shows the one-line diagram of a simple three-bus power system with generation at buses 1 and…

Q: -In distribution substation, the shunt compensation used is of ----------- in nature. -The…

Q: I) Determining the voltage amplitude and angle values of each busbar II) To determine the…

A: In the transmission line, the voltage amplitude and the phase angle are determined at each bus-bar.…

Q: 3 substations A, B and C are spaced 75 km apart as shown in Figure, B and C are connected together…

Q: Three zones of a single-phase circuit are identified shown in Figure below. The zones are connected…

Q: Q2) In the network in the figure below Y-Y connected transformers, each with grounded neutrals, are…

A: Given Data :Generator 1 and generator 2 X(d)=0.2 and X(d')=0.25Find :here find bus matrix for z(bus)…

Q: Three single-phase transformers, each rated 10 MVA , 66.4/12.5 kV, 60 Hz , with an equivalent series…

A: Calculate the per unit current with respect to the base.

Q: Calculate the initial symmetrical short circuit current that will occur when a 3 phase short circuit…

A: We can re draw the given system as Let the base MVA of the system i.e SB 500MVA and base Voltage…

Q: A DC Optimal Power Flow problem is to be solved for a 3-bus network. The per-unit reactances of the…

A: The per-unit reactances of the lines A 3-BUS network interconnecting the buses are…

Q: In the single line diagram shown below, generators G₁ and G₂ have a leakage reactance of 0.26 per…

A: Given single line diagram, Ratings of the generator G1 and G2, 66.5 MVA11 kV0.26 pu

Q: In a power system having three conductors A, B and C of a 3-phase line carrying currents IA, IB and…

A: The three-phase line is represented by the phase A, B, and C, the current across the given conductor…

Q: The sample large power system network data's are given below, The total number of buses is 5…

A: There are two types of symmetrical faults: a) Three-phase short circuit fault. b) Three-phase to…

Q: Figure below shows one-line diagram of a simple three bus power system with generation at bus 1. Bus…

A: V1= 1 pu V20 = 1+ j 0 V30 = 1+ j 0 Power at bus 2 are P2 =250 MW Q 2 =110 MVAR Power at bus 3 are…

Q: 1. FIGURE 52 shows the one-line diagram of a simple three-bus power system with generation at bus I.…

A: Convert the line impedances into admittances, using Y=1/Z

Q: Consider the 500 kV, three phase bundled conductor line as shown in the figure below. Find the line…

Q: A single-line diagram of a four-bus system is shown in fiugre. Equipment ratings and per-unit…

A: Given: A single-line diagram of a four-bus system is shown below: Machines 1 and 2: 100 MVA 20 kV;…

Q: A 3-phase, 132 kV, 50 Hz, and 200 km line has a resistance of 0.0765 ohm per km per phase,…

A: In the Question Following data is given. VR= 132 KVf= 50 Hz , ω = 100π…

Q: Q2. Figure Q2 shows the single-line diagram. The scheduled loads at buses 2 and 3 are as marked on…

A: Note: We are authorized to answer three subparts at a time since you have not mentioned which part…

Q: Figure below shows a power system where load at bus 5 is fed by generators at bus 1 and bus 4. The…

Q: 20cn) 10c2) Nodal strees Method. 50(0) 10c0) 50C 80 (A) 3 20c2) 30c2) 5CA) 5CA) 10(A) 20c2) 3 CA)

Q: 2. The one-line diagram of a three-phase power system is as shown in the figure below. Impedances…

A: In this question we need to find the voltage at bus 2 and 1. We convert all the given values in per…

Q: lA = ID- 2kn 4kO Ic= lo = lA- 3kn lE IF 1ko L10 V 5kQ- 6kN. IG = IG 20 V ww ww ww %3D II

Q: 7. In the circuit below write the loop equations and set up (not solve) the matrix equation for the…

Q: Seccion 1 Seccion 2 6.9 kV/115 kV 115 kV/13.8 kV Seccion 3

A: Given data Base complex power; Sb=100 MVA Voltage ratio of Section 1; 6.9 kV/115 kV Voltage ratio of…

Q: 2. For the 3-bus network shown in figure, the impedances indicated are in per unit. a) Draw pu…

A: given that - V1= 1∟0o V2=1.05∟90o (a) At node 1: I1 =Y1V1 + Y3 (V1-V3) + Y6 (V1 – V2) At node 2:…

Q: No-load operation and short circuit tests were performed on three-phase, 50 Hz 480/220 delta / Y…

A: Giveen : No load Test Violtgae =480vCurrent =0.71 A Power =114 w Short circuit test : COltage = 10…

Q: A DC Optimal Power Flow problem is to be solved for a 3-bus network. The per-unit reactances of the…

A: per unit reactance of the interconnecting busses are reference bus 1 as base MVA is 100 MVAthe…

Q: The bus impedance matrix for a three-bus power system has per-unit elements as: Z11 = 0.5 Z12 = 0.4…

A: In this question we need to find a subtransient fault current when a 3 phase fault occur at bus 3.

Q: Following figure shows the one-line diagram of a two bus system. Take bus 1 as slack bus, bus 2 as…

A: The base MVA is The tolerance is The y bus is

Q: The figure below shows the one-line diagram of a four- bus power system. The voltages, the scheduled…

A: Note: We are authorized to answer three subparts at a time since you have not mentioned which part…

Q: In the following network, the voltage magnitudes at all buses are equal to 1 p.u., the voltage phase…

A: Given- Voltage magnitudes at all buses = 1 p.u. Voltage phase angles are small, Line resistance are…

Q: Refer to the 5-bus data given below. Sbase = 400 MVA, the base voltage is 15.0 kV for buses 1 and 3,…

A: a) Single line diagram of given power system here series parameter are in impedance and shunt…

Q: A network consisting of a set of generator and load buses is to be modeled with a DC power flow, for…

A: Given PTDF5,42-4 =-0.2609 LODF2-4,4-5 =-0.6087 Base case flow on line 4-5 is F04-5=13.6 MW Base case…

Q: in distribution transformers; What is 30 degrees phase shift in delta-star connection? What are the…

A: In the star-delta connection, the primary side of the transformer is in delta configuration while…

Q: For the system shown in figure, voltages V2, V3 and angles 82, 83 are calculated using…

Concept explainers

Short Transmission Line

A short transmission line is a transmission line that has a length less than 80 kilometers, an operating voltage level of less than 20 kV, and zero capacitance effect.

Power Flow Analysis

Power flow analysis is a topic in power engineering. It is the flow of electric power in a system. The power flow analysis is preliminary used for the various components of Alternating Current (AC) power, such as the voltage, current, real power, reactive power, and voltage angles under given load conditions and is often known as a load flow study or load flow analysis.

Complex Form

A power system is defined as the connection or network of the various components that convert the non-electrical energy into the electric form and supply the electric form of energy from the source to the load. The power system is an important parameter in power engineering and the electrical engineering profession. The powers in the power system are primarily categorized into two types- active power and reactive power.

Question

A DC Optimal Power Flow problem consists of a 3-bus network. The per-unit reactances of the lines
interconnecting the buses are as follows: X₁2 = 0.35 pu, X₁3 = 0.25 pu and X23 = 0.1 pu. Bus 2 is taken as the
reference bus, and SBase = 125 MVA. The power flow limit on transmission line 2-3 is 500 MW. Which one of
the below is the constraint that needs be incorporated in the DCOPF problem to account for line 2-3
transmission capacity limit?
Select one:
O a. 03 -0.6 rad
O b.
03 = -0.4 rad
О с.
500 (0₁.03) 500
O d. 03 -0.5 rad
О е.
ņ
1000 (0₂.03) = 500
Of. None of these
27 201

Expert Solution

This question has been solved!

Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.

This is a popular solution!

SEE SOLUTION Check out a sample Q&A here

Step 1: Given information and calculating power flow limit on transmission line 2-3 in P.u

VIEW

Step 2: The constraints that needs be incorporated in the DCOPF

VIEW

Solution

VIEW

Trending now

This is a popular solution!

Step by step

Solved in 3 steps

SEE SOLUTION Check out a sample Q&A here

Knowledge Booster

Learn more about

Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, electrical-engineering and related others by exploring similar questions and additional content below.

Similar questions

Consider three ideal single-phase transformers (with a voltage gain of ) put together as three-phase bank as shown in Figure 3.35. Assuming positive-sequence voltages for Va,Vb, and Vc find Va,Vb, and VC. in terms of Va,Vb, and Vc, respectively. (a) Would such relationships hold for the line voltages as well? (b) Looking into the current relationships, express IaIb and Ic in terms of IaIb and Ic respectively. (C) Let S and S be the per-phase complex power output and input. respectively. Find S in terms of S.
Consider the single-Line diagram of a power system shown in Figure 3.42 with equipment ratings given: Generator G1: 50MVA,13.2kV,x=0.15p.u. Generator G2: 20MVA,13.8kV,x=0.15p.u. Three-phase -Y transformer T1: 80MVA,13.2/165YkV,X=0.1p.u. Three-phase Y- transformer T2: 40MVA,165Y/13.8kV,X=0.1p.u. Load: 40MVA,0.8PFlagging,operatingat150kV Choose a base of 100 MVA for the system and 132-kV base in the transmission-line circuit. Let the load be modeled as a parallel combination of resistance and inductance. Neglect transformer phase shifts. Draw a per-phase equivalent circuit of the system showing all impedances in per unit.
Consider a single-phase electric system shown in Figure 3.33. Transformers are rated as follows: XY15MVA,13.8/138kV, leakage reactance 10 YZ15MVA,138/69kV, leakage reactance 8 With the base in circuit Y chosen as 15MVA,138kV determine the per-unit impedance of the 500 resistive load in circuit Z, referred to circuits Z, Y, and X. Neglecting magnetizing currents, transformer resistances, and line impedances, draw the impedance diagram in per unit.
Q2. Figure Q2 shows the single-line diagram. The scheduled loads at buses 2 and 3 are as marked on the diagram. Line impedances are marked in per unit on 100 MVA base and the line charging susceptances are neglected. a) Using Gauss-Seidel Method, determine the phasor values of the voltage at load bus 2 and 3 according to second iteration results. b) Find slack bus real and reactive power according to second iteration results. c) Determine line flows and line losses according to second iteration results. d) Construct a power flow according to second iteration results. Slack Bus = 1.04.20° 0.025+j0.045 0.015+j0.035 0.012+j0,03 3 |2 134.8 MW 251.9 MW 42.5 MVAR 108.6 MVAR
A network consisting of a set of generator and load buses is to be modeled with a DC power flow, for the sake of conducting a contingency analysis. The initial flows calculated with the DC power flow give the following information: f°2-4 = - 65.3 MW and fº4-5 = 13.6 MW. The following values of LODF and PTDF factors are given: PTDF54,2-4 = -0.2609, LODF2-4,4-5 = -0.6087. Calculate the contingency flow on line 2-4 due to outage of line 4-5. Select one: O a. -75.5MW O b. None of these O c. -68.85MW O d. -73.58MW O e. 75.5MW O f. -61.75MW
Write current equations and determine the admittance matrix of the network Determine the load voltage VL at the 5th Bus-Bar, the current of the Load IL and the current of each generator.
In the single line diagram shown below, generators G₁ and G₂ have a leakage reactance of 0.26 per unit on a 66.5MVA rating at 11kV, and transformers T₁ and T₂ have a voltage ratio of 11/145kV and a leakage reactance of 0.125 per unit on a 75MVA rating. Choosing 100MVA and 132kV (at the lines side) as base quantities, find the reactance of G₁, G₂, T₁ and T2 in per unit to the new base quantities. 66.5MVA 11kV 0.26pu 66.5MVA 11kV 0.26pu (G1 G2 75MVA 11/145kV 0.125pu T1 T2 75MVA 11/145KV 0.125pu 132kV Lines
The figure below shows the one-line diagram of a four- bus power system. The voltages, the scheduled real power and reactive powers, and the reactances of transmission lines are marked at this one line diagram (The voltages and reactances are in PU referred to 100 MW base. The active power P2 in MW is the last three digits (from right) of your registration number (i.e for the student that has a registration number 202112396, P2 =396). [10] Starting from an estimated voltage at bus 2, bus 3, and bus 4 equals V2 (0) = 1.15<0°, V3 = 1.15 < 0°, V4 1.1< 0°. 1- Specify the type of each bus and known & unknown quantities at each bus. 2- Find the elements of the second row of the admittance matrix (i.e. [Y21 Y22 Y23 Y24]). 3- Using Gauss-Siedal fınd the voltage at bus 2 after the first iteration. 4- Using Newton-Raphson, calculate: |- The value of real power (P2), at bus 2 after the first iteration. Il- The second element in the first row of the Jacobian matrix after the first iteration. 2 P2…
A three-phase symmetrical double circuit line is arranged in a horizontal plane as shown in figure below. Calculate and derive an expression for the transposed line for the inductance. Assume balanced equally distributed loads
2. For the 3-bus network shown in figure, the impedances indicated are in per unit. a) Draw pu admittance diagram and obtain the bus admittance matrix Ybus for the network. b) Find the source voltages Eai and Ecz so that buses 1 and 2 have the voltages V = 120°, V2 = 1.05490° X= 0.20 pu X = 0.20 pu X= 0.36 pu Xo = 0.36 pu Xo 0.15 pu X p= 0.36 pu X- 0.36 pu X - 0.3 pu Load %3D
Three zones of a single-phase circuit are identified shown in Figure below. The zones are connected by transformers T1 and T2, whose ratings are also shown. Using base values of 33 kVA and 232 volts in zone 1, Find: 1- Draw the per-unit circuit including the per-unit impedances and the per-unit source voltage. 2- Calculate the load current both in per-unit and in amperes (actual or original value). Vs Zone 1 232.940° Vs G. 38 T₁ 30 KVA 240/480 volts Xeq = 0.10 p.u. Zone 2 Xiine = 4 Ω T₂ 20 KVA 460/115 volts Zload = Xea = 0.10 p.u. Zone 3 u 1+j2.2 Ω 2
t Figure below shows a power system where load at bus 5 is fed by generators at bus 1 and bus 4. The generators are rated at 100MVA; 11 KV with subtransient reactance of 25%. The transformers are rated each 100 MVA, 11/112 KV and have a leakage reactance of 8%. The lines have an inductance of 1 mH/phase/km. Line L1 is 100 km long while lines L2 and L3 are each of 50 km in length. Load For a 3-phase fault at bus 5, the fault current is equal to 2530A. What the value of the change in the fault current if the value of the base voltage is changed to .10 kV (i.e. new value/old value) 1.0426 0.9833 1.0245 1.0166 0.9751 1