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Rajasthan Technical University, Kota COURSE - FILE
Rajasthan Technical University, Kota COURSE - FILE Name Branch Session Semester Specialization : : : : : Dr. Dinesh Birla Electrical Engineering 2013-14, Odd Semester M. Tech I Semester Power System Index: Course–File Year : I Subject: POWER SYSTEM ANALYSIS 2013-2014 Rajasthan Technical University, Kota Sr. No. Content/ Item no. Sem : I Page No. 1 Students Detail 2 4 Course Schedule Course-File General Format Time-Table Syllabus Course Plan More on Course Schedule Method of Evaluation Guidelines to Study the Subject Course Objectives Course Outcome Objectives – Outcome Relationship Matrix Assignment-1 5 Assignment-2 13 6 Assignment-3 14 7 Assignment-4 15 8 Assignment-5 16 10 Tutorial-1 17 11 Tutorial-2 18 12 Tutorial-3 19 13 Tutorial-4 20 14 Tutorial-5 21 15 Lecture Plan 22-26 17 Mid–Term Question Paper (I & II) 27-28 18 Performance of Students in Mid Terms 3 3 4-6 7-11 12 29 Student Details Year : I Subject: POWER SYSTEM ANALYSIS 2013-2014 Rajasthan Technical University, Kota S. No. Roll No. Student Name 1 13EUCPS600 AKHILESH KUMAR 2 13EUCPS601 AMIT SINGHAL 3 13EUCPS602 AMRITA JAIN 4 13EUCPS603 ASHU VERMA 5 13EUCPS604 BHASKAR SHARMA 6 13EUCPS605 BHEEMRAJ SUMAN 7 13EUCPS606 FAIZAL KHAN 8 13EUCPS607 HARSHITA BAJPAI 9 13EUCPS608 HEM MANOHAR 10 13EUCPS609 KRIPAL SINGH 11 13EUCPS610 NEHA KUMARI 12 13EUCPS611 POOJA NAGAR 13 13EUCPS612 POOJA SHARMA 14 13EUCPS613 RAJARAM CHANDRA MEENA 15 13EUCPS614 RANJEET KUMAR 16 13EUCPS615 KM SHIVANGI CHAUHAN 17 13EUCPS616 SHOBHIT JAIN 18 13EUCPS617 VIVEK NATH Sem : I Course Schedule Year : I Subject: POWER SYSTEM ANALYSIS Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering Sem : I 2013-2014 Course Details Name of the Programme : M. Tech. Batch : Electrical Branch : Electrical Semester :I Title of the Subject : Power System Analysis Subject Code : 1MPS1 No. of Students: 18 General: About Course File Format 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. Time Table and Syllabus. Course Schedule including Course Plan. Experiments List and Lab manual also, if required. List of Assignments / Tutorials/ Seminar Topics given to students. Tutorial Sheet (If required, as per the syllabus). Lecture Plan. Model Question Paper of the subject distributed to students included (Question Bank of important Questions). Mid –Term Question Paper (I & II) and answer-books. Question of previous years available by University. Marks details of the Students in respect of MTE I (Mid Term Exam) and MTE II. Course File Year : I Subject: POWER SYSTEM ANALYSIS 2013-2014 Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering Sem : I SYLLABUS COPY M. TECH. I-SEMESTER 1MPS1 - POWER SYSTEM ANALYSIS Fault Analysis: Positive, Negative and Zero sequence equivalent circuits of lines, two and three winding transformers and synchronous machines. Analysis of shunt and series faults, effect of neutral grounding. Admittance and Impedance Model and Network Calculations: Calculation of Z-bus, Y-bus. Algorithm for the formation of bus admittances and impedance matrices, Fault calculation using Z-bus. Load Flow Studies: Formulation of load flow problem. Various types of buses. Gauss-Siedel, NewtonRaphson and Fast Decoupled Algorithms. Calculation of reactive power at voltage controlled buses in the Gauss-Siedel interactive method using Y-bus. Representation of transformers-Fixed tap setting transformer, Tap changing under load transformers, Phase shifting transformers, Comparison of methods for load flow. Power System Security and State Estimation: Concepts of security states and security analysis in power system, State estimation in power system. 2. Unit No. 1 2 3 4 5 COURSE PLAN Name of Unit Fault Analysis Topics to cover Introduction, Electrical Power System Per Unit Quantities, Basic Terms, Single line diagram for a balanced 3-phase system Admittance Model and calculations Mutually coupled branches in Ybus Bus Admittance Matrix formation and numerical. Formation of Ybus using Singular transformation method and numericals Formation of Zbus using Singular transformation method and numerical Admittance Bus admittance and impedance matrices. Thevenin’s theorem and Z bus. and Direct determination of Z bus. Modification of an existing bus. Impedance Transient on a Transmission line, short circuit of a synchronous machine on no Model and load, short circuit of a loaded synchronous machine. Network EquIalent circuits of synchronous machine under sub transient, transient and Calculation steady state conditions. s: Selection of circuit breakers, Algorithm for short circuit studies. Analysis of three-phase faults Load Flow Fortescure theorem, symmetrical component transformation. Studies Phase shift in star-delta transformers. Sequence Impedances of transmission lines, Synchronous Machine and Transformers, zero sequence network of transformers and transmission lines. Construction of sequence networks of power system. Analysis of single line to ground faults using symmetrical components Analysis of line to line fault using symmetrical components. Analysis of double line to ground faults using symmetrical components Analysis of unsymmetrical shunt faults using bus impedance matrix method Connection of sequence networks under fault conditions Calculation Load flow problem, Development of load flow equations of reactive Bus classification. Gauss Seidel power Newton Raphosn Decoupled and fast decoupled methods for load flow analysis. Comparison of load flow methods Calculation of reactive power at voltage controlled buses in the gauss siedel interactive method under load Representation of transformers Fixed tap setting transformer,tap changing under load condition Phase shifting transformers Concepts of security states Power System Security analysis in power system Security State estimation in power system and State Estimation Lecture No. 1 2 3, 4 5 6 7, 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24,25 26,27 28,29 30 31 32 33 Course File Year : I Subject: POWER SYSTEM ANALYSIS Rajasthan Technical University, Kota 3 2013-2014 METHOD OF EVALUATION 3.1 Mid Term Examinations (MTE I & II) 3.2 Assignment / Tutorials 3.3 Viva wherever applicable 3.4 Term End Examination Foundation Topics: Introduction to per unit quantities Introduction to Symmetrical component and fault analysis methods Advanced Topics: Admittance model and Admittance matrix Impedance model and Impedance matrix Sem : I More on Course Schedule Year : I Subject: POWER SYSTEM ANALYSIS Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering 2013-2014 Sem : I Guidelines to Study the Subject 1. Preparation: - Basic fundamental of knowledge of simple power flow and faults for their study and analysis. 2. Core Competence: - To provide students the knowledge of power system design and analysis and to determine the operational performance of existing systems. 3. Breadth: -To prepare for a better future in the field of designing new electrical systems. Learning Environment: - To provide student a friendly and professional environment. More on Course Schedule Year : I Subject: POWER SYSTEM ANALYSIS Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering 2013-2014 Sem : I On completion of this Subject / Course the students shall be able to understand the following: S. No. Objectives Provides the knowledge of per unit system and admittance model by describing per unit quantities , single line diagram for a balanced three phase system, branch and node admittance, equIalent admittance networks and calculation of Ybus Provides knowledge of impedance models and sysmetrical fault analysis by describing bus admittance matrix and impedance matrix Provides practical knowledge of connection of sequence networks under fault conditions. Outcomes a,k IV Provides knowledge of unsymmetrical fault and connection of sequence under fault conditions. a,e,i V Provides techniques for load flow analysis like Gauss Siedal, Newton Ralphson, etc a,f,g,h,I,j I II III a,b,c,d,e,k a,c,d More on Course Schedule Year : I Subject: POWER SYSTEM ANALYSIS 2013-2014 Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering Sem : I The expected outcomes of the Course / Subject are: S.No. General Categories of Outcomes a Ability to acquire knowledge of specific discipline or professional area with an ability to discriminate, evaluate, analyze and synthesize existing and new knowledge, and integration of the same for enhancement of knowledge. b Ability to formulate and analyse complex electrical engineering problems. c Ability to solve engineering problems and arrive at feasible, optimal solutions after considering public health and safety. d Ability to apply appropriate research methodologies, techniques and tools, design,conduct experiments, analyse and interpret data. e Ability to apply appropriate techniques, resources, and modern engineering f Ability to collaborative-multidisciplinary scientific research,demonstrate a capacity for selfmanagement and teamwork. g Ability to manage projects efficiently after consideration of economic and financial factors. h Ability to make effective presentations and design documentation by adhering to appropriate standards. i Ability to engage in life-long learning independently to improve knowledge and competence j Ability to contribute to the community for sustainable development of society k Ability to learn from mistakes without depending on externalfeedback Specific Outcomes of the Course Post Graduate will demonstrate knowledge of power system design and analysis Post Graduate will demonstrate an ability to identify, formulate and study different faults. Post Graduate will demonstrate an ability to design power system for proper load distribution. Post Graduate will demonstrate an ability to visualize and work in laboratory and other tasks Post Graduate will demonstrate skills to use modern devices fabrication techniques and equipments. Post Graduate will demonstrate knowledge of eventual yield in power system design Post Graduate will show the understanding of need of power systems in daily lIes. Post Graduate will develop self confidence in knowledge of Power system designing and analysis. Post Graduate can participate and succeed in competitIe examinations related to power system analysis. Post Graduate can design different Power system devices etc. Post Graduate will show the understanding of new technology in power system designing. More on Course Schedule Year : I Subject: POWER SYSTEM ANALYSIS Sem : I 2013-2014 Rajasthan Technical University, Kota Objectives – Outcome Relationship Matrix (Indicate the relationship by x mark). Program Outcomes a Course Objectives I b c d e f g h i j X II X III X IV X V X k X X X X X X X X X X X X X X X Assignment Sheet - I Year : I Subject: POWER SYSTEM ANALYSIS Sem : I 2013-2014 Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering Assignment- I 1. A 30 MVA, 13.8 KV, 3-phase alternator has a subtransient positive reactance of 15 % and negative and zero sequence reactances of 15% and 5% respectively. The alternator supplies two motors over a transmission line having transformers at both ends shown in figure (one line diagram). The motor have rated inputs of 20 MVA and 10 MVA both at 12.5 KV with 20% subtransient reactance and negative and zero sequence reactances are 20% and 5% respectively. Current limiting reactors of 2 Ohms each are in the center of the alternator and large motor. The 3 phase transformer are both rated 35 MVA, 13.2 ∆ - 115 Y KV with leakage reactances of 10%, series reactances of the line is 80 Ohms. The zero sequence reactance of the line is 200 Ohms. Determine the fault current when (i) L-G fault takes place at point ‘P’. (ii) L-L fault takes place at point ‘P’. (iii) L-L-G fault takes place at point ‘P’. Assume V f = 120 KV. 20 MVA, 12.5 KV 30 MVA, 13.8 KV ∆ ∆ 10 MVA, 12.5 KV Assignment Sheet - II Year : I Subject: POWER SYSTEM ANALYSIS Sem : I 2013-2014 Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering Assignment-II 1. Derive the necessary conditions of the equation for L-L-G fault in transmission system. Assignment Sheet - III Year : I Subject: POWER SYSTEM ANALYSIS Sem : I 2013-2014 Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering Assignment- III . 1. Formulate Y-Bus for the network shown in figure. The values shown are impedances. Transformer leakage reactances is 0.05 or 5%. G1, 10% j 0.05 1 2 j 0.15 j 0.1 j 0.4 j 0.2 j 0.15 3 Fault j 0.1 4 j 0.05 G2, 10% Assignment Sheet - IV Year : I Subject: POWER SYSTEM ANALYSIS Sem : I 2013-2014 Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering Assignment- IV 1. A 25 MVA, 13.2 KV alternator with solidly grounded neutral has a sub-transient reactance of 0.25 pu and negative and zero sequence reactance of 0.35 pu and 0.10 pu respectively. A L-G fault occours at terminal of the unloaded generator, determine fault current and line to line voltages. Assignment Sheet - V Year : I Subject: POWER SYSTEM ANALYSIS Sem : I 2013-2014 Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering Assignment- V Q.1 Explain the analysis of single line to ground faults using symmetrical components. Q.2 Describe the sub-transient and transient reactance calculation values for transformer transmission line and synchronous generator. Q.3 Describe any two steps out of four steps of step by step Z- bus building algorithm. Tutorial Sheet – I Year : I Subject: POWER SYSTEM ANALYSIS 2013-2014 Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering Sem : I TUTORIAL-1 1. The generator of Problem 1 is feeding 150 MVA at 0.85 pf lagging infinite bus bar at 15 kV. a. Determine Ey and d for the above operation. What are P and Q fed to the bus bars? b. Now E, is reduced by l0o/o keeping mechanical input to generator same, find new dand Q delIered. c. Et is now maintained as in part (a) but mechanical power input to generator is adjusted till Q = 0. Find new d and P. d. For the value of Ey in part (a) what is the maximum Qthat can be delIered to bus bar. 2. Two generators rated 10 MVA, 13.2 KV and 15 MVA, 13.2 KV are connected in parallel to a bus bar. They feed supply to 2 motors of inputs 8 MVA and 12 MVA respectIely. The operating voltage of motors is 12.5 KV. Assuming the base quantities as 50 MVA, 13.8 KV, draw the per unit reactance diagram. The percentage reactance for generators is 15% and that for motors is 20%. 3. A 30 MVA, 13.8 KV, 3-phase generator has a sub transient reactance of 15%. The generator supplies 2 motors through a step-up transformer - transmission line – step- down transformer arrangement. The motors have rated inputs of 20 MVA and 10 MVA at 12.8 KV with 20% sub transient reactance each. The 3-phase transformers are rated at 35 /115 KV-Y with 10 % leakage reactance. The line reactance is 80∆MVA, 13.2 KV- ohms. Draw the equIalent per unit reactance diagram by selecting the generator ratings as base values in the generator circuit. 4. A 80 MVA, 10 KV, 3-phase generator has a sub transient reactance of 10%. The generator supplies a motor through a step-up transformer - transmission line – step-down transformer arrangement. The motor has rated input of 95 MVA, 6.3 KV with 15% sub transient reactance. The step-up 3-phase transformer is rated at 90 MVA, 11 KV-Y /110 KV-Y with 10% leakage reactance. The 3phase step-down transformer consists of three connected transformers, each rated at 33.33 MVA, 68/6.6 KV with 10%∆single phase Y- leakage reactance. The line has a reactance of 20 ohms. By selecting the 11 KV, 100 MVA as base values in the generator circuit, determine the base values in all the other parts of the system. Hence evaluate the corresponding pu values and draw the equIalent per unit reactance diagram. Tutorial Sheet – II Year : I Subject: POWER SYSTEM ANALYSIS 2013-2014 Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering Sem : I Tutorial-II 1. A transmission line of inductance 0.1 H and resistance 5 short circuited at t = 0, at the far end of a transmission line and is supplied by an ac t+150πsource of voltage v = 100 sin (100 ). Write the expression for the short circuit current, i(t). Find the approximate value of the first current maximum for the gIen =900? What should be the instant ofθ=0, and α. What is this value for θ and αvalues of short circuit so that the DC offset current is (i)zero and (ii)maximum? 2. A 25 MVA, 11 KV, 20% generator is connected through a step-up transformer- T1 (25 MVA, 11/66 KV, 10%), transmission line (15% reactance on a base of 25 MVA, 66 KV) and step-down transformer-T2 (25 MVA, 66/6.6 KV, 10%) to a bus that supplies 3 identical motors in parallel (all motors rated: 5 MVA, 6.6 KV, 25%). A circuit breaker-A is used near the primary of the transformer T1 and breaker-B is used near the motor M3. Find the symmetrical currents to be interrupted by circuit breakers A and B for a fault at a point P, near the circuit breaker B. 3. Two synchronous motors are connected to a large system bus through a short line. The ratings of the various components are: Motors(each)= 1 MVA, 440 volts, 0.1 pu reactance; line of 0.05 ohm reactance and the short circuit MVA at the bus of the large system is 8 at 440 volts. Calculate the symmetrical short circuit current fed into a three-phase fault at the motor bus when the motors are operating at 400 volts. 4. The one line diagram for a radial system network consists of two generators, rated 10 MVA, 15% and 10 MVA, 12.5 % respectIely and connected in parallel to a bus bar A at 11 KV. Supply from bus A is fed to bus B (at 33 KV) through a transformer T1 (rated: 10 MVA, 10%) and OH line (30 KM long). A transformer T2 (rated: 5 MVA, 8%) is used in between bus B (at 33 KV) and bus C (at 6.6 KV). The length of cable running from the bus C up to the point of fault, F is 3 KM. Determine the current and line voltage at 11 kV bus A under fault conditions, when a fault occurs at the point F, gIen that Zcable = 0.135 + j 0.08 ohm/ kM and ZOH-line = 0.27 + j 0.36 ohm/kM Tutorial Sheet – III Year : I Subject: POWER SYSTEM ANALYSIS 2013-2014 Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineeing Sem : I Tutorial-III 1. 2. 3. 4. 5. 6. The line b of a 3-ph line feeding a balanced Y-load with neutral grounded is open resulting in line currents: Ia = 10<0o& Ic = 10< 120o A. Determine the sequence current components. One conductor of a 3-ph line feeding a balanced delta-load is open. Assuming that line c is open, if current in line a is 10<0 A , determine the sequence components of the line currents. Three identical resistors are Y-connected to the LT Y-side of a delta-star transformer. The voltages at the resistor loads are |Vab| = 0.8 pu., |Vbc|=1.2 pu., and |Vca|=1.0 pu. Assume that the neutral of the load is not connected to the neutral of the transformer secondary. Find the line voltages on the HT side of the transformer. The line currents in a 3-ph 4 –wire system are Ia = 100<30o, Ib = 50<300o, Ic = 30<180o. Find the symmetrical components and the neutral current. Determine the sequence components if are Ia = 10<60o A, Ib = 10<-60o A, Ic = 10<180o A. A 250 MVA, 16 kV rated generatori s feeding into an infinite bus bar at 15 kV. The generator as a synchronous reactance of 1.62pu.lt is found that the machine excitation and mechanical power input are adiusted to gIe E, = 24 kY and power angle 6 = 30o. a. Determine the line current and actIe and reactIe powers fed to the bus bars. b. The mechanical power input to the generator is increased by 20Vo from that in part(a) but its excitation is not changed. Find the newline current and power factor. c. With reference to part (a) current is to be reduced by 20Vo at the same power factor by adjusting mechanical power input to the generator and its excitation. Determine Ey, 6 and mechanical power input. d. With the reduced current as in part (c), the power is to be delIered to bus bars at unity pf, what are thre corresponding values of El and and also the rnechanical ower input to the generator. Tutorial Sheet – IV Year : I Subject: POWER SYSTEM ANALYSIS Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering 2013-2014 Sem : I Tutorial-IV 1) A three phase generator with constant terminal voltages gIes the following currents when under fault: 1400 A for a line-to-line fault and 2200 A for a line-to-ground fault. If the positIe sequence generated voltage to neutral is 2 ohms, find the reactances of the negatIe and zero sequence currents 2) A dead fault occurs on one conductor of a 3-conductor cable supplied y a 10 MVA alternator with earhed neutral. The alternator has +ve, -ve and 0-sequence components of impedances per phase respectIely as: (0.5+j4.7), (0.2+j0.6) and (j0.43) ohms. The corresponding LN values for the cable up to the point of fault are: (0.36+j0.25), (0.36+j0.25) and (2.9+j0.95) ohms respectIely. If the generator voltage at no load (Ea1) is 6600 volts between the lines, determine the (i)Fault current, (ii)Sequence components of currents in lines and (iii)Voltages of healthy phases. 3) A generator rated 11 kV, 20 MVA has reactances of X1=15%, X2=10% and X0=20%. Find the reactances in ohms that are required to limit the fault current to 2 p.u. when a a line to ground fault occurs. Repeat the analysis for a LLG fault also for a fault current of 2 pu. 4) A three phase 50 MVA, 11 kV generator is subjected to the various faults and the surrents so obtained in each fault are: 2000 A for a three phase fault; 1800 A for a line-to-line fault and 2200 A for a line-toground fault. Find the sequence impedances of the generator. 5) Determine the fault currents in each phase following a double line to ground short circuit at the terminals of a star-connected synchronous generator operating initially on an open circuit voltage or i.o pu. The positIe, negatIe and zero sequence reactance of the generator are respectIely 70.35, j0.25 and j0.20, and its star point is isolated from ground. Tutorial Sheet – V Year : I Subject: POWER SYSTEM ANALYSIS 2013-2014 Rajasthan Technical University, Kota 1. Name of the Faculty : Dr. Dinesh Birla 2. Designation : Professor 3. Department : Electrical Engineering Sem : I Tutorial-V Q1. Prepare short notes on power system security and state estimation. Q.2 A generator-transformer unit is connected to a line through a circuit breaker. The unit ratings are: Gen.: 10 MVA, 6.6 KV, Xd” = 0.1 pu, Xd’ = 0.2 pu and Xd = 0.8 pu; and Transformer: 10 MVA, 6.9/33 KV, Xl = 0.08 pu; The system is operating on no-load at a line voltage of 30 KV, when a three-phase fault occurs on the line just beyond the circuit breaker. Determine the following: (i) Initial symmetrical RMS current in the breaker, (ii) Maximum possible DC off- set current in the breaker, (iii) Momentary current rating of the breaker, (I) Current to be interrupted by the breaker and the interrupting KVA and (v) Sustained short circuit current in the breaker. Lecture Plan Year : I Rajasthan Technical University, Kota Subject: POWER SYSTEM ANALYSIS Subject Code: 1MPS1 Duration of Lesson: 55 min 2013-2014 Sem : I Lesson – 1; Title: Introduction of Electrical Power System S.NO. 1 2 3 4 Topic: Introduction Electrical Power System Per Unit Quantities Basic Terms Time Allotted 10 10 15 15 Lesson – 2; Title: Per Unit Quantities S.NO. 1 2 Topic: Per Unit Quantities, Basic Terms, Single line diagram for a balanced 3-phase system Numerical Time Allotted 35 20 Lesson – 3; Title: Admittance Model S.NO. 1 Topic: Admittance Model and calculations Time Allotted 50 Lesson – 4; Title: Admittance Model and calculations S.NO. 1 2 Topic: Admittance Model and calculations Numericals Time Allotted 20 30 Lesson – 5; Title: Mutually coupled branches in Ybus S.NO. 1 2 Topic: Mutually coupled branches in Ybus Numericals Time Allotted 20 30 Lesson – 6; Title: Formation of Ybus S.NO. 1 2 Topic: Bus Admittance Matrix formation and numerical. Numericals Time Allotted 20 30 Lesson – 7; Title: Bus admittance Matrices for fault analysis S.NO. 1 Topic: Formation of Ybus using Singular transformation method and numericals Time Allotted 50 Lesson – 8; Title: Formation of Ybus using Singular transformation S.NO. 1 2 Topic: Formation of Ybus using Singular transformation method Numericals Time Allotted 30 20 Lesson – 9; Title: More on “Formation of Ybus” using Singular transformation S.NO. 1 2 Topic: Formation of Zbus using Singular transformation method and numerical Numericals based on above Lesson – 10; S.NO. 1 2 Title: Bus admittance and impedance matrices Topic: Bus admittance and impedance matrices. Thevenin’s theorem and Z bus. Numerical Lesson – 11; S.NO. 1 2 S.NO. 1 2 2 Time Allotted 30 20 Title: Transient on Transmission lines, Synchronous Machines Topic: Transient on a Transmission line, short circuit of a synchronous machine on no load Short circuit of a loaded synchronous machine. Lesson – 13; S.NO. 1 Time Allotted 35 15 Title: Direct determination of Zbus Topic: Direct determination of Z bus. Modification of an existing bus. Numerical Lesson – 12; Time Allotted 25 25 Time Allotted 35 15 Title: Equivalent Circuits Topic: EquIalent circuits of synchronous machine under sub-transient, transient and steady state conditions. Numerical Time Allotted 40 10 Lesson – 14; S.NO. 1 2 3 Title: Algorithm for Short Circuit Studies Topic: Selection of circuit breakers, Algorithm for short circuit studies. Analysis of three-phase faults Numerical Lesson – 15; S.NO. 1 2 S.NO. 1 2 2 Topic: Phase shift in star-delta transformers. Sequence Impedances of transmission lines, Synchronous Machine and Transformers, zero sequence network of transformers and transmission lines. Numericals 2 S.NO. 1 2 S.NO. 1 2 Time Allotted 35 15 Time Allotted 25 25 Title: Connection of Sequence Networks Under Fault Conditions Topic: Connection of sequence networks using symmetrical components under fault conditions Examples of the fault analysis Lesson – 20; 15 Title: Analysis of line to line fault Topic: Analysis of line to line fault using symmetrical components. Analysis of double line to ground faults Numerical Lesson – 19; Time Allotted 35 Title: Construction of Sequence Networks Topic: Construction of sequence networks of power system. Analysis of single line to ground faults using symmetrical components Numerical Lesson – 18; S.NO. 1 Time Allotted 35 15 Title: Synchronous Machine and Transformers Lesson – 17; S.NO. 1 Title: Symmetrical Component Topic: Fortescure theorem, symmetrical component transformation. Numerical Lesson – 16; Time Allotted 20 20 10 Time Allotted 30 20 Title: Connection of Sequence Networks Under Fault Conditions Topic: Analysis of unsymmetrical shunt faults using bus impedance matrix method Numerical Time Allotted 30 20 Lesson – 21; S.NO. 1 2 Topic: Load flow problem, Development of load flow equations Numerical Lesson – 22; S.NO. 1 2. Topic: Bus classification. Gauss Seidel Numericals Topic: Newton Raphosn Numericals Lesson – 24; Lesson – 25; 2 Time Allotted 20 30 Title: Calculation of Reactive Power at Voltage Controlled Buses Topic: Calculation of reactive power at voltage controlled buses in the gauss siedel interactive method under load Lesson – 27; S.NO. 1 Time Allotted 30 20 Title: Comparison of Load Flow Methods Topic: Comparison of load flow methods Numericals Lesson – 26; Time Allotted 30 20 Title: Fast Decoupled Method Topic: Decoupled and fast decoupled methods for load flow analysis. Numerical S.NO. 1 2 Time Allotted 30 20 Title: Newton Raphson Load Flow Method S.NO. 1 2 S.NO. 1 2 Time Allotted 35 15 Title: Gauss Seidel Load Flow Method Lesson – 23; S.NO. 1 Title: Load flow problem Time Allotted 50 Title: Calculation of Reactive Power Topic: Calculation of reactive power at voltage controlled buses in the gauss siedel interactive method under load Numerical Time Allotted 30 20 Lesson – 28; S.NO. 1 2 Topic: Representation of transformers Fixed tap setting transformer, tap changing under load condition Numericals based on it Lesson – 29; S.NO. 1 2 Title: Representation of Transformers, Fixed Tap Setting Topic: Representation of transformers Fixed tap setting transformer, tap changing under load condition Numerical S.NO. 1 2 S.NO. 1 20 Time Allotted 40 10 Title: Concepts of Security States Topic: Concepts of Security States Lesson – 32; Time Allotted 30 Title: Phase Shifting Transformers Topic: Phase Shifting Transformers Numerical Lesson – 31; Time Allotted 50 Title: Security Analysis in Power System Topic: Security Analysis in Power System Lesson – 33; S.NO. 1 35 15 Title: Representation of Transformers Fixed Tap Setting Lesson – 30; S.NO. 1 Time Allotted Time Allotted 50 Title: State Estimation in Power System Topic: State Estimation in Power System \ Time Allotted 50 I Mid Term Question Paper Year : I Subject: POWER SYSTEM ANALYSIS Sem : I 2013-2014 Rajasthan Technical University, Kota Rajasthan Technical University, Kota M. Tech I Year, I Sem, Branch: Power System I Mid Term Examination (2013-14) Subject: Power System Analysis Date: 04/10/2013 Duration: 1Hr Maximum Marks: 12.5 Instructions to Candidates: Attempt all questions. Q.1 Derive the fault current equation for L-L-G fault for a unloaded generator for solid fault. Q.2 Describe the type-3 step for Z bus. Q.3 In the Fig. for P-V data shown in table1 common base MVA 100. Determine fault current for balanced three phase fault at bus 3 through a fault impedance Z f = j0.1 pu. Item Base MVA Voltage Rating X1 X2 X0 G1 100 20kv 0.15 0.15 0.05 G2 100 20kv 0.15 0.15 0.05 T1 100 20/220kv 0.10 0.10 0.10 T2 L12 100 100 20/220kv 220kv 0.10 0.125 0.10 0.125 0.10 0.30 L13 100 220kv 0.15 0.15 0.35 L23 100 220kv 0.15 0.15 0.7125 II Mid Term Question Paper Year : I Subject: POWER SYSTEM ANALYSIS Sem : I Rajasthan Technical University, Kota 2013-2014 Rajasthan Technical University, Kota M. Tech I Year, I Sem, Branch: Power System II Mid Term Examination (2013-14) Subject: Power System Analysis Date: 06/12/2013 Duration: 1Hr Maximum Marks: 12.5 Instructions to Candidates: Attempt all questions. Q.1 Evaluate the element of Jacobian matrix for a 3 bus system one slack, one PV, one PQ bus, V 3 =2.04pu Y Bus = Q.2 Describe the various step of power system with respect to power system security in terms of recovery of security. Q.3 Give a comparison of various load flow method. Performance of Students in Mid Term Exams Year : I Rajasthan Technical University, Kota S. No. Subject: POWER SYSTEM ANALYSIS Subject Code: 1MPS1 Maximum Marks: 25 2013-2014 Roll No. Student Name 1 13EUCPS600 AKHILESH KUMAR 2 13EUCPS601 AMIT SINGHAL 3 13EUCPS602 AMRITA JAIN 4 13EUCPS603 ASHU VERMA 5 13EUCPS604 BHASKAR SHARMA 6 13EUCPS605 BHEEMRAJ SUMAN 7 13EUCPS606 FAIZAL KHAN 8 13EUCPS607 HARSHITA BAJPAI 9 13EUCPS608 HEM MANOHAR 10 13EUCPS609 KRIPAL SINGH 11 13EUCPS610 NEHA KUMARI 12 13EUCPS611 POOJA NAGAR 13 13EUCPS612 POOJA SHARMA 14 13EUCPS613 RAJARAM CHANDRA MEENA 15 13EUCPS614 RANJEET KUMAR 16 13EUCPS615 KM SHIVANGI CHAUHAN 17 13EUCPS616 SHOBHIT JAIN 18 13EUCPS617 VIVEK NATH Sem : I Average Marks obtained in MT I & MT II