Lovely Professional University, Punjab

Course Code Course Title Course Planner Lectures Tutorials Practicals Credits ELE521 POWER SYSTEM MODELING AND ANALYSIS 17092::Mukul Chankaya 3.0 0.0 0.0 3.0 Course Category Courses with numerical and conceptual focus

TextBooks Sr No Title Author Edition Year Publisher Name T-1 Power System Stability and Control P. Kundur 2nd 1994 Tata McGraw Hill

Reference Books

Sr No Title Author Edition Year Publisher Name R-1 Power System Analysis John J. Grainger and

Stevenson.D 2nd 1994 Tata McGraw Hill

R-2 Power Systems Modelling and Fault Analysis

Nasser D. Tleis 1st 2008 Elsevier

R-3 Electric Energy systems theory An Introduction

Olle L. Elgerd 1st 1982 Tata McGraw Hill

R-4 Power system operation and control P.S.R Murthy 3rd 1987 Tata McGraw Hill

Relevant Websites Sr No (Web address) (only if relevant to the course) Salient Features RW-1 Power system modeling http://nptel.iitm.ac.in/courses/108101004/

RW-2 Synchronous machine modeling http://nptel.iitm.ac.in/courses/108101004/11

RW-3 Excitation system modeling http://www.youtube.com/watch?v=5t06qtCUH08

RW-4 Transient Stability http://www.powerapps.org/PAES_TStability.aspx

RW-5 Small signal stability http://www.youtube.com/watch?v=FwlpLlACGs8

RW-6 Load flow analysis http://www.nptel.iitm.ac.in/courses/Webcourse-contents/IIT-KANPUR/power-system/ui/Course_home-4.htm

RW-7 Z bus algorithm http://askguru.net/s/algorithm-for-modification-of-z-bus-of-power-system-network

RW-8 Load forecasting http://www.youtube.com/watch?v=DVEbZ__FNRg

RW-9 Flux linkage model http://www.ewh.ieee.org/soc/es/Nov1998/08/SYNCMACH.HTM

LTP week distribution: (LTP Weeks)

Weeks before MTE 7

Weeks After MTE 7

Spill Over 3

Detailed Plan For Lectures

Week Number

Lecture Number

Broad Topic(Sub Topic) Chapters/Sections of Text/reference books

Other Readings, Relevant Websites, Audio Visual Aids, software and Virtual Labs

Lecture Description Learning Outcomes Pedagogical Tool Demonstration/ Case Study / Images / animation / ppt etc. Planned

Week 1 Lecture 1 Introduction to power system modeling(Distinction between steady state and Quasi steady state)

T-1:1 R-1:15

Differentiation between steady state and quasi state stability

students will understand the basic concept of stability

Lecture 2 Introduction to power system modeling(Gauss seidel iterative technique)

T-1:6.4.2 R-1:9.2 R-4:5.7

To study the load flow method of Gauss iteration method

Students will learn about the guass elimination tech of load flow

Lecture 3 Introduction to power system modeling(Newton-Raphson method for power flow)

T-1:6.4.3 R-1:9.4 R-4:5.9

RW-6

To study the concept of newton raphson method for load flow in power analysis

Students will learn about Newton raphson method of load flow

Showing the MATLAB simulink model for NR load flow method

Week 2 Lecture 4 Introduction to power system modeling(Multi area power flow analysis with tie line control)

R-3:9.2.5

RW-1

To learn the concept of multi area power flow analysis with tie line control

Students will learn about the coordination of multi area power flow with tie line

showing the Matlab simulink model regarding multi-area power flow analysis

Lecture 5 Introduction to power system modeling(Algorithm for symmetrical fault analysis using Z bus)

T-1:13.4.5 R-1:8.1

RW-7

To learn the basic algo for fault analysis

Students will be able to develop an algo for fault analysis

Lecture 6 Introduction to power system modeling(Symmetrical components and sequence impedances)

R-1:13.4 R-2:

R-4:7.2

To study the basic concepts related to Symmetrical components and sequential impedance

Students will understand the unsymmetrical fault solving using sequential components

Week 3 Lecture 7 Synchronous machine modeling(Mathematical description of a synchronous machine)

T-1:3.2 R-1:

R-2:5.2 R-3:4.2

RW-2

To learn the mathematical description of a synchronous machine

Students will learn about the modeling of synchronous machine

Lecture 8 Synchronous machine modeling(dq0 transformation)

T-1:3.3 R-2:5.3 R-3:4.2

To study the dqo transformation

students will learn about importance of dqo transformation

Lecture 9 Synchronous machine T-1:3.4 To study importance of Students will learn

modeling(Per unit transformation) R-2:5.2 R-3:4.2

Per unit in synchronous machine

about per unit representation of machine

Week 4 Lecture 10 Synchronous machine modeling(Equivalent circuit)

T-1:3.5 3.6

To study Basic equivalent circuit and steady state of synchronous machine

students will understand about the importance of equivalent circuit in steady state analysis

Synchronous machine modeling(Steady state analysis)

T-1:3.5 3.6 R-3:4.4

To study Basic equivalent circuit and steady state of synchronous machine

students will understand about the importance of equivalent circuit in steady state analysis

Lecture 11 Synchronous machine modeling(Transient performance characteristics)

T-1:3.7 R-2:5.3

RW-2

To study Transient performance characteristics

Students will understand about the transient performance of synchronous machine

Lecture 12 Quiz,Test1 Week 5 Lecture 13 Synchronous machine

modeling(Constant flux linkage model including the effect of sub transient circuits)

T-1:5.3

RW-9

To study Constant flux linkage model of synchronous machine

Students will understand about Constant flux linkage model

Lecture 14 Synchronous machine modeling(Review of machine modeling)

T-1:3.2.1 R-2:5.5

To study direct and quadrature axis of synchronous machine

Students will understand the concept of machine modeling

Lecture 15 Synchronous machine modeling(Classification of power system stability)

T-1:12.1 13.1

RW-5

To analyse and study classification of power system stability

Students will understand the different classes of power system stability

Week 6 Lecture 16 Synchronous machine modeling(Small signal stability analysis of SMIB)

T-1:12.3

To study the small signal stability analysis of Single machine infinite bus

Students will understand the importance of stability in single machine infinite bus

Lecture 17 Excitation system modeling(A.C. excitation system)

T-1:8.3.1 8.3.2

RW-3

To study the A.C. and D.C. excitation system

Students will learn the working of A.C. and DC excitation system and their interrelation

Excitation system modeling(D.C. excitation system)

T-1:8.3.1 8.3.2

RW-3

To study the A.C. and D.C. excitation system

Students will learn the working of A.C. and DC excitation system and their interrelation

Lecture 18 Quiz,Test2

Week 7 Lecture 19 Excitation system modeling(Dynamic performance of excitation system)

T-1:8.4

To study the dynamic performance of excitation system

Students will understand the excitation system performance in dynamic state

Excitation system modeling(Control and protective function of excitation system)

T-1:8.4

To study the dynamic performance of excitation system

Students will understand the excitation system performance in dynamic state

Lecture 20 Excitation system modeling(Control and protective function of excitation system)

T-1:8.4

To study the dynamic performance of excitation system

Students will understand the excitation system performance in dynamic state

Excitation system modeling(Dynamic performance of excitation system)

T-1:8.4

To study the dynamic performance of excitation system

Students will understand the excitation system performance in dynamic state

Lecture 21 Excitation system modeling(Modeling of excitation system)

T-1:8.6

To study modeling of excitation systemModeling of excitation system

Students will learn to make the mathematical model of excitation system

MID-TERM Week 8 Lecture 22 Small signal stability(Power

system stabilizer on small signal stability)

T-1:12.5 R-1:16.8 R-4:8.6

To learn the small signal stability of multimachine system

Students will understand the importance of PSS in power system stability

Lecture 23 Small signal stability(Small signal stability of multi-machine system)

T-1:12.7 R-1:16.8

To learn the small signal stability of multimachine system

Students will learn the effect of multi machine system on small signal stability

Lecture 24 Small signal stability(Analysis of large system)

T-1:12.8

RW-5

To study basic concepts related to large power system analysis

Students will understand the the large power system analysis

Week 9 Lecture 25 Small signal stability(Characteristics of small signal stability problem)

T-1:12.9

To learn characteristics of small signal stability problem

Students will understand the Characteristics of small signal stability problem

Lecture 26 Small signal stability(Method of improving small signal stability)

T-1:17.2 R-1:16.10

To study the different Method of improving small signal stability, Contigency lecture

Students will learn the Method of improving small signal stability

Lecture 27 Transient stability analysis(Interfacing of steam and

T-1:16.3

To learn about the interfacing of steam and

Students will understand about

hydro turbine-governor model) hydro turbine governing system

turbine governing system model

Week 10 Lecture 28 Transient stability analysis(Implicit method of modeling)

T-1:13.2

RW-4

To learn about the implicit method of modeling

Students will understand about the implicit method of transient modeling

Lecture 29 Transient stability analysis(Interfacing excitation system model with transient stability algorithm)

T-1:8.4

RW-8

To learn the interfacing of excitation system model and transient modeling

Students will observe about the use of transient stability algo in excitation system

Lecture 30 Transient stability analysis(Hydraulic turbine)

T-1:9.1

To learn about the importance of hydraulic turbine

Students will understand about working of hydraulic turbine in power generation

Week 11 Lecture 31 Transient stability analysis(Governing system of hydraulic turbine)

T-1:9.1

To analyse the working and importance of governing system of hydraulic turbine

Students will understand about the necessity of governing system

Lecture 32 Quiz,Test3 Lecture 33 Static var systems(Configuration

of static var system) T-1:11.2.7

L-33 To learn about the Configuration of static var system L-34 Contingency

L-33 Students will learn about the SVC and FACTS devices

L-34 Revision

showing the Matlab simulink model showing the SVC

Week 12 Lecture 34 Static var systems(Configuration of static var system)

T-1:11.2.7

L-33 To learn about the Configuration of static var system L-34 Contingency

L-33 Students will learn about the SVC and FACTS devices

L-34 Revision

showing the Matlab simulink model showing the SVC

Lecture 35 Static var systems(Thyristor controlled rectifier and Thyristror switched capacitor)

T-1:11.2.7 R-1:13.5

L-35 To learn TCR L-36 To learn TSC

Students will be able to learn about the basic facts devices and there operation in power system

Showing the Matlab simulimk model showing the TCR and TSC

Lecture 36 Static var systems(Thyristor controlled rectifier and Thyristror switched capacitor)

T-1:11.2.7 R-1:13.5

L-35 To learn TCR L-36 To learn TSC

Students will be able to learn about the basic facts devices and there operation in power system

Showing the Matlab simulimk model showing the TCR and TSC

Week 13 Lecture 37 Static var systems(Interfacing of static var devices with transient stability algorithm)

T-1:11.2.7

To learn the interfacing of static var device with transient stability algorithm

Students will understand the effect of static var device during transient instability in system

Lecture 38 Static var systems(Induction motor modeling)

T-1:7.2

L-38 To learn about the modeling of induction

L-38 Students will understand the

Showing the Matlab model of induction

machine

L-39 mathematical model of induction machine

modeling of induction machine L-39 students will learn about the mathematical description of machine

machine

Lecture 39 Static var systems(Induction motor modeling)

T-1:7.2

L-38 To learn about the modeling of induction machine

L-39 mathematical model of induction machine

L-38 Students will understand the modeling of induction machine L-39 students will learn about the mathematical description of machine

Showing the Matlab model of induction machine

Week 14 Lecture 40 Static var systems(Interfacing of induction modeling with transient modeling)

T-1:12.2

L-40 To learn about interfacing of induction modeling with transient modeling

L-41 Contingency

L-40 students will learn about behavior of induction machine with transient condition

L-41 Revision

Lecture 41 Static var systems(Method of improving transient stability)

T-1:17.1 R-4:8.5

L-41& L-42 To learn about several method of transient stability improvement

L-41 Students will understand the 1). Eular method 2). modified Eular method L-42 3). R.K. method of transient stability analysis

Lecture 42 Static var systems(Method of improving transient stability)

T-1:17.1 R-4:8.5

L-41& L-42 To learn about several method of transient stability improvement

L-41 Students will understand the 1). Eular method 2). modified Eular method L-42 3). R.K. method of transient stability analysis

SPILL OVER Week 15 Lecture 43 Spill Over

Lecture 44 Spill Over

Lecture 45 Spill Over

Scheme for CA:

Component Frequency Out Of Each Marks Total Marks

Quiz,Test 2 3 10 20

Total :-

10

20

Details of Academic Task(s)

AT No. Objective Topic of the Academic Task Nature of Academic Task (group/individuals/field

work

Evaluation Mode Allottment / submission Week

Test1 To analyse the students knowledge about power system modeling and analysis

Distinction between steady state and Quasi steady state, Gauss seidel iterative technique, Newton-Raphson method for power flow, Multi area power flow analysis with tie line control, Algorithm for symmetrical fault analysis using Z bus, Symmetrical components and sequence impedance, Mathematical description of a synchronous machine, dq0 transformation, Steady state analysis, Equivalent circuit, Transient performance characteristics

Individual On the basis of students performance in written test

3 / 4

Test2 To analyse the students knowledge in power system modeling and analysis

Constant flux linkage model including the effect of sub transient circuits, Review of machine modeling, Classification of power system stability, Small signal stability analysis of SMIB, A.C. excitation system, D.C. excitation system, Transient performance characteristics

Individual On the basis of students performance in written test

5 / 6

Quiz1 To analyse the students knowledge of student about the power system modeling and analysis

Power system stabilizer on small signal stability, Small signal stability of multi-machine system, Analysis of large system, Characteristics of small signal stability problem, Method of improving small signal stability, Interfacing of steam and hydro turbine-governor model, Implicit method of modeling, Interfacing excitation system model with transient stability algorithm, Hydraulic turbine, Governing system of hydraulic turbine, Steam turbine, Governing system of steam turbine

Individual On the basis of students performance in Quiz.

10 / 11