proposed scheme of m.tech (integrated power system) first ... · 2. to introduce converter and...

PROPOSED SCHEME OF M.Tech (Integrated Power system)

FIRST SEMESTER IPSL611 : ADVANCED CONTROL THEORY: Course Objectives:

1. The Subject deals with advanced concepts required for handing control related problem. 2. To introduce optimal control and fuzzy Control Strategy. 3. To Introduce Stability of discrete time systems, Non Linear system.

Course Outcome: Upon successful completion of the course, students shall be able to- 1. Apply the knowledge of advanced state variable analysis technique. 2. Understand the discrete time system and pole placement design to improve stability. 3. Implement stability of systems using Lyapunov method. 4. Understand optimal control theory and Lagrange parameter techniques. 5. Understand the fuzzy logic control and it‟s application.

. Details of Course:

S. No.

Contents Contact Hours

1 Unit1: Review of state variable analysis, controllability and Observability. Discrimination of continuous time state equations. Solution of state difference equation, controllability and Observability tests for Digital Control Systems.

(10 Hrs)

2 Unit 2: Stability of discrete time Systems. Stability improvement by state feedback , pole placement design and observers.

(10 Hrs)

3 Unit 3: Lyapunov stability Analysis. Basic concepts, Lyapunov‟s first and second methods Stability definitions, Stability theorems, Lyapunov functions for linear and non-linear systems.

(10 Hrs)

4 Unit 4: Optimal Control, parameters optimization techniques, Lagrange parameter techniques, Calculus of variation, unconstrained and constrained minimization of functional. Two point boundary value problems.

(10 Hrs)

5 Unit 5 : Introduction to Fuzzy control: Fuzzy sets and linguistic variables, The fuzzy control scheme, Fuzzification and de fuzzufication methods, Examples, Comparison between conventional and fuzzy control. Introduction to adaptive control and variable structure control. Advanced topic on the subject: Co-ordination and integrated control of different systems in industry.

(10 Hrs)

Suggested Books:

Sr. No.

Title Author Name Publisher Year of

Publication Edition

1 Digital Control And State Variable Methods

M.Gopal Tata Mcgraw –Hill

(Sep-08) 3rd Ed

2 Control Systems Engineering

I. J. Nagrath, M. Gopal

New Age International

(2010)

2nd

Ed

3 Optimal Control Theory: An Introduction

Donald E. Kirk, Dover Publications

(30-apr-04) 2

nd Ed

4 Digital Control Systems Benjamin C. Kuo

Oxford University Press

(2007)

Revised

5 Fuzzy Logic: With Engineering Applications

Timothy J. Ross Wiley India Pvt Ltd

(July 2007)

2nd

Ed,

IPSL612 : ADVANCED POWER ELECTRONICS Course Objectives: 1. This Subject deals with the modern power semiconductor Switches and their application. 2. To introduce converter and inverter performance with various loads. 3. To introduce design of switch mode converter and resonant converter. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Analyse and design AC/AC Cyclo-converter circuit topologies. 2. Apply the switched mode techniques to inverters. 3. Have acquired a good understanding of basic switched-mode DC/DC topologies, operation,

performance and modelling. 4. Have acquired a basic understanding of resonant converter and its method of loss reduction. 5. Understand to design controller and its simulation. Details of Course:

S. No.


1 Unit 1: Over view of power semiconductor device structure, characteristics, rating and protection ( Thyristor , BJT , MOSFET , IGBT, Integrated Gate- Commutated Thyristor (IGCT), MOS controlled Thyristor etc.) GTO, comparison of controlled switches.

( 08 Hrs)

2 Unit 2: Inverters, type (Hard/soft switch inverter), Voltage source inverter current source inverter) multilevel Operation with different types of loads, Performance parameters Harmonic elimination, control of output, voltage using different switching techniques. Discontinuous mode of operation.

(10Hrs)

3 Unit 3: DC to DC switch mode converters , Basic concepts , analysis of switch on and Off transients types , DC to DC converters comparison , soft switching , close loop control .

(10 Hrs)

4 Unit 4: Resonant converters , comparison of PWM and resonant converters , classification , Basic resonant circuit concepts , Analysis and design of SRC ( series ), PRC ( parallel ) , SPRC( series -parallel ) resonant converters, DC-DC as well as AC-DC resonant converter, Power conditioners and uninterruptible power supplies, Recent industrial power electronic applications.

(12 Hrs)

5 Unit 5: controller design with applications and simulation. Advanced topic on the subject.

(10Hrs)

Suggested Books:

Sr. No.


Publication Edition

1 “Power Electronics- Converter Application and Design”

Ned Mohan Tora M. Undeland, William P.Robbins

John Wiley & Sons.

1999 2nd

Ed

2 “Power Electronics Circuits and Application”

M.H. Rashid Prentice Hall of India

2004.

3rd

Ed

3 “Power Electronics” C.V. Lander Mc Graw Hills International Edition.

1998 2nd

Ed

IPSL613 : SWITCHGEAR AND PROTECTION Course Objectives: 1. This course aims to upgrade the knowledge of operatically and control of power system. 2. To introduce protection of generator, transformer, transmission and distribution Lines. 3. To Study Switch gear against different faculty and abnormal conditions. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Design the relevant protection systems for the main elements of a power system. 2. Students will gain ability to design the relevant protection systems for EHV line. 3. Students are knowledgeable in the field of Transformer protection and faults occurring in

Transformer. 4. Students will get the knowledge about the Instrumental Transformer for relaying purposes. 5. Students will able to implement the Numerical relays.

Details of Course:

S. No.


1 Unit 1: Switchgear installation and criteria for selection. Circuit breaker ratings, principles of a-c circuit breaking. RRRV and recovery voltage and their control. Current chopping. Switching of capacitive currents. Kilometric faults. Resistance switching. D-C current interruption. Salient features and characteristics of different arc interrupting media - air, oil, air-blast, SF6, and vacuum. The electric arc and circuit -breaker. Establishing an arc, discharge characteristic of arc, long arc, short arc, energy transfer between electric field and the arc column, energy transfer out of the column. Theories of arc interruption - restriking voltage and energy balance theories and their applications.

(08 Hrs)

2 Unit 2 : EHV Line Protection: Protection of EHV lines against short circuit and over voltages. Distance and carrier aided schemes. Stability of protection on power swing. Out of step blocking and tripping schemes. (With emphasis on implementation using static relays)

(08 Hrs)

3 Unit 3 : Transformer Protection: Various fault occurring on transformer &complete protection against these fault. Machine Protection: Protection of Alternators and large motors. Bus Protection: Schemes for complete protection on EHV bus bars.

(08 Hrs)

4 Unit 4: Instrument transformer for relaying: performance of conventional CT/VT as well as capacitive voltage transformers. Principle of operation of magneto optic CT/ VT, special cases like ferroresonance.

(08 Hrs)

5 Unit 5: Philosophy of Numerical relaying: Anti-aliasing Filters, sampling, Measurements principles using Fourier and other algorithms and its application for implementation of various numerical relays. Introduction to advanced industrial protection. Advanced topic on the subject: Microcontroller based relays

(08 Hrs)

Suggested Books:

Sr. No.


Publication Edition

1. Power Systems Protection

by Elmore ABB 2004 ---

2. Art and science of protective relaying

C.R. Mason --- 1956 1

st

3. Transmission Network Protection

Y.G. Paithankar. (Marcel Dekkar Pub.)

1997 1st

4. Power System Protection

B.Ram TMH. 2011 1

st

5. Computer Relaying for Power System

James Thorp John Wiley Publication

1988 1st

6. “Modern Power Electronics

P.C. Sen “ A.H. Wheeler publication Co

2005 2nd

7. NPTEL Learning Resources

IPSL614 : POWER SYSTEM MODELING : (Elective –I) Course Objectives: 1. Techniques to represent all major Components of a power system are introduced. 2. To introduce load modeling of different types of load. 3. To introduce modeling of synchronous machines and doubly fed induction generator. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Develop mathematical model for synchronous Machine. 2. Understand three phase transformation into two phase using Parks equations. 3. Understand the characteristics of power system components and also the importance of dynamic

behaviour of all passive components under steady state operation. 4. Analyse and design the different types of IEEE system. 5. Develop and simulate the modeling of Doubly fed Induction generator (DFIG). Details of Course:

S. No.


1 Unit 1 :Synchronous Machines: Basic Models, Electric equations, Mechanical equations, per unit system and Normalization, Parks transformation, Flux linkages equations Voltage & current equations, Formulation of state-space equations.

(12 Hrs)

2 Unit 2: Equivalent circuit sub transient and transient inductances and time constants. Classical model of Synchronous Machines. Steady state equations and phasor diagram, Determination of Machines parameters from manufactures data. Linear model of single Machines infinite bus system.

(10 Hrs)

3 Unit 3: Load modeling for different types of loads. Transformer on nominal ratios. Tap representation three –phase models of transformer.

(06Hrs)

4 Unit 4: Modeling of excitation, IEEE systems type 1,2,3,4. Essentials elements of automatic feed back control system, concepts of voltage drop compensation and modeling of Prime mover controllers. Simulation by using recent software.

(06 Hrs)

5 Unit 5 : Modeling of Induction generator– Doubly fed.(DFIG) ( 06 Hrs )

Suggested Books:

Sr. No.


Publication Edition

1 “Power System Control and stability”

Anderson P.M. and A.A. Fouad

IEEE Computer Society Press,

2002-10-17

2nd

Ed

2 “Power System Dynamics, Stability and control”

Padiyar K.R., Interline Publishing Private Ltd. Bangalore.

2007 2nd

Ed

3 Computer Modeling of Electric Power System

Arrilaga J. and Arnold C.P

John Wiley and Sons

2005 1st Ed

4 “Power System Operation and Control “

Murthy P.S. R Tata Mc Graw Hill Publishers, New Delhi.

2008 1st Ed

5 „Power System Analysis‟ Bergen & Vittal, Prentice Hall. 2000 Revised

6 “ Power system Analysis, operation, and control”

Chakraborty and Halder

PHI Learning

Revised edition of

2011

7 Wind Turbine Control Systems

Bianchi, F D., Battista, H de, Mantz, R J, Springer,

2007. 1

st Ed.,

IPSL615: Course Title: ANALYSIS OF ELECTRICAL MACHINES : (Elective –I) Course objective:-

1. This course upgrades the knowledge of students with various reference frame theories. 2. The study of transformations and applications to induction and synchronous machine.

3. The study related to dynamic modeling and self controlled operation

Course Outcome: Upon successful completion of the course, students shall be able to- 1. Apply various reference frame theories to particular application. 2. Determine synchronous machine dynamic equivalent circuit parameters. 3. Apply generalized theory of rotating electrical machine 4. Design modeling for induction machine. 5. Understand the working principle of synchronous machine. Details of Course:

S. No.


1 Unit 1: Principles of electromagnetic energy conversion: General expression of stored magnetic energy, co-energy and force/torque, example using single and doubly excited system; Calculation of air gap mmf and per phase machine inductance using physical machine data; Voltage and torque equation of dc machine.

08 Hrs

2 Unit 2:Three phase symmetrical induction machine and salient pole synchronous machines in phase variable form; Introduction to reference frame theory: static and rotating reference frames, transformation relationships, examples using static symmetrical three phase R, R-L, R-L-M and R-L-C circuits.

08 Hrs

3 Unit 3: application of reference frame theory to three phase symmetrical induction and synchronous machines, dynamic direct and quadrature axis model in arbitrarily rotating reference frames, voltage and torque equations, derivation of steady state phasor relationship from dynamic model, generalized theory of rotating electrical machine and Kron‟s primitive machine.

08 Hrs

4 Unit 4: Determination of synchronous machine dynamic equivalent circuit parameters: standard and derived machine time constants, frequency response test; Analysis and dynamic modeling of two phase asymmetrical induction machine and single phase induction machine.

08 Hrs

5 Unit 5: Permanent magnet synchronous machine: Surface permanent magnet (square and sinusoidal back emf type) and interior permanent magnet machines , construction, operating principle and true synchronous characteristics, dynamic modeling and self controlled operation; Analysis of Switch Reluctance Motors: design trade-off and basic operating characteristics.

08 Hrs

Suggested Books:

Sr. No.

Title Author Name Publisher Year of Publication

Edition

1 Electric Motor Drives, Modelling, Analysis & Control

R. Krishnan Prentice Hall.

2001, 1st Ed

2 Electrical Drive „Vedam Subramanyam.”

Tata Mc Graw Hill

1999 2nd

Ed

3 Analysis of Electric Machinery.

Paul C Krause, Mc Graw Hill. 2000 2nd

Ed

4 Variable frequency AC motor Drives, system

David Finney IEE Press 2002 1st Ed

IPSL616: RENEWABLE & DISTRIBUTED ENERGY SYSTEM: (Elective –I) Course Objectives: 1. To study wind energy conversion systems. 2. To study the distributed generation standards.

3. To Study the wind system with grid stability Course Outcome: Upon successful completion of the course, students shall be able to- 1. Understand the different types of renewable source of energy. 2. Understand integrated operation of wind power generation with grid system. 3. Understand the importance of ancillary services for frequency and voltage control. 4. Implement the uses of various types of wind generators. 5. Understand the technical and economical impacts Distributed Generation Technologies. Details of Course:

S. No.


1 Unit –1 : Dispersed photovoltaic, solar, wind, fuel cell and conventional dispersed generation technologies, economic factors and technical impact on utility distribution systems, interfacing and optimal location of dispersed generation.

08 Hrs

2 Unit –2 :Principles of wind energy extraction, electromechanical energy conversion, characteristics of wind turbines, Photovoltaic and Thermo-solar power generation profiles, Aerodynamics of wind turbines, aerodynamic power controls, pitch, stall, active stall, rotor power characteristics CP-λ, Power curves

08 Hrs

3 Unit –3 : Wind energy conversion systems, Induction generator , Synchronous generator with full scale power electronic block, variable speed operations, doubly fed induction generation. Wind interconnection requirements, low-voltage ride through (LVRT).

08 Hrs

4 Unit –4 : ramp rate limitations, and supply of ancillary services for frequency and voltage control, current practices and industry trends wind interconnection impact on steady-state and dynamic performance of the power system including modeling issue.

08 Hrs

5 Unit –5 :Distributed Generation Standards, DG potential, Definitions and terminologies; current status and future trends, Technical and economical impacts, Definitions and terminologies; current status and future trends, Technical and economical impacts DG Technologies, DG from renewable energy sources, DG from non-renewable energy sources .

08 Hrs

Suggested Books:

Sr. No.


Publication Edition

1. Power Conversion of Renewable Energy

Ewald F. Fuchs, Springer

Spinger 2011 1

st

Systems

2. “Electrical Distribution Engineering”

Anthony J. Pansini CRC Press. 2000 2

nd

3. “Distributed Power Generation Planning and Evaluation

H Lee Willis, CRC Press. 2007 1

st

4. “Electric Power Distribution Automation Protection And Control”

James A Momoh, CRC press 2007 2

nd

5. “Power distribution engineering: fundamentals and applications”

James J. Burke CRC Press.

1994 2nd

IPSL617: EHVAC TRANSMISSION SYSTEMS: (Elective –II) Course objective:- 1. Generation of fields by extra high voltages, transmission and their effect on human being, plants. 2. Design of EHVAC Lines, advantages and protection of EHVAC transmission. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Understand EHVAC and its analysis of all properties of EHVAC Transmissions. 2. Understand the Corona effect and its advantages and disadvantages. 3. Understand the analysis of 3 phase single and double circuits and study of electric and magnetic

fields. 4. Understand the different type of Lightning Protection Scheme. 5. Understand the different types of voltage stability and reactive power compensation. Details of Course:

S. No.


1 Unit 1: Introduction of EHV AC transmission, Tower configurations. Thermal ratings of lines and cables, transformer technology, circuit breakers.Power handing capacitiesofEHV AC Transmission lines. Electric field of point charge . sphere gap- line charge, single and three phase lines and bounded conductors- Maxwell‟s potential co- efficients

12 Hrs

2 Unit 2: Voltage gradients of conductors. Corona effects , Types of critical disruptivevoltages Factor affecting corona , Methods for reducing corona power loss, corona current wave form charge voltage diagram audible noise and ratio interference power loss and audible noise, radio interference.

8 Hrs

3 it 3: Electrostatic and electromagnetic fields of EHV Lines, Electric shock and threshold current : Capacitance of long object , calculation of electromagnetic field of A.C. Lines (3-ph Single and double circuit line only) Effect of high electrostatics field

8 Hrs

4 Unit 4: Electrostatic field of transmission lines. Lightning and lightning protection. Insulation characteristics of long air gaps.

6 Hrs

5 Unit 5: Design of EHV lines based upon steady state limits, transient over voltages and voltage stability. Series and shunt compensation. Reactive power control apparatus.

6 Hrs

Suggested Books:

Sr. No.


Publication Edition

1 EHV AC and HVDC transmission Engineering and practice

S. Rao Khanna 2001 3rd

Ed

2 Electrical power systems C. L. Wadhwa New Age Publication

2010 6th Ed

3 EHV AC Transmission Begamudre. New Age Publication

2010 4th Ed

PSL618 : ELECTRICAL DRIVES-I : (Elective-II) Course objective:-

1. To understand the basic concept of DC Drives. 2. To understand the various control techniques involved with DC Drives.

Course Outcome: Upon successful completion of the course, students shall be able to-

1. Identify and understand the different components of en Elctrical Drives System. 2. Understand the DC motor drives system. 3. Apply the knowledge of control techniques to control DC drives. 4. Understand the concept of controlled 3 phase converter & dc-dc converter. 5. Understand modern control techniques for Induction Motor.

Details of Course:

S. No.


1 Unit-1 : Controlled Bridge Rectifier (1-Ф) and (3-Ф) with DC Motor load separately excited DC motors with rectified single phase supply- single phase semi converter and single phase full converter for continuous and discontinuous modes of operation – power and power factor. Three phase semi converter and three phase full converter for continuous and discontinuous modes of operation – power and power factor – Addition of free-wheeling diode – Three phase double converter

10 Hrs

2 Unit-2 : Three phase naturally commutated bridge circuit as a rectifier or as an Inverter Three phase controlled bridge rectifier with passive load impedance, resistive load and ideal supply – Highly inductive load and ideal supply for load side and supply side quantities, shunt capacitor compensation, three phase controlled bridge rectifier inverter.

6Hrs

3 Unit-3: Phase Controlled DC Motor Drives: Three phase controlled converter, control circuit, control modeling of three phase converter –Steady state analysis of three phase converter control DC motor drive – Two quadrant, Three phase converter controlled DC motor drive – DC motor and load, converter.

6Hrs

4 Unit-4: Current and Speed controlled DC Motor drives :Current and Speed controllers - current and speed feedback –– Design of controllers – Current and Speed controllers – Motor equations – Filter in the speed feedback loop speed controller – current reference generator – current controller and flow chart for simulation – Harmonics and associated problems – sixth harmonics torque.

6 Hrs

5 Unit-5: Chopper controlled DC motor drives &Closed loop operation of DC motor Drives:Principle of operation of the chopper – Four quadrant chopper circuit – Chopper for inversion – Chopper with other power devices – model of the chopper –input to the chopper – Steady state analysis of chopper controlled DC motor drives – rating of the devices – Pulsating torque. Speed controlled drive system – current control loop – pulse width modulated current controller – hysterisis current controller – modeling of

12 Hrs

current controller – design of current.

Suggested Books (Minimum – 3):

Sr. No.


Publication Edition

1 Power Electronics and motor control

Shepherd,Hulley, Liang –CU Press

1996 2nd

Ed

2 Electric motor drives modeling, Analysis and control

R. Krishnan – PHI. 2001 ---

3 Power Electronic Circuits, Devices and Applications

M.H.Rashid PHI, 1995 1st Ed

4 Fundamentals of Electric Drives

G. K. Dubey – Narosa Publications

1995 2nd

Ed

5 Power Semiconductor drives

S.B. Dewan and A. Straughen

Addison-Wesley 1975. 1st Ed

IPSL619 : DISTRIBUTED AUTOMATION : (Elective –II) Course objective:- 1. Implement the load fore casting strategy . 2. Understand the size and location of sub stations. 3. Implement the SCADA system and remote metering Course Outcome: Upon successful completion of the course, students shall be able to- 1. To understand the strategy of load-forecasting. 2. To understand the Load flow study for distribution system 3. To understand analysis of sizing and location of sub stations. 4. Understand Distribution System and its Planning. 5. Understand the different applications of SCADA in distribution system. Details of Course:

S. No.


1 Unit 1: Introduction to distribution systems. Nature of loads and load forecasting .Layout of substations and feeders. Design considerations. Power quality issues.

8 Hrs

2 Unit 2: Distribution system load flow. 6 Hrs

3 Unit 3: Optimum siting and sizing of substations, optimum capacitor placement. 6 Hrs

4 Unit –4 :Distribution system planning Short term planning, Long term planning, Dynamic planning,. Sub-transmission networks configurations, Substation bus schemes, Distribution substations ratings, Service areas calculations, Substation application curves

10 Hrs

5 Unit 5: Automation, configuration of distribution system. Distribution system monitoring and control : SCADA, Remote metering and load control strategies, Optimum feeder switching for loss minimization and load control. Distribution system restoration. Distribution system protection and switchgear.

10 Hrs

Suggested Books:

Sr. No.


Publication Edition

1 “Electrical Distribution Engineering” Anthony J. Pansini CRC Press 2000 1

st Ed

2 “Distributed Power Generation Planning and Evaluation”

H Lee Willis, CRC Press. 1999 1

st Ed

3 “Electric Power Distribution Automation Protection And Control”

James A Momoh CRC press

2002 Revised

4 “Power distribution engineering: fundamentals and applications”

James J. Burke CRC Press. 2000 2

nd Ed

IPSLXXX : SMART GRID TECHNOLOGIES AND APPLICATIONS : (Elective –II) Course Objectives:- 1. Understand concept of smart grid and its advantages over conventional grid 2. Know smart metering techniques 3. Learn wide area measurement techniques 4. Appreciate problems associated with integration of distributed generation & its solution through smart

grid. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Understand the concept of smart grid, their comparison over conventional grid & international policies 2. To implement smart metering & vehicle to grid applications. 3. Analyse Smart Substation & PMU‟s (Phasor Measurement Unit) 4. To practice power quality issues & audit. 5. To integrate grid with ICT(Information & Communication Technologies) Details of Course:

S. No.


1 Introduction to Smart Grid:Evolution of Electric Grid, Concept of Smart Grid,

Definitions, Need of Smart Grid, Functions of Smart Grid, Opportunities & Barriers of Smart Grid, Difference between conventional & smart grid, Concept of Resilient & Self-Healing Grid, Present development & International policies in Smart Grid. Case study of Smart Grid . CDM opportunities in Smart Grid

7

2 Introduction to Smart Meters, Real Time Pricing, Smart Appliances, Automatic Meter Reading(AMR), Outage Management System(OMS), Plug in Hybrid Electric Vehicles(PHEV), Vehicle to Grid, Smart Sensors, Home & Building Automation, Phase Shifting Transformers

6

3 Smart Substations, Substation Automation, Feeder Automation. Geographic Information System(GIS), Intelligent Electronic Devices(IED) & their application for monitoring & protection, Smart storage like Battery, SMES, Pumped Hydro, Compressed Air Energy Storage, Wide Area Measurement System(WAMS), Phase Measurement Unit(PMU)..

7

4 Micro-grids and distributed energy resources: concept of micro-grid, need and application of micro-grid, formation of micro-grid, issue of inter-connection, protection and control of micro-grid. Plastic and organic solar cells, thin flims solar cells, variable

7

speed wind generators, fuel cells, micro turbines, captive power plant, Integration of renewable energy sources.

5 Power Quality Management in Smart Grid:Power Quality & EMC in Smart Grid,

Power Quality issues of Grid connected Renewable Energy Sources, Power Quality Conditioners for Smart Grid, Web based Power Quality monitoring, Power Quality Audit

6

6 Information and Communication Technology for Smart Grid:Advanced Metering

Infrastructure (AMI), Home Area Network (HAN), Neighborhood Area Network (NAN), Wide Area Network (WAN).

7

Suggested Books:

Sr. No.


Edition

1 Design of smart power grid renewable energy systems

Ali Keyhani Wiley IEEE 2011 1st

2 The Smart Grid: Enabling Energy Efficiency and Demand Response

Clark W. Gellings CRC Press 2009 1st

3 Smart Grid: Technology and Applications

Janaka Ekanayake, Nick Jenkins, Kithsiri Liyanage

Wiley 2012 1st

4 Smart Grids Jean Claude Sabonnadière, Nouredine Hadjsaïd

Wiley ISTE 2012

5 Smart Grid Fundamentals of Design and Analysis

James Momoh Wiley 2012

6 Smart Power Grid Renewable Energy Systems

. A. Keyhani Wiley 2011

SECOND SEMESTER IPSL621: PROCESSOR APPLICATIONS TO POWER SYSTEMS Course Objectives: - 1. Problems in modern power systems have to be solved with modern tools . 2. Processor applications are useful for quite a few varieties which are introduced here. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Understand the advance Microprocessor & Microcontroller, FPGA Controller. 2. Understand interfacing of DSP with various applications. 3. Understand the Operation and control of 28335. 4. Understand the application of DSP and FPGA to power System. 5. Apply the logic to control modern power system. Details of Course:

S. No.


1 Unit 1:Review of Advance Microprocessor & Microcontroller, FPGA Controller (06 Hrs)

2 Unit 2: Fundamentals of DSP:2812 (08Hrs)

3 Unit 3: Operation and control of 28335, (piccolo ) (10 Hrs)

4 Unit 4: Application of DSP and FPGA to power System (09 Hrs)

5 Unit 5: Interfacing ADC & DAC, LCD display, stepper motor with 8051. Application of DSP to drives. Advanced topic on the subject

(07 Hrs)


Sr. No.


Publication Edition

1

Microprocessor & Interfacing: Programming & hardware

Douglas and Hall Mc. Graw Hills

books. 1990 1

st

2 DSP Kit manual (www.ti.com)

--- --- --- ---

3 Advanced Microprocessors And Peripherals, , ISBN: 9780070140622

Ajoy Ray, K Bhurchandi

McGraw Hills Books,

2006 3rd

4 The 8051 Microcontroller And Embedded Systems Using Assembly And C, i,

Muhammad Ali Mazidi, Rolin Mckinlay, Janice Gillispie Mazid

Pearson

2007 2nd

5 The 8051 Microcontroller Kenneth Ayala, Delmar Cengage

Delmar Cengage Learning.

2007 3rd

6 Abel: IBM PC Assembly Language &

Dorling Kindersley India

TMH

Programming,

7 Digital Signal Processing : Principles, algorithms, And Applications

John G. Proakis, Dimitris G Manolakis:

Pearson Publishers. 2006 4

th

IPSL622: ENERGY SYSTEMS MANAGEMENT Course Objectives: 1. This Subject deals with power flow analysis by using Programming methods in large power System 2. To Introduce the optimal power flow methods 3. To Study transmission by B coefficient Course Outcome: Upon successful completion of the course, students shall be able to- 1. Apply various power flow techniques in large power system. 2. Understand the OPF solutions in large power system. 3. Understand the transmission losses B coefficient solution technique. 4. Understand the hydro-thermal co-ordination and optimal scheduling of hydrothermal system. 5. Understand the importance of unit commitment. Details of Course:

S. No.


1 Unit 1: Load flow Analysis – Gauss Seidel Method, Newton Raphson Method, Fast decoupled load flow and dc load flow, Contingency Analysis

(07 Hrs)

2 Unit 2: Representation of transmission loss by B coefficient, Interactive producer for the solution of co-ordination equation. Derivation of transmission loss. Emission Dispatch. Effects of Pollutions, Problem formulation, Practical measures Regulations.

(08 Hrs)

3 Unit 3: Optimal Power Flow: Introduction, sub problem of OPF, Methods for OPF solution. Gradient method, Co-ordination of steam, Hydro and Nuclear Power Solutions. Optimum generation allocation to thermal units. Input Output curve of a power generation unit, optimal generation allocation without losses. Reactive power management, Elementary introduction to deregulated Power System and Market.

(08 Hrs)

4 Unit 4: Hydro-thermal co-ordination: Advantages of co-ordination. Optimal scheduling of hydrothermal system. Optimal operation of hydrothermal scheduling. Combined working of Runoff river plant with steam plant. Pumped storage hydro plants

(08 Hrs)

5 Unit 5:Unit Commitment: Optimal Unit commitment, Solution to unit commitment by Dynamic programming. Optimal unit commitment with security. Performance optimization by reactive power control. Advanced topic on the subject.

(09 Hrs)

Suggested Books:

Sr. No.


Edition

1 Power system operation and control

PSR Murthy. B.S.Publication 2011 2nd

2 Economics operation of Power Systems by

L.K. Kirchmayer. John Wiley & Sons

1958 1st

3 Power Generation, operation control

A. J. Wood and B. F. Wolenberg

Academic 1988 2nd

4 Recent Trends in Electric Energy systems

Nanda and Kothari. Wheeler 1995 2nd

5 Modern Power System Analysis

Nagrath & Kothari TMH. 2003, 3rd

Ed

6 Power System Analysis Hadi Sadaat, PSA Publishing, 2010. 3rd Ed.,

IPSL 623: HVDC TRANSMISSION SYSTEMS: (Elective-III) Course Objectives: 1. This deals with power transmission system with converter and inverter dc transmission. 2. To introduce digital simulation of various converter topologies. 3. To introduce multiterminal HVDC System. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Understand the DC transmission concept with EHVAC systems. 2. Analysis of inverter and rectifier with two and three valve conduction. 3. To simulate converter with different valve conductions. 4. To understand how to control HVDC converters and systems. 5. To understand how to mitigate different harmonics, faults and its protection. Details of Course:

S. No.


1 Unit 1: Development of HVDC technology, comparison between HVAC and HVDC. Application of HVDC transmission. Type of DC transmission. Selection of converter configuration. Rectifier and inverter operation. Analysis of rectifier with two –valve conduction.

(05 Hrs)

2 Unit 2: Analysis of rectifier with two –three valve conduction, Analysis of inverter with two valve conduction. Analysis of inverter with two-three valve conduction.

(09 Hrs)

3 Unit 3: Digital simulation of converters .Generalized equation for simulation of courses. Derivation of converter equation with two valve conduction, three valve conduction, four valve conduction

(08 Hrs)

4 Unit 4: Control of HVDC converters and systems: Requirements from control systems of HVDC converters, rectifier compounding Inverter compounding, converter control characteristics. Converter firing schemes individual phase control (IPC), Equidistant pulse control (EPC) Draw backs of individual phase control. Draw backs of EPC.

(08 Hrs)

5 Unit 5: Higher Level controls, power controllers, Characteristics & non- characteristics harmonics. Different methods to over come problems of non characteristics Harmonics. Fault development and protection. Interaction between AC - DC power systems. Over voltage on AC –DC side, Multiterminal HV –DC systems .Control of MTDC systems ,Modeling of HVDC systems. Per unit system representation for power flow solution. Representation for stability studies. Introduction to HVDC light.Advanced topic on the subject

(10 Hrs)


Sr. Title Author Name Publisher Year of Edition

No. Publication

1 “High Voltage direct current transmission.” J.Arrilaga,

Peter Peregrinus ltd. London, U.K.

1999 2nd

Ed

2 “Direct Current Transmission (Vol. I),”

E.W. Kimbark Wiley Interscience 1971. 2

nd Ed

3 “HVDC Power Transmission Systems”

K.R. Padiyar New Edge International 2002 Revised

4 EHV-AC Transmission R.D. Begamudre New Age International. 2005 1

st Ed

5 EHV-AC, HVDC Transmission & Distribution Engineering

S Rao Khanna Publishers 1997 Revised

6 Computer Modelling of Electrical Power Systems

I. Arillaga, C.P. Arnold and B.J. Haskar,

John, Wiley 1993. 2

nd Ed

IPSL 624 : DIGITAL SIGNAL PROCESSING : (Elective-III) Course Objectives: 1. To study the concept of frequency in continuous and discrete time frame. 2. To study the Z transform applications. 3. Linear filter and prediction model of filters. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Apply the theoretical & practical aspects of modern signal processing in digital environment. 2. Apply appropriate techniques for application areas in electrical engineering. 3. Apply the knowledge of Z transform for HR system & optimum filters for the system. Details of Course:

S. No.


1 Unit 1: Classification of signals, concept of frequency in continuous-time and discrete- Time signals A/D and D/A conversion i.e. sampling and quantization, Classification of discrete time systems, introduction HR and FIR systems.

6 Hrs

2 Unit 2.:Analysis of discrete-time linear time invariant systems, techniques for the Analysis of linear systems, convolution sum, properties of convolution and the Interconnection of LTI systems, stability of LTI systems, difference equation to Describe the LTI system, impulse response of LTI system.

6 Hrs

3 Unit 3 .:Z-transform, ROC, properties of Z-transformation, rational Z-transformation, one sided Z-transformation, solution of difference equation, basic network structure for HR system: direct form, cascade form, parallel form, basic network structure for FIR systems, DFT and its properties, fast Fourier transforms (FFT), decimation- In-time algorithm, decimation-in-frequency algorithm, design of HR filter by the bilinear transformation, design of FIR filter using window, property of the FIR filters.

8 Hrs

4 Unit 4 :Linear prediction and optimum linear filters-forward and backward linear Prediction, levinson Durbin algorithm, schur algorithm, AR & ARMA model, Wiener filter –FIR, HR, non causal (speech recognition applications).

8 Hrs

5 Unit 5. :Effects of finite register length in digital signal processing, effect of truncation or rounding, finite register length effects in realization of HR digital signal filters: statistical analysis of quantization in fixed point realization of HR digital signals, statistical analysis of quantization in floating point realization of HR digital filter, finite register length effects in realization of FIR digital filter, statistical analysis of quantization in fixed point realization of FIR digital filters, statistical Analysis of quantization in floating point point realization of FIR digital filter.

12 Hrs

Suggested Books:

Sr. No.


Publication Edition

1 Digital Signal Processing,

Alan V.Oppenhelm/Ronald W.Schafer,

Pearson Education

2009 3rd

2 Digital Signal Processing,

John G. Prokis & Dimities G.Manolakis,

PHI, 2013 4

th

3 Statistical and Adaptive Signal Processing,

Dimities G. Manolakis, Vinay K. Ingle & Stephen M Kogon,

McGraw Hill International Editions

IPSL625 : SUB-STATION ENGINEERING : (Elective-III) Course Objectives: This subject deals with technical aspects related to planning, operation & maintenance of high voltage substations suitable for the modern era. Thus, it will cater to the needs of utilities as well as large industrial houses. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Design aspect of sub stations for efficient working strategy. 2. Understand the various substation components. 3. Understand the different type of voltage control methods. 4. Demonstrate operation, maintenance of substation. 5. Understand the Indian electricity grid code.

Details of Course:

S. No.


1 Unit 1: Development of Indian Power Sector and grid Management, Development in Distribution Power Sector, Sub-station:Types of substation(Indoor & outdoor), Layout, Busbar sectionalization, Power transformers, Design of Earthing, Gas Insulated substation (GIS).

(08 Hrs)

2 Unit 2 : Overhead Insulators, CT/PT‟s, Station Batteries and charging equipment, Parameters of Overhead Lines and under-ground cables, Fault finding, Computer applications for Sub-station engineering

( 08 hrs)

3 Unit 3 :Voltage control: Protection against over-voltages, bus-bars protection ( 08 hrs)

4 Unit 4 : Operation, Maintenance & safety aspects of substation, including metering aspects, super capacitor controlled modern substation: principle, working, components, and variable PLC applications

( 08 hrs)

5 Unit 5 : Indian electricity grid code, Case studies with 100 % stand-bye, Case studies with Participation for Co-generation and energy-sale, Case studies with emergency-supply arrangements: Short duration / Long duration Advanced topic on the subject.

( 08 hrs)


Sr. No.


Publication Edition

1 “Sub station engineering”

Dahiya R S and Attri V,

KATSON books, 2009 1st Ed

2 “A Text book of Electric Power Distribution Automation‟,

Khedkar Dr.Mohan K.& G M Dhole,

University Science Press, New Delhi, 2009 1

st Ed

IPSL626: Flexible AC Transmission System(FACTS) : (Elective-IV) Course Objectives: 1. This Subject deals with SSR and its control Strategy. 2. To Introduce concept of voltage Stability and reactive power Control Strategy 3. To Introduce voltage source converter based devices for active power, reactive power and voltage

control Course Outcome: Upon successful completion of the course, students shall be able to- 1. Analyse and design voltage source converter topologies. 2. Apply the VSC for active power, reactive power and voltage control of the power system. 3. Understand different stability problems and modelling requirements for mitigating them. 4. Synchronous VAR compensators. 5. Understand different shunt and series acting FACTS devices for power quality improvement.

Details of Course:

S. No.


1 Unit 1 : SSR, Determination of SSR Methods of analysis SSR, (a) Eigen value analysis (b) Frequency domain analysis. Analysis of SSR with fixed series compensation and HVDC converter control. Counter measures for SSR. (a) System planning considerations. (i) Series Vs shunt compensation (ii) Static blocking filter (iii) By pass damping filter (b) Damping scheme (i) N.G. Hingorani Damping scheme (ii) Dynamic stabilizers.

(10 Hrs)

2 Unit 2: Voltage stability, Basic concepts, Active/Reactive power flow transmission using elementary models, Difficulties with reactive power transmission. classification, methods of analysis, voltage collapse. Factors affecting Voltage stability (i) Transient voltage stability (ii) Long-term voltage instability and its prevention, continuation power flow.

( 08 hrs)

3 Unit 3:Comparison of rotor angle stability & voltage stability. (P-V) curves (nose curves) Methods of analysis (i) Dynamic and Static analysis. Modeling requirements for voltage stability. Recent case studies.

(12 Hrs)

4 Unit 4: Static VAR compensator (SVC), Types of SVC characteristics of ideal and realistic SVC their operation, Composite characteristics, modeling of SVC, Six pulse TCR, Application of SVC, Flexible AC Transmission Systems ( FACTS )

(10 Hrs)

5 Unit 5: Basic concepts, Voltage source converters, Current source converter comparison of STATCOM and SVC, series FACTS devices: SSSC, TCSC. Static Voltage and phase angle regulators: TCVR and TCPAR combine compensator UPFC (Unified Power Flow), IPFC (Interline power flow controller), Active Filters (Series and Shunt types only). Advanced topic on the subject.

(10 Hrs)


Sr. No.


Edition

1 “Power System stability and control”

K.R. Padiyar Interline publishing Pvt. Ltd. Bangalore.

2009 2nd

2 “Power system stability and controls”.

Kundur Mc Graw –Hills. Inc New York.

2009 2nd

3 “Analysis of synchronous resonance in power systems,” Wolter

K.R. Padiyar Kluwer Academic publisher

1998. 1st

4 “Power System Voltage stability”

C.W. Taylor Mcgraw –Hill” 1993. 1st

5 “Power System Control and Stability,

Anderson P.M. and Fauad A.A.

Galgotia Publication

1981. 1st

6 „Al Techniques in power system‟

Edited by Kevin Warwick Artinur Ekwue & Raj Aggrwal.

IEE Power Engg.

Series 22,

7 Understanding FACTS : Concepts & Technology of Flexible AC Transmission Systems by

N.G. Hingorani & L.Gyugyi ,

IEEE presss First edition

2001 1st

IPSL 627: ELECTRICAL DRIVES –II : ( Elective-IV) Course Objectives: 1. This subject deals with modern drives controls techniques Such as vector / Scalar control 2. To introduce VVVF Control. 3. To introduce variable reluctance motor drives .

Course Outcome: Upon successful completion of the course, students shall be able to- 1. Able to understand the different types of electrical drives and their classification. 2. Understand the different types of electrical machnies and there reference condition. 3. Able to implement various control methods of drives and their different methods. 4. Study and analysis of ac and dc drives with their practical applications. 5. Understand VCM and SCM and study their recents controllers techniques and effects on the motor

and transformation of space vector cordinates and induction to DTC.

Details of Course:

S. No.


1 Unit-1 :Introduction to motor drives-torque production- Equivalent circuit analysis-Speed-Torque characteristics with variable voltage operation, variable frequency operation, constant v/f operation-Induction motor characteristics in constant torque and field weakening regions

(10 Hrs)

2 Unit-2 :Control of Induction motor drives : Voltage fed inverter control-Open loop volts/Hz Control-Speed control slip regulation- Speed control with torque and flux control-Current controlled voltage fed inverter drive-Current fed inverter control-Independent current and frequency control-Speed and flux control in current fed inverter drive-Volts/Hertz Control current fed-Inverter drive-Efficiency optimization control by flux program

( 08 hrs)

3 Unit-3 : Control of Synchronous machines: Synchronous motor and its characteristics – control strategies – constant torque angle control- Unity power factor control-Constant mutual flux linkage control, operation of PMSM for bilateral power control.

(12 Hrs)

4 Unit-4 :Controllers: Flux weakening operation- Maximum speed-Direct flux weakening algorithm – Constant torque mode controller- Flux Weakening controller- Indirect flux weakening – Maximum permissible torque-Speed control scheme- Implementation strategy – Speed controller design

(10 Hrs)

5 Unit-5 :Special motors control : Variable reluctance motor drives- Torque Production in the variable reluctance motor- Drive characteristics and control principles- Current control variable reluctance servo drive. Three phase full wave Brushless dc motor – Sinusoidal type of Brushless dc motor-Current controlled Brushless dc servo drives.

(10 Hrs)

Suggested Books:

Sr. No.


Publication Edition

1 Electric Motor Drives modeling, analysis and control

R.Krishnan Pearson Publication

2002 1st Ed

2 Modern Power Electronics and AC drives

B.K Bose Pearson Publication 2001 1

st Ed

3 Power Electronic Control of AC motors-

MD Murphy & FG Turn Bull

Pergman Press(For Chapters II,III, V) –

1998 1st Ed

4 Power Electronics and AC drives

B.K Bose Prentice Hall Publication

1995 1st Ed

5 Power Electronics Circuits, Devices and Application

M.H Rashid PHI 1995 2

nd Ed

6 Fundamentals of Electric Drives

GK Dubey- Narora Publications -

1995

2nd

Ed

7 Power Electronics and Variable Frequency drives

B.K.Bose IEEE press-Standard publication- -

2002 1st Ed

IPSL628: LOAD FORECASTING & LOAD MANAGEMENT : (Elective- IV) Course objectives: 1. To study the loads and its forecasting methods. 2. To study the various load management techniques . 3. To develop knowledge for energy pricing strategies .

Course Outcome: Upon successful completion of the course, students shall be able to- 1. Implement effective load management technique. 2. Understand the applications of state estimation to load forecasting. 3. Understand the Load Management system. 4. Able to design the alternative load management. 5. Understand the Tariff structure and load management.

Details of Course:

S. No.


1 Unit 1: Load Forecasting : Classification and characteristics of loads. Approaches to load forecasting. Forecasting methodology.

08 Hrs

2 Unit 2: Energy forecasting. Peak demand forecasting. Non-weather sensitive forecast. Weather sensitive forecast. Total forecast. Annual and monthly peak demand forecasts. Applications of state estimation to load forecasting.

08 Hrs

3 Unit 3: Load Management : Introduction to load management. Electric energy production and delivery system structure (EEPDS), Demand side management.

08 Hrs

4 Unit 4: Design alternatives for EEPD systems. Communication/ Control technologies for load management.

08 Hrs

5 Unit 5: Tariff structure and load management. Some principles of microeconomics and energy pricing strategies. Assessing the impacts of load management.

08 Hrs

Suggested Books:

Sr. No.


Publication Edition

1 Electrical Load Forecasting: Modeling and Model Construction

S.A. Soliman, Ahmad Mohammad Al-Kandari

elsevier publisher -

2010 1st

2 Energy management W.R. Murphy & G. Mckay Butter worth,

Heinemann publications. 1982 1

st Ed

3 Energy management

Paul o‟ Callaghan

Mc-graw Hill Book company

1998 1st Ed

4 Energy efficient electric motors

John C. Andreas Marcel Dekker Inc Ltd 1995 2

nd Ed

5 Energy management hand book

by W.C.Turner, john Wiley and sons

1992 3rd

THIRD SEMESTER IPSL631 : POWER SYSTEM STABILITY : (Elective –V) Course Objectives: 1. This subject deals with stability of the power system. 2. To study transient of SMIB multi machine System. 3. To introduce the effect AVR & PSS on stability. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Analyze the power system under different stability conditions 2. Simulate the power system on computer for transient stability analysis. 3. Simulation of SMIB and MMIB system. 4. Understand the various types of disturbance present in power system. 5. Understand the role of automatic voltage regulator & other system for improving stability.

Details of Course:

S. No.


1 Unit 1: Small Signal Stability Analysis. (10 Hrs)

2 Unit 2: Transient stability : - a) Consideration of rotor angle, b) Consideration of time. (11 Hrs)

3 Unit 3:Review of classical method, dynamic and transient stability investigations and simulation of single machine infinite bus and multi machine system.

(11 Hrs)

4 Unit 4: Effects of grounding on stability, effects of various disturbance, parameters and controls on stability, prevention of stability, pull out.

(10 Hrs)

5 Unit 5: Role of automatic voltage regulator (AVR) on improving stability. Effect of excitation control and turbine Governing. Augmentation of stability of conventional methods. Recent software for power system analysis. Power system stabilizers (PSS): Introduction, Basic concepts, Choice of control signals, Torsional interaction with PSS. AI application to power system stability studies. Advanced topic on the subject

(08 Hrs)

Suggested Books:

Sr. No.


Publication Edition

1 “Power System Dynamics, Stability And Control”

Padiyar K.R. Interline publishing Pvt. Ltd, Banglore .

2007 1st Ed

2 “Power System Stability Vol I and III,”

Kimbark, John Wiley and sons, New York.

1996 1st Ed

3 “Computer method in Power System Analysis”

STAGG and EI-abide,

MC–Graw Hills. Co., Ltd. 1968 1

st

4 “Electrical Power System”,

B.M. Weedy & Cory

John Wiley and sons, New York. 1999 --

5 “Power system stability and controls”.

P. Kundur Mc – Graw –Hills. Inc New York

1994 ---

6 Computer Techniques in Power System Analysis,

M. A. Pai, Tata Mc Graw Hill, 2006. 2

nd Ed.,

IPSL632 : ELECTRIC VEHICLES : (Elective –V) Course Objectives: Electrical Vehicles need strong sources, efficient power-drives & excellent co-ordination within the vehicle. This course introduces modern subsystems for efficient operation of vehicles. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Learn pollution problems due to petrol or diesel driven vehicles. 2. Suggest the remedial measures by developing skills to use sensors, motors, batteries, fuel cells,

ultra-capacitors. 3. Understand high- efficiency optimised control in electric vehicles. 4. Understand the slip phenomena, Road condition estimation with driving force observer. 5. Design hybrid system for electric vehicles in cost effective way.

Details of Course:

S. No.


1 Unit 1: Electric vehicles (EV) development, past, present and future, comparison with IC engine driven vehicles.

(06 Hrs)

2 Unit 2: Batteries, fuel cells, ultracapacitors. Power converters in EV. Different types of motors used in EV and their torque-speed characteristics, motor control techniques,

(08Hrs)

3 Unit 3: High performance and efficiency-optimized control, sensorless control. EV modeling, Their Characteristics

(08Hrs)

4 Unit 4: Slip phenomena. Road condition estimation, driving force observer. EV motion control, optimum slip ratio control, movement control, lateral motion stabilization

(10 Hrs)

5 Unit 5 : Fuel cell Vehicles, Hybrid Electric Vehicles (HEV), series, parallel and series-parallel (split) systems, Recent industrial power electronic applications. Advanced topic on the subject

(08Hrs)

Suggested Books:

Sr. No.


Edition

1 Electric Vehicle Battery Systems –, , 252 pages, price not quoted.

Sandeep Dharmeja

Newnes 2001 1st

2 Chaos in Electrical Drive Systems: Analysis, Control & Applications

K.T.Chau , Zheng Wang,

John Wiley and Sons , 288 pages.

2011, 1st

3 Electrical Vehicle Technology Explained

James Larminie, John Lowry,

J ohn Wiley and Sons,

2003,296 pages

1st

4 Modern Electric Vehicle Technology

Chung Chow Chan, K.T.Chau

Oxford University Press,

2001. 1st

5 Electrical Vehicle Integration into Modern Power Networks

Springer Books

1st

IPSL633 : POWER SYSTEM PLANNING : (Elective – V) Course Objectives:

This subject deals with generation, transmission, distribution and planning. Advanced mathematical methods for finding reliability for successful operation of power plants are also taught. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Demonstrate the source of power generations. 2. Understand load forecasting methods. 3. Understand the generation planning 4. Understand transmission planning. 5. Understand the transmission reliability evaluation. Details of Course:

S. No.


1 Unit 1: Brief Outline of conventional commercial power plants. Thermal, Hydro, Nuclear, Solar, Wind etc., and Division each type of power plant in total installed capacity. Concept of adequacy and security, System Analysis. Selection of units. Load forecasting, Introduction to Energy Conservation.

(07 Hrs)

2 Unit 2: Classification of load forecasting uncertainty. The concept of reliability, reliability indices .Component reliability hazards models conventional UP–DOWN times. Absolute and relative measures. Power system reliability. Outage definition. Construction of reliability models.

(08 Hrs)

3 Unit 3:Generation planning. Generation system model, Loss of load indices, force outage rates, loss of energy indices. Reserve capacity evaluation, frequency and duration method. System risk indices. Generation expansion planning.

(08 Hrs)

4 Unit 4: Transmission planning: - Probability arrays method of two interconnected system equivalent assisting unit approach to interconnected system. Factors affecting the emergency assistance available through interconnection. Weather effects on transmission lines, load point indices. Transmission planning under deregulated environment.

(07 Hrs)

5 Unit 5:Transmission reliability evaluation. Distribution system reliability: - Basic concept, Customer Oriented indices in Distribution System of Planning, parallel and mesh networks. Effect of transferable load economy considerations. Planning of Generation using non-conventional (renewable) Energy sources. Recent Case studies. Advanced topic on the subject.

(10 Hrs)

Suggested Books:

Sr. No.


Edition

1 Reliability Evaluation of Power System

Billington and Allian

Spinger 1996 2nd

Ed

2 Reliability Modeling in Electrical Power System

J. Endrenvi John Wiley 1979 Revised

3 Electrica Power Distribution System

Tarun Gonen McGraw-Hill 1986 1st Ed

4 Electric Transmission System Engg

Tarun Gonen Pearson Education

2007 2nd

Ed

5 Generation of Electric Energy by

B. R. Gupta, S. Chand & Co 2009, 2nd

Ed

6 Generation Planning

A S Pabla McGraw-Hill 2004 6th Ed

IPSL634 : POWER QUALITY : (Elective-VI) Course Objectives: 1. To acquire the knowledge of various power qualities issues. 2. To study the standard norms for power qualities. 3. To study the various methods for control and measurements. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Understand the power quality issues. 2. Control and measure the power quality issues. 3. Understand the different type of transient present in power system. 4. Understand the different type of harmonics present in power system. 5. Understand the various standards related to power quality.

Details of Course:

S. No.


1 Unit -1:Electric power quality phenomena- IEC and IEEE definitions - power quality disturbances-voltage fluctuations-transients-unbalance-waveform distortion-power frequency variations

10 Hrs

2 Unit -2 :Voltage variations, Voltage sags and short interruptions flicker-longer duration variations sources range and impact on sensitive circuits-standards solutions and mitigations equipment and techniques.

8 Hrs

3 Unit –3:Transients – origin and classifications – capacitor switching transient – lightning-load switching – impact on users – protection – mitigation.

6Hrs

4 Unit -4:Harmonics – sources – definitions & standards – impacts - calculation and simulation, Harmonic power flow - mitigation and control techniques – filtering – passive and active

8 Hrs

5 Unit -5 :Power Quality conditioners – shunt and series compensators-DStatcom-Dynamic voltage restorer-unified power quality conditioners-case studies

08 Hrs

Suggested Books:

Sr. No.


Edition

1 1. Electric Power Quality, Indiana,

Heydt, G.T., Stars in a Circle Publications

1994. 2nd edition

2 Understanding Power Quality Problems: Voltage sags and interruptions

Bollen, M.H.J, IEEE Press, New York,

2000. ---

3 Power System Quality Assessment,

Arrillaga, J, Watson, N.R., Chen, S.,

Wiley, New York 2000. ---

IPSL635 : ADVANCED ELECTRIC DRIVES AND THEIR CONTROL : (Elective-VI)

Course Objectives: This Subject deals with modern drives controls techniques such as vector/scalar control for VVVF & DTC for industrial applications. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Understand Dynamics of Electrical Drives classification of electric drives. 2. Understand analysis of electric machinery. 3. Understand different motor control methods. 4. Understand synchronous servomotor drives with different waveforms. 5. To understand state variable approach ,Scalar control method / Vector control method. Details of Course:

S. No.


1 Unit 1:Dynamics of Electrical Drives classification of electric drives – Basic elements of an electric drive. Dynamic condition of electric System. Stability consideration of electric drives.

(07 Hrs)

2 Unit 2: Analysis of electric machinery. Reference frames, Theory of symmetrical IM and synchronous machines.

(09 Hrs)

3 Unit 3: Motor Control : Induction motor control systems AC regulation and static switches. Control of effective rotor resistance, Recovery of slip energy. Variable frequency control of AC motor, harmonic analysis in VFD, Cycloconverter control of slip frequency, Forced commutated inverter drive, analysis.

(10 Hrs)

4 Unit 4: Synchronous servomotor drives with sinusoidal waveform, with trapezoidal waveforms, Load commutated inverter drives, Control of AC /DC machines, Digital control of drives, Application of microprocessor / computers to Electric AC / DC Drives.

(12 Hrs)

5 Unit- 5: State variable approach ,Scalar control method / Vector control method , comparison , Space vectors , stator space current ., stator voltage space vector ,stator flux linkages space vector , transformation of space vector coordinates from one reference frame to another . Introduction to DTC, Switched reluctance motor control, PMSM Motor, Study of recent drives controllers.Advanced topic on the subject: Effects of harmonics on motors.

(12 Hrs)

Suggested Books:

Sr. No.


Edition

1 Electric Motor Drives, Modelling, Analysis & Control

R. Krishnan Prentice Hall. 2001, 1st Ed

2. Electrical Drive „Vedam Subramanyam.

Tata Mc Graw Hill 2011 2nd

Ed

3. Analysis of Electric Machinery. Paul, C, Krause, Mc Graw Hill. 1987 1st Ed

4. Variable frequency AC motor Drives, system

David Finney – IEE Press 2002 1st Ed

5. Power Electronics and AC Drives

B.K. Bose , Prentice Hall 1995 1st Ed

6. Power Electronics , principles and application

Joseph Vithayathil

Mcgraw Hill 1995 ---

7. Power Electronics Circuit devices and application ,.

M. Rashid , Prentic e Hall of India.,

2004 3rd

Ed

8. Power Electronics, converters, Application and design,

Mohan Undeland, Robbins

John Wiley 1999 2nd

Ed

9. Power semiconductor Drives G.K. Dubey. Narosa Publications

1995 2nd

Ed

IPSL636 : RESTRUCTURED POWER SYSTEMS : (Elective –VI) Course objectives: 1. To study the deregulation of power system. 2. To study the transmission open access and pricing of power. 3. To study the different market models. Course Outcome: Upon successful completion of the course, students shall be able to- 1. Understand the transmission open access operation and pricing of power transactions. 2. Understand the various market models and congestion management. 3. Understand the power wheeling and security management in deregulated environment. 4. Understand the management of various ancillary services. 5. Demonstrate operational planning activities. Details of Course:

S. No.


1 Unit –1:Deregulation, Reconfiguring Power systems, unbundling of electric utilities, Background to deregulation and the current situation around the world, benefits from a competitive electricity market after effects of deregulation

12 Hrs

2 Unit –2:Role of the independent system operator, Operational planning activities of ISO: ISO in Pool markets, ISO,EMS, in Bilateral markets, Operational planning activities of a GENCO: Genco in Pool and Bilateral markets, market participation issues, competitive bidding

08 Hrs

3 Unit –3:Power wheeling, Transmission open access, pricing of power transactions, security management in deregulated environment, and congestion management in deregulation

06 Hrs

4 Unit –4:General description of some ancillary services, ancillary services management in various countries, reactive power management in some deregulated electricity markets

06 Hrs

5 Unit –5: Different practices in power market operations: different market models, different types of bilateral transactions, centralized & decentralized dispatch philosophies , regulatory framework, open assess issues.

08 Hrs


Sr. No.


Edition

1 “Operation of Restructured Power Systems”

K. Bhattacharya, MHT Bollen and J.C Doolder,

Academic Publishers, USA Kluwer,

2001. 2nd

2 “Power System restructuring and deregulation”,

Lei Lee Lai John Wiley and Sons, UK.

2001. 2nd

3 “Power System Operations and Electricity Markets”

Fred I Denny and David E. Dismukes

CRC Press, LLC,

2002 2nd

4 Fundamentals of power system economics ltd

D.Kirschen Wiley 2004 1st

IPSP637: POWER SYSTEM DESIGN LAB

S. No.


1 Advanced experiments based on Load forecasting, voltage stability, Power system security & design issues. Open-ended experiments

04 Hrs

IPSP638: Dissertation : (Phase –I) Course Objectives: 1. To understand the ideas regarding the research topic and research Objectives. 2. To marshal knowledge of content issues from their respective fields. 3. To articulate, summarize and present their dissertation feasibility.

Course Outcome: Upon successful completion of the course, students shall be able to- 1. To select and identify broad area of research 2. To do a proper literature review, analyze data and put forward the findings 3. To define the problem statement as outcome of literature review 4. To get conversant with relevant hardware and software tools to be used for carrying out dissertation

work 5. To deliver and improve upon the seminar delivery skills. IDA 402: Advanced teaching Methodologies

FOURTH SEMESTER IPSP641 : Dissertation : (Phase –II ) Course Objectives: 1. To make independent, systematic progress on their individual dissertation work 2. To undertake the extensive research work and conduct the experimentation work for finding the

solution of defined and problem in dissertation Phase-I course 3. To present the work accomplished for further suggestions and implementation. 4. To articulate, summarize, and present their dissertation studies

Course Outcome: Upon successful completion of the course, students shall be able to- 1. To interpret relevant scientific theories and literature of concerned identified topic and defined

problem. 2. To plan the research work execution in phased manner and link the different phases of work for

proper research work outcome. 3. To design, implement and simulate the system and experimental setup with techno managerial skills 4. Undertake an extensive and independent research work and perform experimentation, analyze and

interpret data and records to put forward the conclusion in the form of outcome of research work carried out.

5. To document the dissertation work carried out effectively and to present the dissertation work and finding thereof.

proposed scheme of m.tech (integrated power system) first ... · 2. to introduce converter and...

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