COURSE STRUCTURE FOR M.TECH. ELECTRICAL … Syllabus_Wef 2018-19_BOS.pdfCOURSE STRUCTURE FOR M.TECH....

1 | P a g e

COURSE STRUCTURE FOR M.TECH. ELECTRICAL ENGINEERING(POWER SYSTEMS)

SEMESTER I

w. e. f. 2018-2019

Sr.

No Course

Code Course Name

Teaching Scheme Exam Scheme

L T P C Hrs/wk

Theory Practical Total

MS ES IA LW LE/Viva Marks

1 MA 503T

Advanced Numerical

Techniques and Computer

Programming

3 1 0 4 4 25 50 25 -- -- 100

2 MA 503P

Advanced Numerical

Techniques and Computer

Programming

0 0 2 1 2 -- -- -- 50 50 100

3 EE 501 Advanced Electrical Machines 3 0 0 3 3 25 50 25 -- -- 100

4 EE 502 Advanced Power System

Protection 4 0 0 4 4 25 50 25 -- -- 100

5 EE 514 Power Quality Enhancement 3 0 0 3 3 25 50 25

100

6 EE 504 Laboratory-I 0 0 4 2 4 -- -- -- 50 50 100

7 EE 505 Open Elective I 3 0 0 3 3 25 50 25 -- -- 100

Total 16 1 6 20 23 125 250 125 100 100 700

MS = Mid Semester, ES = End Semester; IA = Internal assessment (like Test/quizzes, assignments etc.)

LW = Laboratory work; LE = Laboratory Exam

2 | P a g e


SEMESTER II

w.e.f. 2018-2019

Sr.

No Course

Code Course Name


L T P C Hrs/wk



1 EE 506 Modern Control Systems 3 0 0 3 3 25 50 25 -- -- 100

2 EE 507 Power System Analysis and

Dynamics 3 0 0 3 3 25 50 25 -- -- 100

3 EE 508 Advanced Power Electronics 3 0 0 3 3 25 50 25 -- -- 100

4 EE 509 Digital Signal Processing 3 0 0 3 3 25 50 25 -- -- 100

5 EE 510 Laboratory-II 0 0 4 2 4 -- -- -- 50 50 100

6 EE 5xx Department Elective 3 0 0 3 3 25 50 25 -- -- 100

7 Open Elective II 3 0 0 3 3 25 50 25 -- -- 100

8 Successful Research and

Development Program 2 0 0 2 NP/PP

Total 20 0 4 20 24 150 300 150 50 50 700



Department Elective

EE 511 Smart Grid Technologies and Applications

EE 512 EHV AC and HVDC Transmission

3 | P a g e


SEMESTER III

w.e.f. 2018-2019

Sr.

No Course Code Course Name


L T P C Hrs/wk



1 MT 611 Seminar

5

40 60 --

100

2 MT 612 Project

14

40 60 --

100

3 MT 613 Industrial Training NP/PP

4

Total

19

80 120 200



4 | P a g e


SEMESTER IV

w. e. f. 2018-2019

Sr.

No Course

Code Course Name


L T P C Hrs/wk



1 MT 621 Seminar

5

40 60 --

100

2 MT 622 Project and Dissertation

24

40 60 --

100

Total

29

80 120

200



of 23

List of Open Electives (C2)

(FOET Level) Sr. No. Open Elective I (Sem I) Open Elective II (Sem II)

1 ME 512 Finite Element Method CE 568 Finite Element Method

2 CE 514 Geographical Information Systems EN 513 Environmental Impact Assessment

3 EN 502 Air Pollution Modelling, Monitoring

and Control CE 525 Earthquake Engineering

4 NE 511 Introduction to quantum and statistical

Mechanics MA 511 Operation research

5 ME 513 Renewable Energy and Energy

Management ME 516: Solar Thermal Systems

6 SE 505 Renewable Energy and Energy

Management (Solar) EE 513 Control Motors

7 EN 506 Atmospheric Process & Climate

Change (Chemical/Science)

8 EN 504 Environmental Legislation

9 EE 505 Renewable Energy Systems

Department Elective



of 23

EE 501 Advanced Electrical Machines

Teaching Scheme Examination Scheme

L T P C Hrs/Week Theory Practical Total

Marks MS ES IA LW LE/Viva

3 0 -- 3 3 25 50 25 -- -- 100

UNIT I 10

INDUCTION GENERATORS: self-excitation requirements, steady state analysis, voltage regulation,

different methods of voltage control, application to mini and micro hydro systems.

DOUBLY FED INDUCTION MACHINES: control via static converter, power flow, voltage/frequency

control (generation mode), application to grid connected wind and mini/micro hydro systems.

HIGH PERFORMANCE ENERGY EFFICIENT MACHINES: Technology of energy efficient motors, selection

and application of energy efficient motors.

UNIT II 08

SWITCHED RELUCTANCE MOTOR: Construction, operating performance, control and applications.

UNIT III 12

BRUSHLESS DC MACHINES: construction operation, performance, control and applications.

LINEAR MACHINES: Linear Induction Machines and Linear Synchronous Machines. Construction,

operation, performance, control and applications.

UNIT IV 09

PERMANENT MAGNET MATERIALS : Properties of different Permanent Magnet materials, B-H loop and

demagnetization characteristics, temperature effects, mechanical properties, applications

APPLICATION OF PERMANENT MAGNETS IN ELECTRICAL MACHINE: structure, magnetic materials used,

types of motors e.g. PMDC and PM Synchronous Machine, control and applications.

RECENT DEVELOPMENTS IN ELECTRICAL MACHINES

TOTAL HOURS 39

Texts and References:

1 T. J. E. Miller, “Brushless PM and Reluctance Motor Drives”, Clarendon Press Oxford

2 R. Krishnan, “Electric Motor Drives”, PHI

3 JacekGierasewing, “P. M. motor technology”, Marcel Dekker

4 Denis O’Kelly , “Performance and Control of Electrical Machines”, McGraw-Hill

5 P. C. Sen, “ Principles of Electrical Machines and Power Electronics”, Wiley

6 Web-Resources : http://www.beeindia.in/

7 Howard E. Jordan, “Energy Efficient Electric Motors & Their Applications”, Springer

of 23

EE 502 Advanced Power System Protection




4 -- -- 4 4 25 50 25 -- -- 100

UNIT I 09

PROTECTIVE RELAYING FUNDAMENTALS: General Background, Zones of Protection, Requirements of

Protection System, Unit and Non-unit Protection, Primary and Back-up Protection, Historical

Development of protection, Classification of Protective Relays, Electro-mechanical (Electromagnetic)

Relays( Thermal relay(Electromagnetic) Relays, Attracted Armature Relay, Induction Relays, Induction

Disc Relay, Induction Cup Relay, Balance Beam Relay, Universal Torque Equation), Solid State Relays

(Introduction, Comparison between Static and Electromechanical Relays, Classification of Static Relays,

Generalized Static Time-Over current Relays), Digital Relaying( Merits and Demerits of Digital Relay,

Generalized Block Diagram of Digital Relay, Sampling and Data Window), Tripping Mechanism of Relay,

Different Relay Algorithms( Algorithms assuming pure sinusoidal relaying signal, Algorithms based on

solution of system differential equations, Algorithms Applicable to Distorted Relaying Signals), Concept

of Adaptive Relaying

UNIT II 10

PROTECTION OF TRANSMISSION LINES: Introduction, Various Types of Transmission Line Faults,

Overview of Over Current Protection of Transmission Lines, Over View of directional Protection Relay,

Modern Digital/Numerical Over current & Earth Fault Relay, Over Current Relay Coordination in an

Interconnected Power System( Introduction, LINKNET Structure, Determination of Primary/Back-Up

Relay Pairs)

DISTANCE RELAYING: Introduction, Transmission Line Protection, Distance Protection, Reach of Distance

Relay, Selection of Measuring Unit, current and Voltage Connections, Problems & Remedies in Distance

Protection( Close-in fault, Fault Resistance, Remote In-feed, Mutual Coupling, Series Compensated

Transmission Lines, Power Swing, Overload, Transient Condition), Examples on Setting of Distance

Protection, Symmetrical Component Based Distance Relay, Digital Distance Relaying Scheme

PILOT RELAYING SCHEMES FOR TRANSMISSION LINE: Introduction to Pilot Protection System,

Circulating Current Based Wire Plot Relaying Scheme, Carrier Current Protection Scheme(Phase

Comparison Scheme, Directional Comparison Scheme, Blocking and Unblocking Carrier aided Distance

Scheme, Carrier Blocking Scheme, Carrier Unblocking Scheme, Transfer Tripping Carrier aided Distance

Scheme, Under Reach Transfer Tripping Scheme, Over Reach Transfer Tripping Scheme)

UNIT III 10

PROTECTION AGAINST TRANSIENTS AND SURGES: Introduction, Sources of Transients or Surges in EHV

Line, Switching of Transmission Line, Switching of Capacitor Bank, Switching of Coupling Capacitor

Voltage Transformer (CCVT), Switching of Reactor, Arcing Ground, Lightning Strokes, Overvoltage

Phenomenon due to Lightning and Switching, Surges and Travelling Waves, Wave Propagation on

Transmission Line, Reflection and Attenuation, Reflection, Attenuation of Transients, Attenuation of

of 23

Transients Using Filter, Attenuation of Transients Using Isolation Transformer, Neutral Grounding,

effects of Ungrounded Neutral on System Performance Methods of Neutral Grounding, Solid Grounding,

Resistance Grounding, Reactance Grounding, Resonant Grounding, Grounding Practices, Protection

against Transients and Surges, Protection against Lightning, Earthing Screen (Overhead Shielding),

Overhead Ground Wires, Surge Modifier or Absorber, Lightning Arrester (Surge Diverter), Types of

Lightning Arresters, Rod Gap Arrester, Horn Gap Arrester, Multi Gap Arrester, Expulsion Type Arrester,

Valve Type Arrester, Silicon Carbide (SiC) Lightning Arrester, Metal Oxide (MO) Lightning Arrester,

Selection Procedure for Lightning/Surge Arresters, Common Ratings of Lightning/Surge Arresters

UNIT IV 10

AUTORECLOSING AND SYNCHRONIZING & SYSTEM RESPONSE TO SEVERE UPSETS: Introduction,

History of auto reclosing, Advantages of auto reclosing, Classification of auto reclosing Relay, auto

reclosing based on number of phases, autoreclosing based on number of attempts, autoreclosing based

on speed, Sequence of Events of a Typical Single-shot autoreclosing Scheme, Factors to be considered

during Reclosing( Choice of zone in case of distance relay, Dead time/ Deionizing time, Reclaim Time,

Instantaneous Lock out, Intermediate Lock Out, Breaker supervision function), Synchronism

Check(Phasing Voltage Method, Angular Method, Automatic Synchronizing)

SYSTEM RESPONSE TO SEVERE UPSETS: Introduction, Nature of system response to severe upsets,

System Response to Islanding Conditions (Undergenerated Islands, Overgenerated Islands, Reactive

Power Balance, Power Plant Auxiliaries, Power System Restoration), Load Shedding, Factors to be

considered for Load Shedding Scheme( Maximum Anticipated Overload, Number of Load Shedding

Steps, Size of Load Shed at Each Step, Frequency Setting, Time Delay), Rate of Frequency Decline,

Frequency Relays, Islanding( Issues with Islanding, Methods of Islanding Detection)

TOTAL HOURS 39


1 Stanley H. Horowitz and ArunG .Phadke, “Power System Relaying”, Research Studies Press Ltd,

3rd

Edition

2 Bhavesh Bhalja, R. P. Maheshwari, Nilesh G. Chothani, “Protection and Switchgear”, Oxford Press

3 B. A. Oza, Date, Nair and Makwana, “Power System Protection and Switchgear”, Tata McGraw Hill

4 Walter A. Elmore, “Protective Relaying Theory and Application”, Marcel Dexxer INC, New York

5 J. J. Blackburn, “Protective Relaying Fundamentals”, John Wiley and Sons

of 23

M.Tech in Electrical Engineering (Power Systems) Semester I

Course Code: EE514 Course: POWER QUALITY ENHANCEMENT




3 0 -- 3 3 25 50 25 -- -- 100

Prerequisites : Power Systems & Power Electronics

Course Objectives:

- To understand the power quality issues, their impact and mitigation techniques

- Toget a fair knowledge about the national and international power quality standard

- To gain knowledge about the design and practical implementation of the power converters for

power quality mitigation

UNIT I : POWER QUALITY ISSUES 08

Introduction to Power Quality, Electric power quality phenomenon, Characterization of Electric Power

Quality, Power Quality Issues: Voltage Sag, Voltage Swell, Interruptions, Voltage Transients, Voltage

Flicker, Voltage Unbalance, Voltage Fluctuations, Harmonics, Voltage Notching, Power frequency

variation, Poor load power factor, Non linear and unbalanced loads, DC offset in loads, Disturbance in

supply voltage, Power quality standards.

UNIT II : HARMONICS & UNBALANCE SYSTEMS 10

Linear and nonlinear loads, Impact of Sinusoidal & Non-Sinusoidal Sources on linear and nonlinear load,

Unbalanced Supply Voltages, Voltage Distortions, Voltage and Current Harmonics, Inter Harmonics,

Sources of Harmonics, Displacement Factor, Distortion Factor, Harmonic Factor, Total Harmonic

Distortion, Total Demand Distortion, True Power Factor, Limit on individual Harmonics as per IEEE

Standard – 519, Effect of Harmonics on Electric Machines and Equipments, Harmonic Power Flow.

UNIT III : ELECTRICAL TRANSIENTS & POWER QUALITY MONITORING 12

Electrical Transients: Sources of Transient Over voltages- Atmospheric and switching transients- motor

starting transients, PF correction capacitor switching transients, UPS switching transients, neutral voltage

swing etc, Devices for over voltage protection.

Power Quality Monitoring: Harmonic Analyzer, Transient Disturbance Analyzer, Wiring and

Grounding Tester, Flicker Meter, Oscilloscope, Multimeter etc. Smart Power Quality Monitors,

Transducer Requirements, Power Quality Monitoring Standards.

UNIT IV : CUSTOM POWER DEVICES 14

Passive Filters, Design of Passive Filters, Problems associated with Passive Filters, Classification of

Custom Power Devices, Active Filters, Shunt Active Filters, Series Active Filters, Hybrid Filters, Power

Electronic Converters in Active Filtering, STATCOM, Unified Power Quality Conditioners, Recent

Control Strategies.

TOTAL HOURS 44


1. H. Akagi, Edson Hirokazu Watanabe, and Mauricio Aredes, “Instantaneous Power Theory and

of 23

Applications to Power Conditioning,” IEEE Press Series on Power Engineering

2. M.H.J., “Understanding Power Quality Problems: Voltage sags and interruptions,” IEEE Press,

New York, 2000.

3. Arrillaga, J, Watson, N.R., Chen, S., “Power System Quality Assessment,” Wiley, New York,

2000.

4. Arinthom Ghosh, Gerard Ledwich, and Kluwer “Power Quality Enhancement Using Custom

Power Devices,” Academic Publishers

5. Roger C. Dugan, Mark F. McGranaghan, Surya Santoso, and H. Wayne Deaty, “Electrical Power

Systems Quality,” McGraw-Hill.

6. C. Sankaran, “Power Quality,” CRC Press.

of 23

EE 506 Modern Control Systems




3 0 -- 3 3 25 50 25 -- -- 100

UNIT I 11

ANALYSIS OF CONTROL SYSTEMS IN STATE SPACE: Concept of state and state space, state and output

equations, state variable representations, canonical realizations, solution of state equations, Concepts

of controllability and observability.

UNIT II 11

STATE VARIABLE ANALYSIS OF DIGITAL CONTROL SYSTEMS: Discretisation of continuous time state

equation, discrete time state equations, solution of discrete state space equations, Controllability to the

origin and reachability.

UNIT III 08

DESIGN OF MODERN CONTROL SYSTEMS: Pole placement design through state feedback, stability

improvement by state feedback, state regulator design, Design of state observer and state estimator,

Quadratic optimal regulator design.

UNIT IV 09

MODEL PREDICTIVE CONTROL: Different models used in MPC, Dynamic Matrix Control, Optimal Control

filtering, Linear Kalman Filters, EKF

TOTAL HOURS 39

Text and References:

1 C.T.Chen, “Linear system theory and design”, Oxford, 3rd

Edition

2 K. Ogata, “Modern Control Engineering”, PHI, 4th

Edition

3 M. Gopal, “Digital Control and State Variable Methods”, TMH, 3rd

Edition

4 John Bay, “Fundamentals of linear state space systems”, McGraw Hill

5 Wilson Rugh, “Linear system theory”, Prentice Hall, 2nd

edition

6 Thomas Kailath, “Linear systems”, Prentice Hall International

7 B.C.Kuo, “Automatic Control System”.

of 23

EE 507 Power System Analysis and Dynamics




3 0 -- 3 3 25 50 25 -- -- 100

UNIT I 05

NETWORK FORMULATION AND GRAPH THEORY: Introduction, Network Equations, Graph Theory,

Development of Network Matrices from Graph Theoretic Approach, Augment Cut set Incidence Matrix

Cut set and Circuit Equations, Building Algorithm for the Bus Impedance Matrix Modification of ZBUS

matrix due to changes in the primitive network

UNIT II 15

GENERATOR MODELING - I (MACHINE VIEWPOINT): Classical Machine Description, Voltage Generation,

Open-Circuit Voltage, Armature Reaction, Terminal Voltage, Power Delivered by Generator,

Synchronizing Generator to an Infinite Bus, Synchronous Condenser, Role of Synchronous Machine

Excitation in Controlling Reactive Power.

GENERATOR MODELING – II (CIRCUIT VIEWPOINT): Energy Conversion, Application to Synchronous

Machine, The Park Transformation, Park’s Voltage Equation, Park’s Mechanical Equation, Circuit Model,

Instantaneous Power Output, Applications, Synchronous Operation, Steady-state Model, Simplified

Dynamic Model, Generator Connected to Infinite Bus (Linear Model).

UNIT III 12

EXCITATION AND PRIME MOVER CONTROLLERS: Excitation System requirements, Elements of an

Excitation System, types of Excitation System – AC/DC excitation, Static excitation system, Modelling of

excitation system.

ANALYSIS OF SINGLE MACHINE SYSTEM: Small Signal Analysis with Block Diagram Representation,

Characteristic Equation (CE) and Application of Routh-Hurwithz Criterion, Synchronizing and Damping

Torque Analysis, Small Signal Model: State Equation, Nonlinear Oscillations – Hopf Bifurcation.

UNIT IV 07

ANALYSIS OF MULTI-MACHINE SYSTEM: Simplified system Model, Detailed models: Case I, Detailed

models: Case II, Inclusion of Load and SVC dynamics, Modal Analysis of Large Power Systems, Case

Studies.

TOTAL HOURS 39


1 Vijay Vittal, “Power Systems Analysis”, Bergen, Pearson Education

2 K R Padiyar, “Power System Dynamics”, B S Publications

3 P.Kundur, “Power System Stability & Control”, Tata Mcgraw hill

4 L. P. Singh, “Advanced Power System Analysis and Dynamics”, New Age International Ltd, New

Delhi

of 23

EE 508 Advanced Power Electronics




3 0 -- 3 3 25 50 25 -- -- 100

UNIT I 08

REVIEW OF POWER SEMICONDUCTOR DEVICES: Review of Power semiconductor devices, Gate and

Base drive circuits - Preliminary design considerations, Temperature control of power devices.

DESIGN CONSIDERATIONS Design and selection of magnetic components, inductor, high-frequency

transformers, line and EMI filters, Heat sink design, IEEE 519 (1992) considerations

UNIT II 12

FLEXIBLE AC TRANSMISSION SYSTEMS: Principle of power transmission, Principle of shunt

compensation, Shunt compensators: Thyristor controlled reactor, Thyristor switched capacitor, Static

VAR compensator, Advanced static VAR compensator. Principle of series compensation, Series

Compensators: Thyristor switched series capacitor, Thyristor controlled series capacitor, Force

commutation controlled series capacitor, Series static VAR compensator. Principle of phase angle

compensation, Phase angle compensator, Unified Power Flow Controller, Comparisons of compensators.

UNIT III 13

Matrix Converter, Vector control, Indirect and direct vector control, various grid connected inverters,

Multilevel inverters: Concept, Diode-Clamped, Flying-Capacitor, Cascaded type multilevel inverters,

Features and comparison

UNIT IV 6

APPLICATIONS OF POWER ELECTRONICS: Unity power factor conversion, Control of wind generators,

active filters, photovoltaic applications, maximum power point tracking

TOTAL HOURS 39


1 N.Mohan, T.M. Undeland&W.P.Robbins, “Power Electronics: Converter, Applications & Design”,

John Wiley & Sons

2 R. Bausiere& G. Seguier, “Power Electronic Converters”, Springer- Verlag

3 D.M.Mitchell, “DC-DC Switching Regulator Analysis”, McGraw Hill

4 B. JayantBaliga, “Fundamentals of Power Semiconductor Devices”, Springer

5 Web-Resources: https://ieeexplore.ieee.org

6 N.G.Hingorani&Gyugyi, “Understanding Facts”, Standard Publishers

7 K.R.Padiyar, “FACTS Controller in Power Transmission & Distribution”, Anshan Ltd.

of 23

EE 509 Digital Signal Processing




3 0 -- 3 3 25 50 25 -- -- 100

UNIT I 10

Introduction to Discrete Time Signals and Systems: Introduction, Classification of signals, Sampling of

analog signals, Brief review of Sampling Theorem, Reconstruction of Signals, and Concept of Aliasing

using frequency domain representation, Discrete time signals, Discrete time systems.

Frequency Spectra and DTFT: Frequency analysis of discrete time signals, Frequency domain and time

domain signal properties, linear convolution using DTFT, Fourier transform properties for discrete time

signals.

UNIT II 10

Discrete Fourier Transform and FFT: Frequency analysis of signals using DFT, Correlation between DTFT

and DFT, circular convolution using DFT: limitations and workarounds; Frequency domain sampling,

properties of DFT, Efficient computation of DFT: FFT algorithms, Quantization effects in the computation

of the DFT.

UNIT III 09

Digital Filters: Structures of FIR and IIR filters, Symmetric and Antisymmetric FIR filters, design of FIR

filters using windows; Design of IIR filters from analog filters by bilinear transformations; Impulse

Invariance method.

UNIT IV 10

Applications of DSP: Measurement algorithms for digital protection: magnitude of voltage, current and

power; Measurement of impedance and its components; Phase and phase shift measurement,

frequency measurement; Filtering of symmetrical components

TOTAL HOURS 39


1 John G. Proakis, and Dimitris G. Manolakis, “Digital Signal Processing”, PHI

2 Alan V. Oppenheim, Ronald W. Schafer, “Discrete-Time Signal Processing”, PHI

3 Waldemar Rebizant, Janusz Szafran, Andrzej Wiszniewski, “Digital Signal Processing in Power

System Protection and Control” Springer

4 Sanjit K Mitra, “Digital Signal Processing: A computer-based approach”, Tata McGraw Hill

5 Jonatham Stein, “Digital Signal Processing”, John Wiley

of 23

Successful Research and Development Program

Teaching Scheme Examination Scheme (audit course)

L T P

Hrs/Week Theory Practical Total


2 0 0

2

-- -- (Pass/fail)

The Research Organization: Objectives & Goals of a Research Organization, Components of a research

organization, Contracting & Operational Support Activities, Indirect Support Activities, Di rect Support

Activities, Costs & Infrastructure Accounting, General & Administration Activities, Market & Business

Development Activities, Profit & Non-Profit Entity Implications, Business Case for R&D, R&D Structures &

Costs for Selected Industry Segments, Success stories.

Research Staff: Research & Academic Faculty, Scientists & Technologists, Research Associates,

Graduate Students, Visiting Researchers, Employment Laws, Contracts, & Implications, Workplace

Regulations.

Sponsors & Funding Agencies: Funding Agencies – Types, Types of Interface with Funding & Sponsor

Agencies, Call for Proposals & Opportunity Tracking, Types of Proposals & Grants, Contracting Vehicles &

Arrangements, Deliverables, Interim & Final Reviews, Cost & Performance Audits, Contract Laws &

Enforcement, Ethics & Lobbying, Conflict of Interest & its Management.

Proposals for Research Program Funding: Center & Consortia Proposals, Individual Principal Investigator

Proposals, Continuation & Renewal Proposals, Prime/Subcontractor Relationships & Contracting, Cost

Accounting, Laws and Regulations.

Research Program Contracts: Types of Contracts – IDIQ, Cost-Sharing, Cost-Plus, Intellectual Property &

Patent Laws, Export Control & Arms Regulations Compliance, Academic versus Commercial Contracts,

Technology Transfer, Overhead & Indirect Costs, Federal & Government Cost & Accounting Regulations

(FAR), Case Studies.

Writing a Successful Research Proposal: Technical Proposal, Management Proposal, Cost Proposal,

Technology Proposal, Statement of Work & Deliverables, Case Studies.

The Research Process – I: Steps in development of successful research program, Quality and Cost

consideration, Laboratories and infrastructure setup, Staffing & Support Models, Peer-Review,

Independent Verification & Validation, Internal & External Review processes, Ethics & Regulatory Laws

& Guidelines, Case Studies.

The Research Process – II: Problem Definition, Background Study, Valuation & Current Practice,

Proposal Writing, Deliverables & Timelines Development, Results Projection, Staffing, Costs & Progress

Tracking, Quality Management, Publication & Patents, Intellectual Property & Licensing, Technology

Transfer, Validation & Test.

Deliverables & Audits: Technical Reports, Software, Hardware, Systems, Qualification, Cost Reports,

Test Reports, Papers & Publications, Patents, Case Studies.

of 23

Department Elective

of 23





3 0 -- 3 3 25 50 25 -- -- 100

UNIT I 08

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

UNIT II 15

SMART GRID TECHNOLOGIES: 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, 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)

UNIT III 06

MICRO GRIDS AND DISTRIBUTED ENERGY RESOURCES: Concept of micro grid, need & applications of

micro grid, formation of micro grid, issues of interconnection, protection & control of micro grid.

Islanding, need and benefits, different methods of islanding detection.

UNIT IV 10

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.

INFORMATION AND COMMUNICATION TECHNOLOGY FOR SMART GRID: Advanced Metering

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

Network (WAN). Bluetooth, Zig-Bee, GPS, Wi-Fi, Wi-Max based communication, Wireless Mesh Network,

Broadband over Power line (BPL)

TOTAL HOURS 39


1 Ali K., M.N. Marwali, Min Dai, “Integration of Green and Renewable Energy in Electric Power

Systems”, Wiley

2 Clark W. Gellings, “The Smart Grid: Enabling Energy Efficiency and Demand Response”, CRC Press

3 JanakaEkanayake, N. Jenkins, K. Liyanage, J. Wu, Akihiko Yokoyama, “Smart Grid: Technology and

Applications”, Wiley

4 Jean Claude Sabonnadiere, NouredineHadjsaid, “Smart Grids”, Wiley Blackwell

of 23

5 Tony Flick and Justin Morehouse, “Securing the Smart Grid”, Elsevier Inc.

6 Peter S. Fox-Penner, “Smart Power: Climate Change, the Smart Grid, and the Future of Electric

Utilities”, Island Press

of 23





3 0 -- 3 3 25 50 25 -- -- 100

UNIT I 08

INTRODUCTION TO EHV AC TRANSMISSION: Basic requirements of a transmission system, Basic

parameters, Need of EHV AC transmission, Configuration of EHV AC transmission link, Special features

and technical considerations for EHV AC lines

TRANSMISSION LINE TRENDS AND PRELIMINARIES: Choice of voltage, standard transmission voltages,

power handling capacity and line loss calculations, cost of transmission line and equipment, mechanical

considerations of line performance.

UNIT II 15

Conductors used for EHV transmission lines, resistance of conductors, effect of resistance of conductor,

temperature rise of conductors and current carrying capacity, conductor configurations used for

Bundles, GMR of bundled conductors, Calculation of line and ground parameters, surge impedance

loading.

Voltage gradients of conductors, Corona effects including power loss, audible noise and radio

interference, calculation of corona loss, Radio Interference, Audible noise.

UNIT III 06

Shunt and series compensation, Design of EHV AC lines based on steady state limits, Electrostatic and

magnetic fields of EHV lines

UNIT IV 10

HVDC TRANSMISSION: Comparison of AC and DC transmission, applications, types of DC links,

components of HVDC transmission, advantages and limitations, thyristor valve, analysis of HVDC

converter, HVDC system control, smoothing reactors, transient over voltages in DC lines, protection of

DC lines, reactive power control, harmonics and filters, multi terminal HVDC systems.

TOTAL HOURS 39


1 Rakosh Das Begamudre, “Extra high voltage AC transmission engineering”, New Age International

ltd

2 K. R. Padiyar, “HVDC power transmission systems technology and system interactions”, New Age

International ltd

of 23

Open Elective I

of 23

EE505 RENEWABLE ENERGY SYSTEMS




3 0 -- 3 3 25 50 25 -- -- 100

UNIT I

10

INTRODUCTION: World energy use, Reserves of energy resources, Environmental aspects of energy

utilization, Renewable energy scenario in India, Potentials, Achievements, Applications, Concept of

energy conservations.

UNIT II 10

SOLAR ENERGY: Solar radiation, Solar radiation spectrum, Solar constant, Extra terrestrial radiation,

Geometrical parameters – Longitude, Latitude and Altitude angles, Solar angles- solar azimuth angle,

surface azimuth angle, air mass, incidence angle, slope. Solar thermal applications, Flat plate and

concentrating collectors, Solar heating and cooling techniques, Solar desalination, Solar Pond, Solar

cooker, Solar thermal power plant, Solar photo voltaic conversion, Solar cells, PV applications, Blocking

diode, Bypass diode

UNIT III 09

WIND ENERGY: Wind data and energy estimation, Betz limit, Basic components of wind electric system,

Types of Wind energy conversion devices (Dutch windmills, Mutli-bladed water pumping windmills, High

speed propeller type wind machines), Principle of Lift and Drag force on aerofoil (Basics of

Aerodynamics), Design of Wind turbine rotor, Power Speed Characteristics, Power torque

characteristics, Concept of Savonius and Darrious rotors, Types of wind energy systems, Performance

and calculations, Details of wind turbine generator, Comparison of Wind generators, Wind turbine

control system (pitch, stall and yaw controls).

UNIT IV 10

BIOMASS ENERGY: Biomass direct combustion, Biomass gasifier, Biogas plant, Ethanol production, Bio

diesel, Cogeneration, Biomass applications

OTHER RENEWABLE ENERGY SOURCES: Tidal energy, Wave energy, Open and closed OTEC Cycles, Small

hydro, Geothermal energy, Fuel cell systems

TOTAL HOURS 39


1 G.D. Rai, “Non Conventional Energy Sources”, Khanna Publishers, New Delhi, 1999.

2 S.P. Sukhatme, “Solar Energy”, Tata McGraw Hill Publishing Company Ltd., New Delhi, 1997.

3 Godfrey Boyle, “Renewable Energy, Power for a Sustainable Future”, Oxford University Press, U.K,

1996.

4 Twidell, J.W. & Weir, A., “Renewable Energy Sources”, EFN Spon Ltd., UK, 1986.

5 G.N. Tiwari, “Solar Energy, Fundamentals Design, Modelling and applications”, Narosa Publishing

House, New Delhi, 2002.

6 L.L. Freris, “Wind Energy Conversion systems”, Prentice Hall, UK, 1990.

7 Johnson Gary, L., “Wind Energy Systems”, Prentice Hall, New York, 1985.

of 23

Open Elective II

of 23

EE513 Control Motors




3 0 -- 3 3 25 50 25 -- -- 100

UNIT I

Servomotors

Servo system, Requirements of a good servomotor, Types of servomotors, DC Servomotors

Basic operating principle, Field controlled dc servomotor, Armature controlled dc

servomotor, Characteristics and applications of dc servomotors.

10

UNIT II

AC Servomotors 06

Construction, types of rotors, Operating principle, Torque/Speed characteristics, Applications of AC

Servomotors.

UNIT II 12

Stepper Motors

Terms used in step motors, Types of stepper motors, Various modes of operation of Variable reluctance

motors, micro stepping control of stepper motor, Multistack VR stepper motor, Construction and

working of PM stepper motor and hybrid stepper motors, Torque/speed characteristics of the stepper

motor.

UNIT IV 09

Single phase and special purpose motors

Universal motor, AC Series motors, starting and speed control of single phase induction motors,

Repulsion motors, Reluctance and hysteresis motors, Brushless dc motors.

TOTAL HOURS 39


1 T.J.E. Miller, “Brushless Permanent Magnet and Reluctance motor drives”, Clarendo Press, oxford.

2 V.V. Athani, “Stepper Motors: Fundamentals, applications and Design”, Mc Graw Hill

3 Y. Dote and S. Kinoshita, “Brushless Servomotors-Fundamentals and applications”, Clarendo Press,

oxford.

4 A.E. Fitzerald, Charles Kingsley and Stephen D Umans, “Electric Machinery”, TMH Publication.

COURSE STRUCTURE FOR M.TECH. ELECTRICAL … Syllabus_Wef 2018-19_BOS.pdfCOURSE STRUCTURE FOR M.TECH....

Documents

Transcript of COURSE STRUCTURE FOR M.TECH. ELECTRICAL … Syllabus_Wef 2018-19_BOS.pdfCOURSE STRUCTURE FOR M.TECH....