1 Approved BoS May 2018 (AY 2018-19)
PANDIT DEENDAYAL PETROLEUM UNIVERSITY
SCHOOL OF TECHNOLOGY
COURSE STRUCTURE FOR B.TECH. ELECTRICAL ENGINEEING
SEMESTER V B.TECH. ELECTRICAL ENGINEEING
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 16EE301T Electromagnetics 3 1 -- 4 4 25 50 25 -- -- 100
2 16EE302T Microprocessors and
Microcontrollers 4 0 -- 4 4 25 50 25 -- -- 100
3 16EE303T Power Electronics 4 0 -- 4 4 25 50 25 -- -- 100
4 16EE304T Power System II 3 1 -- 4 4 25 50 25 -- -- 100
5 16EE305T Instrumentation & Control 3 0 -- 3 3 25 50 25 -- -- 100
6 16EE306P
Laboratory-I
(Control Instrumentation and Simulation)
- - 3 1.5 3
50 50 100
7 16EE307P Laboratory-II
(Power Electronics and Controllers) - - 3 1.5 3
50 50 100
Total 17 2 6 22 25 700
MS = Mid Semester, ES = End Semester; IA = Internal assessment (like quiz, assignments etc)
LW = Laboratory work; LE = Laboratory Exam
2 Approved BoS May 2018 (AY 2018-19)
PANDIT DEENDAYAL PETROLEUM UNIVERSITY
SCHOOL OF TECHNOLOGY
DEPARTMENT OF ELECTRICAL ENGINEERING
Semester V
Course Code: 16EE301T Course: ELECTROMAGNETICS
Teaching Scheme Examination Scheme
L T P C Hrs/Week Theory Practical Total
Marks MS ES IA LW LE/Viva
3 1 -- 4 4 25 50 25 -- -- 100
Prerequisites: Linear Algebra, Vector Calculus, Coordinate Geometry
Course Objectives:
- The purpose of this course is to enable the students to have a fair knowledge about the theory and
problems in Electromagnetic Fields.
- To understand the concepts of Electrostatics and their applications.
- To understand the concepts of Magneto statics and their applications.
- To understand the concept of Electromagnetic Fields, waves and wave propagation
UNIT I : VECTOR CALCULUS 10
Vector Algebra, Coordinate Systems and Transformation, Circular Cylindrical Coordinates, Spherical
Coordinates, Vector Calculus: Differential Length, Area, and Volume, Line, Surface, and Volume
Integrals, Gradient of a Scalar, Divergence of a Vector and Divergence Theorem, Curl of a Vector and
Stokes's Theorem, Laplacian of a Scalar
UNIT II : ELECTROSTATICS 16
Coulomb's Law, Electric Field Intensity, Electric Flux Density, Gauss's Law, Divergence, Electric field
and potential due to point, line, plane and spherical charge distributions, Effect of dielectric medium,
Capacitance of simple configurations and Examples
UNIT III : ELECTROSTATIC BOUNDARY-VALUE PROBLEMS & MAGNETO
STATICS
16
Poisson's and Laplace's Equations, Uniqueness Theorem, General Procedure for Solving Poisson's or
Laplace'sEquation, Resistance and Capacitance, Method of Images, Biot-Savart's Law, Ampere's Circuit
Law—Maxwell's Equation, Applications of Ampere's Law, Faraday’s law, Lorentz force, Inductance,
Magnetomotive force, Reluctance, Magnetic circuits, Self and Mutual inductance of simple
configurations
UNIT IV: ELECTROMAGNETIC WAVE PROPAGATION 14
Waves in General, Wave Propagation in Lossy Dielectrics, Plane Waves in Lossless Dielectrics, Plane
Waves in Free Space, Plane Waves in Good Conductors, Power and the Poynting Vector, Reflection of a
3 Approved BoS May 2018 (AY 2018-19)
Plane Wave at Normal Incidence,
Transmission Lines
Transmission Line Parameters, Transmission Line Equations, Input Impedance, SWR, and Power, The
Smith Chart, Some Applications of Transmission Lines, Transients on Transmission Lines. Introduction
to waveguides and antennas
TOTAL HOURS 56
Texts and References:
1 Rao, N. N., “Elements of Engineering Electromagnetic”, Prentice Hall, India
2 Mathew, N. Sadiku, O., “Elements of Electromagnetic”, , Saunders College Publishing
3 Ramo, S., Whinnery, S., and Van Duzer, T., “Fields and waves in communication electronics”,
3rdEdition, John Wiley and Sons
4 Kraus, “Electromagnetic”, 3rdEdition, McGraw Hill
5 Hayt William H., “Engineering Electromagnetic”, McGraw Hill.
4 Approved BoS May 2018 (AY 2018-19)
Semester V
Course Code: 16EE302T Course: MICROPROCESSORS &MICROCONTROLLERS
Teaching Scheme Examination Scheme
L T P C Hrs/Week Theory Practical Total
Marks MS ES IA LW LE/Viva
4 0 -- 4 4 25 50 25 -- -- 100
Prerequisites : Computer Programming
Course Objectives:
- To get familiar with microprocessors and microcontrollers and their role in designing embedded
systems.
- To understand the architecture, assembly programming and timing diagram for a microprocessor
and microcontroller
- To write basic programs in C to explore the functionalities of microcontrollers for real-world
applications
UNIT I : FUNDAMENTALS OF MICROPROCESSORS 14
Introduction to Microprocessors:8-bit microprocessor and microcontroller architecture, Comparison of
8-bit, 16-bit and 32-bit microcontrollers, Definition, classification and examples of Embedded systems
Internal architecture of Intel 8085 microprocessor: Block diagram, Registers, Internal Bus
Organization, Functional details of pins, Registers, ALU
UNIT II : 8085 MICROPROCESSOR 14
Memory Interfacing: Interfacing external RAM and ROM, Bus System, Control signals, Address / Data
bus multiplexing and de-multiplexing.
Assembly language programming: 8085 instruction set: Instructions, Classifications, Addressing
modes, Decision Making, Looping, Stack and Subroutines etc. and Programming examples. Timing
Diagrams of various instructions, Interrupts.
UNIT III : 8051 MICROCONTROLLER 14
Introduction to 8051 microcontroller: Introduction, Architecture of 8051 Microcontroller, 8051
microcontroller hardware, Pin diagram of 8051, input/output pins, ports and circuits. Internal RAM and
ROM, SFR’s
On-board Peripherals: GPIO, Timers and Counters, Interrupt, Serial data communication (UART)
UNIT IV: 8051 C PROGRAMMING 14
Basics of C programming, programming examples for GPIO, Timers, Round-robin with interrupts, PWM,
LCD, UART
TOTAL HOURS 56
Texts and References:
1 Ramesh S. Gaonkar, “Microprocessor Architecture, Programming, and Applications with the
8085”, Penram International.
2 David E. Simon, “An Embedded Software Primer”,Addison-Wesley Professional
3 William Kleitz, “Microprocessor and Microcontroller fundamentals: The 8085 and 8051
5 Approved BoS May 2018 (AY 2018-19)
Hardware and Software”
4 Douglas V. Hall , “Microprocessors, Interfacing and Peripherals”, Tata McGraw Hill,
5 Ajoy Ray, K Bhurchandi, “Advanced Microprocessors and Peripherals”, Tata McGraw Hill
6 Muhammad Ali Mazidi, Janice GillispieMazidi and RolinMcKinlay, “The 8051 Microcontroller and
Embedded Systems Using Assembly and C”, Pearson Education.
7 K. J Ayala, D. V. Gadre, “The 8051 Microcontroller and Embedded Systems using Assembly and
C”,CengageLearning, India Edition.
6 Approved BoS May 2018 (AY 2018-19)
Semester V
Course Code: 16EE303T Course: POWER ELECTRONICS
Teaching Scheme Examination Scheme
L T P C Hrs/Week Theory Practical Total
Marks MS ES IA LW LE/Viva
4 0 -- 4 4 25 50 25 -- -- 100
Prerequisites : Electronic Devices & Circuits, Electrical Machines I & II
Course Objectives:
- To understand the significance of Power Electronics and its applications in various sectors
- To understand the basic operating characteristics of power semiconductor switches
- To get a fair knowledge about the operational analysis, applications, features and control of
different power converters
- To gain knowledge about the design and practical implementation of the power converters
UNIT I : POWER SEMICONDUCTOR SWITCHES 15
Introduction to Power Electronics, Classification of Power Converters and their Applications,
Classification Power Semiconductor Switches, Operating Characteristics of Power Semiconductor
Switches (Power Diode, SCR, DIAC, TRIAC, Power BJT, MOSFET, IGBT, GTO), Terminologies and
Familiarization with Datasheet, Commutation Techniques, Gating Characteristics, Gating Techniques,
Optical Isolation, Snubber Circuit Design, Heat Sink Design, Series and Parallel Operation of SCR,
Introduction to SiC switches
UNIT II : CONTROLLED RECTIFIERS & DC-DC CONVERTERS 14
1-Phase Controlled Rectifiers – Half Wave, Full Wave and Semi Controlled Rectifiers with R and R-L
Loads, Effect of Free Wheeling Diode on Operation of 1-Phase Controlled Rectifiers, Quadrant of
Operation
3-Phase Controlled Rectifiers – Half Wave, Full Wave, Semi Controlled Rectifiers with R and R-L
Loads, Effect of Free Wheeling Diode on Operation of 3-Phase Controlled Rectifiers, Quadrant of
Operation
Dual Converters, Triggering Circuit Design for Controlled Rectifiers
Choppers & dc-dc Converters – Introduction to Choppers and dc-dc Converters, Operational Analysis
and Design of Buck Converter, Boost Converter, Buck-Boost Converter, Cuk Converter, Triggering
Circuit Design for dc-dc converters
UNIT III : INVERTERS 18
Classification, Significance, Applications, Principle of Operation, 1-Phase Half Bridge Inverter, 1-Phase
Full Bridge Inverter, 3-Phase Voltage Source Inverter (180o Mode of Conduction & 120o Mode of
Conduction), Modulation Techniques (Uniform Pulse Width Modulation, Multi-Pulse Pulse Width
Modulation, Trapezoidal Pulse Width Modulation, Sinusoidal Pulse Width Modulation, Modified
Sinusoidal Pulse Width Modulation, Selective Harmonic Elimination), Unipolar & Bipolar Pulse Width
Modulation, Harmonics, Power Factor, Distortion Factor, Displacement Factor, Harmonic Factor, Impact
of Harmonics on Load Operation, Current Source Inverters, Comparison of Current and Voltage Source
Inverters, Triggering Circuit Design for Inverters, Introduction to Multilevel Inverters
7 Approved BoS May 2018 (AY 2018-19)
UNIT IV: AC-AC CONVERTERS 09
AC Voltage Controllers – Classification, Application, Principle of Operation (Phase Angle Control &
Integral Cycle Control), Operational Analysis of 1-Phase ac Voltage Controller feeding R and R-L Loads,
Introduction to 3-Phase ac Voltage Controller, ac Voltage Controller as a Soft Starter
Introduction to Cycloconverter – Operating Principle, Topological Overview, Associated Problems
Introduction to Matrix Converter – Operating Principle, Topological Overview, Associated Problems
TOTAL HOURS 56
Texts and References:
1 M. H. Rashid, Power Electronics: Circuits, Devices and Applications, Prentice Hall of India Ltd.
2 Ned Mohan, T. M. Undeland and W. P. Robbins, Power Electronics: Converters, Applications and
Design, Wiley India Ltd.
3 B. K. Bose, Modern Power Electronics and ac Drives, Prentice Hall Inc.
4 P. S Bimbhra, Power Electronics, Khanna Publishers-Delhi.
5 D. W. Hart, Power Electronics, Tata Mcgraw-Hill, 2011.
6 Bin Wu, High Power Converters and AC Drives, Wiley-IEEE Press.
8 Approved BoS May 2018 (AY 2018-19)
Semester V
Course Code: 16EE304T Course: POWER SYSTEM II
Teaching Scheme Examination Scheme
L T P C Hrs/Week Theory Practical Total
Marks MS ES IA LW LE/Viva
3 1 -- 4 4 25 50 25 -- -- 100
Prerequisites : Power System I
Course Objectives:
- To introduce the students with the detail knowledge of fault analysis methods.
- To give exposure on power system analysis when it is imperiled to different symmetrical and
unsymmetrical faults or abnormalities.
- To give exposure on load flow analysis and methods, power system stability concepts
- To introduce the students about the concepts of travelling waves
UNIT I 10
Representation of Power System Components: Synchronous machines, Transformers, Transmission
lines, one line diagram, Impedance diagram, per unit system.
Symmetrical Components: Symmetrical components of unbalanced phasors, power in terms of
symmetrical components, sequence impedances and sequence networks.
UNIT II 17
Symmetrical Fault Analysis: Transient in R-L series circuit, calculation of 3-phase short circuit current
and reactance of synchronous machine, internal voltage of loaded machine under transient conditions,
Analysis of Symmetrical Fault using Thevenin’s Equivalent circuit
Unsymmetrical Fault Analysis: Analysis of single line to ground fault, line to line fault and double line to
ground fault on unloaded generators and power system network with and without fault impedance.
UNIT III 10
Load Flow: Introduction, bus classification, nodal admittance matrix(Y Bus), Formation of Zbus using
singular transformation and algorithm, development of load flow equations, load flow solution using Gauss
Seidel and Newton-Raphson method, approximation to N-R method, line flow equations.
UNIT IV 19
Power System Stability: Stability and stability limit, Steady state stability study, derivation of Swing
equation, transient stability studies by equal area criterion and step-by-step method, Factors affecting steady
state and transient stability and methods of improvement.
Travelling Waves: Wave equation for uniform Transmission lines, velocity of propagation, surge
impedance, reflection and transmission of travelling waves under different line loadings, Bewlay’s lattice
diagram, protection of equipments and line against travelling wave.
TOTAL HOURS 56
Texts and References:
1 W.D. Stevenson, “Elements of Power System Analysis”,McGraw Hill.
2 C.L. Wadhwa, “Electrical Power Systems”, New Age International.
9 Approved BoS May 2018 (AY 2018-19)
3 T.K Nagsarkarand M.S. Sukhija, “Power System Analysis”, Oxford University Press
4 Hadi Sadat, “Power System Analysis”, Tata McGraw Hill
5 J.D. Glover, M.S. Sharma and T.J. Overbye, “Power System Analysis and Design”,Thomson
6 Stagg and El-Abiad, “Computer Methods in Power System Analysis”,Tata McGraw Hill.
7 Kothari and Nagrath, “Modern Power System Analysis”, TataMcGraw Hill.
8 E. W. Bewlay Book to be added
10 Approved BoS May 2018 (AY 2018-19)
Semester V
Course Code: 16EE305T Course: INSTRUMENTATION & CONTROL
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
Prerequisites : Control Theory
Course Objectives:
- To understand the concept of measurement systems and transducer characteristics.
- To get a fair knowledge about various sensors and transducers for the measurement of various
physical quantities.
- To understand the concept of data acquisition and signal transmission in a measurement system.
- To learn the various control strategies used in industrial process control.
UNIT I :MEASUREMENT SYSTEM 09
Introduction to measurement system, sensors and transducers, static and dynamic characteristics of
measuring device, transducer classifications, electrical transducers, transducer calibrations and
specifications.
UNIT II : SENSORS & TRANSDUCERS 10
Position sensors, speed and vibration measurements, force and pressure measurement using capacitive
and Piezo-electric transducers, stain gauge, LVDT, torque measurement, Hall-effect transducer,
temperature measurement using resistance thermometer, thermistors, RTD, thermocouples, pyrometer,
measurement of liquid level and flow.
UNIT III : DATA ACQUISITION & SIGNAL TRANSMISSION 09
Signal conditioning of the inputs, data conversion, analog to digital and digital to analog converters,
telemetry system, current to voltage, voltage to current, current to pressure convertors, industrial data
communication signals and communication protocols.
Smart Sensors and smart transmitters, proximity sensors, Study of related Datasheets.
UNIT IV: PROCESS CONTROL 16
Principle and elements of process control system, process characteristics,continuous& discontinuous
control, proportional, integral, derivative and composite control modes, tuning of PID controller, cascade
control, feed-forward control, application of the process control in a power plant, Chemical Analyzers for
process industries.
Introduction to PLC and DCS: Introduction to SCADA, PLC architecture, input-output modules,
working of PLC, introduction to PLC programming using ladder logic, Introduction to distributed control
system (DCS) and its architecture.
TOTAL HOURS 44
Texts and References:
1 Ernest O. Doebelin, “Measurement Systems - Application and Design”, 5th edition, McGraw Hill,
2007.
11 Approved BoS May 2018 (AY 2018-19)
2 A. K. Sawhney, “Advanced Measurements and Instrumentation”, DhanpatRai and Sons, New
Delhi.
3 Curtis Johnson, “Process Control Instrumentation Technology”, 8th Edition, Prentice-Hall, 2006.
4 John R. Hackworth, Frederick, D. Hackworth, “Programmable Logic Controllers: Programming
Methods and Applications”, Prentice-Hall, 2003.
5 E. A. Parr, Newnes, “Programmable Controllers: An Engineer’s guide”, 3rd Edition, 2003.
12 Approved BoS May 2018 (AY 2018-19)
Semester V
Course Code: 16EE306P Course: LABORATORY – I
CONTROL, INSTRUMENTATION & SIMULATION
Teaching Scheme Examination Scheme
L T P C Hrs/Week Theory Practical Total
Marks MS ES IA LW LE/Viva
-- -- 3 1.5 3 -- -- -- 50 50 100
PART-1 : CONTROL & INSTRUMENTATION
List of Experiments:
1. Introduction to Matlab, basic commands and programming
2. Solution of differential equations using MatLab and Simulink environment
3. Introduction to control system tool box in Matlab.
4. To perform step response of single board heater system (First order Process)- an experimental study
5. Stability analysis using root locus and bode plots.
6. Design of PID controllers for single board heater system- an experimental study
7. To study Analog to digital and digital to analog convertor.
8. To study and identify various sensors and transducers.
9. Study of displacement measurement using LVDT
10. PLC programming using ladder logic and experimental demonstrations on dual conveyor belt system.
11. Design of PID controllers for pressure, flow and level control.
PART-2 : POWER SYSTEM SIMULATION
List of Experiments:
1. Introduction to MiPower, Matlab & PSCAD software and its applications in power system
simulations.
2. Transient analysis of simple RC, RL and RLC circuits.
3. Performance analysis of Transmission line (Short, Medium and Long)
4. To obtain Y-bus and Z- bus for given power system configuration.
5. To perform load flow study using Gauss -Seidel, Newton-Raphson and fast decoupled methods.
6. To perform symmetrical and un-symmetrical fault analysis
7. Solving the linear equations /systems using different Methods like Gauss-Siedel and Newton Raphson
8. To perform transient stability analysis of a power system
NOTE: Course coordinator needs to ensure that at least 80% of the experiments listed in each part are
covered during the semester
13 Approved BoS May 2018 (AY 2018-19)
Semester V
Course Code: 16EE307P Course: LABORATORY-II
POWER ELECTRONICS & CONTROLLERS
Teaching Scheme Examination Scheme
L T P C Hrs/Week Theory Practical Total
Marks MS ES IA LW LE/Viva
-- -- 3 1.5 3 -- -- -- 50 50 100
PART-1 : POWER ELECTRONICS
List of Experiments:
1. To design and implement 5V regulated power supply
2. To determine holding and latching current of SCR and demonstrate the static V-I Characteristic
of SCR
3. To design and implement gate drive circuit for MOSFET
4. To demonstrate the operation of different configurations of 1-Phase Uncontrolled Rectifier
feeding R-Load, R-L Load, and R-L Load with Freewheeling Diode
5. To demonstrate the operation of different configurations of 3-Phase Uncontrolled Rectifier
Feeding R-Load, R-L Load, and R-L Load with Freewheeling Diode
6. To demonstrate the operation of different configurations of 1-Phase Controlled Rectifier feeding
R-Load, R-L Load, and R-L Load with Freewheeling Diode
7. To demonstrate the operation of different configurations of 3-Phase Controlled Rectifier Feeding
R-Load, R-L Load, and R-L Load with Freewheeling Diode
8. To demonstrate the operation of buck, boost and buck-boost converter
9. To demonstrate the operation of Class A, B, C Chopper
10. To demonstrate the operation of 1-Phase ac voltage regulator feeding lamp load
11. To demonstrate the operation of 1-Phase cycloconverter
12. To demonstrate the operation of 3-phase inverter driving an Induction Motor with a suitable
admission technique
13. To carry out simulation study related to power electronic converters
PART-2 : CONTROLLERS
List of Experiments:
1. Write an assembly language program for 8085
- to transfer a block of data
- to find square of a number using lookup table
- to multiply two numbers
2. Write an assembly language program for 8085
- to swap two numbers using a subroutine
- to sort N numbers in ascending order
3. Write an assembly language program for for 8051
- to add two numbers from the IRAM where result is 8bits
- to add two numbers from the IRAM where result is 16bits
- to add two numbers from the Code Memory and store result in External Memory
14 Approved BoS May 2018 (AY 2018-19)
- to add two numbers from the External Memory and store result in External Memory
4. Write a C Programs for 8051
- to toggle LED every 500ms using Software Delay
- to turn ON leds from D0 to D7 one at a time
- LEDs lighting up from D0 to D7 while the ones already lit staying ON
- Repeat (b) and (c) for the reverse order
5. Write a C program to toggle a LED every 500ms using timer interrupts and round robin
scheduling.
6. Write a C program to implement keyscan() to toggle a LED on PRESS and RELEASE of a key.
Use timer interrupts and round robin scheduling.
7. Write a C program to do the following:
- Obtain a 20% duty ratio at 100Hz on P1.0
- When the UP key (P3.2) is pressed, increase the duty ratio by 10%
- When the DOWN key (P3.5) is pressed, decrease the duty ratio by 10%
- Duty ratio must stay within 10% and 90% always
8. Write a program to display a single digit on the 4digit 7-segment display.
9. Write a program to display a 4-digit number on the 7-segment display.
10. Write a program to implement a 4-digit up and down counter on the 7-segmend display.
11. Write a program to output a single character via the UART.
12. Write a program to send and receive a string via the UART.
NOTE: Course coordinator needs to ensure that at least 80% of the experiments listed in each part are
covered during the semester
15 Approved BoS May 2018 (AY 2018-19)
PANDIT DEENDAYAL PETROLEUM UNIVERSITY
SCHOOL OF TECHNOLOGY
COURSE STRUCTURE FOR B.TECH. ELECTRICAL ENGINEEING
SEMESTER VI B.TECH. ELECTRICAL ENGINEEING
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 16EE308T Switchgear and Protection 4 0 -- 4 4 25 50 25 -- -- 100
2 16EE309T High Voltage Engineering 3 0 -- 3 3 25 50 25 -- -- 100
3 16EE310T Renewable Energy Engineering 4 0 -- 4 4 25 50 25 -- -- 100
4 16EE311T Power System Design & Practice 3 1 -- 4 4 25 50 25 -- -- 100
5 16EE3xxT Department Elective-I 3 0 -- 3 3 25 50 25 -- -- 100
6 16EE314P Laboratory-I
(Switchgear & Protection) -- -- 3 1.5 3 -- -- -- 50 50 100
7 16EE 315P Laboratory-II
(High Voltage &Renewable
Energy) -- -- 3 1.5 3 50 50 100
Total 17 1 6 21 24 700
MS = Mid Semester, ES = End Semester; IA = Internal assessment (like quiz, assignments etc)
LW = Laboratory work; LE = Laboratory Exam
List of Department Elective-I 1. 16EE312T Advances in Power Systems
2. 16EE313T Electric Drives
16 Approved BoS May 2018 (AY 2018-19)
PANDIT DEENDAYAL PETROLEUM UNIVERSITY
SCHOOL OF TECHNOLOGY
DEPARTMENT OF ELECTRICAL ENGINEERING
Semester VI
Course Code: 16EE308T Course: SWITCHGEAR & PROTECTION
Teaching Scheme Examination Scheme
L T P C Hrs/Week Theory Practical Total
Marks MS ES IA LW LE/Viva
4 0 -- 4 4 25 50 25 -- -- 100
Prerequisites : Power System – I & II
Course Objectives:
- To introduce the students with basic concepts of Relays, Protection schemes, Switch gear and Modern
trends in protection for protecting the power system equipments
- To appreciate and understand scientific concepts underlying engineering and technological applications
- To educate the basic concepts and new developments in power system protection & Switchgear
- To emphasize the significance of protection for electrical equipments
UNIT I 12
Theory Of Circuit Interruption:Introduction, Physics of arc phenomena, Maintenance of the arc, Losses from
plasma, Essential properties of arc, Arc interruption theories.
Circuit Constants In Relation To Circuit Breaking: Introduction, Circuit breaker rating, Circuit constants
and circuit conditions Re-striking voltage transient Characteristics of re-striking voltage, Interaction
between the breaker and circuit, Current chopping, The duties of switchgear.
Theory And Practice Of Conventional Circuit Breakers:Automatic switch, Air-break circuit breakers, Oil
circuit breakers, Single and multi break construction, Air-blast circuit breaker, Performance of circuit breakers
and system requirements, Modification of circuit breaker duty by shunt resistors, Power factor correction by
series resistance, Comparative merits of different types of conventional circuit breakers.
Recent Developments In Circuit Breakers:Modern trends, Vacuum circuit breakers, Sulphur hexafluoride
(SF6) circuit breakers DC circuit breaker.
UNIT II 06
Introduction And Philosophy Of A Protective Relaying System:Types of Faults – Abnormalities – Functions
of Protective Relay Schemes – major Components of Power system – Basic Tripping Circuit – Testing and
Maintenance of Relays – Zones of Protection – Requirements of Protective Systems – Relay Operating Criteria
– Main and Backup Protection – Historical Review of Protective Relay Technology.
Protective Current And Potential Transformer:CT Equivalent Circuit, Vector diagram, Construction,
magnetization Curve, Core, Errors, accuracy, Specifications, Factors affecting selection PT: Equivalent circuit,
Construction, CVT, Specifications.
Different Types of Relays:
Electromagnetic Relays: Classification, Thermal O/L Relays, Types Over Current Relays, Differential Relay,
Directional Relay, Impedance Relays.
Static Relays:Advantages and Limitations, basic Elements, Static Relays Architecture.
17 Approved BoS May 2018 (AY 2018-19)
UNIT III 30
Generator Protection: Differential Protection , Inter-turn fault Protection, stator E/F, Rotor E/F, NPS, Field
Failure, Over Load, Over Voltage, Reverse Power, Pole-Slipping, Back-up Impedance, Under Frequency ,
Miscellaneous Protection.
Transformer Protection:Faults in Transformer – Gas operated relays – Over Current Protection – REF
Protection – Differential Protection – Protection against over fluxing – Protection of Grounding transformers –
Protection Against Overheating - Protection for small transformers.
Induction Motor Protection:Starting of IM – Faults in IM – Abnormalities of IM – Protection of small IM –
Protection of Large IM.
Protection Of Transmission Lines:Protection of Lines by Over Current Relays-Protection of Lines by
Distance Relays-Carrier Current Protection for lines.
Bus Zone Protection: Protection Requirements-Non unit protection-Unit protection schemes- Breaker Back-up
Protection.
UNIT IV 08
Microprocessor Based Digital Protection: Advantages of Numerical Relays – Numerical Relay Hardware -
Digital Signal Processing – estimation of Phasors – Full Cycle Fourier Algorithm – Half Cycle Fourier
Algorithm – Practical Consideration for Selection of Algorithm – DFT- FFT.
Numerical Approach to Apparatus Protection (Overview): Generator Protection – Transformer Protection –
Induction Motor Protection.
TOTAL HOURS 56
Texts and References:
1 Y. G. Parithankar and S. R. Bhide, “Fundamentals Of Power System Protection” 2nd edition, PHI.
2 S. S. Rao, “Switchgear And Protection” Khanna publication.
3 Oza, Nair, Mehta, Makwana, “Protection and switchgear”,
4 C. Russell Masson, “Art And Science Of Protective Relaying”
5 B. Ravindranath And M. Chander, “Power System Protection And Switchgear”
6 B. Ram, “Power System Protection” TMH Publication.
7 Patra and Basu, “Power System Protection”
8 Divyesh Oza, “Modern Power System Protection” TMH Publication.
9 Bhavesh Bhalja, Nilesh Chothani, “Protection and switchgear”, Oxford Publication 2011.
18 Approved BoS May 2018 (AY 2018-19)
Semester VI
Course Code: 16EE309T Course: HIGH VOLTAGE ENGINEERING
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
Prerequisites : Power system-I and Power system-II
Course Objectives:
- To understand the concept of solid, liquid and gaseous dielectrics and various breakdown mechanisms
- To get a fair knowledge about the generation and measurements of high dc, ac, impulse voltages and
currents and understand various methods for the generation and measurements of High voltages used in
high voltage laboratories.
- To gain knowledge about the different testing technologies used for ensuring the qualities of insulating
materials and high voltage equipments used in electrical network.
UNIT I :BREAKDOWN MECHANISMS IN VARIOUS DIELECTRICS 14
Breakdown in Gases: Gases as insulating medium, Properties of insulating gases, Ionization processes,
Townsend’s theory, Current growth equation, Townsend’s criteria of breakdown, Breakdown in electronegative
gases, Time lags for breakdown, streamer theory, Paschen’s law, Breakdown in non uniform field; Corona
Formation–mechanism characteristics and effects, Breakdown in vacuum.
Breakdown in Liquid Dielectrics: Liquid dielectrics: Application, characteristics and properties, Classification
of liquid dielectrics, Breakdown in pure liquid, Breakdown in commercial liquid.
Breakdown in Solid Dielectrics: applications and properties, Various breakdown mechanisms, Intrinsic
breakdown, electromechanical breakdown, thermal breakdown, breakdown due to treeing and tracking,
breakdown due to internal discharges, breakdown in composite dielectrics.
UNIT II : GENERATION OF HIGH VOLTAGES AND CURRENTS 12
Need of Generation of High ac, dcand impulse voltages, Different methods/techniques used for the generation
of high dc and ac voltages. Generation of high frequency high voltages, Generation of high impulse voltages
and currents, Specifications of standard impulse wave, circuits for producing impulse waves and its analysis and
control, Multistage impulse generators, Modified Marx circuit, tripping and control of impulse generators.
UNIT III : MEASUREMENT OF HIGH VOLTAGES AND CURRENTS 08
Different methods/techniques used for the measurement of High dc, ac and impulse voltages, measurement of
High dc, ac and impulse currents, CRO/DSO for impulse voltage and current measurements.
UNIT IV: HIGH VOLTAGE TESTING OF ELECTRICAL APPARATUS 08
High Voltage Testing: Testing of Insulators and Bushings, testing of isolators and circuit Breakers, testing of
Cables, High voltage Testing of Transformers, testing of Surge Arresters, Measurement of breakdown strength
of transformer oil, Radio interference measurement.
Non-Destructive Testing: Measurement of direct current resistivity, measurement of dielectric constant and
loss factor, partial discharge measurements, High Voltage Schering bridge.
TOTAL HOURS 42
19 Approved BoS May 2018 (AY 2018-19)
Texts and References:
1 M. S. Naidu and V. Kamaraju, “High Voltage Engineering”, Tata Mc-Graw Hill.
2 E. Kuffeland W. S. Zacngai, “High Voltage Engineering”, Pergamon Press.
3 M. P. Chaurasia, “High Voltage Engineering”, Khanna Publishers.
4 R. S. Jha, “High Voltage Engineering”, DhanpatRaiand Sons.
5 C. L. Wadhwa, “High Voltage Engineering”, Wiley Eastern Ltd.
6 M. Khalifa, “High Voltage Engineering Theory and Practice”, Marcel Dekker.
7 Subir Ray, “An Introduction to High Voltage Engineering”, Prentice Hall of India.
20 Approved BoS May 2018 (AY 2018-19)
Semester VI
Course Code: 16EE 310T Course: RENEWABLE ENERGY ENGINEERING
Teaching Scheme Examination Scheme
L T P C Hrs/Week Theory Practical Total
Marks MS ES IA LW LE/Viva
4 0 -- 4 4 25 50 25 -- -- 100
Prerequisites : Electrical Machines – I & II, Power Electronics, Power Systems – I & II
Course Objectives:
- To understand the concept present generation of renewable energy sources and other conventional
sources in India.
- To get a knowledge of basic types of available energy sources.
- To acquire the knowledge of generation of electrical energy from Solar Photovoltaics and Wind
energy systems to get effective electrical energy, and its control.
- To know the basics about other upcoming renewable energy technologies.
UNIT I: INTRODUCTION 07
Basics of energy, unit conversions, Indian and world energy scenario, environmental concerns and
importance of renewable energy, Indian renewable energy scenario and future projections, Development
of new energy sources, Energy conservation & their methods, Concept of Distributed Energy Resources,
grid codes (IEEE standard 1547).
UNIT II: SOLAR ENERGY&PHOTOVOLTAICS 21
Solar Energy: General Terms: Solar radiation, Basics of Solar Generation, Basic Sun and Earth
relationships, Solar Constant, Direct or Beam Radiation, Diffuse Radiation, Irradiance, Irradiation,
Elliptical orbit of earth’s revolution, Extraterrestrial Radiation, Terrestrial Radiation, Air mass, Sun
angles (the Earth's Equator, the Meridian, Longitude, Latitude, Declination angle, Hour angle, Latitude or
angle of latitude, Solar Altitude angle, Solar Zenith angle, Solar Azimuth angle, Surface azimuth angle,
Slop or Tilt angle), Introduction to solar to thermal energy, Flat plate collectors and concentrated
collectors.
Photovoltaics: A generic photovoltaic cell, module, array, Equivalent circuit, IV & PV Characteristics of
module, impacts of temperature and insolation on IVcurves, Standard test conditions (STC) of PV
module, Physics of shading and comparison of characteristics, Bypass and blocking diode, Hot spot
generation, Current–voltage curves for loads, Standalone PV systems - Calculation of balance of PV
systems, Maximum power point tracking algorithms, Introduction of PV grid connected systems, Design
of solar power plants at utility scale, Applications of energy storage in Solar PV systems.
UNIT III: WIND ENERGY 20
Wind data and energy estimation, Wind energy conversion system and its efficiency, Classification of
wind turbines, Principle of Lift and Drag force on aerofoil of the wind turbine, Power Speed
Characteristics & Power torque characteristics, Concept of Savonius and Darrious rotors, Types of wind
energy systems in context with type of generator used (Type A, B, C, D), Performance and calculations,
system design and site selection for windfarm, Wind turbine control system (pitch, stall and yaw
controls), Generator side and grid side control systems, Standalone and grid connected wind energy
conversion systems, Hybrid energy conversion system (Wind solar, wind diesel, wind battery, etc.).
21 Approved BoS May 2018 (AY 2018-19)
UNIT IV: OTHER RENEWABLE SOURCES 08
Concept of tidal power with tidal turbine, Introduction to geothermal plant, Concept of biomass and
biomass/biogas plant design, Overview of fuel cell, Generators used in small hydro system, Techno-
commercial comparison of renewable and non-renewable energy sources.
TOTAL HOURS 56
Texts and References:
1 S. Rao and Dr. B. B. Parulekar, “Energy Technology”, Khanna Publishers.
2 G. D. Rai, “Renewable Energy Sources”, Khanna Publishers.
3 Johnson Gary, L., “Wind Energy Systems”, Prentice Hall, New York.
4 Masters G. “Renewable and Efficient Electric Power Systems”, Willey Intersciene Publication,
ISBN 0-471-28060-7.
5 Lara O, Jenkins N, Ekanayake J, “Wind energy generation modelling and control”, 2009 John
Wiley & Sons, Ltd.
6 Patel M R. “Design, Analysis, and Operation Wind and SolarPower Systems”, Second Edition.
7 G. S. Sawhney, “Non-conventional energy sources”, PHI learing Pvt. Ltd.
22 Approved BoS May 2018 (AY 2018-19)
Semester VI
Course Code: 16EE 311T Course: POWER SYSTEM DESIGN AND PRACTICE
Teaching Scheme Examination Scheme
L T P C Hrs/Week Theory Practical Total
Marks MS ES IA LW LE/Viva
3 1 -- 4 4 25 50 25 -- -- 100
Prerequisites : Power system-I and Power system-II
Course Objectives:
- To understand the design aspects of transmission and distribution of power in today’s scenario of
interconnected power system
- To enhance the technical knowledge related to designing EHV, HV and LV substations
- To introduce the design aspects of transmission line from the electrical and mechanical
perspective
- To get the student acquainted with the current industry practices related to grounding/earthing
systems and technicalities related to its design.
UNIT I : DESIGN OF TRANSMISSION LINES 16
Electrical Design of transmission line: Requirements of transmission lines, selection of voltage level,
choice of conductors, spacing of conductor, corona, insulators, surge impedance loading of transmission
line, design problem.
Design of EHV lines: Design considerations of EHV lines, selection and spacing of conductors, corona
and radio interference, shunt and series compensation, tuned power lines, insulation coordination and
different types of EHV towers, EHV systems in India.
Mechanical Design of transmission line:General mechanical design considerations, loading on
conductors, span, sag and tension,clearance from ground, stringing. Transmission line tower design
including location of tower, earth wires, reduction of tower footing resistance.
UNIT II : DESIGN OF SUBSTATION AND POWER SYSTEM 12
Design of substation: Introduction,classification, selection and location of site for substation, selection
and ratings of various equipments used in a substation, key diagrams of typical substations, Introduction
to Gas Insulated Substation, design, construction and commissioning process.
Design of power system: Introduction, selection of sizes and location of generating stations, selection
and specifications of transmission lines, sizes and location of substations, interconnection, advantages of
interconnections.
Power system improvement: Introduction, determination of voltage regulation and losses in a power
system, Methods of improvement.
UNIT III: DESIGN OF DISTRIBUTION SYSTEM 15
Types of distribution system arrangements, selection and size of feeders using Kelvin’s law, design of
cables in distribution system, primary and secondary distribution design, calculation of voltage drop and
size of distributor size, voltage regulation and lamp flicker, application of capacitors to distribution
systems, design of radial distribution, planning and design of town electrification scheme, design of
industrial distribution system, Economics of distribution system.
UNIT IV: POWER SYSTEM GROUNDING & INSULATION COORDINATION 13
23 Approved BoS May 2018 (AY 2018-19)
Power station and substation grounding: Objectives of grounding, definitions, tolerable limits of body
currents, soil resistivity, measurement of soil resistivity, earth resistance, measurement of earth resistance,
tolerable step and touch potential, actual step and touch potential, design of earthing grid.
Insulation coordination& lightning arrestor:Introduction, definitions, insulation-co-ordination curves,
determination of line insulation, basic insulation level, insulation levels of substation equipment, selection
of lightning arrestor and location, selection of arrestor voltage rating, arrestor discharge voltage and
arrestor discharge current, protective margin.
TOTAL HOURS 56
Texts and References:
1. M. V. Deshpande, “Electrical Power System Design”, TMH publication
2. B. R. Gupta, “Electrical Power System Design”, S. CHAND
3. A. S. Pabla, “Electrical Power System Planning”, TMH publication
4. Satnamand Gupta, “Substation Design”, DhanpatRai and Co
5. Soni,Gupta and Bhatnagar, “A course in Electrical Power”, DhanpatRai and Sons
24 Approved BoS May 2018 (AY 2018-19)
Semester VI
Course Code : 16EE312T COURSE : DEPARTMENT ELECTIVE – I
ADVANCES IN POWER SYSTEM
Teaching Scheme Examination Scheme
L T P C Hrs/Week Theory Practical Total
Marks MS ES IA LW LE/Viva
3 - - 3 3 25 50 25 - - 100
Prerequisites : Power system-I & II
Course Objectives:
- To understand the fundamentals of HVDC transmission system and to differentiate between
HVAC and HVDC transmission.
- To study the principles of FACTS controllers, their requirement and operation.
- Understand the concept of Smartgrid, Microgrid, Distributed generation, Deregulated power
system.
- To empower students to understand the operation of power system in modern system equipped
with FACTS, Electric Vehicles, Distributed generation sources.
UNIT I : HVDC TRANSMISSION 09
HVDC system configuration and components, HVDC links, Comparison of EHV-AC and HVDC:
Technical-economical comparison, Converter theory, valve characteristic, converter circuit and its
analysis with no ignition delay, with ignition delay, commutation overlap, Inverter equivalent circuits,
Converter transformer rating, abnormal operation of HVDC system, control of HVDC system, Converter
firing control systems, Influence of AC system strength on AC/DC system interaction
UNIT II : FLEXIBLE AC TRANSMISSION SYSTEMS 15
Mechanism of active and reactive power flow control: Analysis of uncompensated and series-capacitor
compensated line, Shunt Controllers - Objective of shunt compensation, Operation and control of shunt
controllers-SVC, STATCOM; Static Series Controller- Objective of series compensation, Operation and
control of series controllers-SSSC, TCSC; Phase- shifting and Voltage Controller- Objective of phase
angle and voltage compensation, Operation of - TCPAR, TCVAR; Combined type Controller- UPFC,
IPFC; Modeling of FACTS Controllers; Improvement of transient and dynamic stability with FACTS
controllers
UNIT III : CONCEPT OF RESTRUCTURING & DEREGULATION 07
Introduction, Concept of restructuring and deregulation, Components of restructured systems,
Independent System Operator (ISO): Functions and responsibilities, Indian Electricity Act 2003 and
Electricity (Amendment) Act 2007, Concept of Power Pooling and Cyber Security
UNIT IV : SMART GRID 13
Concept of a smart grid, Real time information infrastructure power grid, Substation information
architecture, Evolution of Electric Grid, Concept of micro grid, classifications of microgrid, applications
of micro grid, formation of micro grid, Concept of Smart Grid, Definitions, Need of Smart Grid,
Functions of Smart Grid, Difference between conventional & smart grid, Concept of Resilient & Self-
Healing Grid, Recent development, A case study of Smart Grid, Automatic Meter Reading (AMR),
Outage Management System (OMS), Plug in Hybrid Electric Vehicles (PHEV), Vehicle to Grid,
25 Approved BoS May 2018 (AY 2018-19)
Introduction to Wide area measurement systems (WAMS), Phase shifting transformers.,
TOTAL HOURS 44
Texts and References:
1 P. Kundur,“Power system stability and control”
2 Hingorani, “Understanding FACTS”, IEEE press
3 H. Lee Willis and Walter G. Scott,“Distributed Power Generation: Planning and Evaluation-Power
Engineering”
4 Kimbark, “Direct current transmission”, Wiley-Interscience
5 V. Kamaraju, “HVDC transmission”, Tata McGraw Hill
6 Padiyar, “HVDC power transmission systems”, New age international (P) Limited, 2007
7 K.R Padiyar, “FACTS Controllers In Power Transmission And Distribution”, New Age
International (P) Limited, 2007
8 JanakaEkanayake, N. Jenkins, K. Liyanage, J. Wu, Akihiko Yokoyama, “Smart Grid: Technology
and Applications”, Wiley
26 Approved BoS May 2018 (AY 2018-19)
Semester VI
Course Code: 16EE313T COURSE:DEPARTMENT ELECTIVE – I
ELECTRIC DRIVES
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
Prerequisites : Analog and Digital Electronics, Electrical Machines I & II, Power Electronics
Course Objectives:
- To understand the significance of electric drives in present industrial scenario
- To get sound idea about the fundamental concepts, objectives and elements of electric drives
- To understand the basic operating characteristics of electric motors and power converters
- To get a fair knowledge about the operational analysis, applications, features and control of dc
and ac motor drives
UNIT I : FUNDAMENTALS OF ELECTRIC DRIVES 10
Introduction to Electric Drives, Significance of Electric Drives, Elements of Electric Drives, Fundamental
Torque Equation, Four Quadrant Operation, Classification of Load Torque, Steady State Stability, Basic
Design of Electric Drives
UNIT II : DC MOTOR DRIVES 10
Introduction to dc Motors, Starting and Braking of dc Motors, Conventional Techniques for Speed
Control of dc Motors (Armature Voltage Control and Field Control), Solid State Control of dc Motors,
Controlled Rectifier fed dc Motor Drives, Chopper fed dc Motor drives
UNIT III : INDUCTION MOTOR DRIVES 15
Introduction to Induction Motors, Starting and Braking of Induction Motors, Impact of Unbalanced Stator
Voltage on Motor Performance, Impact of Non-Sinusoidal Stator Voltage on Motor Performance,
Conventional Techniques for Speed Control of Induction Motors (Stator Voltage Control, Pole Changing
Method, Rotor Resistance Control, Frequency Control, Slip Power Recovery Scheme), Solid State
Control of Induction Motors, ac Voltage Controller based Induction Motor Drives, VSI fed Induction
Motor Drives, Scalar Control, Static Rotor Resistance Control, Static Kramer Drive, Static Scherbius
Drive, CSI fed Induction Motor Drives
UNIT IV: PERMANENT MAGNET BRUSHLESS DC MOTOR DRIVES 09
Permanent Magnet Materials, PMBL dc Motors, Applications, Construction, Operating Principle &
Characteristics, Electronic Commutation, Mathematical Modelling, Hall Effect Sensors for Position
Measurement, Speed Control of PMBL dc Motors
TOTAL HOURS 44
Texts and References:
1 G. K. Dubey, “Fundamentals of Electrical Drives,” 2nd Edition, Narosa Publication.
2 R. Krishnan, “Electric Motor Drives: Modelling Analysis and Control,” Prentice Hall Inc.
3 B. K. Bose, “Modern Power Electronics and ac Drives,” Prentice Hall Inc.
4 B. K. Bose, “Power Electronics and Variable Frequency Drives: Technology and Applications,”
27 Approved BoS May 2018 (AY 2018-19)
Wiley Publications.
5 VedamSubramanyam, “Electric Drives – Concepts and Applications,” Tata McGraw –Hill.
28 Approved BoS May 2018 (AY 2018-19)
Semester VI
Course Code: 16EE314P Course: LABORATORY – I
SWITCHGEAR & PROTECTION
Teaching Scheme Examination Scheme
L T P C Hrs/Week Theory Practical Total
Marks MS ES IA LW LE/Viva
-- -- 3 1.5 3 -- -- -- 50 50 100
List of Experiments:
1. Introduction & familiarization with the laboratory
2. Study & Performance of MCB, ELCB, FUSE & plotting their performance characteristic
3. Study of the construction & Operation of Electromechanical Relay
4. Testing, Calibration of Electromechanical Over Current Relays (Normal Inverse, Very Inverse &
Extreme Inverse Characteristics)
5. Principles of Radial feeder Protection – Calculations, Relay Settings
6. Principles of Radial feeder Protection – Verifications through Hardware Simulations
7. Study & familiarization of Numerical Relay
8. Principles of Over Voltage & Under voltage Protection – Calculations, Relay Settings
9. Principles of Over Voltage & Under voltage Protection – Verifications through Hardware
Simulations
10. Principles of Parallel feeder Protection - Calculations, Relay Settings
11. Principles of Parallel feeder Protection– Verification through Hardware Simulations
12. Principles of Transformer Protection - Calculations, Relay Settings
13. Principles of Transformer Protection -Verification through Hardware Simulations
14. Principles of Transmission Line Protection (Distance Protection) – Calculations , Relay Settings
& Verification through hardware simulations
15. Principles of Transmission Line Protection (Carrier Current Protection) – Calculations , Relay
Settings & Verification through hardware simulations
16. Principles of Induction Motor Protection- Calculations , Relay Settings & Verification through
hardware simulations
17. Principles of Generator Protection- Calculations & Relay Settings
18. Principles of Generator Protection -Verification through hardware simulation
NOTE: Course coordinator needs to ensure that at least 80% of the experiments listed are covered during
the semester
29 Approved BoS May 2018 (AY 2018-19)
Semester VI
Course Code: 16EE315P Course: LABORATORY-II
HIGH VOLTAGE & RENEWABLE ENERGY
Teaching Scheme Examination Scheme
L T P C Hrs/Week Theory Practical Total
Marks MS ES IA LW LE/Viva
-- -- 3 1.5 3 -- -- -- 50 50 100
PART-1 : HIGH VOLTAGE ENGINEERING
List of Experiments:
1. Design, planning and layout of the high voltage laboratory.
2. To measure the breakdown strength of transformer oil.
3. To measure the insulation level of solid material.
4. To determine the breakdown characteristics of air for different types/shapes of electrodes
5. Electric field plotting by electrolytic tank
6. To Measure the A.C. Voltage using Rod gap apparatus
7. To Measure the D.C. Voltage using sphere gap apparatus
8. To understand the components, control and operation of 140kV, 1kJ impulse generator and observe
the Impulse Voltage waveform as per IS (1.2/50 microseconds) on digital storage oscilloscope
9. To perform generation of switching surges impulse wave.
10. To study the phenomenon of corona formation (using horn gap Apparatus).
11. Testing of 11kV pin insulator
PART-2 : RENEWABLE ENERGY ENGINEERING
List of Experiments:
1. To calculate the power consumption of various electrical appliances at home, hostel and college
laboratories
2. To demonstrate the I-V and P-V characteristics of PV module with varying radiation
and temperature level
3. To demonstrate the I-V and P-V characteristics of series and parallel combination of PV modules
4. To demonstrate the effect of variation in tilt angle on PV module power
5. To demonstrate the effect of shading on the output power of PV Panel connected in Series and
Parallel
6. To demonstrate the working of diode as Bypass diode and blocking diode
7. To workout power flow calculations of standalone PV system of DC load with battery
8. To evaluate the cut-in speed of wind turbine experimentally using Wind energy training system
9. To evaluate the Tip Speed ratio (TSR) at different wind speeds using Wind energy training system.
10. To evaluate the coefficient of performance of wind turbine using Wind energy training system.
11. To determine the turbine power versus wind speed curve using Wind energy training system.
12. To carry out simulation study related to solar/wind energy conversion system.
NOTE: Course coordinator needs to ensure that at least 80% of the experiments listed in each part are
covered during the semester